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WO1992017192A1 - Fragments therapeutiques du facteur willebrand - Google Patents

Fragments therapeutiques du facteur willebrand Download PDF

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Publication number
WO1992017192A1
WO1992017192A1 PCT/US1992/002475 US9202475W WO9217192A1 WO 1992017192 A1 WO1992017192 A1 WO 1992017192A1 US 9202475 W US9202475 W US 9202475W WO 9217192 A1 WO9217192 A1 WO 9217192A1
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WIPO (PCT)
Prior art keywords
vwf
polypeptide
fragment
subunit
von willebrand
Prior art date
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PCT/US1992/002475
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English (en)
Inventor
Zaverio M. Ruggeri
Jerry L. Ware
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The Scripps Research Institute
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Publication date
Application filed by The Scripps Research Institute filed Critical The Scripps Research Institute
Priority to EP92909515A priority Critical patent/EP0648268A1/fr
Publication of WO1992017192A1 publication Critical patent/WO1992017192A1/fr

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    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K14/00Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
    • C07K14/435Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from animals; from humans
    • C07K14/745Blood coagulation or fibrinolysis factors
    • C07K14/755Factors VIII, e.g. factor VIII C (AHF), factor VIII Ag (VWF)
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K16/00Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies
    • C07K16/18Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from animals or humans
    • C07K16/36Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from animals or humans against blood coagulation factors
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K38/00Medicinal preparations containing peptides

Definitions

  • This invention relates to polypeptides which are useful in the treatment of vascular disorders such as thrombosis.
  • This invention relates also to polypeptides which are useful in the treatment of hemorrhagic diseases, such as von Willebrand disease (vWD) .
  • This invention further relates to the production by reco binant DNA-directed methods of pharmacologically useful quantities of the polypeptides of the present invention.
  • hemostasis refers to those processes which comprise the defense mechanisms of the body against loss of circulating blood caused by vascular injury. Processes which are normal as a physiologic response to vascular injury may lead in pathologic circumstances, such as in a patient afflicted with atherosclerotic vascular disease or chronic congestive heart failure, to the formation of undesired thrombi (clots) with resultant vascular occlusion.
  • Impairment of blood flow to organs under such circumstances may lead to severe pathologic states, including myocardial infarction, a leading cause of mortality in developed countries.
  • the restriction or termination of the flow of blood within the circulatory system in response to a wound or as a result of a vascular disease state involves a complex series of reactions which can be divided into two processes, primary and secondary hemostasis.
  • Primary hemostasis refers to the process of platelet plug or soft clot formation.
  • the platelets are non-nucleated discoid structures approximately 2-5 microns in diameter derived from egakaryocytic cells.
  • Effective primary hemostasis is accomplished by platelet adhesion, the interaction of platelets with the surface of damaged vascular endothelium on which are exposed underlying collagen fibers and/or other adhesive macromolecules such as proteoglycans and glycosaminoglycans to which platelets bind.
  • Therapeutic drugs for controlling thrombosis have been classified according to the stage of hemostasis which is affected by the administration thereof.
  • Such prior art compositions are typically classified as anticoagulants, thrombolytics and platelet inhibitors.
  • the anticoagulant therapeutics typically represent a class of drugs which intervene in secondary hemostasis. Anticoagulants typically have no direct effect on an established thrombus, nor do they reverse tissue damage. Associated with the use of existing anticoagulants is the hazard of hemorrhage, which may under some conditions be greater than the clinical benefits otherwise provided by the use thereof. As a result, anticoagulant therapy must be closely monitored. Certain anticoagulants act by inhibiting the synthesis of vitamin K-dependent coagulation factors resulting in the sequential depression of, for example, factors II, VII, IX, and X. Representative anticoagulants which are used clinically include coumarin, dicoumarol, phenindione, and phenprocoumon.
  • Thrombolytics act by lysing thrombi after they have been formed.
  • Thrombolytics such as streptokinase and urokinase have been indicated for the management of acute myocardial infarctions and have been used successfully to remove intravascular clots if administered soon after thrombosis occurs.
  • the lysis effected thereby may be incomplete and nonspecific, i.e., useful plasma fibrinogen, in addition to fibrin polymers within clots, is affected.
  • a common adverse reaction associated with the use of such therapeutics is hemorrhage.
  • a third classification, antiplatelet drugs includes drugs which suppress primary hemostasis by altering platelets or their interaction with other circulatory system components.
  • the present invention relates to this classification of antiplatelet drugs.
  • Specific antiplatelet drugs operate by one or several mechanisms.
  • a first example involves reducing the availability of ionized calcium within the platelet cytoplasm thereby impairing activation of the platelet and resultant aggregation.
  • Pharmaceuticals representative of this strategy include prostacyclin, and also Persatine ® (dipyridamole) which may affect calcium concentrations by affecting the concentration of cyclic AMP. Numerous side effects related to the administration of these compounds have been reported.
  • An additional class of antiplatelet drugs acts by inhibiting the synthesis of thromboxane A 2 within the platelet, reducing the platelet activation response.
  • Non-steroidal anti- inflammatory agents such as ibuprofen, phenolbutazone and napthroxane may produce a similar effect by competitive inhibition of a particular cyclooxygenase enzyme, which catalyzes the synthesis of a precursor of thromboxane A 2 .
  • a similar therapeutic effect may be derived through the administration of aspirin which has been demonstrated to irreversably acetylate a cyclooxygenase enzyme necessary to generate thromboxane A 2 .
  • a third anti-platelet mechanism has involved the platelet membrane so as to interfere with surface receptor function.
  • ticlopidene a large branched polysaccharide, which is believed to impair the interaction of fibrinogen with platelet receptors that are exposed during aggregation.
  • Dextran is contraindicated for patients with a history of renal problems or with cardiac impairment.
  • the therapeutic ticlopidine is stated to inhibit platelet adhesion and aggregation by suppressing the binding of von Willebrand factor and/or fibrinogen to their respective receptors on the platelet surface.
  • ticlopidene possesses insufficient specificity to eliminate the necessity of administering large doses which, in turn, may be associated with clinical side effects.
  • the aforementioned pharmaceuticals are foreign to the body and may cause numerous adverse clinical side effects, there being no way to prevent such compounds from participating in other aspects of a patient's physiology or biochemistry, particularly if high doses are required. It would be desirable to provide for pharmaceuticals having such specificity for certain of the reactions of hemostasis, that they could be administered to patients at low doses, such doses being much less likely to produce adverse effects in patients.
  • An example of a pharmaceutical which is representative of a therapeutic that is derived from natural components of the hemostatic process is described in EPO Publication No. 317278. This publication discloses a method for inhibiting thrombosis in a patient by administering to the patient a therapeutic polypeptide comprised of the amino-terminal region of the ⁇ chain of platelet membrane glycoprotein lb, or a subfragment thereof.
  • the present invention is directed to the provision of antithrombotic polypeptides derived from a von Willebrand factor, one of the proteins of the hemostatic mechanism.
  • vWF von Willebrand factor
  • this invention provides for host cells containing recombinant vWF DNA sequences in which are expressed biologically active and therapeutically useful polypeptides related to the 52/48 kg/mole (kg/mol) tryptic fragment or domain of mature vWF subunit.
  • polypeptides when present in monomeric form, may be used as antithrombotic agents. In dimerized form they can be used as antihemorrhagic agents. When expressed in mammalian host cells, such polypeptides are typically also glycosylated.
  • biologically active polypeptides which are effective in preventing adhesion of platelets to surfaces, in inhibiting activation or aggregation of platelets, and in inhibiting thrombosis. More specifically there are provided polypeptides which are effective in inhibiting the binding of von Willebrand factor multimers to platelet membrane glycoprotein Ib ⁇ and which are created by expression in host cells of DNA sequences which reflect one or more mutations determined from the vWF gene in one or more patients having Type IIB von Willebrand disease, said mutations providing in whole, or in part, the molecular basis for the disease.
  • a process for producing from DNA encoding mature von Willebrand factor subunit, or a fragment thereof, a biologically active polypeptide which process comprises the steps of (A) providing a DNA sequence encoding a mature vWF subunit, or a fragment thereof, in which one or more wild type codons are replaced by codons specifying one or more amino acid mutations found in the vWF DNA sequence of one or more Type IIB von Willebrand disease patients; (B) inserting the DNA sequence so provided into a suitable vector to create a construct comprising an expression plasmid or viral expression vector, said construct being capable of directing the expression in cells of said biologically active polypeptide; (C) transforming a host cell with said construct; and (D) culturing said transformed host cell under conditions which cause expression within said host cell of the polypeptide.
  • Known mutations reflective of the genotype and phenotype of Type IIB von Willebrand disease and suitable for incorporation into the DNA sequences useful in the practice of the invention include Trp 550 ⁇ Cys 550 ; Arg 511 ⁇ Trp sn ; Arg 5 * 3 ⁇ Trp 543 ; Val 553 ⁇ Met 553 ; and Gly 561 ⁇ Asp 561 . It is believed that the invention, and the mutagenesis and protein expression procedures thereof, will be widely practiced in the art to generate mutant fragments of mature von Willebrand factor subunit with improved therapeutic utility.
  • Particularly useful examples of antithrombotic polypeptides produced according to the practice of the invention include the following:
  • A a monomeric polypeptide patterned upon a parent polypeptide which comprises the amino acid sequence of that fragment of mature von Willebrand factor subunit beginning approximately at residue 441 (arginine) and ending approximately at residue 730 (asparagine) , or a subfragment thereof, in which when compared to the parent polypeptide, one or more amino acid residues thereof are replaced by the corresponding residues found at the equivalent sequence positions of mature vWF subunit as isolated from one or more humans with Type IIB von Willebrand disease; and
  • (H) isolating the mutant vWF-derived polypeptide produced thereby.
  • von Willebrand factor is an unusually large, multivalent plasma protein that is involved in platelet adhesion to the subendothelium and in the formation of platelet plugs at sites of vascular injury. Due specially to its multivalent character, the protein links platelets to each other, to collagen and to glycosaminoglycans and proteoglycans, and also protects and then localizes coagulation factor VIII to the site of a forming blood clot.
  • the bivalent or multivalent character of circulating vWF and the multiple potential functions of each mature subunit thereof provide a unique opportunity to affect in vivo binding properties through mutagenesis of or covalent alteration of the relevant binding sites.
  • a process for producing a polypeptide useful for treating or inhibiting thrombosis said polypeptide being patterned upon the wild type mature vWF subunit, or a fragment thereof, and being derived therefrom as follows:
  • mutant vWF DNA sequence providing a mutant vWF DNA sequence, said mutant sequence being characterized as encoding a mature vWF subunit, or a fragment thereof, the encoded polypeptide having, relative to the corresponding wild type polypeptide sequence, an increased binding affinity for one or more of collagen, glycosaminoglycans, proteoglycans, platelet glycoprotein Ib ⁇ , platelet glycoprotein Ilb/IIIa or coagulation factor VIII;
  • Polypeptides of the present invention possess high specificity for target binding domains on other macromolecules, including platelet receptors involved in the hemostatic mechanism. Generally speaking, polypeptides of the present invention are believed to function by preventing platelet adhesion, activation and aggregation, and are expected to be effective at concentrations which are not associated with clinically disadvantageous side effects.
  • Figure 1 is a table which shows the previously reported amino acid and DNA sequence for the mature von Willebrand factor subunit (human) between residue 431 and residue 750 thereof (see also SEQ ID NO: 1) .
  • Figure 2 is a drawing of the disulfide dependent association of two 52/48 kg/mol vWF fragments to form a 116 kg/mol homodimer.
  • Figure 3 is a graph which shows the effect of two Type IIB mutations on the ability of bacterially expressed vWF fragments to bind to platelets.
  • Figure 4 is a graph which shows the effect of a single Type IIB mutation on the ability of bacterially-expressed vWF fragments to bind platelets at two different concentrations of a monoclonal antibody which competes with vWF fragments for platelet GPIb ⁇ receptor.
  • Figure 5 is a map of the pCDM8 plasmid.
  • Figure 6 is a graph which shows the effect of the Trp 550 ⁇ Cys 550 mutation on the affinity of the reduced and alkylated 36 kg/mol vWF fragment for platelet GPIb ⁇ receptor.
  • Figure 7 is a graph which shows the effect of the Trp 550 ⁇ Cys 550 mutation on the affinity of the 116 kg/mol homodimeric vWF fragment for platelet GPIb ⁇ receptor.
  • Codon A DNA sequence of three nucleotides (a triplet) which encodes through mRNA an amino acid, a translation start signal or a translation termination signal.
  • the DNA nucleotide triplets TTA, TTG, CTT, CTC, CTA and CTG encode the amino acid leucine ("Leu") ;
  • TAG, TAA and TGA are translation stop signals;
  • ATG is a translation start signal encoding methionine.
  • Structural Gene A DNA sequence which encodes through its corresponding messenger RNA ("mRNA”) a sequence of amino acids characteristic of a specific polypeptide.
  • Structural genes may also have RNAs as their primary product such as transfer RNAs (tRNAs) or ribosomal RNAs (rRNAs) .
  • Transcription The process of producing RNA from a structural gene.
  • Coding * Sequence (Encoding DNA) - DNA sequences which, in the appropriate reading frame, code for the amino acids of a protein.
  • synthesis or use of a coding sequence may necessarily involve synthesis or use of the corresponding complementary strand, as shown by: 5'-CGG-GGA-GGA-3'/3'- GCC-CCT- CCT-5' which "encodes" the tripeptide NH 2 -arg-gly- gly-CO j H.
  • cDNA - A DNA molecule or sequence which has been enzymatically synthesized from the sequence(s) present in an mRNA template.
  • Transcribed Strand The DNA strand whose nucleotide sequence is read 3' ⁇ 5' by RNA polymerase to produce mRNA. This strand is also referred to as the noncoding strand. Coding Strand or Non-Transcribed Strand - This strand is the antiparallel compliment of the transcribed strand and has a base sequence identical to that of the mRNA produced from the transcribed strand except that thymine bases are present (instead of uracil bases of the mRNA) . It is referred to as "coding" because like mRNA, and when examined 5' -* 3', the codons for translation may be directly discerned. Expression - The process undergone by a structural gene to produce a product. In the case of a protein product, it is a combination of transcription and translation. Mutation - A hereditable change in the genetic information of a DNA molecule.
  • Recombinant DNA Molecule - A molecule consisting of segments of DNA from different genomes which have been joined end-to- end and have, or can be modified to have, the capacity to infect some host cell and be maintained therein.
  • Replicon the DNA required for replication in a particular organism. It includes an origin of replication.
  • Biological Activity One or more functions, effects of, activities performed or caused by a molecule in a biological context (that is, in an organism or in an in vitro facsimile) .
  • a characteristic biological activity of the 116 kg/mol homodimeric fragment of the mature von Willebrand factor subunit is the potential ability to bind to more than one platelet GPIb receptor thereby enabling the molecule to facilitate aggregation of platelets in the presence of ristocetin.
  • Other resultant or related effects of the 116 kg/mol species include function as a thrombotic and the induction of platelet activation, and/or adhesion to surfaces.
  • Such a fragment has therapeutic utility in the treatment of von Willebrand disease, as an antihemorrhagic agent.
  • a characteristic biological activity of the 52/48 kg/mol monomeric fragment of the mature von Willebrand factor subunit is the potential ability to bind to only one platelet GPIb receptor thereby enabling the molecule to inhibit botrocetin-induced binding of multimeric vWF to platelets.
  • Other resultant or related effects of the undimerized 52/48 kg/mol species include inhibition of platelet activation, aggregation, or adhesion to surfaces.
  • such a fragment has therapeutic utility as an antithrombotic agent.
  • Mutant Polypeptide A polypeptide derived from DNA encoding a parent polypeptide, the DNA having been mutated leading to the presence of one or more altered codons which dictate the placement, during translation, into the mutant polypeptide amino acid sequence of one or more substitute amino acids.
  • Reducing Conditions Refers to the presence of a "reducing" agent in a solution containing von Willebrand factor, or polypeptides derived therefrom, which agent causes the disruption of disulfide bonds of the vWF.
  • the "reducing" agent such as dithiothreitol (DTT) causes a vWF disulfide bond to be broken by forming a disulfide bond between a vWF cysteine and the DTT with no net change in oxidation state of the involved sulfur atoms.
  • DTT dithiothreitol
  • Phage or Bacteriophage - Bacterial virus many of which consist of DNA sequences encapsulated in a protein envelope or coat ("capsid") . Promoter - DNA sequences upstream from a gene which promote its transcription.
  • Cloning Vehicle - A plasmid, phage DNA or other DNA sequence which is able to replicate in a host cell, typically characterized by one or a small number of endonuclease recognition sites at which such DNA sequences may be cut in a determinable fashion for the insertion of heterologous DNA without attendant loss of an essential biological function of the DNA, e.g., replication, production of coat proteins or loss of expression control regions such as promoters or binding sites, and which may contain a selectable gene marker suitable for use in the identification of host cells transformed therewith, e.g., tetracycline resistance or ampicillin resistance.
  • a selectable gene marker suitable for use in the identification of host cells transformed therewith, e.g., tetracycline resistance or ampicillin resistance.
  • Plasmid - A nonchromosomal double-stranded DNA sequence comprising an intact "replicon" such that the plasmid is replicated in a host cell.
  • the characteristics of that cell may be changed (or transformed) as a result of the DNA of the plasmid.
  • a plasmid carrying the gene for tetracycline resistance (Tet R ) transforms a cell previously sensitive to tetracycline into one which is resistant to it.
  • a cell transformed by a plasmid is called a "transformant.”
  • Cloning The process of obtaining a population of organisms, or DNA sequences or other macromolecules derived from one such organism or sequence by asexual reproduction or DNA replication.
  • Expression Plasmid A plasmid into which has been inserted the DNA being cloned, such as the von Willebrand factor structural gene.
  • the DNA sequence inserted therein may also contain sequences which control the translation of mRNA resultant therefrom, and contain restriction endonuclease sites which facilitated assembly of, and may facilitate further modification of, said expression plasmid.
  • An expression plasmid is capable of directing, in a host cell, the expression therein of the encoded polypeptide and usually contains a transcription promoter upstream from the DNA sequence of the encoded structural gene.
  • An expression plasmid may or may not become integrated into the host chromosomal DNA.
  • an integrated plasmid is nonetheless referred to as an expression plasmid.
  • Viral Expression Vector - A viral expression vector is similar to an expression plasmid except that the DNA may be packaged into a viral particle that can transfect cells through a natural biological process.
  • a nucleotide of the transcribed strand of a structural gene is said to be downstream from another section of the gene if the nucleotide is normally read by RNA polymerase after the earlier section of the gene.
  • the complimentary nucleotide of the nontranscribed strand, or the corresponding base pair within the double stranded form of the DNA, are also denominated downstream.
  • a restriction endonuclease sequence added upstream (or 5') to the gene means it is added before the sequence encoding the amino terminal end of the protein, while a modification created downstream (or 3') to the structural gene means that it is beyond the carboxy terminus-encoding region thereof.
  • von Willebrand factor fvWF - It is understood that all references herein to von Willebrand factor refer to vWF in humans. The term "von Willebrand factor" is intended to include within its scope any and all of the terms which are defined below.
  • Pre-pro-vWF von Willebrand factor is subject to extensive posttranslational processing.
  • "Pre-pro-vWF” contains (from the N to the C terminus) a signal peptide comprised of approximately 22 amino acid residues, a propeptide of approximately 741 amino acids, and then the approximate 2,050 residues of circulating vWF.
  • Pro-vWF - The signal peptide has been removed from pre-pro- vWF.
  • vWF - Circulating vWF as found in the plasma or as bound to the subendothelium. It consists of a population of polypeptide monomers which are typically associated into numerous species of multimers thereof, each subunit of which being 2,050 residues in length. Additionally, when expressed in mammalian cells, mature vWF is usually glycosylated. Additionally, von Willebrand factor is found as a component of the subendothelial matrix, as a component of the ⁇ -granules secreted by activated platelets, and as a circulating blood plasma protein. It is possible that the three-dimensional subunit structure or multisubunit structure of vWF varies in these different contexts potentially caused, for example, by differences in glycosylation. Such differences do not prevent useful therapeutic vWF-derived polypeptides from being produced from the vWF DNA sequences of endothelial cells or megakaryocytes according to the practice of this invention.
  • Heparin Binding Site - A domain comprised of one or more regions of amino acid primary sequences of one or more mature vWF subunits having a specific binding affinity for heparin and/or other glycosaminoglycans and/or one or more species of proteoglycans.
  • von Willebrand factor contains binding sites having affinity for glycosaminoglycans, said sites being known to demonstrate affinity for heparin or other glycosaminoglycans patterned upon repeating units similar to those of heparin. Because of these "heparin binding sites," vWF also has affinity for proteoglycans (glycosaminoglycans anchored to a protein core) typically found in the subendothelium.
  • a signal peptide is the sequence of amino acids in a newly translated polypeptide which signals translocation of the polypeptide across the membrane of the endoplasmi ⁇ reticulum and into the secretory pathway of the cell.
  • a signal peptide typically occurs at the beginning (amino terminus) of the protein and is 20-40 amino acids long with a stretch of approximately 5-15 hydrophobic amino acids in its center.
  • the signal sequence is proteolytically cleaved from the protein during, or soon after, the process of translocation into the endoplasmic reticulum. That portion of a gene or cDNA encoding a signal peptide may also be referred to as a .signal sequence.
  • Wild Type Amino Acid Sequence - refers to the amino acid sequence of mature vWF subunit, or of a fragment thereof, which is present in the large majority of humans, and refers also to any mutant amino acid sequence as isolated from vWF of a particular person if no detectable functional differences in the vWF with respect to its interaction with GPIb ⁇ result therefrom in humans.
  • Modified Amino Acid Sequence - reflects any change in the primary structure of a sequence of amino acids of mature vWF subunit compared to wild type sequence.
  • modifications with respect to one or more amino acid residues at one or more primary sequence positions in a polypeptide include deletions, additions, substitutions and the covalent labelling of amino acids present therein or the addition of amino acids containing such labels, i.e., radicals or blocking groups which affect the properties of the amino acid residues so labelled.
  • Peptide - for the purposes of this invention, the terms "peptide” and “polypeptide” are interchangable. Purified or Substantially in Pure Form - when used with respect to one or more vWF-encoding DNAs or vWF-derived polypeptides, these and similar terms mean that the- composition is substantially free of most of the cellular protoplasm, non vWF-protein, or extracellular material with which the DNA or polypeptide normally occurs in the body. Monomeric - when used with respect to polypeptides, “monomeric” refers to a polypeptide which is not covalently linked to another polypeptide. “Dimeric” refers to a covalent association of two monomers.
  • Fragment - when used with respect to vWF subunit refers to any sequence composed of less than the 2,050 amino acid residues of the mature subunit which can be generated by deleting one or more residues from either the amino or the carboxy terminals of said subunit, or by deletion of one or more residues within the subunit.
  • the term refers to any combination of subunits and/or fragments of subunits having a combined molecular weight less than about 30 times the weight of a single subunit.
  • vWF-Derived Polypeptide - a vWF-derived polypeptide refers to any amino acid sequence which is patterned upon the 2,050 residue mature vWF subunit sequence, or any combinations of subsets thereof, and which contains any of the above defined "modifications". Such derived polypeptides can be made through expression of an appropriate encoding DNA or by chemical modification of vWF subunit or a fragment thereof.
  • Other terms used in connection with the description of vWF- derived polypeptides of the invention include "comparable wild type sequence" and "equivalent sequence position" which are best described by way of example.
  • the "comparable wild type sequence” is the 441-730 fragment containing tryptophan at position 550.
  • "Equivalent sequence position” means that the substituted amino acid (for example Cys 550 ) occupies the same position in the vWF-derived polypeptide (position 550) as in the amino acid sequence of vWF subunit from the Type IIB patient from which the mutation was identified, and thus, for example, the incorporation of a Trp 550 ⁇ Cys 550 mutation into a vWF-derived polypeptide would not affect the positioning of Lys 549 or Val 551 .
  • Table 1 shows the standard three letter designations for amino acids as used in the application.
  • vWF performs an essential role in normal hemostasis during vascular injury and is also of central importance in the pathogenesis of acute thrombotic occlusions in diseased blood vessels. Both of these roles involve the interaction of vWF with platelets which are induced to bind at the affected site and are then crosslinked. It is believed that single platelets first adhere to a thrombogenic surface after which they become activated, a process involving major metabolic changes and significant morphological changes within the platelet.
  • Activation is evidenced by the discharge of platelet storage granules containing adhesive substances such as von Willebrand factor (an adhesive protein) , and the expression on the surface of the platelet of additional functional adhesive sites.
  • von Willebrand factor an adhesive protein
  • Platelet thrombus formation during surgical procedures may also interfere with attempts to relieve preexisting vessel obstructions.
  • the adhesion of platelets to damaged or diseased vessels occurs through mechanisms that involve specific platelet membrane receptors which interact with specialized adhesive molecules.
  • One such platelet receptor is the glycoprotein Ib-IX complex which consists of a noncovalent association of two integral membrane proteins, glycoprotein lb (GPIb) and glycoprotein IX (GPIX) .
  • the adhesive ligand of the GPIb-IX complex is the protein von Willebrand factor which is found as a component of the subendothelial matrix, as a component of the ⁇ -granules secreted by activated platelets, and also as a circulating blood plasma protein.
  • the actual binding site of the vWF to the GPIb-IX receptor has been localized on the amino terminal region of the ⁇ chain of glycoprotein lb which is represented by GPIb( ⁇ ) .
  • von Willebrand factor exists as a series of high molecular weight multimers of up to 30 glycosylated subunits per multimer in which the subunits are believed to be identical, with each having an approximate molecular weight of 270,000 (270 kg/mol).
  • vWF surface bound multimeric vWF binds on the one side to components of the subendothelium, such as collagen or proteoglycans, and on the other side to the GPIb-IX receptor of a platelet membrane.
  • Evidence that von Willebrand factor is necessary for thrombus formation has been provided by studies using anti-vWF monoclonal antibodies to induce a deficieny in circulating vWF, Bellinger, D.A. et al. , Proc. Natl. Acad. Sci..
  • vWF glycoprotein Ib-IX complex
  • GPIb( ⁇ ) glycoprotein Ib-IX complex
  • the rapidly accumulating platelets are also crosslinked (aggregated) by the binding of fibrinogen at platelet glycoprotein Hb-IIIa receptor sites, and possibly also by vWF at these sites, and/or at additional glycoprotein Ib-IX receptor sites.
  • the glycoprotein Ilb/IIIa receptor may also be involved in the formation of the initial monolayer of platelets.
  • the multimeric and multivalent character of circulating vWF which enables the macromolecule to effectively carry out its binding and bridging functions.
  • the present invention relates to the development of polypeptides which are effective in accomplishing the foregoing. Although preventing unwanted thrombi is of great importance, there are circumstances where promoting thrombus formation is desirable.
  • von Willebrand disease the most common of the bleeding disorders, is the term used to describe a heterogeneous disease state which results when von Willebrand factor is produced in inadequate quantities or when circulating vWF molecules are somehow defective.
  • Various subtypes of the disease have been described. It is apparent that supplying the bridging function of vWF is of central importance in the treatment of patients afflicted with von Willebrand disease.
  • the present invention is concerned with preparation of fragments of von Willebrand factor capable of performing a bridging function between the GPIb( ⁇ ) receptor or GPIIb/IIIa receptor of the platelet membrane and a receptor on another platelet, or between such a receptor and components of the subendothelium, thereby performing in affected individuals the crucial physiological role of native multimeric von Willebrand factor.
  • von Willebrand factor which circulates in the blood exists as a series of high molecular weight multimers containing up to 30 glycosylated subunits per multimer in which the subunits are believed to be identical, each having an approximate molecular weight of about 270 kg/mol.
  • the circulating "mature" human subunit consists of 2050 amino acid residues. Its structure is the final result of extensive post-translational processing, von Willebrand factor is synthesized in endothelial cells and megakaryocytes.
  • the vWF mRNA is comprised of approximately 9,000 bases and encodes for a polypeptide containing 2,813 amino acid residues. This protein is known as "pre-pro-vWF".
  • the von Willebrand factor subunit After translation and entry into the endoplasmic reticulum, the von Willebrand factor subunit is believed to rapidly dimerize via disulfide bonds involving the carboxy and amino termini regions of respective subunits. Associated with the passages of pre-pro-vWF into the endoplasmic reticulum is the cleavage of the 22 amino acid signal peptide resulting in the "pro-vWF" form of the polypeptide.
  • vWF subunits (each subunit now comprising 2050 amino acids) are assembled into multimers of larger size by formation of interchain disulfide bonds.
  • vWF protein from endothelial cells is either secreted constitutively or stored in Weibel-Palade bodies for later release.
  • vWF from megakaryocytes is packaged into the alpha granules of platelets and is secreted at the time of platelet activation.
  • the domain of the von Willebrand factor subunit which binds to the platelet membrane glycoprotein Ib-IX receptor (GPIb( ⁇ )) has been identified within a fragment of vWF.
  • the fragment may be generated by trypsin digestion, followed by disulfide reduction, and extends from approximately residue 449 (valine) of the circulating subunit to approximately residue 728 (lysine) thereof.
  • this segment also contains (between residues 509 and 695 thereof) binding domains for components of the subendothelium, such as collagen and proteoglycans, although other regions of the mature vWF subunit may be more important in recognizing these substances (an additional proteoglycan or heparin binding site is located in residues 1-272 of the mature subunit and an additional collagen binding site within residues 910-1110 thereof).
  • the tetrapeptide Arg-GlyAsp- Ser (SEQ ID NO: 2) (residues 1744 to 1747) , a sequence which vWF shares with many other adhesive proteins, is believed to represent the platelet glycoprotein Hb-IIIa binding site.
  • Amino acids are shown by standard three letter designations.
  • the DNA sequence is represented by the coding strand (non-transcribed strand) .
  • Very little polymorphism has been reported in the 52/48 human sequence with one significant exception - histidine/aspartic acid at position 709, see Mancuso, D.J. et al. J. Biol. Chem. , 264(33), 19514-19527, Table V, (1989). (See also SEQ ID NO:
  • polypeptides derived from the above mentioned region of the circulating (mature) von Willebrand factor subunit - from approximately residue 449 to approximately residue 728, or subsets thereof are considered useful as antithrombotic pharmaceuticals when added to blood in such sufficient amounts as to compete successfully with multimeric vWF for platelet GPlb( ⁇ ) receptor sites, thereby preventing monolayer formation by, or crosslinking of, the platelets in circumstances where thrombus formation is undesirable, such as in the treatment of vascular disorders.
  • the , 606 application identifies numerous publications which relate to the structure, function and molecular genetics of von Willebrand factor, such publications being incorporated herein by reference.
  • mutant therapeutic antithrombotic polypeptides of the present invention With respect to the mutant therapeutic antithrombotic polypeptides of the present invention, the following information concerning vWF is of particular interest.
  • a fragment of mature von Willebrand factor having platelet glycoprotein lb( ⁇ ) binding activity and of approximately 116,000 (116 kg/mol) molecular weight is isolated by digesting vWF with trypsin. If the 116 kg/mol fragment is treated with a reducing agent capable of cleaving disulfide bonds, a pair of identical fragments is generated. Each of the identical fragments (which together comprise the 116 kg/mol polypeptide) has an apparent molecular weight of about 52,000 (52 kg/mol). (Polypeptide molecular weight are typically measured by migration, relative to standards, in a denaturing gel electrophoresis system.
  • the 52,000 molecular weight fragment is referred to as a "52/48" fragment reflecting the fact that human enzyme systems glycosylate the fragment contributing to its molecular weight.
  • the amount of glycosylation varies from molecule to molecule, with two weights, 52,000 and 48,000, being most common.
  • the 52/48 fragment has been demonstrated to have as its amino-terminus residue 449 (valine) of the mature subunit, and as its carboxy-terminus residue 728 (lysine) thereof. Without the additional weight contributed by glycosylation, the polypeptide has a molecular weight of approximately 38,000.
  • the 52/48 fragment has been demonstrated to competitively inhibit the binding of von Willebrand factor to platelets.
  • manipulation of the 52/48 fragment or its unglycosylated 38 kg/mol equivalent has proved difficult.
  • Successful manipulation of the fragment has typically required that the cysteine residues thereof be reduced and permanently alkylated. Without this treatment, undesired reaction of the cysteine residues thereof invariably occurs, leading to the formation of insoluble and biologically inactive polypeptide aggregates unsuited for effective use as therapeutics.
  • the residue 449-728 fragment of mature von Willebrand factor subunit which contains the platelet glycoprotein Ib( ⁇ ) binding domain, has cysteine residues at positions 459, 462, 464, 471, 474, 509 and 695. It is known also that all of the cysteine residues of the mature vWF subunit are involved in disulfide bonds. (Legaz, et al. , J. Biol. Chem.. 248, 3946-3955 (1973)). Marti, T. et al. Biochemistry, 26, 8099-8109 (1987) conclusively identified mature subunit residues 471 and 474 as being involved in an intrachain disulfide bond. Residues 509 and 695 were identified as being involved in a disulfide bond, although it was not demonstrated whether this pairing was intrachain or interchain (that is, within the same mature vWF subunit) .
  • the epitope of NMC-4 was found to map into the same two discrete regions of the vWF amino acid sequence previously noted as having GPIb( ⁇ ) receptor binding capability (Leu ⁇ -Asp 498 and Glu 689 -Val 713 ) .
  • the epitope was demonstrated to require the simultaneous presence of amino acid sequence from both primary sequence regions as demonstrated by the binding of NMC-4 to the ho odimeric 116 kg/mol vWF subunit fragment in unreduced form but not to the reduced 52/48 fragment.
  • Cysteine is unique among the amino acids which typically form the primary sequence of proteins in that, with rare exceptions, it is the only amino acid which forms a covalent bond to another residue of the protein other than a backbone amide linkage, and-thereby alters the three-dimensional structure of the polypeptide.
  • the thiol group (SH) of a cysteine residue in a polypeptide is capable of combining with the equivalent group of another cysteine to form a covalent disulfide bridge (-S- S-) . Since cysteine residues otherwise far apart in the primary sequence of the molecule can be combined in this way, disulfide bonds are a potentially important factor in determining the three dimensional structure of a protein. In fact for many proteins, their structures, catalytic activities, or other functions require that certain disulfide bonds be formed.
  • the bond is defined as "intrachain.” If the cysteines forming a disulfide bond are found on different protein molecules, or polypeptides thereof, the bond is defined as "interchain.”
  • the fragment of mature von Willebrand factor subunit (approximate residues 449 to 728) which contains the platelet glycoprotein lb' ⁇ ) binding domain, and which is thus useful in the design of antithrombotic therapeutics, contains 7 cysteine residues, at positions 459, 462, 464, 471, 474, 509 and 695 thereof.
  • first embodiment of the invention involving recombinant DNA molecules expressed in host bacterial cells and suitable for the expression of therapeutic polypeptides patterned on vWF
  • second embodiment involving recombinant DNA molecules expressed in host eucaryotic cells and suitable for the expression of therapeutic polypeptides patterned on vWF
  • third embodiment of the invention comprising the construction and utilization of vWF-derived polypeptides reflecting enhanced affinity for GPIb ⁇ and patterned upon the polypeptides of the aforementioned first and second embodiments.
  • a first embodiment of the invention provides for polypeptides derived from the residue 449-728 region of the mature von Willebrand factor subunit which are useful in the treatment of vascular disorders such as thrombosis.
  • A a polypeptide patterned upon a parent polypeptide and comprising the amino acid sequence of that fragment of mature von Willebrand factor subunit which begins approximately at residue 441 (arginine) and ends at approximately residue 733 (valine) , or any subset thereof, in which one or more of the cysteine residues normally present in the parent polypeptide, or subset thereof, have been deleted and/or replaced by one or more other amino acids, said polypeptide having therefore less tendency than the parent polypeptide, or subset thereof, to form intra or interchain disulfide bonds in aqueous media at a physiological pH; and
  • Such molecules can be made from DNA which encodes that fragment of mature von Willebrand factor subunit comprising essentially the amino acid sequence from approximately residue 441 (arginine) to approximately residue 733 (valine) , or which encodes any subset of said amino acid sequence, a mutant polypeptide fragment, or subset thereof, which contains fewer cysteine residues than that of the comparable wild-type amino acid sequence.
  • Preparation of the molecules comprises culturing a host organism transformed with a biologically functional expression plasmid which contains a mutant DNA sequence encoding a portion of said von Willebrand factor subunit under conditions which effect expression of the mutant von Willebrand factor fragment, or a subset thereof, by the host organism and recovering said fragment therefrom.
  • the preferred means for effecting mutagenesis of cysteine codons in a vWF DNA to codons encoding amino acids incapable of disulfide bonding is based upon the site directed mutagenesis procedure of Kunkel, T.A. , Proc. Natl. Acad. Sci. U.S.A., 82, 488-492 (1985).
  • compositions of said vWF-derived polypeptides which are less prone to aggregation and denaturation caused by undesired disulfide bonding within the inclusion bodies of host expression cells (or resultant from inclusion body solubilization procedures) than previous preparations.
  • the development employs mutagenesis to limit the number of cysteine residues present within said polypeptides. More specifically, preparation of a mutant polypeptide fragment which corresponds to that fragment of mature von Willebrand subunit having an amino terminus at residue 441 (arginine) and a carboxy terminus at residue 733 (valine) , but which differs therefrom in that each of the cysteine residues thereof is replaced by a glycine residue is disclosed.
  • the embodiment also teaches that retention of a certain disulfide bond within polypeptides corresponding to the 449-728 vWF subunit region is particularly important for the design of therapeutic molecules derived therefrom.
  • Willebrand factor gene (for the pre-propeptide) was utilized.
  • the cDNA was then subjected to enzymatic amplification in a polymerase chain reaction using oligonucleotides which flanked the indicated region.
  • the first oligonucleotide representing coding strand DNA contained an EcoRI site 5' to the codon for residue 441 (arginine) and extended to the codon for residue 446 (glycine) .
  • the resultant double stranded von Willebrand factor cDNA corresponding to the amino acid sequence from residue 441 to residue 733 (of the mature subunit) was then inserted, using EcoRI and Hindlll restriction enzymes, into the double stranded replicative form of bacteriophage M13mpl8 which contains a multiple cloning site having compatible EcoRI and Hindlll sequences.
  • Kunkel, T.A. Proc. Natl. Acad. Sci. USA.
  • site directed mutagenesis was performed using hybridizing oligonucleotides suitable for replacing all of the cysteine codons (residue positions 459, 462, 464, 471, 474, 509 and 695) with individual glycine codons (see Example 1) or 5 of the cysteine codons (residue positions 459, 462, 464, 471 and 474) with individual glycine codons (see Example 4) .
  • Mutant double stranded vWF cDNA fragments derived from the procedure were removed from M13mpl8 phage by treatment with EcoRI and Hindlll restriction endonucleases, after which the ends of the vWF cDNA fragments were modified with BamHI linkers.
  • mutant vWF cDNA containing either 5 or 7 Cys to Gly mutations
  • pET-3A expression vector see Rosenberg, A.H. et al.. Gene. 56, 125-136 (1987)
  • pET-3A vehicle containing cDNA for the vWF subunit fragment with 7 cysteine to glycine mutations is referred to as "p7E", and as "p5E” when the contained vWF cDNA fragment encoded the 5 above specified cysteine to glycine mutations.
  • Mutant von Willebrand factor polypeptides produced by bacterial cultures containing expression plasmid p5E were compared with those expressed from cultures containing p7E plasmids.
  • the p5E molecule is capable of forming a disulfide bond between cysteine residue 509 and 695 whereas the p7E molecule cannot.
  • the behavior of p5E and p7E extracts was examined using immunological methods (see Example 5) .
  • vWF-specific urine monoclonal antibodies RG-46 and NMC-4 were used as probes.
  • RG-46 has been demonstrated to recognize as its epitope a linear sequence of amino acids, comprising residues 694 to 708 within the mature von Willebrand factor subunit.
  • NMC-4 has as its epitope the domain of the von Willebrand factor subunit which contains the glycoprotein lb binding site. Mapping of the epitope has demonstrated that it is contained within two discontinuous domains (comprising approximately mature vWF subunit residues 474 to 488 and also approximately residues 694 to 708) brought into disulfide- dependent association, Mohri, H.
  • the single chain p5E polypeptide fragment (representing the sequence from residue 441 to residue 733) displays an approximate 120 fold increase in binding affinity for NMC-4 compared to the comparable cysteine-free species isolated from p7E.
  • the single chain p5E species shows a remarkably decreased affinity for NMC-4, which was then very similar to that of the cysteine-free p7E species under either reduced or nonreduced conditions.
  • NMC-4 also failed, under reducing or non-reducing conditions, to recognize as an epitope disulfide-linked dimers from the p5E extract.
  • nitrocellulose filters used to produce autoradio- graphs based on NMC-4 were rescreened with RG-46 by subtracting the initial NMC-4 exposure response, which was kept low through a combination of low antibody titer and short exposure time.
  • the binding of RG-46 to the 36,000 kg/mol p7E polypeptide on the filters was the same whether reducing or non-reducing conditions were chosen, consistent with the replacement of all cysteines by glycine in the expressed polypeptide.
  • the 52/48 tryptic fragment of the mature vWF subunit has been established to comprise the amino acid sequence between residues 449 and 728. Contained within that sequence is a subfragment consisting approximately of residues 500 to 700 known as the A x domain. This domain has substantial amino acid sequence homology to the A 2 and A 3 domains of the 2,050 residue subunit and which are located at approximately residue positions 710-910 (A 2 ) and 910-1110 (A 3 ) . See Titani, K. et al "Primary Structure of Human von Willebrand Factor” in Coagulation and Bleeding Disorders, Marcel Dekker, New York, 1989.
  • the A 3 domain contains also a pair of cysteine residues which are believed to form, in vivo, a loop analogous to the residue 509-695 Aj loop structure.
  • the potential utility of this new mutant vWF fragment as an inhibitor of the binding of multimeric vWF to collagen can be demonstrated following the procedures of Pareti, F.I. et al., J. Biol. Chem.. 262(28), 13835-13841 (1987) and Mohri, H. et al., J. Biol. Chem., 264(29), 17361- 17367 (1989).
  • This second embodiment includes within its scope the recognition of certain of the roles performed by cysteine residues present in the residue 449-728 primary sequence fragment of the mature vWF subunit.
  • this embodiment confirms that the cysteine 509-695 disulfide bond is an intrachain bond and provides for effective therapeutics incorporating the 509-695 bond for the purpose of treating thrombosis, or for the purpose of treating von Willebrand's disease.
  • Both the antithrombotic polypeptides and antihemorrhagic polypeptides of this the second embodiment of the invention are based upon that amino acid sequence domain which comprises approximately residues 449 to 728 of the mature von Willebrand factor subunit and which, if fully glycosylated, would be equivalent in weight to the 52/48 kg/mol vWF subunit fragment.
  • Difficulties include effective separation of 116 kg/mol and 52/48 kg/mol fragments from other components of tryptic digests and effective sterilization of blood- derived components from human viruses such as hepatitis and AIDS.
  • vWF polypeptides analogous to the 52/48 tryptic fragment
  • the production by recombinant DNA-directed means of therapeutic vWF polypeptides analogous to the 52/48 tryptic fragment has met with certain limitations. It is desirable that the polypeptide not only be made by the host cells but that it be correctly folded for maximum therapeutic utility. It is believed that the principal factor which has to date prevented the expression of the most therapeutically active forms of the 52/48 fragment is the incorrect folding of the molecule caused by the linking up of cysteine residues to form incorrect disulfide contacts. In addition, such polypeptides appear to exhibit hydrophobic properties or solubility problems which would not be encountered if they were to be contained within the entirety of the natural vWF subunit, or were properly glycosylated.
  • vWF-derived therapeutic polypeptides are the selection of conditions which minimize the formation of improper disulfide contacts.
  • Prior expression of such polypeptides from recombinant DNA in host bacterial cells has certain disadvantages.
  • newly produced vWF polypeptides are unable to escape from the host cells, causing them to be accumulated within insoluble aggregates therein (inclusion bodies) where the effective concentration of cysteine residues was extremely high.
  • inclusion bodies insoluble aggregates therein
  • This embodiment provides a solution to these difficulties by causing the vWF-derived polypeptides to be expressed in mammalian cells using a DNA sequence which encodes the polypeptide and which also encodes for a signal peptide, the presence of which causes the vWF polypeptide to be secreted from the host cells. Incorrect disulfide bond formation is minimized by limiting the accumulation of high local concentrations of the polypeptide as in inclusion bodies.
  • enzymes present in the host eucaryotic cells unlike bacteria, are able to glycosylate (add carbohydrate chains to) the vWF-derived polypeptides resulting in therapeutic molecules which more closely resemble domains of vWF molecules derived from human plasma.
  • the recombinant 116 kg/mol polypeptide generated according to this invention is demonstrated to represent a dimer of the subunit fragment consisting of residues 441-730 and possesses an amount of glycosylation equivalent to that found in the comparable region of plasma-derived vWF.
  • this second embodiment includes any fragment of mature von Willebrand subunit comprising that sequence of amino acids between approximately residue 449 and approximately residue 728, or a subfragment thereof, from which at least one of cysteine residues 459, 462 and 464 thereof is removed. Such removal reduces the tendency of the fragment to form undesired interchain disulfide bonds (and resultant dimers) with the result that therapeutic utility as an antithrombotic is improved.
  • a further aspect of the embodiment encompasses a glycosylated form of the above defined polypeptides.
  • cysteine residues be retained at positions 509 and 695 so that the tertiary structure of the GPIb( ⁇ ) binding domain of the mature vWF subunit fragment is preserved.
  • a glycosylated polypeptide derived from the aforementioned region of vWF in which cysteine residues are retained at positions 509 and 695 and in which each of cysteine residues 459, 462 and 464 is deleted or replaced by residues of other amino acids.
  • a glycosylated polypeptide derived from the aforementioned region of vWF in which cysteine residues are retained at positions 509 and 695 and in which any one of cysteine residues 459, 462 and 464 is deleted or replaced by a single residue of another amino acid.
  • the preferred mutant polypeptides (antithro botics) of the invention are described hereafter.
  • the polypeptide can be redesigned (for example, by proteolysis, covalent labelling or mutagenesis) to delete or alter the loop region, or a subdomain thereof.
  • both platelets and von Willebrand factor molecules contain large numbers of negative charges such as, for example, those contributed by sialic acid. Such charges can facilitate desirable mutual repulsion of the molecules under non-injury conditions.
  • the addition of one or more positively charged residues of lysine and/or of arginine extending, for example, from the amino and/or from the carboxy terminus of the 52/48 tryptic fragment or recombinant equivalents thereof can overcome electrical repulsions with respect to the GPIb( ⁇ ) receptor, thus facilitating use of the fragment as an antithrombotic therapeutic.
  • polypeptides patterned upon the 449-728 vWF subunit fragment it is within the scope of the invention to remove certain cysteine residues by site directed mutagenesis and to thereafter inactivate any remaining cysteine residues by chemical inactivation thereof, such as, for example, by S-carboxymethylation.
  • the second embodiment is also concerned with the preparation of polypeptides which are useful in the treatment of hemorrhagic disease.
  • the monomeric fragment initially formed assumes a tertiary structure suitable for dimerization, and dimerization thereof is effected (see Example 7) .
  • the process conditions are such that it is possible to form a properly glycosylated dimeric polypeptide.
  • Essential elements necessary for the practice of the embodiment are: (A) a DNA sequence which encodes the residue
  • the expression of the DNA sequence of the von Willebrand factor subunit fragment is facilitated by placing a eucaryotic consensus translation initiation sequence and a methionine initiation codon upstream (5') to the residue 449- 728 encoding DNA.
  • the vWF DNA sequence may be a cDNA sequence, or a genomic sequence such as, for example, may be produced by enzymatic amplification from a genomic clone in a polymerase chain reation.
  • Expression of the residue 449-728 encoding sequence is further facilitated by placing downstream therefrom a translation initiation codon such as TGA.
  • vWF-polypeptide so expressed typically remains within the host cells because of the lack of attachment to the nascent vWF polypeptide of a signal peptide. In such a situation, purification of proteins expressed therein and the extraction of pharmacologically useful quantities thereof are more difficult to accomplish than if the polypeptide were secreted into the culture medium of the host cells. Such expression systems are nonetheless useful for diagnostic assay purposes such as, for example, testing the proper function of platelet GPIb-IX receptor complexes in a patient.
  • vWF-encoding DNA sequence for insertion into a suitable host cell in which there is also inserted upstream from the residue 449-728 encoding sequence thereof a DNA sequence encoding the vWF signal peptide (see Example 7) .
  • Other vWF- encoding DNA sequences corresponding to different regions of the mature vWF subunit, or corresponding to the propeptide, or to combinations of any of such regions, may be similarly expressed by similarly placing them downstream from a vWF signal peptide sequence in a suitable encoding DNA.
  • the signal peptide When attached to the amino terminal end of the residue 449-728 fragment of the vWF subunit, the signal peptide causes the fragment to be recognized by cellular structures as a polypeptide of the kind to be processed for ultimate secretion from the cell, with concomitant cleavage of the signal polypeptide from the 449-728 fragment.
  • functional fragments may be expressed from which, when compared to the 449-728 fragment, several residues adjacent to the amino and carboxy terminals have been removed as long as the GPIb( ⁇ ) binding sequences are not compromised.
  • a wide variety of expression plasmids or viral expression vectors are suitable for the expression of the residue 441-730 mature vWF subunit fragment or similar vWF fragments.
  • One factor of importance in selecting an expression system is the provision in the plasmid or vector of a high efficiency transcription promoter which is directly adjacent to the cloned vWF insert.
  • Another factor of importance in the selection of an expression plasmid or viral expression vector is the provision in the plasmid or vector of an antibiotic resistance gene marker so that, for example, continuous selection for stable transformant eucaryotic host cells can be applied.
  • plasmids suitable for use in the practice of the invention include pCDM8, pCDM8 neo , pcDNAl, pcDNAl" 60 , pMAM ⁇ 0 and Rc/CMV.
  • Preferred plasmids include pCDMS 0*50 , pcDNAl" 00 , pMAMTM *0 and Rc/CMV.
  • viral expression vector systems suitable for the practice of the invention include those based upon retroviruses and those based upon baculovirus Autographa californica nuclear polyhedrosis virus.
  • Representative host cells comprising permanent cell lines suitable for use in the practice of the invention include CHO-K1 Chinese hamster ovary cells, ATCC-CCL- 61; COS- 1 cells, SV-40 transformed African Green monkey kidney, ATCC- CRL 1650; ATT 20 murine pituitary cells; RIN-5F rat pancreatic ⁇ cells; cultured insect cells, Spodoptera frugiperda: or yeast (Sarcomyces) .
  • Example 7 contains a detailed explanation of preferred procedures used to express and secrete the 441-730 sequence.
  • the fragment is secreted as a homodimer held together by one or more disulfide bonds involving cysteine residues 459, 462 and 464.
  • Expression of monomeric fragments useful as antithrombotics necessitates control be made of the disulfide bonding abilities of the monomers which is achieved most preferably by mutagenesis procedures as described below.
  • Suitable techniques include mutagenesis using a polymerase chain reaction, gapped-duplex mutagenesis, and differential hybridization of an oligonucleotide to DNA molecules differing at a single nucleotide position.
  • suitable codon altering techniques see Kraik, C. "Use of Oligonucleotides for Site Specific Mutagenesis", Biotechnigues, Jan/Feb 1985 at page 12.
  • the codon for cysteine 459 could be replaced by two or more codons such as one for serine and one for glycine, such replacement resulting in a new amino acid sequence: His ⁇ -Ser ⁇ -Gly ⁇ -Gln 60 ; or
  • one or more codons for residues adjacent to cysteine residue 459 could be deleted along with codon 459 as represented by - - Glu ⁇ '-Gln 460 - -. It is contemplated that codons for amino acids other than alanine, threonine, serine, glycine or asparagine will also be useful in the practice of the invention depending on the particular primary, secondary, tertiary and quaternary environment of the target cysteine residue.
  • alanine, threonine, serine, glycine and asparagine will generally be satisfactory because they are, like cysteine, neutrally charged and have side chains which are small or relatively small in size.
  • Serine is a preferred amino acid for use in the practice of this invention because it most closely approximates the size and polarity of cysteine and is believed not to disrupt ⁇ -helical and /3-sheet domains.
  • cysteine and the group of threonine, serine, and asparagine are found to be indifferent to ⁇ -helical structure, as opposed to being breakers or formers of such regions.
  • threonine, serine and asparagine are likely to leave unperturbed an ⁇ -helical region in which a potential target cysteine might be located.
  • glycine, alanine and serine were found to be more or less indifferent to the formation of /3-regions. It is noted that serine, threonine and asparagine residues represent possible new sites of glycosylation making them potentially unsuitable replacement residues at certain positions in secretory proteins subject to glycosylation.
  • the primary consideration which should be taken into account in connection with selecting suitable amino acid replacements is whether the contemplated substitution will have an adverse effect on the tertiary structure of the fragment.
  • other amino acids may be suitable as acceptable substitutes for particular cysteine residues as long as the new residues do not introduce undesired changes in the tertiary structure of the 449-728 fragment.
  • Reactivity with NMC-4 antibody is recommended as a -test of whether a mutant polypeptide has the desired therapeutic properties.
  • Example 9 The specific protocol used to generate the mutant vWF residue 441-730 fragment containing cysteine to glycine substitutions at each of residue positions 459, 462 and 464 is described in Example 9.
  • the expression plasmid used therein was designated pAD4/ ⁇ 3C.
  • Example 14 The specific protocol, adapted from that of Example 9, and which was used to generate the three mutant residue 441- 730 fragments, each of which contains a different single Cys ⁇ Gly mutation (at positions 459, 462 or 464) is described in Example 14.
  • the respective expression plasmids used therein were designated pAD4/G 459 , pAD4/G 462 and pAD/G 464 (collectively "the pAD4/ ⁇ lC plasmids").
  • Example 7 discloses the use of stably transformed CHO-Kl cells to express the unmutagenized residue 441-730 vWF subunit fragment. As set forth in Example 10 below, the unmutagenized fragment was also expressed in unstable COS-1 transformants.
  • SDS-polyacrylamide gel electrophoresis of secreted and immunoprecipitated proteins derived from CHO-Kl cells demonstrates that, under nonreducing conditions, the dominant vWF-derived polypeptide, detected by staining with Coomassie blue, has an apparent molecular weight of about 116,000 (Example 7) .
  • This result was confirmed by characterizing the polypeptides secreted by pAD4/WT transformed COS-1 cells (Examples 12-14) using autoradiographs of 35 S-labelled proteins.
  • the 116 kg/mol fragment Under disulfide-reducing conditions (such as in the presence of 100 mM dithiothreitol) the 116 kg/mol fragment was no longer detected and the vWF-derived material appears as the expected 52/48 kg/mol monomer.
  • the apparent molecular weight of the recombinant 116 kg/mol polypeptide was consistent with the presence of said polypeptide as a homodimer of the 441-730 fragment. This homodimer carries also an amount of glycosylation equivalent to that observed in the 116 kg/mol polypeptide isolated by tryptic digestion of mature plasma (circulating) vWF.
  • the dimeric 116 kg/mol fragment which is within the scope of the present embodiment and which contains two GPIb( ⁇ ) binding sites supports ristocetin-induced platelet aggregation by virtue of its bivalent character. This was evidenced in Example 8 below.
  • the interchain bonds which stabilize the 116 kg/mol homodimer must be formed from one or more of residues 459, 462 and 464. It is further noted that since residues 459, 462 and 464 are in such close proximity in any monomer, there may be variation as to which particular residue or residues contribute the interchain disulfide bond or bonds which form the interpolypeptide contact in any particular mature vWF dimer or multimer, or recombinant 116 kg/mol fragment. Therapeutically-active populations of dimeric molecules can be generated according to the practice of the invention utilizing any of the possible combinations of interchain disulfide bonds.
  • the 116 kg/mol polypeptide is capable of performing a bridging function between a platelet and the subendothelium. This enables it to be used in a method for inducing platelet adhesion to surfaces such as, for example, vascular subendothelium. There is also provided a method of inducing platelet activation and/or aggregation which comprises contacting platelets with an effective amount of the recombinant 116 kg/mol polypeptide.
  • Another important aspect of the second embodiment of the invention is the provision of glycosylated 52/48 kg/mol monomeric fragments of the vWF subunit having substantial elements of normal tertiary structure. Such fragments have a reduced tendency to form dimers which tend to be unsuitable for use as antithrombotic therapeutics.
  • residue 441-730 vWF fragments were produced in which one or more of cysteine residues 459, 462 and 464 were replaced with glycine residues.
  • Examples 9, 10 and 11 explain the mutagenesis and cell culture conditions necessary to create COS-1 cell transformants expressing these mutant vWF polypeptides.
  • Examples 6 to 8 of the invention describe the properties of the molecules so derived in comparison with the recombinant 116 kg/mol polypeptide produced from pAD4/WT transformed COS-1 cells.
  • vWF-derived polypeptides expressed by pAD4/ ⁇ 3C transformed COS-1 cells were compared with the polypeptides secreted by pAD4/WT transformed COS-1 cells.
  • 35 S-methionine-supplemented culture medium from each culture was subjected to immunoprecipitation using equal amounts of NMC-4 and RG-46 anti-vWF antibodies (Example 6) to collect the vWF-derived secreted proteins.
  • vWF polypeptides were then resolved by autoradiography of 35 S-lab ' el on SDS polyacrylamide gels. No 116 kg/mol polypeptide could be detected in culture extracts of pAD4/ ⁇ 3C transformed cells under nonreducing conditions. Instead, under either reducing or nonreducing conditions, a band having an apparent molecular weight of 52 kg/mol was seen. In contrast, the pAD4/WT transformed COS-1 cells produce under nonreducing conditions, as expected, a polypeptide of apparent molecular weight of 116 kg/mol.
  • the immunoprecipitation procedure was also repeated using only conformation-dependent NMC-4 antibody (Example 13) .
  • the major vWF-derived component isolated from the culture medium of pAD4/WT transformed cells again had an apparent molecular weight of 116 kg/mol under nonreducing conditions and 52 kg/mol under reducing conditions. A band of apparent 52 kg/mol molecular weight was detected under nonreducing conditions on gels of pAD4/ ⁇ 3C derived polypeptide material.
  • reactivity with NMC-4 antibody is important evidence that the 52 kg/mol fragment detected in pAD4/ ⁇ 3C transformed cells possesses the tertiary structure of the natural residue 441-730 domain.
  • the immunoprecipitation procedure was also used to detect NMC-4 reactive vWF polypeptide produced by pAD4/ ⁇ lC transformed COS-1 cells cultured under conditions similar to those for pAD4/WT and ⁇ 3C transformants in the presence of 35 S methionine. Immunoprecipitated proteins were run under reducing and nonreducing conditions in SDS-polyacrylamide gels and compared with vWF polypeptides produced by pAD4/WT and pAD4/ ⁇ 3C transformants (Example 14) .
  • the apparent molecular weight of 52 kg/mol for recombinant polypeptides derived from COS-1 cells transformed with either pAD4/ ⁇ 3C or pAD4/ ⁇ lC plasmids is consistent with said polypeptides being monomers of the 441-730 fragment, while carrying also an amount of glycosylation equivalent to that seen in the 52 kg/mol polypeptide as isolated from tryptic digestion and reduction of mature plasma (circulating) vWF.
  • a method of preventing platelet activation and/or aggregation which comprises contacting platelets with an effective amount of a mutant recombinant 52/48 kg/mol polypeptide which polypeptide shows at least a substantially reduced tendency to dimerize when compared with nonmutant (wild type) recombinant 52/48 kg/mol polypeptides.
  • a method of preventing the adhesion of platelets to surfaces which comprises contacting platelets with an effective amount of a mutant recombinant 52/48 kg/mol polypeptide which shows at least a substantially reduced tendency to dimerize when compared with nonmutant recombinant 52/48 kg/mol polypeptides.
  • Contained within the 441-730 vWF fragment are potential binding sites for collagen (approximately residues 542-622) and glycosaminoglycans and proteoglycans (also within the residue 509-695 disulfide loop) , in addition to the GPIb ⁇ binding sites.
  • This embodiment of the invention provides for antithrombotic polypeptides patterned on mature von Willebrand factor and fragments thereof. Stated more precisely, this embodiment of the invention reflects the discovery that certain mutant polypeptides patterned on mature von Willebrand factor and capable of enhanced binding (relative to wild type) to specific receptors or ligands of vWF can be used to inhibit binding by native or wild type vWF to the same receptors or ligands thereby preventing or inhibiting thrombosis.
  • the mutant vWF polypeptides having antithrombotic activity can be expressed from recombinant bacterial or eucaryotic expression systems.
  • a principal goal of the invention is to modify von Willebrand factor or fragments thereof by, for example, mutation or covalent labelling so that the vWF-derived polypeptides bind to one or more receptors (ligands) with a greater affinity than the comparable sequence of amino acids present in wild type vWF, or in the equivalent fragment thereof.
  • Provision of such polypeptides having an "increased binding affinity" allows for more effective clinical treatments including the provision of an effective dose by a lower concentration of therapeutic, with the result that adverse clinical consequences such as immune response are minimized.
  • a binding affinity is considered increased if the modification enhances the therapeutic utility of the polypeptide by either (1) increasing the affinity of the vWF-derived polypeptide for a ligand by about 10% in relation to the comparable wild-type sequence and as measured in a suitable in vitro or in vivo assay, or (2) achieving an equivalent amount of binding to a ligand with about 10% less polypeptide; or (3) with respect to a particular amino acid sequence modification, achieving (1) or (2) above by use of the said modification in combination with one or more other "modifications" to the amino acid sequence as that term was above defined. More preferably, therapeutics of the invention have an increased binding affinity of about 100% or more for a ligand and most preferably an increased binding affinity for a ligand, compared to the wild type sequence, of about 5 fold or higher.
  • the mutant polypeptides are designed to have only one binding function, that is, they are capable of binding to only one receptor or ligand, thereby preventing a bridging function in which two or more components which participate in the hemostatic process such as, for example, platelets and damaged vascular wall tissue, are joined, potentially initiating an unwanted thrombus. Methods are described below whereby such additional binding functions can be avoided.
  • the preferred receptor or ligand of the mutant vWF polypeptides is platelet membrane glycoprotein Ib ⁇ .
  • Preferred as clinically useful antithrombotic polypeptides are those polypeptides patterned upon the mature von Willebrand factor subunit amino acid sequence between approximately residue 441 and approximately residue 733, or subfragments thereof, and having, relative to the wild type amino acid sequence of said polypeptide, or of a subfragment thereof, an enhanced affinity for platelet glycoprotein Ib ⁇ .
  • vWF-derived polypeptides having a similarly enhanced affinity for platelet glycoprotein Ib ⁇ encompassing all or part of the mature subunit residue 441- 733 sequence and containing additional vWF polypeptide sequence.
  • vWF polypeptide fragments reflecting wild type vWF sequences can be used to effect inhibition of the binding of vWF to platelet GPIb ⁇ receptors in patients, it is desirable to identify polypeptides having enhanced affinity for GPIb ⁇ which are therefore effective at lower doses.
  • an important aspect of the invention is the recognition that certain amino acid substitutions, additions or deletions (compared to the wild type vWF sequence) can be made in the polypeptides to enhance their affinity for GPIb ⁇ , thereby making them more effective when administered in therapeutic compositions.
  • a principal discovery, of the invention is that such suitable amino acid substitutions, additions, or deletions are reflected in, or are suggested by, the amino acid sequences of mature vWF subunit as derived from patients afflicted with Type IIB of von Willebrand disease, said amino acid sequence mutations being responsible for the affliction which is manifested by a prolonged bleeding time after injury.
  • the term von Willebrand disease (vWD) defines a bleeding disorder that is heterogenous in its modalities of genetic transmission, clinical and laboratory manifestations, and underlying pathogenic mechanisms.
  • vWF ristocetin
  • ristocetin i.e., occuring with lower ristocetin concentrations than are needed to induce aggregation in platelet-rich plasma of normal individuals.
  • Purified Type IIB vWF has an increased affinity for platelets and, unlike vWF from normal individuals, binds in vitro to platelet GPIb ⁇ in the absence of any modulating substance. See Berkowitz, S.D. et al., in Coagulation and Bleeding Disorders, von Willebrand Disease, Chapter 12,
  • This invention recognizes the significance of the greater IIB-type affinity for platelet receptors, which can be demonstrated in the presence and/or in the absence of modulators (see Examples 18-19 and 23-24 below) , the mutations responsible therefor being used to design therapeutic vWF fragments reflective of said mutations and having enhanced antithrombotic utility.
  • Type IIB von Willebrand disease typically exhibit thrombocytopencia (a reduction in the number of circulating functional platelets) which is thought, Holmberg, L. et al., N. Engl. J. Med.. 309, 816-821 (1983) , to result from intravascular platelet clumping initiated by the binding of Type IIB vWF molecules to the platelets. Platelets if so aggregated may be transiently removed from circulation leaving the patient with inadequate levels of functional platelets and less able to form clots in the event of vascular injury.
  • this invention provides for vWF-derived polypeptides which are designed to incorporate mutations associated with Type IIB vWD phenotype and have therefore, relative to the wild type sequence, an enhanced ability to bind to platelet GPIb ⁇ receptors.
  • the polypeptides demonstrate antithrombotic utility, that is, they prevent platelets from participating in the processes which under normal or pathological circumstances lead to thrombus formation.
  • Representative of processes involved in thrombus formation and which can be inhibited by the polypeptides of the invention are platelet adhesion, activation and aggregation.
  • the important characteristic of the new polypeptides is an enhanced affinity for GPIb ⁇ receptor, irrespective of whether the mutation is reflected in one or more particular IIB patients.
  • the terms "IIB-like”, “IIB phenotype”, “reflective of Type IIB vWF”, “IIB-like properties", and the like refer to enhanced binding of GPIb ⁇ . The methods described below are useful in the identification or creation of such other, additional polypeptide sequences.
  • Type IIB mutations or lib-like mutations can be incorporated into vWF, or fragments thereof, thereby providing enhanced affinity for GPIb ⁇ even though said mutant amino acid residues are not inserted into the polypeptide at the exact equivalent sequence positions that the mutations occupy in the vWF from particular patients. It is understood that all such resulting polypeptides having similar functional properties are within the scope of the invention.
  • the aforementioned antithrombotic polypeptides are made by a process of genetic engineering (recombinant DNA technology) which involves transferring into vWF-encoding DNA that coding information which causes the resultant expressed polypeptide to contain one or more amino acid substitutions reflective of vWF as isolated from one or more patients with Type IIB disease.
  • genetic engineering recombinant DNA technology
  • the types of amino acid mutations useful in the design of said polypeptides and additional effective amino acid substitutions, additions or deletions are described below.
  • An additional aspect of the invention provides for the chemical modification or inactivation of a side chain or one or more amino acids in a vWF-derived polypeptide reflective of wild type vWF leading to a polypeptide expressing the vWD Type IIB phenotype.
  • Example 15 of the invention provides procedures representative of those which may be used to identify the particular mutations in mature von Willebrand factor which are responsible, in particular patients, for Type IIB von Willebrand disease.
  • One propositus was determined to have a Trp 550 ⁇ Cys 550 mutation.
  • a second propositus was determined to have an Arg 5II ⁇ Trp 5u mutation.
  • a third propositus having certain Type IIB-like symptoms was determined to have a Gly ⁇ ' ⁇ Asp 561 mutation.
  • the mutations believed responsible for Type IIB phenotype were identified as Arg ⁇ Trp 543 and Val 553 ⁇ Met 553 . Cooney, K.A. et al.. Blood, 76(supp. 1), abstract 1661, page 418a, Nov. 15, 1990.
  • Example 15 provides for methods suitable to analyze also DNA encoding mature vWF subunit sequence(s) outside of the above-indicated domains thereof.
  • the invention also provides for therapeutic vWF-derived polypeptides that are designed to incorporate one or more of such other potential mutations.
  • the interaction of the vWF fragment comprising approximately residues 441-730 with platelet GPIb ⁇ involves "actual binding regions or sequences" (residues 474- 488 and 694-708 thereof) supported in the tertiary structure of the fragment by a disulfide stabilized loop which modulates the position and therefore the activity of the actual binding regions.
  • sequences and the loop are believed responsible for the adhesion of multisubunit vWF to platelets at GPIb ⁇ sites. It may be determined, however, that additional amino acid sequences also participate in binding to GPIb ⁇ or in the modulation of said binding.
  • Methods 1 to 4 of Example 16 provide representative techniques for the identification of potential amino acid substitutions which although not identified from a particular Type IIB patient, confer nonetheless Type IIB-like properties on recombinantly produced vWF-derived polypeptides incorporating same.
  • the above methods are also representative of techniques which can be used to identify proposed amino acid changes in the vWF polypeptide sequence which effect an increased affinity for GPIb ⁇ and which do not correspond with any known human vWF sequence.
  • Arg 545 could be deleted or substituted for.
  • Parallel arguments apply to any negatively charged residue positions of wild type vWF determined by comparison with vWF from Type IIB patients to be necessary for proper in vivo function.
  • any of the above strategies can be used in any combination thereof so that, for example, one or more mutations from the vWF gene of one Type IIB vWD patient could be incorporated into a DNA encoding a vWF-derived therapeutic polypeptide along with one or more mutations from the DNA of another such patient, or along with one or more mutations not derived from a patient but predicted or determined in a vWF- derived polypeptide to confer Type IIB-like properties.
  • more than one such predicted or determined mutation can be combined in an encoding DNA for expression therefrom of a therapeutic polypeptide.
  • Examples 15-24 of the invention are representative of procedures useful in the practice of the invention, including those for the preparation of DNA sequences from which can be expressed the polypeptides of the invention, and those whereby the utility of said polypeptides as antithrombotic therapeutics can be demonstrated.
  • Other suitable procedures known to those skilled in the art may be substituted if necessary and as the context requires.
  • Antihemorrhagic polypeptides derived from the polypeptides of the invention are provided.
  • An additional aspect of the invention is the recognition that certain amino acid substitutions, additions or deletions, which in the context of a monomeric fragment (such as 52/48 kg/mol fragment) have antithrombotic utility, have instead antihemorrhagic utility when incorporated into a dimeric fragment (such as the 116 kg/mol fragment) . Accordingly, such mutations may be incorporated into a DNA sequence in a host eucaryotic cell which encodes the residue 441-730 fragment, with resultant expression therefrom
  • the invention is initially described in terms of constructing therapeutically active fragments of mature vWF subunit patterned upon the residue 441-730 domain thereof and having enhanced affinity for platelet GPIb ⁇ receptor, the multivalent character of circulating vWF, and the multiple potential functions of each mature subunit provide a unique opportunity to design other fragments of vWF having additional enhanced antithrombotic properties.
  • the fragment can be further mutated or chemically altered to inactivate the particular undesired binding activity.
  • Antithrombotic polypeptides which are monomeric and which are unable to perform a potentially thrombotic bridging function may also be designed to target the collagen fibers such as are exposed at the site of disease-caused circulatory system lesions, and upon which a thrombus may otherwise form. By occupying these collagen binding sites, to the exclusion of multimeric vWF, the complex sequence of events resulting in platelet aggregation and thrombus formation can be avoided.
  • the random mutagenesis procedure of Hutchison, CA. et al., supra, may be used to target the collagen binding domain within the loop of the 52/48 kg/mol vWF fragment.
  • Suitable clones expressing polypeptides with enhanced binding activity toward collagen may be screened according to the procedure of Example 25.
  • it may be desireable to cause substitution or deletion (by mutation) or inactivation (by chemical labelling or proteolysis) of the actual GPIb ⁇ binding sequences in order to prevent a potentially thrombotic bridging activity within the monomeric 52/48 kg/mol fragment.
  • a particularly important benefit of the invention, and of the Second Embodiment thereof (see Examples 9 and 11) is the provision of a 52/48 kg/mol vWF fragment which has a substantially reduced tendency to participate in disulfide- induced dimerization; it therefore lacks potentially thrombotic bridging activity.
  • An additional collagen binding site is represented by the A 3 domain of the mature vWF subunit. This domain comprises approximately residues 910-1100 of the subunit and contains also a disulfide loop formed by cysteine residues 921 and 1108.
  • the A 3 domain is believed to represent a partially autonomous structural domain containing within its primary amino acid sequence information adequate to allow assembly of a polypeptide patterned thereon into a structure mimicing in whole or part the natural tertiary structure of the A 3 domain as present in multimeric vWF.
  • the A 3 domain itself lacks additional cysteines, analogous, for example, to cysteine residues 459, 462 and 464 positioned adjacent to the Aj domain, and which would tend to cause dimerization of the fragment.
  • the A 3 domain is a region from which to derive effective antithrombotics.
  • a DNA sequence corresponding to the A 3 domain may be prepared by any of several standard methods based upon the known vWF gene sequence, the location of exon/intron boundaries therein, the nucleotide sequence of available vWF mRNA or cDNA and the known amino acid sequence of pre-pro-vWF.
  • a vWF mRNA could be used, for example, as a template for reverse transcriptase with the resultant cDNA being subjected to a polymerase chain reaction using suitable oligonucleotide primers to flank the ends of the target A 3 encoding region.
  • a nucleotide sequence sufficiently large to facilitate efficient replication, transcription and translation (such as corresponding to amino acid positions 850-1150) can be chosen for amplification with random mutagenesis, Hutchison, CA. et al., supra, applied to emphasize permutation of the DNA region encoding amino acid residues 948-998. Screening of clones expressing the randomly mutagenized population of polypeptide sequences for particular species demonstrating enhanced collagen binding activity would follow the method of Example 27.
  • Binding Sites for Glycosaminoglycans and Proteoglycans Bacterial clones possessing mutagenized DNA sequences corresponding to the "heparin binding sites" of the mature vWF subunit (believed to be positioned in whole or part within the loop of the 52/48 kg/mol fragment and also in whole or part within the mature subunit region represented by residues 1-272) may be similarly generated and screened for the necessary enhanced binding affinity toward their respective target macromolecules to create antithrombotic therapeutic polypeptides. The screening procedure follows the procedure of Examples 26 and 29.
  • vWF heparin-binding domains
  • the "heparin-binding domains" of vWF may prove to be instrumental in the binding of vWF to exposed subendothelium in response to vascular injury and in the pathogenesis of vascular disease. It has been shown that vWF binds to endothelial cell-produced extracellular matrices even after collagen has been enzymatically digested away. It is likely that proteoglycans are responsible for this interaction.
  • the platelet glycoprotein Ilb/IIIa receptor site Although the binding reaction believed primarily responsible for crosslinking (aggregation) of individual platelets that have adhered to the subendothelium at the site of vascular injury is the bridging of platelet GPIIb/IIIa receptor sites by fibrinogen, multimeric vWF can also contribute to this crosslinking activity. Suitable vWF fragments can also be used to inhibit the activity. vWF and fibrinogen contain within their respective polypeptides a domain of primary sequence consisting of Arg- Gly-Asp (residues 1744-1746 in mature vWF subunit) which is known to be at least part of the platelet GPIIb/IIIa recognition site for these adhesive proteins.
  • Aggregation of platelets can be inhibited in a patient by administering therapeutic compositions containing mutant polypeptides derived from the Arg-Gly-Asp region of the mature vWF subunit.
  • Such polypeptides possessing enhanced binding affinity are effectively made by systematic random mutagenesis (see Example 16, method 1 thereof) of a suitable DNA sequence encoding the GPIIb/IIIa binding domain of vWF. Screening of mutant clones for expressed polypeptide of enhanced binding activity follows the procedure of Example 28.
  • mutagenesis procedures are also applicable to targeting the interaction of vWF with coagulation factor VIII, a necessary participant in secondary hemostasis and believed to be necessary to facilitate activation of coagulation factor X by factor IX,.
  • Factor VIII has been shown to be extremely labile except when complexed to vWF.
  • This invention provides a fragment of vWF capable of binding factor VIII, and having, relative to wild type, an enhanced affinity therefor, but of insufficient size to substantially protect factor VIII so complexed from denaturation or proteolysis. Screening of mutant vWF polypeptides for enhanced binding affinity follows the procedure of Example 30.
  • the following considerations are of particular significance. It has been mentioned previously that it is possible for more than one of the GPIb ⁇ , glycosaminoglycan (proteoglycan) , or collagen binding domains of such a therapeutic polypeptide to be occupied by a respective target receptor or ligand at any particular time. Methods were described to prevent one or both of the undesired binding activities, said aforementioned methods involving further modifications to the therapeutic polypeptide.
  • glycosaminoglycans are found on the surface of many types of human cells including those that form the walls of blood vessels.
  • heparin itself has anticoagulant activity and is commonly administered to patients presenting or suspected of presenting a vascular disease state. Consequently, there is a considerable possibility that the administration of a monomeric 52/48 kg/mol polypeptide or, for example, a modified form of the polypeptide containing also one or more Type lib mutations (see Example 22 below) as an intended antithrombotic will be ineffective, the therapeutic molecules having sufficient affinity for the widely dispersed array of glycosammoglycan macromolecules or for additionally administered heparins.
  • antithrombotic polypeptides patterned upon the 52/48 kg/mol vWF fragment said fragments intended to have affinity for platelet GPIb ⁇ receptors, that the binding domain for glycosaminoglycans within such fragments be deleted or inactivated by, for example, one of the following methods:
  • Similar strategies may be used to modify different or larger fragments of vWF directed to platelet GPIb ⁇ binding sites, including those up to the size pf the entire mature subunit thereof, or larger, and demonstrated to have potential antithrombotic activity but one or more potential binding sites for other ligands or receptors, the deletion or inactivation of which is preferable.
  • those polypeptides of the invention patterned upon the mature vWF subunit, or a fragment thereof, which are directed to receptor sites or macromolecules other than GPIb ⁇ see Example 25-30
  • any other binding function of the polypeptide can be deleted or inactivated by the above-mentioned strategies.
  • a polypeptide patterned upon the 116 kg/mol vWF homodimer (Example 7, below), directed to the platelet GPIb ⁇ receptor, in which one or more other binding functions of the polypeptide have been deleted or inactivated.
  • Antibodies and particularly conformation dependent antibodies, are powerful tools for analyzing the structure and function of macromolecules. By blocking macromolecular interactions, antibodies can also have important therapeutic utility.
  • this invention includes within its scope an antibody which is specific for the vWF subunit, or any polypeptide containing a subset thereof, and which is made by a process which involves immunizing animals with a polypeptide patterned upon the mature vWF subunit sequence between approximately residue 441 and residue 730 thereof, and containing one or more residues corresponding to a Type IIB vWF, or with any other polypeptide of the invention.
  • Further diagnostic or therapeutically useful antibodies can be generated against polypeptides so patterned upon the above stated sequence region and in which cysteine residues 509 and 695 form a disulfide bond, thereby recreating important domains of tertiary structure. Procedures useful in immunizing animals with vWF polypeptides are well known in the art.
  • compositions One or more of the polypeptides of the present invention can be formulated into pharmaceutical preparations for therapeutic, diagnostic, or other uses. To prepare them for intravenous administration, the compositions are dissolved in water containing physiologically compatible substances such as sodium chloride (e.g. at 0.35-2.0 M) , glycine, and the like and having a buffered pH compatible with physiological conditions, which water and physiologically compatible substances comprise a pharmaceutically acceptable carrier.
  • physiologically compatible substances such as sodium chloride (e.g. at 0.35-2.0 M) , glycine, and the like and having a buffered pH compatible with physiological conditions, which water and physiologically compatible substances comprise a pharmaceutically acceptable carrier.
  • the amount to administer for the prevention or inhibition of thrombosis will depend on the severity with which the patient is subject to thrombosis, but can be determined readily for any particular patient.
  • Willebrand disease will depend on the severity with which the patient is subject to hemorrhage, but can be determined readily for any particular patient.
  • Example 1 Expression of a mutant cysteine-free mature von Willebrand factor subunit fragment having an amino terminus at residue 441 (arginine) and a carb'oxy terminus at residue 733 (valine)
  • RNA from endothelial cells (the major source of plasma vWF) was sedimented in sucrose gradients, with RNA larger than 28S being selected for construction of a cDNA library.
  • This enriched fraction was further purified using two separate cycles of poly(u)-Sephadex ® chromatography to select for RNA species (mRNA) having 3' polyadenylated ends.
  • mRNA RNA species having 3' polyadenylated ends.
  • Lynch et al., supra estimated the prevalence of vWF mRNA in this fraction at about l in 500, which fraction was used to generate a cDNA library of approximately 60,000 independent recombinants.
  • standard techniques were used. The mRNA population was primed using an oligo (dT) primer, and then transcribed with a reverse transcriptase.
  • RNA strands were then removed by alkaline hydrolysis, leaving cDNA anticoding strands (equivalent to transcribed strands) which were primed by hairpin looping for second strand synthesis using DNA polymerase I.
  • the hairpin loop was removed with Si nuclease and rough ends were repaired with DNA polymerase I.
  • GC tailing Maniatis, T. et al., Molecular Cloning. 2nd ed., v.l, p.5.56 (1987), was then used to anneal the cDNA into plasmid vector pBR322. Oligo(dC) tails were added to the cDNA fragments with terminal transferase and were annealed to oligo(dG) tailed pBR322. The plasmids were transformed into ampicillin sensitive E.coli. strain HB101 for propagation. Suitable clones were identified after screening with 32 P-labelled cDNA prepared as reverse transcriptase product of immunopurified vWF polysomes. Positive clones were subcloned into pSP64 (Promega Co., Madison, WI) .
  • oligonucleotides used herein were synthesized by the phosphoramidite method , Sinha, et al. , Tetrahedron Letters, 24, 5843 (1983) , using a model 380B automated system, Applied Biosystems, Foster City, CA.
  • Oligonucleotide (1) (SEQ ID NO: 3)
  • Oligonucleotide (2) (SEQ ID NO: 4)
  • Oligonucleotides overlap the ends 1 of the coding region for that fragment of the mature vWF subunit which can be produced by digestion with trypsin and which begins with residue 449 (valine) and ends with residue 728 (lysine) .
  • Oligonucleotide (1) corresponds to coding strand DNA (analogous with mRNA) for amino acid positions 441 to 446 and adds an EcoRI restriction site 5' to the codon for amino acid 441.
  • Oligonucleotide (2) corresponds to the non-coding strand (transcribed strand) of mature vWF DNA for amino acids positions 725-733 and adds a Hindlll restriction site 3' to the codon for amino acid 733.
  • the coding strand complementary to (2) is shown in lower case letters.
  • a cDNA fragment corresponding to mature vWF residues Nos. 441-733, and containing EcoRI and Hind III linkers was then synthesized in a polymerase chain reaction following the method of Saiki, R.K. et al. Science. 239, 487- 491 (1988) .
  • the procedure utilizes a segment of double-stranded vWF cDNA, a subsegment of which is to be amplified, and two single-stranded oligonucleotide primers (in this case oligonucleotides (1), (2)) which flank the ends of the subsegment.
  • the primer oligonucleotides (in the presence of a DNA polymerase and deoxyribonucleotide triphosphates) were added in much higher concentrations than the DNA to be amplified. Specifically, PCR reactions were performed with a DNA thermal cycler (Perkin Elmer Co., Norwalk, CT/Cetus Corporation, Berkeley, CA) using Taq polymerase (Thermus aguaticus) .
  • the reactions were run in 100 ⁇ l volumes containing 1.0 ⁇ g of pre-pro-vWF cDNA, 1.0 ⁇ g of each synthetic oligonucleotide primer, and buffer consisting of 50 mM KC1, 10 mM Tris-HCl (pH 8.3), 1.5 mM MgCl 2 , 0.1% gelatin (BioRad Co., Richmond, CA) and 200 mM of each dNTP.
  • PCR conditions were 35 cycles of 30 seconds at 94°C, 30 seconds at 52°C and 1 minute at 72°C. Amplified fragments were then purified and isolated by electrophoresis through a 2% agarose gel, Maniatis et al., Molecular Cloning. A Laboratory Manual.
  • cDNA corresponding to the mature vWF fragment beginning at amino acid sequence position 441 and ending at position 733 was prepared and amplified directly from platelet mRNA following the procedure of Newman, P.J. et al. J. Clin. Invest.. 82, 739-743 (1988). Primer nucleotides No. 440 and 733 were utilized as before with the resulting cDNA containing EcoRI and Hindlll linkers.
  • the resultant double stranded von Willebrand factor cDNA corresponding to the amino acid sequence from residue 441 to 733 was then inserted, using EcoRI and Hindlll restriction enzymes, into the double stranded replicative form of bacteriophage Ml3mpl8 which contains a multiple cloning site having compatible EcoRI and Hindlll sequences.
  • M13 series filamentous phages infect male (F factor containing) E.coli strains.
  • the infecting form of the virus is represented by single stranded DNA, the ( + ) strand, which is converted by host enzymes into a double stranded circular form, containing also the minus ( " ) strand, which double stranded structure is referred to as the replicative form (RF) .
  • the ability to isolate a stable single stranded ( + ) form of the virus is particularly useful to verify the integrity of any cloned sequences therein. See Messing, J. , Meth. Enzvmoloqy. 101, 20-78 (1983) ; Yanish-Perron, C et al., Gene. 33, 103-109 (1985).
  • the vWF cDNA insert was completely sequenced using single-stranded dideoxy methodology (Sanger, F. et al. Proc. Natl. Acad. Sci USA. 74, 5463-5467 (1977)), utilizing the single-stranded ( + ) form of M13mpl8, to confirm that the vWF cDNA fragment contained the correct coding sequence for mature vWF subunit residues 441-733.
  • oligonucleotides (see Sequence Listing ID NOS: 5-8) encompassing the region of each cysteine codon of the vWF cDNA were prepared as non-coding strand (transcribed strand) with the corresponding base substitutions needed to substitute glycine for cysteine.
  • the oligonucleotides used were as follows: Oligonucleotide (3) (SEQ ID NO: 5)
  • Oligonucleotide (4) (SEQ ID NO: 6)
  • Oligonucleotide (5) (SEQ ID NO: 7)
  • Oligonucleotide (6) (SEQ ID NO: 8)
  • Hybridizing oligonucleotides are shown in capital letters and are equivalent to the transcribed strand (non- coding DNA) .
  • the equivalent coding strand is shown in lower case letters with the corresponding amino acids shown by standard three letter designation, (for designations see Table 1)
  • cysteines 459, 462 and 464 were replaced simultaneously using oligonucleotide (3) .
  • Cysteine residues 471 and 474 were then replaced simultaneously using oligonucleotide (4) .
  • Cysteine residues 509 and 695 were then replaced individually using oligonucleotides (5) and (6) respectively.
  • the cysteine to glycine cDNA substitutions were accomplished following the procedure of Kunkel, T.A., Proc. Natl. Acad. Sci. USA, 82,488-492 (1985) which procedure repeats a series of steps for each oligonucleotide and takes advantage of conditions which select against a uracil containing DNA template:
  • E.coli strain which is incapable of removing uracil such as (ung ⁇ ) strains which lack uracil glycosylase.
  • Uracil- containing nucleotides are lethal in 10 single stranded ( + ) M13mpl8 DNA in ung + strains due to the creation of abasic sites by uracil glycosylase.
  • the single stranded ( + ) form of the virus contains the specified vWF cDNA at its multiple cloning site which cDNA is equivalent to the nontranscribed vWF DNA
  • oligonucleotide concentrations typically 40 ng of oligonucleotide was annealed to
  • Steps (A) to (F) of the above process are then repeated for each of oligonucleotides (4) , (5) and (6) until each successive cysteine codon of the vWF sequence within the M13mpl8 phage has been replaced by a glycine codon.
  • H Upon completion of mutagenesis procedures the sequence of the vWF cDNA insert was reconfirmed using the single stranded DNA dideoxy method.
  • the double stranded vWF cDNA fragment containing 7 site- specific cysteine to glycine mutations is then removed from M13mpl8 phage by treatment with EcoRI and Hindlll restriction endonucleases, after which the ends of the fragment are modified with BamHI linkers (Roberts, R.J. et al. Nature. 265, 82-84 (1977)) for cloning into a high efficiency E.coli expression vector.
  • the particular expression vector chosen is plasmid pET-3A, developed by Rosenberg, A.H. et al. Gene.
  • the pET-3A vehicle is refered to as "p7E n or p7E expression plasmid.
  • a second pET-3A-derived expression plasmid (designated p7D) was constructed containing the identical vWF coding sequence cloned into the plasmid in the opposite orientation. p7D should be unable to express the vWF polypeptide fragment.
  • a third expression plasmid (pJDl ⁇ ) contains wild type 52/48 tryptic vWF fragment cDNA encoding the vWF amino acid sequence between residues 441 and 733, (with 7 cysteines) in the same pET-3 vector.
  • the p7E (or p7D and pJD18) expression plasmids were then cloned into an ampicillin sensitive E.coli strain, BL21(DE3), Novagen Co., Madison WI, according to a well established protocol Hanahan, D. , J. Mol. Biol. , 166, 557-580 (1983).
  • Strain BL21(DE3) is engineered to contain a gene for T7 RNA polymerase so that the vWF insert can be transcribed with high efficiency.
  • vWF polypeptide A high level of expression of vWF polypeptide was obtained with p7E and pJDl ⁇ resulting in the generation of cytoplasmic granules or "inclusion bodies" which contain high concentrations of vWF polypeptide in essentially insoluble form. Solubilization of vWF polypeptide was accomplished according to the following procedure. As explained in Example 2, p7E and pJD18 extracts responded very differently to solubilization procedures. See Maniatis, T. et al., Molecular Cloning, 2nd ed., vol. 3, Sec. 17.37, (1989) Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY, for a general discussion of the properties of, and successful manipulation strategies for, inclusion bodies.
  • the cells were harvested by centrifugation at 4000 g for 15 minutes in a JA-14 rotor at 4°C
  • the pelleted cells were washed in 50 ml of ice cold buffer (0.1 M NaCl, 10 mM Tris pH 9.0, 1 mM EDTA) and repelleted by centrifugation at 4000 g at 4°C.
  • the cell pellets from p7E, p7D and pJD18 cultures were each redissolved in 5 ml of lysing buffer and kept ice-cold for 30 minutes.
  • the lysing buffer comprises a solution of sucrose 25%(w/v), 1 mM phenylmethylsulfonylfluoride (PMSF) , 1 mM ethylene diaminetetraacetic acid (EDTA) , 2 mg/ml lysozyme and 50 mM Tris hydrochloride, adjusted to pH 8.0.
  • the relatively insoluble pelleted material derived from each culture (which contains the desired polypeptides except in the case of p7D) was washed at 25°C in 10 ml of buffer No. 2 (0.5% (w/v) Triton X-100 surfactant, 2 mM EDTA, 0.02 M Tris hydrochloride, pH 7.5) and vortexed extensively.
  • the suspension was centrifuged at 14,000 g for 30 minutes at 4°C and the supernatant was then discarded.
  • the process of resuspension of the pelleted material in buffer No. 2, vortexing and centrifugation was repeated twice. Each pellet was then washed in 5 ml of buffer No.
  • the cysteine-free vWF polypeptide (comprising subunit positions 441 to 733) constitutes more than 75% of the material solubilized from the inclusion bodies according to the above procedure. Further purification of the cysteine- 25 free mutant vWF polypeptide was accomplished by redialyzing the partially purified peptide extract against 6 M guanidine-HCl, 50 mM Tris-HCl, pH 8.8 followed by dialysis against 6 M urea, 25 mM Tris-HCl, 20 mM KCl, 0.1 mM EDTA, pH 8.0. The extract was then subjected to high performance 30 liquid chromatography using Q-Sepharose ® Fast Flow
  • the extract from expression plasmid p7E contains as the major component, the mutant von Willebrand factor polypeptide which migrates with an apparent molecular weight of approximately 36,000 gram/mole (g/mol) .
  • the polypeptide appears as a single band under both reducing conditions (addition of between 10 and 100 mM dithiothreitol "DTT" to the sample for 5 min at 100°C prior to running the gel in a buffer also containing the same DTT concentration) and nonreducing conditions, which result is consistent with the substitution of glycine residues for all of the cysteine residues therein.
  • No vWF polypeptide could be extracted from host cells containing p7D expression plasmids as expected from the opposite orientation of the vWF cDNA insert.
  • the cysteine-containing vWF polypeptide expressed by host cells containing pJD18 plasmids, and which contains the wild type amino acid sequence of the 52/48 fragment, (herein represented by a residue 441 to 733 cloned fragment) behaved differently under reducing and nonreducing conditions of electrophoresis.
  • the wild-type sequence expressed from pJD18 forms intermolecular disulfide bridges resulting in large molecular weight aggregates which are unable to enter the 10% acrylamide gels. After reduction (incubation with 100 mM DTT for 5 min at 100°C) , the vWF peptide migrates as a single band with a molecular weight of approximately 38,000.
  • the proteins were blotted and immobilized onto a nitrocellulose sheet (Schleicher and Schuell, Keene, NH) and the pattern was then visualized using immunoreactivity.
  • the von Willebrand factor-specific monoclonal antibodies (from mice) used to identify the polypeptides were RG-46 (see Fugimura, Y. et al. J. Biol. Chem.. 261(1), 3 ⁇ l-3 ⁇ 5 (1986), Fulcher, CA. et al. Proc. Natl. Acad. Sci. USA. 79, 1648- 1652 (1982)), and NMC-4 (Shima, M. et al. J. Nara Med. Assoc. , 36, 662-669 (1985)), both of which have epitopes within the expressed vWF polypeptide of this invention.
  • the secondary antibody ( I25 I-rabbit anti-mouse IgG) , labelled by the method of Fraker, P.J. et al. Biochem. Biophvs. Res. Commun.. 80, 849-657 (1978)), was incubated for 60 minutes at 25°C on the nitrocellulose sheet. After rinsing, the sheet was developed by autoradiography.
  • Peptide extracts from host cells containing p7E and pJDl ⁇ expression plasmids display strong immunoreactivity for RG-46 antibody and a weaker but definite affinity for NMC-4 antibody.
  • peptide extracts from p7D plasmids show no immunoreactivity with either RG-46 or NMC-4.
  • Example 3 Inhibition of botrocetin-induced binding of vWF to platelets by the cysteine-free mutant polypeptide expressed by p7E
  • botrocetin extracted from the venom of Bothrops iararaca modulates the in vitro binding of multimeric von Willebrand factor to platelets (Read, et al. Proc. Natl. Acad. Sci.. 75, 4514-4518 (197 ⁇ )) and that botrocetin binds to vWF within the region thereof containing amino acid sequence positions 441-733 (of the mature subunit) , and thus the GPIb binding domain.
  • vWF Within the region thereof containing amino acid sequence positions 441-733 (of the mature subunit)
  • the urea-solubilized and dialyzed polypeptide extracts obtained (according to the method of Example 1) from cultures containing expression plasmids p7E, p7D and pJD18, were tested without further purification for their ability to inhibit botrocetin-induced vWF binding to formalin-fixed platelets on a dose dependent basis.
  • Formalin-fixed platelets prepared according to the method of MacFarlane, D. et al., Thromb. Diath. Haemorrh.
  • I25 I-vWF binding to the platelets was referenced against 100% binding which was defined as the amount of J25 I- vWF bound in the absence of added peptide extracts.
  • Peptide extracts from expression plasmids p7D, and also pJD18 (unreduced and unalkylated) could not compete with plasma-derived vWF for platelet GPIb receptor binding sites.
  • the peptide extract from plasmid p7E was effective in a dose dependent manner (using a range of 0 to 100 ⁇ g extract/ml) in inhibiting vWF binding.
  • the concentration of urea- solubilized polypeptide extract ( ⁇ g/ml) in the incubation mixture reflects the total protein concentration from the extract. Addition of peptide extracts to the reaction mixture causes certain nonspecific effects which raise apparent initial binding to 110% of the value found in the absence of the added peptide extracts.
  • the 125 -IvWF concentration used was 2 ⁇ g/ml.
  • Example 4 Expression of a mutant vWF fragment of reduced cysteine content containing a disulfide-dependant conformation
  • vWF polypeptide fragment (corresponding to the mature vWF subunit sequence from residue 441 to residue 733) was prepared in which the cysteines at positions 459, 462, 464, 471 and 474 were each replaced by a glycine residue. Cysteine residues were retained at positions 509 and 695, and allowed to form an intrachain disulfide bond.
  • Site directed mutagenesis was performed only with oligonucleotides No. 459 and 471, thereby substituting glycine codons only at positions 459, 462, 464, 471 and 474.
  • mutant vWF cDNA was confirmed using the single-stranded dideoxy method.
  • p5E BamHI linkers, and cloned into pET-3A.
  • the pET-3A vehicle so formed is referred to as "p5E” or p5E expression plasmid.
  • the p5E expression plasmids were then cloned into ampicillin sensitive E.coli strain BL21(DE3), Novagen Co., Madison, WI, according to the procedure of Hanahan, D. , J.
  • the p5E mutant polypeptide was expressed from cultures of E.coli BL21(DE3) following the procedure of Example 1 except that solubilization of inclusion body pellet material in the presence of 8 Molar urea need not be continued beyond the initial 2 hour period at room temperature, at which point redissolved material had reached a concentration of 200 ⁇ g/ml. Oxidation of cysteine residues 509 and 695 to form a disulfide bond was accomplished by dialysis overnight against Hepes-buffered saline.
  • Example 1 pertaining to the p7E extracts, final purification of urea-solubilized inclusion body preparations was accomplished by dialysis against the 6 M guanidirie and 6 M urea buffers followed by anion exchange chromatography.
  • Example 5 Characterization of the mutant vWF fragment produced by expression plasmid p5E
  • the mutant von Willebrand factor polypeptides produced by cultures containing expression plasmid p5E were characterized utilizing the procedures of Example 2, and in particular compared with the vWF fragment expressed by plasmid p7E.
  • Urea-solubilized and dialyzed polypeptides extracted from inclusion bodies were compared with similar extracts from p7E plasmid cultures produced as in Example 1.
  • Example 2 was used to compare the p5E vWF fragments, which can form disulfide bonds using cysteine residues 509 and 695, with the p7E fragment which has no cysteine residues.
  • Electrophoresis was conducted using 7.5 ⁇ g of protein extract per lane on 10% acrylamide gels under reducing (100 mM dithiothreitol) and non-reducing conditions.
  • Coomassie blue extracts from p7E and p5E have identical electrophoretic mobilities. Electrophoresis under nonreducing conditions, however, demonstrates the effects of disulfide bonds involving residues 509 and 695. A substantial amount of the p5E extract appears as a high molecular weight complex (resulting from interchain disulfide bonds) which enters the gel only slightly. Densitometric scanning of the gels of initial preparations indicates that approximately 25% of the p5E polypeptide material found on nonreducing gels is represented by monomers of the 441-733 fragment having an apparent molecular weight of approximately 38,000.
  • the percent of monomer present in p5E extracts can be improved significantly by conducting urea solubilization, dialysis, and thiol oxidation at a more dilute protein concentration, such as 50- 100 ⁇ g/ml, to favor intrachain rather than interchain disulfide bond formation.
  • This p5E monomeric species has a slightly higher mobility during electrophoresis under nonreducing conditions than the comparable p7E product species which has no cysteine residues.
  • the mobilities of these p5E and p7E monomeric 3 ⁇ kg/mol species appear identical under reducing conditions.
  • the slightly accelerated mobility of a polypeptide which retains tertiary structure in the presence of SDS under nonreducing conditions, when compared to the mobility of the homologous polypeptide which the anionic detergent converts completely into a negatively charged fully rigid rod under said conditions, is generally considered suggestive of the presence of an intrachain disulfide bond.
  • vWF-specific murine monoclonal antibodies RG-46 and NMC-4 were used as probes.
  • RG-46 has been demonstrated to recognize as its epitope a linear sequence of amino acids, comprising residues 694 to 70 ⁇ , within the mature von Willebrand factor subunit. The binding of this antibody to its determinant is essentially conformation independent. Mohri, H. et al., J. Biol. Chem.. 263(34), 17901-17904 (19 ⁇ ) .
  • NMC-4 however, has as its epitope the domain of the von Willebrand factor subunit which contains the glycoprotein lb binding site. Mapping of the epitope has demonstrated that ⁇ 5 it is contained within two discontinuous domains (comprising approximately mature vWF subunit residues 474 to 488 and also approximately residues 694 to 708) brought into disulfide- dependent association, Mohri, H. et al., supra, although it was unknown whether the disulfide bond conferring this tertiary conformation in the native vWF molecule was intrachain or interchain. Id. at 17903.
  • antibody to the nitrocellulose sheets was usually accomplished with antibody solutions prepared as follows. Mice were injected with B-lymphocyte hybridomas producing NMC-4 or RG-46. Ascites fluid from peritoneal tumors was collected and typically contained approximately 5 mg/ml of monoclonal antibody. The ascites fluid was mixed (1 part per 1000) into blocking fluid (PBS containing 5% (w/v) non-fat dry milk, Carnation) to minimize non-specific background binding. The antibody-containing blocking fluid was then applied to the nitrocellulose.
  • blocking fluid PBS containing 5% (w/v) non-fat dry milk, Carnation
  • the single chain p5E polypeptide fragment (representing the sequence from residue 441 to residue 733) displayed an approximate 120 fold increase in binding affinity for NMC-4 compared to the comparable cystein-free species isolated from p7E also representing the primary sequence from residue 441 to 733.
  • NMC-4 also fails, under reducing or non-reducing conditions, to recognize as an epitope disulfide-linked dimers from the p5E extract.
  • nitrocellulose filters used to produce autoradio- graphs based on NMC-4 were rescreened with RG-46 by subtracting the initial NMC-4 exposure response, which was kept low through a combination of low antibody titer and short exposure time.
  • the binding of RG-46 to the p7E 36,000 kg/mol polypeptide on the filters is the same whether reducing or non-reducing conditions were chosen, consistent with the replacement of all cysteines by glycine in the expressed polypeptide.
  • vWF antigen reactive to RG-466
  • p5E polypeptide extract A large molecular weight vWF antigen (reactive to RG-46) is present in the p5E polypeptide extract under nonreducing conditions.
  • These p5E vWF aggregates (reflecting interchain disulfide bonds) migrate under reducing conditions in the same position as the p7E polypeptide indicating disruption of their disulfide contacts.
  • the large p5E interchain disulfide aggregates which are readily recognized under nonreducing conditions by RG-46 are not recognized by NMC-4 under either reducing or nonreducing conditions. It is thus demonstrated that the disulfide bond between residues 509 and 695 in native multimeric vWF subunits represents an intrachain contact.
  • Monoclonal antibody LJ-Ibl is known to completely inhibit von Willebrand factor-platelet glycoprotein lb interaction. Handa, M. et al., J. Biol. Chem., 261(27), 12579-12585 (1986) . It reacts specifically with the amino terminal 45 kg/mol domain of GPIb ⁇ which contains the vWF binding site. Vicente, V. et al., J. Biol. Chem.. 265, 274- 280 (1990) .
  • LJ-Ibl was iodinated by the procedure of Fraker, D.J. et al., Biochem. Biophvs. Res. Commun.. 80, 849- ⁇ 57 (1978) using I 125 from Amersham, Arlington Heights, IL and Iodogen (Pierce Chemical Co., Rockford, IL) . Washed platelets were prepared by the albumin density gradient technique of Walsh, et al., Br. J. Haematol. f 36, 281-298 (1977) , and used at a count of 1 x 10 8 /ml. Half-maximal binding of antibody to platelets was observed at 10 ⁇ g/ml LJ-Ibl concentration, which concentration was selected for p5E polypeptide inhibition studies.
  • the p5E polypeptide extract was purified according to the procedure of Example 4 including final purification of the urea-solubilized inclusion body preparation by dialysis against 6.0 M guanidine and urea solutions followed by Q- Sepharose ® chromatography.
  • platelets were incubated for 30 minutes at 22-25°C with LJ-Ibl (10 ⁇ g/ml) and concentrations of purified p5E polypeptide (.002-10.0 ⁇ Molar) .
  • LJ-Ibl 10 ⁇ g/ml
  • concentrations of purified p5E polypeptide 0.2-10.0 ⁇ Molar
  • platelets with bound radioactivity were separated from free antibody by centrifugation at 12000 g through a 20% sucrose layer, in 0.15 M NaCl, 20 mM Hepes, pH 7.4, hereinafter "Hepes-buffered saline" buffer in a microcentrifuge tube.
  • Inhibition of LJ-Ibl binding was plotted in the presence of 2 ⁇ g/ml botrocetin (Sigma Chemical Co., St.
  • botrocetin induces in circulating multisubunit von Willebrand factor and single subunits thereof a conformational change which enhances or permits binding to the GPIb ⁇ receptor.
  • This example demonstrates that the p5E polypeptide (containing an intrachain cysteine 509-695 bond) behaves very much like native circulating von Willebrand factor with respect to how its activity is modulated by botrocetin. Structural similarity is therefore indicated.
  • Example 7 Expression of homodimeric 116 kDa von Willebrand factor fragment in stable mammalian transformants
  • This example is illustrative of conditions under which a DNA sequence encoding the mature vWF subunit fragment having an amino terminus at residue 441 (arginine) and a carboxy terminus at residue 730 (asparagine) may be expressed, and of the secretion from cultured mammalian host cells of a glycosylated homodimeric form of the 441-730 vWF fragment having native tertiary structure.
  • Expression of the 116 kg/mol homodimer is achieved using a DNA construct in which the following structural elements are assembled in a 5' to 3' direction (referring to the coding or nontranscribed strand) : (A) a eucaryotic consensus translation initiation sequence, CCACC; and
  • the cDNA clone, pvWF, encoding the entire pre-pro-vWF gene was obtained from Dr. Dennis Lynch, Dana-Farber Cancer Institute, Boston, MA and was prepared as described in Lynch,
  • the cDNA representing the full length pre-pre-vWF gene from pSP64 was subjected to enzymatic amplification in a polymerase chain reaction according to the method of Saiki, R.K. et al. Science, 239, 487-491 (1988), as described in Example 1.
  • the following oligonucleotides were synthesized by the phosphoramidite method, Sinha, et al., Tetrahedron Letters, 24, 5843 (1983), using a model 380B automated system, Applied Biosystems, Foster City, CA.
  • Oligonucleotide (7) was used to create a Sail restriction site fused 5' to a eucaryotic consensus translation initiation sequence (CCACC) preceding the initiating methionine codon of the vWF cDNA. See Kozak, M. Cell. 44, 183-292 (1986).
  • CCACC eucaryotic consensus translation initiation sequence
  • Oligonucleotide (8) hybridizes with the non-transcribed strand (coding strand) of the vWF cDNA and overlaps with nucleotides which are approximately 360 base pairs from the initiating methionine in the pre-pro-vWF cDNA, thus spanning (at residues 120 and 121 within the pre-pro-vWF cDNA sequence) an Xbal restriction site.
  • the polymerase chain reaction therefore synthesized a cDNA fragment, containing (reading from 5' to 3' on the coding strand) a Sail site, a consensus initiation sequence, an initiating methionine codon, the codon sequence for the signal peptide, and approximately, the first 100 codons of the propeptide, followed by an Xbal site.
  • the amplified cDNA fragment was then inserted, using Sail and Xbal restriction enzymes, into the double stranded replicative form of bacteriophage Ml3mpl8 which contains a multiple cloning site having compatible Sail and Xbal sequences.
  • the resulting clone is known as pADl. See Arrand, J.R. et al. J. Mol. Biol.. 118, 127-135 (1978) and Zain, S.S. et al. J. Mol. Biol.. 115, 249-255 (1977) for the properties of Sail and Xbal restriction enzymes respectively.
  • the vWF cDNA insert was completely sequenced using single- stranded dideoxy methodology (Sanger, F. et al. Proc. Natl. Acad. Sci. USA. 74, 5463-5467 (1977)) to confirm that the vWF cDNA fragment contained the correct vWF coding sequence.
  • a cDNA corresponding to mature subunit residues 441 to 732 may be prepared and then amplified directly from platelet mRNA following the procedure of Newman, P.J. et al. J. Clin. Invest. , 82, 739-
  • Suitable flanking oligonucleotides were synthesized as follows: Oligonucleotide (9) - see SEQ ID NO: 11
  • the ends of the double stranded vWF cDNA fragment product were then modified with BamHI linkers (Roberts, R.J. et al. Nature, 265, 82- ⁇ 4 (1977)), digested with BamHI, and inserted into the BamHI site of pADl, which site is directly downstream(3') from the Xbal site.
  • the resultant plasmid was designated pAD2.
  • Site-directed (loopout) mutagenesis was then performed to synchronize the reading frames of the first insert with the second insert simultaneously deleting all propeptide codon sequence (except that encoding the first 3 amino terminal residues of the propeptide) , and the remaining bases between the Xbal and BamHI sites.
  • oligonucleotide As a loopout primer, the following oligonucleotide was utilized which encodes the four carboxy-terminal amino acid residues of the signal peptide, the three amino-terminal residues of the propeptide, and amino acid residues 441 to 446 of the mature vWF subunit sequence. Oligonucleotide (11) - see SEQ ID NO: 13
  • M13mpl8 phage (containing cDNA corresponding to the consensus translation initiation sequence, the signal peptide, approximately the first 121 amino acids of the propeptide, residual intervening M13mpl ⁇ polylinker sequence, and codons corresponding to mature subunit sequence residues 441 to 732) is grown in an E.coli CJ236 mutant dufung " strain in a uridine rich medium. Since this E.coli strain is deficient in deoxyuridine triphosphatase (dut ⁇ ) , an intracellular pool of dUTP accumulates which competes with dTTP for incorporation into DNA. (see Shlo ai, J. et al. J. Biol. Chem..
  • Viral DNA synthesized under these conditions includes several uracil insertions per viral genome and is stable only in an E.coli strain which is incapable of removing uracil, such as (ung ⁇ ) strains which lack uracil glycosylase. Uracil-containing nucleotides are lethal in single stranded ( + ) M13mpl8 DNA in ung + strains due to the creation of abasic sites by uracil glycosylase.
  • Oligonucleotide (11) is then annealed in vitro to single stranded ( + ) phage DNA, thereby looping out the undesired sequence.
  • oligonucleotide concentrations is suitable in this procedure.
  • 40 ng of oligonucleotide was annealed to 0.5-1.0 ⁇ g M13mpl ⁇ phage ( + ) DNA.
  • a second mutagenesis procedure following steps (A) to (F) above, was performed to add to the cDNA insert a translation termination codon (TGA) , and an Xbal restriction site (TCTAGA) .
  • TGA translation termination codon
  • TCTAGA Xbal restriction site
  • Oligonucleotide (12) - see SEQ ID NO: 14
  • the final M13mpl8 recombinant containing the desired construct as a Sail - Xbal insert was designated pAD3-l.
  • an Xbal site exists in the polylinker region of M13mpl8 directly 5' to the Sail site.
  • the vWF insert was again sequenced by the dideoxy method to verify organization and integrity of the components.
  • the Sall-Xbal fragment was then removed from pAD3-l (as contained within the Xbal-Xbal fragment) and inserted into pBluescript II KS( ⁇ ) vector (Stratagene, La Jolla, CA) which had been previously digested with Xbal.
  • pBluescript II KS( " ) contains an Xhol restriction site which is 5' to the Xbal insert and a Notl site which is directly 3' to the Xbal insert.
  • a resultant plasmid selected as having the proper insert orientation was designated pAD3-2.
  • pCDM8 vector developed by B. Seed et al. Nature, 329, 840-842 (1987) and available from Invitrogen, San Diego, CA
  • Dr. Timothy O'Toole Scripps Clinic and Research Foundation, La Jolla, CA to include a neomycin resistance gene (phosphotransferase II) that was cloned into the BamHI restriction site of pCDM8 as a part of a 2000 base pair BamHI fragment.
  • the site of the BamHI insert is indicated by an arrow in Figure 5.
  • the protein produced by the neomycin(neo) gene also confers resistance against other aminoglycoside antibiotics such as Geneticin ® G418 sulfate (Gibco/Life Technologies, Inc. , Gaithersburg, MD) .
  • the neo gene is provided by the Tn5 transposable element and is widely distributed in procaryots. Lewin, J. , Genes, 3rd ed. , p.596, Wiley & Sons (1987). The final construct places the neo gene under the control of an SV40 early promoter.
  • vWF fragment may be differently restricted or modified for expression capability in these other expression plasmids.
  • Xhol-Notl fragment of pAD3-2 was therefore inserted into pCDM8 neo which had been restricted with Xhol and Notl.
  • Ampicillin sensitive E.coli strain XS-127 cells (Invitrogen, San Diego, CA) were transformed with the resultant ligated DNA mixture following the method of Hanahan, D. , J. Mol. Biol. , 166, 557-5 ⁇ 0 (19 ⁇ 3) .
  • Plasmids from resultant colonies were characterized by restriction mapping and DNA sequencing to identify colonies which contained the intended insert.
  • One such appropriate plasmid (designated pAD5/WT) was maintained in E.coli strain XS-127, and was selected for mammalian cell transformation procedures.
  • supercoiled plasmids Prior to use in transforming mammalian cells, supercoiled plasmids (pAD5/WT) were recovered from host E.coli by an alkaline cell lysis procedure, Birnboim, H.C and Doly, J. , Nucleic Acids Research, 7,1513 (1979), followed by purification by CsCl/ethidium bromide equilibrium centrifugation according to Maniatis, T. et al., Molecular Cloning. 2nd ed. , p. 1.42, Cold Spring Harbor Laboratory Press (19 ⁇ 7) .
  • CHO-Kl cells were grown at 37°C in Dulbecco's modified Eagle's medium (DMEM) (Gibco/Life Technologies, Inc.,
  • CHO-Kl cells have a doubling time in DMEM/10%FCS of approximately 16 hours under these conditions.
  • pAD5/WT plasmids were recovered from cultures of E.coli strain XS-127, according to the method of Birnboim, H.C and Doly, J. , Nucleic Acids Research. 7, 1513 (1979). Ten ⁇ g of plasmids were applied to the cells of each 60 mm dish in a calcium phosphate solution according to the method of Chen et al., supra. After inoculation with plasmid, the cells were maintained in DMEM/10% FCS for 8 hours at 37°C in a 5% C0 2 atmosphere.
  • the growth medium was then replaced with a solution of phosphate-buffered saline, 137 mM NaCl, 2.7 mM KCl, 4.3 mM Na 2 HP0 4 -7H 2 0/1.4 mM KH 2 P0 4 , pH 7.4, hereinafter "PBS", containing also 10% (v/v) glycerol.
  • PBS phosphate-buffered saline
  • the cultures were then maintained in glycerol-PBS for 2 minutes to increase the efficiency of transformation (see Ausukel, et al., eds. Current Protocols in Molecular Biology, p.9.1.3, Wiley & Sons (1987) . After 2 minutes the glycerol-PBS solution was replaced with DMEM/10% FCS.
  • the cells were trypsinized as follows. Growth medium for each dish was replaced by 3 ml of 0.25% trypsin in PBS. Trypsinization was conducted for 3 minutes. The trypsin-containing medium was removed and the dishes were then placed in the incubator for a further 15 minutes after which the cells were resuspended in DMEM containing 10% fetal calf serum. The cells from each dish were then split 20 fold, and plated at a density of 3 x 10 4 cells/60 mm dish (approximately 5% of confluence) .
  • Colonies expressing the recombinant 441-730 vWF polypeptide were detected by dot-blot analysis on nitro- cellulose after lysis in disruption buffer (see Cullen,
  • Confluent transformed CHO-Kl cells were rinsed three times with PBS to remove bovine vWF and then incubated in DMEM without FCS for 16 hours at 37°C in a 5% C0 2 atmosphere.
  • DMEM fetal calf serum
  • lOxIPB lOx immunoprecipitation buffer
  • Immune complexes were precipitated by taking advantage of the affinity of protein A (isolated from the cell wall of Staphylococcus aureus) for constant regions of heavy-chain antibody polypeptides following generally the method of Cullen, B. et al., Meth. Enzymology, 152, 684-704 (1987). See also Harlow, E. et al. eds. Antibodies, A Laboratory Manual, Chapters 14-15, Cold Spring Harbor Laboratory Press (1988) .
  • Protein A-Sepharose ® beads were purchased from Sigma, St. Louis, MO. Immune complexes were then precipitated with the beads in the presence of 3 M NaCl/1.5 M glycine (pH 8.9), and washed twice with lx IPB and then once with lx IPB without Non-idet 40.
  • Immunoprecipitated proteins were then electrophoresed in polyacrylamide gels containing sodium docecyl sulfate (SDS- PAGE) following the method of Weber, K. et al., J. Biol. Chem.. 244, 4406-4412 (1969), or as modified by Laemli, U.K., Nature. 227, 680-685 (1970), using an acrylamide concentration of 10%.
  • Samples of immune-complexed vWF protein were dissociated prior to electrophoresis by heating at 100°C for 5 minutes in non-reducing and 2% SDS-containing acrylamide gel sample buffer to disrupt non-covalent bonds.
  • the protein A-Sepharose ® 4B beads were spun down and discarded. Visualization was accomplished with Coomassie blue staining which revealed the dominant vWF-derived polypeptide species to have an apparent molecular weight, based on molecular weight markers, of about 116,000 g/mol.
  • Protein bands in duplicate gels were blotted and immobilized onto nitrocellulose sheets (Schleicher & Schuell Co., Keene, NH) and the pattern was then visualized using immunoreactivity according to the highly sensitive "Western blot" technique. Burnette, et al., A. Anal. Biochem. , 112, 195-203 (1981) .
  • the von Willebrand factor-specific monoclonal antibodies (from mice) used to identify the polypeptides were RG-46 (see - Fugimura, Y. et al. J. Biol. Chem., 261(1), 381-385 (1986), Fulcher, CA. et al., Proc. Natl. Acad. Sci. USA. 79, 1648- 1652 (1982)), and NMC-4 (Shima, M. et al. , J. Nara Med. Assoc.. 36, 662-669 (1985)), both of which have epitopes within the expressed vWF polypeptide of this invention.
  • the secondary antibody ( 125 I-rabbit anti-mouse IgG) , labelled by the method of Fraker, P.J. et al., Biochem. Biophys. Res. Commun. , 80, 849-857 (1978)), was incubated for 60 minutes at 25°C on the nitrocellulose sheet. After rinsing, the sheet was developed by autoradiography. Growth medium from non-transformed CHO-Kl cells shows no immunoreactivity with RG-46 and NMC-4 anti-vWF monoclonal antibodies under identical conditions.
  • the 116 kg/mol fragment may also be isolated from the culture medium of CHO-Kl cells using immunoaffinity chromatography. Approximately 300 ⁇ g of the 116 kg/mol fragment can be recovered from 500 ml of culture medium derived from transformed CHO-Kl culture plates using NMC-4 antibodies coupled to particles of Sepharose ® 4B.
  • Example 8 - Induction of platelet aggregation by the homodimeric 116 kg/mol von Willebrand factor fragment derived from the culture medium of stable CHO-Kl transformants
  • the tryptic 116 kg/mol fragment has been previously characterized as a dimer consisting of two identical disulfide-linked subunits each corresponding to the tryptic
  • Stable pAD5/WT CHO-Kl transformants were each grown to 90% of confluence in DMEM/10% FCS, at 37°C in a 5% C0 2 atmosphere. The 60 mm plates were then rinsed twice with PBS and the incubation was continued in DMEM (without FCS) for 24 hours. The resultant serum-free culture medium was collected and concentrated (at 18°C) 300 fold in a centrifugation- filtration apparatus, Centricon 30, Amicon Co., Lexington, MA.
  • Dose-dependent platelet aggregation curves were obtained by the addition of concentrated culture medium from pAD5/WT transformed cells to platelets. No aggregation was seen in the presence of control culture medium derived from untransformed CHO-Kl cells. Platelets for the assay were prepared using albumin density gradients according to the procedure of Walsh, et al. British J. of Hematology. 36, 281- 298 (1977) . Aggregation was monitored in siliconized glass cuvettes maintained at 37°C with constant stirring (1200 rpm.) in a Lumi-aggregometer (Chrono-Log Corp. , Havertown, PA) . Aggregation experiments followed generally the procedure of Mohri, H. et al., J. Biol.
  • Ristocetin was then added to a final concentration of lmg/ml at the injection timepoints (time zero) . Aggregation was monitored by recording changes in light transmittance. Platelet aggregation can be observed with as little as 100 ⁇ l of unconcentrated serum-free medium from pAD5/WT-transformed cell lines. Serum-free medium from control untransformed cultures concentrated up to 300 fold, and assayed at up to 10 ⁇ l concentrated medium/100 ⁇ l sample did not induce platelet aggregation.
  • platelets were preincubated with anti-platelet glycoprotein lb monoclonal antibody LJ-Ibl which has been specifically demonstrated to block vWF-platelet GPIb-IX receptor interaction (Handa, et al. , J. Biol. Chem. , 261, 12579-12565 (1986)). Platelets subjected to this preincubation did not exhibit an aggregation response whereas platelets similarly preincubated with monoclonal antibody LJ-CP3 (Trapani- Lombardo et al. , J. Clin. Invest..
  • LJ-CP3 has been demonstrated to block platelet GPIIb/IIIa receptor sites and not vWF-specific GPIb-IX receptors.
  • antibody LJ-Ibl or antibody LJ-CP3 was added, at a concentration of 100 ⁇ g/ml, to the platelet/serum mixture while the mixture was being stirred in the aggregometer, and at a timepoint one minute prior to the point when ristocetin (to 1 mg/ml) was added.
  • Example 9 Construction of a mammalian transformant for the expression of the monomeric 441-730 mature von Willebrand factor subunit fragment with cysteine-to-glycine mutations at residues 459, 462 and 464
  • DNA sequence encoding a mature vWF subunit fragment which has an amino terminus at residue 441 (arginine) and a carboxy terminus at residue 730 (asparagine) and which further contains glycine residues substituted for cysteine residues at positions 459, 462 and 464 thereof, can be constructed and transfected into mammalian cells.
  • the Sall-Xbal insert of pAD3-2 was removed by restriction and then cloned into pcDNAl vector (Invitrogen, San Diego, CA) which had been previously digested with Xhol and Xbal restriction enzymes. Since Xhol and Sail restriction sites contain identical internal sequences -TCGA- / -AGCT- , a Sail restricted fragment may be annealed into an Xhol site. The fragments were ligated with T 4 DNA ligase; however the integrity of the Xhol site was not restored. This plasmid construct was designated pAD4/WT.
  • pcDNAl vector contains an EcoRI site within its polylinker • region which is upstream from the Xhol ("Sail”) site but contains no Smal site.
  • a unique Smal site (CCCGGG) is contained within the vWF cDNA insert, spanning mature subunit residues 716 (glycine) to residue 718 (glycine) .
  • the hybridizing oligonucleotide is shown (3' ⁇ 5') in capital letters and is equivalent to transcribed strand (non- coding strand DNA) . Underlined letters indicate the single base mutations for the mutant codons. The equivalent coding strand is shown in lower case letters with the corresponding glycine substitutions identified by three letter designation.
  • the mutant 950 base pair EcoRI-Smal fragment was then re-inserted into the EcoRI-Smal site of the previously restricted pAD4/WT plasmid.
  • the mutant construct was designated pAD4/ ⁇ 3C
  • pAD4/ ⁇ 3C was transformed into ampicillin sensitive E.coli strain XS-127 according to the method of Hanahan, D., J. Mol. Biol.. 166, 557-560 (1983).
  • COS-l cells pAD4/ ⁇ 3C was introduced into COS-1 cells (SV 40 transformed African Green monkey kidney cells, ATCC - CRL 1650) by a standard calcium phosphate-mediated transfection procedure. Chen, C et al., Mol. Cell. Biol.. 7(8), 2745- 2752 (1987) .
  • COS-1 cells were grown at 37°C in Dulbecco's modified Eagle's medium (DMEM) (Gibco/Life Technologies, Inc., Gaithersburg, MD) supplemented with 10% fetal calf serum (FCS) under a 5% C0 2 atmosphere, and then subcultured 24 hours prior to transformation at a density of 1.5 x 10 5 cells/60 mm tissue culture dish (approximately 25% of confluence) .
  • DMEM Dulbecco's modified Eagle's medium
  • FCS fetal calf serum
  • pAD4/ ⁇ 3C plasmids were recovered from cultures of E.coli strain XS-127 according to the method of Birnboim, H.C and Doly, J., Nucleic Acids Research. 7, 1513 (1979) .
  • Ten ⁇ g of plasmids were applied to the cells of each 60 mm dish in a calcium phosphate solution according to the method of Chen et al., supra. After inoculation with plasmid, the cells were maintained in DMEM/10% FCS for 8 hours at 37°C in a 5% C0 2 atmosphere.
  • the growth medium was then replaced with a solution of phosphate-buffered saline/10% (v/v) glycerol.
  • the cultures were then maintained in glycerol-PBS for 2 minutes to facilitate the production of transformants (Ausukel, et al. eds, Current Protocols in Molecular Biology, p.9.1.3, Wiley & Sons (1987)).
  • the glycerol-PBS solution was replaced with DMEM/10% FCS. Antibiotic resistance was not used to select for stable transformants.
  • the cells were then maintained at 37°C in DMEM/10% FCS in a 5% C0 2 atmosphere.
  • COS-1 cells were also transformed successfully with pAD4/WT plasmids. Although antibiotic resistance was not used to select for stable transformants, transient expression of the 116 kg/mol fragment therefrom was particularly useful for the purpose of comparing the properties of the 116 kg/mol mutagenized polypeptide produced by pAD4/ ⁇ 3C plasmids to those of the pAD4/WT 116 kg/mol homodimer.
  • pAD4/WT plasmids were recovered from storage cultures of E.coli strain XS-127. Transformation of COS-1 cells with pAD4/WT was then accomplished using the procedures of Example 9. The cells were then maintained at 37°C in DMEM/10% FCS in a 5% C0 2 atmosphere.
  • Example 11 Construction of mammalian transformants which express mutant 441-730 mature von Willebrand factor subunit fragments wherein each mutant contains a single cysteine-to-glvcine substitution
  • three plasmids pAD4/G 459 , pAD4/G 462 and PAD4/G 464 , collectively referred to as "pAD4/ ⁇ lC plasmids" were constructed.
  • Such plasmids are identical to pAD4/WT except that each contains a single base pair mutation which corresponds to a single cysteine to glycine substitution at mature vWF subunit residue positions 459, 462 and 464 respectively.
  • the oligonucleotides used are identical to oligonucleotide (13) used to prepare pAD4/ ⁇ 3C except that each contains only one of the three mutant codons of that oligonucleotide, the other two codons being represented by the wild type coding sequence.
  • samples of pAD4/G 459 , pAD4/G 462 , and pAD4/G 464 were each cloned into ampicillin sensitive E.coli strain XS-127 following the method of Example 9.
  • Example 12 Expression and characterization of von Willebrand factor subunit fragments by COS-1 cells transformed with PAD4/WT and pAD4/ ⁇ 3C plasmids
  • COS-1 cells which had been transformed with pAD4/ ⁇ 3C or pAD4/WT plasmids according to the procedures of Examples 9 and 10 respectively were cultured to express the encoded vWF DNA as explained below.
  • COS-1 cells similarly transformed with pcDNAl plasmid vector (not containing a vWF cDNA insert) were used as controls.
  • COS-1 cells at a density of 4-5 x 10 5 /60 mm dish were transformed by adding, at time zero, 10 ⁇ g of pAD4/WT, pAD4/ ⁇ 3C or pcDNAl plasmid. Following the procedure of Examples 9 and 10, the cells were glycerol-shocked after a period of 8 hours. The cells were then covered with DMEM/10% FCS at 37°C in a 5% C0 2 atmosphere for 32 hours.
  • the cells for each culture were then rinsed three times with PBS and the incubation was continued with DMEM (without FCS) which was supplemented with 35 S-methionine (Amersham Co., Arlington Heights, IL) having a specific activity of 1000 Ci/mmol to a final concentration of 100 ⁇ Ci/ml.
  • DMEM without FCS
  • 35 S-methionine Amersham Co., Arlington Heights, IL
  • the cells were returned to the incubator for 16 hours, after which time the respective culture media were harvested for purification by immunoprecipitation of secreted vWF polypeptides.
  • Immunoprecipitation followed generally the procedure of Example 7. Five ml volumes of culture media were incubated with 0.5 ml of 10X immunoprecipitation buffer, 0.05 mg of NMC-4 antibody and 0.05 mg of RG-46 antibody for 16 hours. Treatment with protein A-Sepharose ® 4B was performed according to Example 7. Samples of IgG-complexed vWF protein were dissociated prior to SDS-PAGE in SDS-containing sample buffer.
  • sample buffer was modified to contain 100 mM dithiothreitol (DTT) .
  • COS-l cells transformed with pAD4/WT plasmids produce, under non-reducing conditions, a prominent 35 S-labelled band of an approximate apparent molecular weight of 116,000. This value is consistent with proper mammalian glycosylation of the 441-730 fragment.
  • no 116 kg/mol material is apparent, consistent with the reduction of the disulfide bonds which stabilize the 116 kg/mol homodimer.
  • a prominent 35 S- labelled band is visualized of approximately 52,000 apparent molecular weight.
  • the apparent 52 kg/mol value is again consistent with proper glycosylation of the reduced monomeric 441-730 fragment.
  • the gel lanes corresponding to transformation with pAD4/ ⁇ 3C show no apparent 116 kg/mol material. Instead a band is apparent, under reducing and non-reducing conditions, at an apparent molecular weight of approximately 52,000.
  • Example 13 Use of NMC-4 monoclonal antibody to immunoprecipitate vWF polypeptides 25 secreted by pAD4/WT and pAD4/ ⁇ 3C transformed COS-1 cells
  • the NMC-4 monoclonal antibody has as its epitope the domain of the von Willebrand factor subunit which contains the glycoprotein lb binding site. Mapping of the epitope has
  • Example 12 the procedure of Example 12 was followed to characterize vWF polypeptides secreted by pAD4/WT and pAD4/ ⁇ 3C transformed COS-1 cells, with the modification that immunoprecipitation of the culture media was effected solely with NMC-4 antibody (0.05 mg NMC-4 per 5 ml of culture media to which 0.5 ml of 10X immunoprecipitation buffer had been added) .
  • Example 12 the major component isolated from pAD4/WT culture medium has an apparent molecular weight of 116 kg/mol under non-reducing conditions and 52 kg/mol under reducing conditions.
  • Example 14 Expression and characterization of von Willebrand factor subunit fragments produced by COS-1 cells transformed with
  • PAD4/G 459 PAD4/G 462 or PAD4/G 464 plasmids
  • PAD4/G 462 or PAD4/G 464 plasmid (collectively the "pAD4/ ⁇ lC plasmids") was accomplished according to the procedure of Example 11. Culture media were analyzed for secreted vWF polypeptide according to the procedure of Example 7, using only NMC-4 for immunoprecipitation.
  • This example demonstrates the procedure used to identify the mutation(s) in the mature von Willebrand factor subunit responsible for Type IIB von Willebrand disease in particular patients. Patients selected for screening were previously determined to fulfill all of the criteria for a diagnosis of Type IIB von Willebrand disease. See Ruggeri, Z.M. et al., N. Engl. J. Med.. 302, 1047-1051 (I960).
  • the propositus determined to have a vWF gene with a Trp 550 ⁇ Cys 550 mutation is identified as patient No. 7 in the study reported in Kyrle, P.A. et al., Br. J. Hemat.. 69, 55- 59 (1988) .
  • the propositus determined to have a vWF gene with an Arg 511 ⁇ Trp 511 mutation is identified as patient No. 8 in the same study. Samples of blood were drawn from patients after obtaining informed consent according to the Declaration of Helsinki and institutional guidelines.
  • Platelets were collected from 50 ml of blood drawn into a 5 ml volume of 3.2% trisodium citrate as anticoagulant. The residual total platelet RNA was then isolated by ultracentrifugation through a cesium chloride cushion following the procedure of Newman, P.J. et al., J. Clin. Invest.. 82, 739-743 (1988).
  • vWF-specific oligonucleotide corresponding to the non-coding strand (transcribed strand) for mature vWF subunit residues 899-908.
  • Oligonucleotide (14) see SEQ ID NO: 16 3' GGA CTG GAC CAC • GAC • GTC • TCC • ACG • ACG • AGG • TTCGAA 5' Pro Ser Hindlll
  • the primed vWF mRNA population was then used as template for reverse transcriptase (from Moloney murine leukemia virus, Gibco/Bethesda Research Laboratories, Gaithersburg, MD) according to the procedure of Maniatis, T. et al., Molecular Cloning. 2 ed., Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY (1989) .
  • RNA strands were then removed by alkaline hydrolysis and the first strand cDNA was primed for second strand synthesis using DNA polymerase I and then amplified in a polymerase chain reaction ("PCR") as described in Example 1 using oligonucleotide 14, and also oligonucleotide 15 (equivalent to coding strand, non- transcribed strand DNA, corresponding to amino acid residues 428-436) .
  • PCR polymerase chain reaction
  • vWF pseudogene said gene having an intron-exon arrangement similar to that of the functional gene within the region thereof corresponding to the mRNA region selected for amplification
  • priming oligonucleotides complementary to exons 23 and 24 Mancuso, D.J. et al., J. Biol. Chem.. 264, 19514-19527 (1989)
  • Amplified DNA of the predicted length was therefore verified to be derived from platelet cDNA and not from genomic DNA corresponding to small quantities of leukocytes or other cells which may have contaminated the platelet preparation.
  • the amplified 1.4 kilobase cDNA fragment corresponding to mature subunit residues 428-908 was then subjected to further rounds of PCR amplification which split the fragment into two smaller overlapping cDNA regions (corresponding to amino acid residues 440-670 and 660-905) to facilitate sequence analysis.
  • Priming oligonucleotides therefor were synthesized (according to the method of Example l) to correspond approximately to the first twenty nucleotides on the 5' (upstream) and 3' (downstream) ends of each of the two overlapping fragments and contained also either an EcoRI (if 5') or Hindlll (if 3') restriction sequence so that the amplified 440-670 or 660-905 sequences so prepared could be inserted into M13mpl8 phage for sequencing.
  • Resultant double stranded vWF cDNA corresponding to the residue 440-670 or 660-905 fragment was then inserted into the multiple cloning site of the double stranded replicative form of bacteriophage M13mpl8 using EcoRI and Hind III restriction enzymes, and then sequenced by the single-stranded dideoxy method (Example 1, Sanger, F. supra)
  • One patient was found to have a mutation at the codon corresponding to mature subunit residue 550 that specified a Trp to Cys mutation ( 5' TGG 3' ⁇ 5 TGC 3' ) .
  • the transversion mutation destroys an Avail restriction site overlapping codons for residues 550-552 of the mature subunit. Absence of the restriction site was confirmed in the patient's genomic DNA.
  • Another patient was found to have a mutation at the codon corresponding to mature subunit residue 511 specifying an Arg to Trp mutation ( 5' AGG 3' ⁇ 5' TGG 3' ) . Both patients were found to be heterozygous for their particular amino acid substitutions, a finding consistent with the autosomal dominant mode of inheritance seen in most Type IIB patients. Ruggeri, Z.M. et al., N. Engl. J. Med.. 302, 1047- 1051 (1980) .
  • GPIb( ⁇ ) binding domain of vWF is formed primarily by residues contained in two discontinuous sequences, comprising approximately Cys 474 -Pro 488 and approximately Leu 694 -Pro 708 maintained in proper conformation in native vWF by disulfide bonding. Mohri, H. et al., J. Biol. Chem.. 263(34), 17901-17904 (1988). It has also been demonstrated that an intrachain disulfide bond which is necessary to provide that conformation is formed by cysteine residues 509 and 695 (U.S. Application Serial No. 07/600,183, filed. October 17, 1990 and Examples 1-6 reported herein) .
  • the present development provides substantial evidence that the "loop" region of the mature vWF subunit (between residues 509 and 695) modulates the binding properties toward GPIb ⁇ of the above mentioned primary sequence regions of vWF.
  • the following methods are representative of techniques which can be employed to (A) identify within the "loop" region of vWF further potentially important primary sequence subdomains or specific amino acids involved in modulating binding of vWF to GPIb ⁇ ; and/or (B) create artificial vWF-derived polypeptide sequences with altered modulating or binding activity.
  • vWF DNA from plasmid p5E which encodes the amino acid sequence comprising mature subunit residues 441 to 733 in which the cysteine residues at positions 459, 462, 464, 471 and 474 thereof are replaced by glycine residues
  • novel variant DNA sequences can be constructed which encode variant vWF-derived polypeptides.
  • Resultant potential therapeutic polypeptides can be screened for relative binding affinity (1) in direct binding assays for affinity to GPIb ⁇ , or (2) in botrocetin or ristocetin induced binding assays, or (3) to conformation dependent vWF-specific antibodies. Random mutagenesis experiments can also be performed using vWF DNA constructs suitable for expression in mammalian cells such as those of Example 7.
  • oligonucleotides suitable for site directed mutagenesis protocols and spanning sequential 10 amino acid subdomains of the loop can be generated using a procedure designed to yield a randomly mutagenized oligonucleotide population.
  • the randomized vWF oligonucleotide is then hybridized, for example, to M13mpl8 to copy the mutation into a residue 441-733 encoding DNA sequence.
  • oligonucleotide refers to transcribed strand DNA.
  • each of the four nucleoside phosphoramidite reservoirs (A,T,G,C) for oligonucleotide synthesis would be "doped" with a small amount of each of the other three bases. Incorporation of one of the "doping" nucleotides would result in a mutant oligonucleotide. The amount of doping can be adjusted to control results.
  • the resultant randomized population of mutant oligonucleotides is then used in the standard site directed mutagenesis protocol (Example 1) to construct a pool of mutagenized VWF "loop" DNA sequences in M13mpl8 corresponding to the mature vWF subunit residue 441- 733 fragment and suitable for subcloning into a bacterial expression system. It is possible to control the number of mutations per molecule by controlling the composition of the base mixtures. For example, it is possible to select for only single base pair substitutions or to select for molecules which have 2, 3, 4, or more mutations.
  • the procedure developed by Hutchison, supra typically employed solutions of each of the four bases in which approximately 1.5% impurity of each of the other three bases contaminates the original base solutions.
  • Mutagenesis using this particular doped mixture resulted in roughly 41% of clones with no base substitutions, 40% with one, 15% with two, 3% with three and 0.7% with four (for target nucleotide sequences corresponding to 10 amino acids) .
  • the resultant mutant M13mpl8 populations are then subject to restriction (Example 1) , and the mutagenized DNA sequences are inserted into vectors or plasmids such as pET- 3A for expression in host bacterial cells.
  • Large scale screening of mammalian clones is generally much more difficult than for bacterial clones.
  • promising mutations identified in bacterial constructs may later be inserted into mammalian or other eucaryotic host cells for further testing or for commercial-scale polypeptide production.
  • mutant clones can then be screened in GPIb ⁇ binding assays or in binding assays with vWF-specific monoclonal antibodies (as described below) .
  • Mutant clones having cell lysates which exhibit enhanced platelet binding or antibody response can be sequenced to determine the amino acid alteration(s) responsible for the mutant phenotype. In this way a very systematic analysis of the loop region of vWF can be performed and mutations which alter the binding of vWF to GPIb ⁇ can be identified.
  • the mutagenesis techniques of Method 1 above is equally applicable to permuting the amino acid sequence regions of the mature subunit believed to represent the actual GPIb ⁇ binding site (Leu 469 -Asp 498 and Glu 689 -Val 713 ) for the purpose of enhancing their GPIb ⁇ affinity.
  • Randomly mutagenized oligonucleotides prepared and used as described above, and which span domains of approximately 10 amino acids adjacent to residues 510, 520, 530, 540, 550, 560, 570 and 580 can be utilized.
  • Type IIB disease-conferring neutral mutant codons such as Trp 543
  • Trp 543 may be replaced by codons for other neutral or negatively charged amino acids.
  • Representative further target amino acid sites predicted to yield mutant polypeptides having Type IIB properties and resultant therapeutic utility include the arginine residues at positions 524, 545, 552, 571, 573, 578 and 579, the lysine residues at positions 534 and 549 and the histidine residues at positions 559 and 563.
  • mutagenesis strategies which can be used to probe the specific structural features and amino acid sequence requirements therefor which confer upon the vWF loop region the ability to modulate GPIb ⁇ binding. Such strategies are also useful in constructing vWF-derived polypeptides containing, for example, mutant loop regions which are useful as therapeutics. Representative, additional mutagenesis strategies are hereafter described. In the practice of this invention, effective substitutions need not be made at the exact residue positions corresponding to the targeted wild type residues. For example, substitution of cysteine for Lys 549 or Val 551 or for other nearby residues instead of for Trp 550 may be performed, with the resultant polypeptides being subjected to screening for therapeutic utility.
  • Table 2 presents representative examples of potentially useful amino acid substitutions, deletions and additions which accomplish net reduction of positive charge at or adjacent to specific sites. Similar strategies can be employed at or adjacent to other specific residues of vWF to accomplish net reduction of negative charge or to break or form a hydrogen bond, salt bridge, or hydrophobic contact.
  • IIB mutations may also be subject to the above mentioned random mutagenesis procedures and then screened for restoration of normal binding function such as, for example, having a normal response in a modulator-induced GPIb ⁇ binding assay.
  • normal binding function such as, for example, having a normal response in a modulator-induced GPIb ⁇ binding assay.
  • a particular "reversion" mutation proximal to residue 511 would compensate " for, and nullify the effect of the original Arg ⁇ Trp 511 Type IIB mutation.
  • the associated DNA sequence can then be determined to identify the relevant counteracting amino acid.
  • Such procedures can be used to give important further evidence as to which other residue positions in the mature subunit vWF amino acid sequence are important modulators of GPIb ⁇ binding.
  • a device used for the enzyme- linked immunofiltration assay technique Pierce Chemical Co., Rockford, IL, can be adapted in combination with immobilization of the mutant vWF-derived polypeptides to be tested. It is considered most efficient to initially test the effect of mutant codons on vWF polypeptides expressed from bacterial constructs and to then copy potentially useful mutations (using, for example, mutagenesis in M13mpl ⁇ vehicle and the procedure of Example 22) into a mammalian expression construct. High levels of mutant vWF polypeptides corresponding to mutant DNA sequences can be expressed from pET-3A type bacterial expression plasmids such as p5E.
  • ELIFA enzyme- linked immunofiltration assay technique
  • Mutant polypeptides constitute a major portion of host E.coli cell lysates and can be readily screened for GPIb ⁇ affinity. Accordingly, site directed mutagenesis can be performed following the procedure of Example 1 using as template in M13mpl ⁇ the vWF fragment corresponding to p5E expression plasmid (Example 4) which because of the use of BamHI linkers in assembly of p5E is recovered therefrom and inserted into M13mpl8 as an Xbal/Hindlll fragment (see Example 17) .
  • oligonucleotide pool oligonucleotides each having randomly mutagenized residue 505 to 524 sequences are used.
  • the mutagenized population of M13mpl8 constructs can be cloned into pET-3A plasmids after which the expression plasmids can be transformed into E.coli BL21 (DE3) following the procedure of Example 1.
  • Preparation of mutant polypeptide extracts from E.coli BL21(DE3) for screening follows the procedure of Example 1 with the final step being solubilization of extracted inclusion body material with 8 M urea at room temperature for 2 hours.
  • Resultant extracts of expressed mutant p5E-type vWF polypeptides are immobilized following the manufacturer's instructions onto a nitrocellulose membrane (0.45 ⁇ pore size) using 96-well sample application plates (Easy-Titer ® ELIFA System, Pierce Co., Rockford, IL) and a vacuum chamber.
  • 96-well sample application plates Easy-Titer ® ELIFA System, Pierce Co., Rockford, IL
  • Commercially available pump materials can be used.
  • the apparatus is suitable for screening large series of clone lysates in an ELIFA or dot blot system and allows also quantitative transfer of sample fluids to underlying microtiter wells without cross contamination.
  • Immobilization of the vWF polypeptides is accomplished by causing a suitable volume, such as 200 ⁇ l, of each resuspended inclusion body pellet material (in 8 M urea) to be vacuum-drawn through the individual wells to the nitrocellulose membrane over a 5 minute period. Several 200 ⁇ l volumes of Hepes-buffered saline are then drawn through the membrane to remove urea.
  • a suitable volume such as 200 ⁇ l
  • the protein binding capacity of the membrane is then saturated by passing through it three consecutive 200 ⁇ l aliquots of HEPES/BSA buffer herein comprising 20 mM Hepes, pH 7.4, 150 mM NaCl, and 1% w/v bovine serum albumin (Calbiochem, La Jolla, CA) .
  • a 50 ⁇ l volume of HEPES/BSA containing botrocetin (at approximately 0.5 ⁇ g/ml) or containing ristocetin ( at approximately 1 mg/ml) can be vacuum drawn through the nitrocellulose membrane again over a 5 minute period.
  • the ristocetin-induced precipitation of bacterially-expressed vWF polypeptides observed under some test conditions is not expected to cause difficulty in this assay as the polypeptide is already immobilized.
  • GPIb( ⁇ ) represented by its external domain, glycocalicin, or the 45 kg/mol tryptic fragment thereof is next applied to the nitrocellulose using the vacuum system and the 96-well plate.
  • the GPIb ⁇ fragments are purified and 125 iodinated by standard procedures. Vicente, V. et al., J. Biol. Chem.. 265, 274-280 (1990). 50 ⁇ l aliquots of HEPES/BSA containing 15 I-GPIb ⁇ fragments (0.25 ⁇ g/ml having a recommended specific activity of between approximately 5xl0 8 and approximately 5xl0 9 cpm/mg) can then be vacuum drawn through the nitrocellulose filter over 5 minutes.
  • the membrane is then allowed to dry and discs corresponding to the position of each application well are cut out and counted in a scintillation spectrometer to determine bound radioactivity.
  • An autoradiograph of the membrane can also be obtained before cutting out the discs in order to ascertain that there was no leakage of radioactivity from one well to another.
  • the counting process may be facilitated by scanning the developed autoradiogram in a densitometer to digitize the intensity of developed spots. As long as the autoradiogram is not excessively overdeveloped, beyond the linear region of response, useful qualitative results are obtained.
  • An alternate procedure to derive from individual host E.coli clones an impure extract which can be screened in immunoblot or dotblot procedures is as follows.
  • vWF fragment synthesis is induced by adding isopropyl-/3-d-thiogalactopyranoside (IPTG) , U.S. Biochemicals, Cleveland, OH, to 5 mM and continuing growth for approximately 2.5 hours.
  • IPTG isopropyl-/3-d-thiogalactopyranoside
  • the cells are harvested by centrifugation for 1 minute at 10,000 g and then washed and repelleted (at 10,000 g) 3 times with phosphate buffered saline (0.14 M NaCl, 0.1 M Na 2 HP0 4 pH 7.0).
  • the bacterial pellet is then solubilized by boiling for 10 minutes in a buffer comprising 0.01 M NaH 2 P0 4 , 10 mM Na 2 EDTA, 1% (w/v) sodium dodecylsulfate, pH 7.0.
  • the incubation is continued for 2 hours at 60°C in the presence also of 10 mM dithiothreitol (DTT) .
  • Suitable volumes (such as 200 ⁇ l) of such extracts can be used directly in ELIFA apparatus or dot • immunoblot analyses.
  • ELIFA immunoblot analyses.
  • Prior to adding 125 I-GPIb ⁇ to the plate several rinses of Hepes-buffered saline are washed through the wells. This extract preparation technique is applicable to the screening requirements posed by Examples 25-30.
  • vWF derived polypeptides from colonies representing the most intense response are selected for confirmation of enhanced binding using methods such as subjecting purified or partially purified extracts therefrom as appropriate to (A) i munoblotting according to the procedure of Example 2 with conformation-dependent NMC-4 antibody; (B) assaying for ability to inhibit botrocetin-induced vWF binding to formalin-fixed platelets on a dose dependent basis (Example 3) ; or (C) assayed for ability to inhibit the binding of anti GPIb ⁇ monoclonal antibodies to platelets (Example 6) .
  • the procedure of Example 6 can be readily adapted as a supplementary screening system for other target receptors besides GPIb ⁇ (see Examples 25-30) .
  • Clones which confer enhanced positive responses in these systems are then subjected to standard DNA sequencing procedures to identify the vWF gene mutations responsible for the mutant properties.
  • the appropriate mutations may be copied, according to the procedure of Example 22, into a vWF DNA sequence within a plasmid (such as a pAD5/WT-pCDM8 neo expression plasmid) suitable for expression in CHO-Kl cells. Further characterization, such as enhanced potential for induction of platelet aggregation by 116 kg/mol homodimers thereof can then be performed.
  • Example 17 Selection of oligonucleotides for expression in E.coli of fragments of mature von Willebrand factor subunit reflecting Type IIB disease mutations
  • This example demonstrates the mutagenesis strategy for expression in E.coli of the vWF subunit sequence encoded by p5E or p7E plasmid, said constructs containing also Trp 511 or Cys 550 mutations.
  • p7E and p5E expression plasmids (Examples 1 and 4) were recovered from cultures of E.coli strain BL21 (DE3) according to the alkaline lysis procedure of Birnboim, H.C and Doly, J., Nucleic Acids Research, 7, 1513 (1979).
  • the p5E and p7E constructs contain, in reference to the vWF BamHI insert, an upstream Xbal site and a downstream Hindlll site.
  • the BamHI site at which the vWF sequence is inserted is positioned directly between an upstream initiating methionine codon of the parent plasmid and a downstream stop codon thereof. Rosenberg, A.H. et al.. Gene. 56, 125 (1987) .
  • expressed p5E or p7E vWF polypeptides contain also a 17 residue amino terminal sequence extension derived from the gene 10 capsid protein of the vector.
  • Xbal/Hindlll fragment was removed from p5E or p7E and inserted into Ml3mpl8 which had been previously restricted with Xbal and Hindlll.
  • Site directed mutagenesis was then performed in M13mpl8, according to the procedure of Examples 1 and 4 using the following oligonucleotides (for p7E) to insert either a Trp 511 or Cys 550 mutation.
  • Trp 511 Oligonucleotide (16) - see SEQ ID NO: 18
  • Oligonucleotides are equivalent to non-coding strand (transcribed strand) DNA with the secreted single stranded (+) form of M13mpl8 DNA containing coding strand vWF DNA.
  • Trp 511 using oligonucleotide 18
  • Cys 550 against using oligonucleotide 17
  • the hybridizing oligo ⁇ nucleotide reflected a Cys 509 codon instead of the previously inserted glycine 509 mutation as shown below.
  • Example 18 Effect of recombinant von Willebrand factor p5E fragments reflecting Type IIB mutations on the binding of anti-glycoprotein lb monoclonal antibody LJ-Ibl to platelets
  • Example 14 the von Willebrand factor DNA sequence as contained within p5E (Example 4) was mutagenized to contain either a tryptophan codon or a cysteine codon corresponding to residue positions 511 and 550 respectively.
  • the mutant polypeptides were expressed in E.coli strain BL21(DE3), and then solubilized from inclusion bodies, according to the procedure of Example 4.
  • LJ-Ibl was prepared as described in Handa, M. et al., J. Biol. Chem.. 261(27), 12579-12585 (1986) , iodinated according to the procedure of Example 6 above, purified on protein-A Sepharose ® (Sigma, St. Louis, MO) according to the method of Ey, P.L. et al., Immunoche istry. 15, 429-436 (1978) and then used in the competition assays at a concentration of 20 ⁇ g/ml. Washed platelets (used at 1 x 10 8 /ml) were also prepared according to the procedure of Example 6.
  • the assay is based on the ability under certain circumstances of native vWF to inhibit the binding to platelets of the anti-glycoprotein lb monoclonal antibody LJ- Ibl.
  • the antibody is also a potent inhibitor of vWF binding to platelets, indicating that the epitope of LJ-Ibl must overlap with the vWF binding site in GPIb ⁇ .
  • Incubations were performed by mixing the purified fragments at specified concentrations (Figure 3) with washed platelets and 125 I-LJ-Ibl for 30 minutes at 22-25°C After the incubation separation of platelet-bound from free antibody was achieved by centrifugation through a layer of 20% sucrose in Hepe ⁇ -buffered saline at 12,000 g for 4 minutes. See Ruggeri, Z.M. et al. , J. Clin. Invest.. 72, 1- 12 (1983) .
  • Residual antibody binding ( Figure 3) is expressed as a percentage of binding determined from control incubation mixtures containing LJ-Ibl (20 ⁇ g/ml) in 20 mM Hepes, 150 mM NaCl, pH 7.4 without vWF fragments.
  • the figure demonstrates that both the Trp 511 and the Cys 550 Type IIB mutations increase the affinity of the purified polypeptide for GPIb ⁇ .
  • Example 19 Effect of the recombinant p5E vWF fragment containing a Cys 55 " mutation on LJ-Ibl binding to platelets at different monoclonal antibody concentrations
  • the Cys 550 polypeptide competes for platelet GPIb ⁇ receptor at both antibody concentrations with a higher affinity than the wild type p5E polypeptide.
  • the affinity of the p5E-Cys 550 molecule for platelet receptor is at least 5-fold greater than that of the "wild type" p5E molecule.
  • An additional procedure to test the behavior of vWF polypeptides containing Type IIB mutations is dependent on direct binding of 125 I-labelled polypeptides to platelets. It is noted also that most of the p5E-Cys 550 molecules in the samples whose activity was demonstrated in Figures 3 and 4 are dimers.
  • Example 20 An improved procedure to solubilize recombinant bacterially- expressed and disulfide-stabilized residue 441-733 vWF fragments
  • An optimized procedure for the solubilization of "p5E- type" polypeptides with formation of disulfide bonds therein has been developed which is believed to comprise an improved method to practice this aspect of the invention.
  • a sample of "wet pellet" (Example 1) weighing approximately 350 mg was dissolved in 10 ml of a buffer composed of 6 M guanidine-HC1, 50 mM Tris, pH 8.8.
  • Dithiothreitol (DTT) was then added to a final concentration of 10 mM, and the mixture was allowed to set at 37°C for two hours.
  • the protein concentration of the solution was determined by a bicinchoninic acid (BCA) titration kit
  • the recommended acetonitrile gradient profile is 30% for 5 minutes, increasing linearly to 56% in 35 minutes, to 70% in 5 minutes, and maintained at 70% for an additional 10 minutes.
  • the column is operated at a constant flow rate of 2.5 ml/min.
  • the oxidized monomer of p5E itself corresponds to the most hydrophilic major peak, eluting at approximately 40 minutes.
  • Example 21 Expression in stable mammalian transformants of the homodimeric 116 kg/mol von Willebrand factor fragment containing a Trp 550 to Cys 550 mutation
  • DNA sequence encoding the mature vWF subunit fragment having an amino terminus at residue 441 (arginine) and a carboxy terminus at residue 730 (asparagine) , and containing also a Type IIB mutation may be expressed in a stable mammalian cell transformant with secretion therefrom of the polypeptide.
  • the mutation strategy of Example 9 was adopted, with modifications, to insert the Cys 550 codon mutation into a pCDM ⁇ " 0 construct.
  • pAD4/WT plasmids were recovered from storage cultures of E.coli strain XS127.
  • the approximate 950 base pair EcoRI-Smal fragment of pAD4/WT (Example 9) was subcloned into the EcoRI-Smal site within the polylinker region of M13mpl ⁇ phage;
  • the vWF sequence in M13mpl ⁇ was then mutagenized according to the site directed mutagenesis protocol of Example 1.
  • Oligonucleotide 17 (see Example 17) was used to insert the Trp 550 ⁇ Cys 550 mutation.
  • the oligonucleotide is equivalent to non-coding strand (transcribed strand) DNA with the secreted single stranded (+) form of M13mpl8 DNA containing coding strand vWF DNA.
  • the mutagenized DNA sequence was recovered as the EcoRI- Smal fragment and subcloned into pAD5/WT (Example 7) which had been previously digested with EcoRI and Smal.
  • Example 7 discloses that the Xhol-Notl fragment of pAD3-2 (containing the expression construct for wild type vWF residues 441-730) contains the following sequence of elements
  • No Smal restriction sites are contained in the parent pCDM ⁇ plasmid.
  • the complete nucleotide sequence of pCMD ⁇ is available from Invitrogen, San Diego, CA) .
  • an additional Smal site is contributed to the pAD5/WT construct as part of the pBluescript II KS( " ) polylinker (upstream from the vWF "Xbal- Xbal" insert and downstream from the EcoRI site) .
  • a further Smal site arises in the 2000 base pair neomycin resistance gene fragment cloned into the BamHI site of pCDM ⁇ to create pCDM ⁇ 060 .
  • a strategy of (1) partial digestion with Smal, and (2) agarose gel purification of the appropriately restricted vehicle fragment was used to assure reassembly of the proper expression vector.
  • Five ⁇ g of pAD5/WT plasmid were incubated with 5 units of EcoRI for 60 minutes at 37°C resulting in complete digestion of the site and a homogenous population of linear fragments.
  • a partial digest with Smal was then accomplished using 5 ⁇ g of linearized plasmid as substrate for 0.1 unit of Smal (at 37°C for 15 minutes).
  • Plasmid fragments were purified on an agarose sizing gel and a population of linearized plasmid of approximately 7.3 kb having been cleaved at the vWF residue 716-718 site was selected for insertion of the mutagenized EcoRI-Smal fragment.
  • the Arg 511 to Trp 511 mutation may be similarly expressed in a 116 kg/mol homodimer using oligonucleotide (18) in the mutagenesis protocol.
  • Trp 511 , Cys 550 and further Type IIB mutations may be expressed in a single polypeptide.
  • Example 7 Experimental procedures for effecting stable transformation of Chinese hamster ovary cells and for immunopurification of secreted 116 kg/mol vWF polypeptide were described in Example 7.
  • an immunoaffinity column procedure was used for the purpose of purifying vWF polypeptides containing IIB mutations according to the present example.
  • Twenty mg of purified NMC-4 antibody were coupled to CNBr-activated Sepharose ® 4B beads (Pharmacia, Uppsala, Sweden). The column was preequilibrated with 0.5 M LiCl, 50 mM Tris-HCl, pH 7.4, containing 0.05% (w/v) NaN 3 .
  • An alternate strategy for the transfer of Type IIB mutation codons to pAD5/WT expression constructs is to transform pAD3-2 into E.coli CJ236 and select for bacterial colonies resistant to ampicillin (conferred by plasmid) and chloramphenicol (conferred by host CJ236) .
  • An individual colony is grown in 2X-YT culture medium to late log phase and diluted 1:100 in fresh medium in the presence of VCS-M13 (helper filamentous phage available from Strategene, La
  • the vWF inserts within the mutant plasmids are sequenced completely to confirm the absence of any additional mutagenic errors.
  • the vWF insert is cloned into pcDMS 000 as an Xhol/Notl fragment as described above for the generation of pAD5/WT.
  • An additional strategy is to transform pAD5/WT into CJ236 and to select on plates containing chloramphenicol and kanamycin (Kan r is conferred by the neomycin gene) .
  • a single resistant colony is picked and grown as described above for preparation of single-stranded DNA.
  • An extension reaction using a coding strand oligonucleotide followed by transformation into XS-127 results in colonies with mutations, the frequencies ranging from 20-100%, depending upon the oligo and purity of the single-stranded DNA used in the mutagenesis reaction. Mutant colonies are sequenced to verify the targeted mutation, and the lack of any unexpected mutation.
  • the mutant plasmids are ready for transformation into CHO-Kl cells for the establishment of stable cell lines.
  • Example 22 Construction of a stable mammalian transformant for the expression of the monomeric 441-730 mature von Willebrand factor subunit fragment with cysteine-to- glycine mutations at residues 459, 462 and 464 and containing also one or more mutations reflective of Type IIB disease
  • an EcoRI- Smal fragment may be removed from pAD4/WT plasmid and subjected to two or more successive rounds of site directed mutagenesis in M13mpl8 to (A) replace one or more of cysteine residues 459, 462 and 464 with, for example, glycine or alanine codons and (B) substitute one or more mutant codons identified from Type IIB patients or one or more codons which confer on the resulting polypeptide properties reflective of Type IIB von Willebrand disease.
  • Oligonucleotide 13 can be used to substitute glycine codons for each of the above specified cysteine codons thereby preventing formation of the 116 kg/mol homodimer and leading to the expression of 52/48 kg/mol monomers with wild type tertiary structure.
  • a second round of mutagenesis using, for example, oligonucleotide 17 or 18 is used to insert Type IIB point mutations, in this case Cys 550 or Trp 511 .
  • monomeric residue 441-730 fragments reflecting Type IIB codon mutations and only one or two of glycine substitutions at positions 459, 462 and 464 may be made following the above procedure and using the oligonucleotides of Example 11.
  • Example 23 Effect of reduced and alkylated recombinant von Willebrand factor fragment reflecting the Cys 550 Type IIB mutation on the binding of anti-glycoprotein lb monoclonal antibody LJ-Ibl to platelets
  • Sepharose ® Fast Flow (Pharmacia, Uppsala, Sweden) for anion exchange followed by cation exchange on a Protein-Pack SP 8HR column (Waters Co., Bed f ord, MA).
  • the resultant poly., aptides contain glycine residues at positions 459, 462, 464, 471 and 474 and chemically inactivated cysteines at positions 509 and 695, and in the case of p5E-Cys 550 , an additional chemically inactivated cysteine at position 550. Consistant with the lack of glycosylation arising in the bacterial expression system, the polypeptides have apparent molecular weights of approximately 36 kg/mol.
  • Binding inhibition assays were performed generally according to the procedure of Example 16 with 10 ⁇ g/ml of l25 I-U-Ibl being used to evaluate the inhibitory effect of vWF polypeptides on antibody binding. Ten ⁇ g/ml is approximately the concentration of LJ-Ibl at which, in these assays, half-maximal binding of antibody to platelets is acheived. Various concentrations of vWF-derived polypeptide ( Figure 6) were used with the constant amount of LJ-Ibl. Non-specific binding was determined in the presence of a 100 fold excess of unlabelled LJ-Ibl and has been subtracted from all data points.
  • FIG. 6 demonstrates comparative antibody binding inhibition results for the reduced and alkylated p5E molecule (r36/Trp 550 ) and for the mutant reduced and alkylated p5E molecule carrying also a reduced and alkylated cysteine at position 550 (r36/Cys 550 ) .
  • Example 18 ( Figure 3) where the Cys 550 mutation substantially enhanced the binding of bacterially-expressed polypeptide to platelets to the exclusion of LJ-Ibl in the context of a p5E construct which polypeptide possessed the 509-695 loop.
  • botrocetin at a concentration of approximately 0.4 ⁇ g/ml up to about 10 ⁇ g/ml or higher, to a suitable concentration of bacterially- expressed residue 441-733 vWF fragment (such as approximately 0.5 ⁇ Molar) substantially enhances the ability of the vWF fragment to inhibit the binding of an anti-GPIb ⁇ monoclonal antibody to GPIb ⁇ , as measured by the concentration of the vWF fragment necessary to achieve half-maximal inhibition.
  • the vWF fragment for which the effect can be demonstrated includes the p5E molecule containing an intrachain disulfide bond, reduced and alkylated p5E polypeptide, the p7E polypeptide, and the fragment comprising residues 445-733 when reduced and alkylated.
  • the expressed residue 441-733 fragments of the invention contain attached to the amino terminal residue (441) a 17 residue amino acid sequence derived from the gene 10 capsid protein of the pET-3A vector.
  • Example 24 Inhibition of antibody binding to platelets by mutant and non-mutant homodimeric 116 kg/mol fragments expressed from CHO-Kl cells
  • Example 23 measurement of binding inhibition was performed according to the procedure of Example 23 except that ristocetin (Sigma, St. Louis, MO) was added to a final concentration of 1 mg/ml at a point in time 30 minutes prior to centrifugation.
  • Wild type recombinant 116 kg/mol homodimer (Trp 550 ) was prepared as described in Example 7.
  • the DNA corresponding to mutant 116 kg/mol homodimer (Cys 550 ) was prepared according to the procedure of Example 21 with expression thereof following the procedure of Example 7, as modified in Example 21.
  • the inhibitory effects of mammalian-expressed vWF fragments on anti-GPIb ⁇ antibody binding to platelets were found to be different in certain respects than those of the fragments expressed from bacteria.
  • the wild type recombinant 116 kg/mol homodimers performed similarly to native multimeric vWF in that they effectively inhibit antibody binding in the presence of ristocetin (and also botrocetin) but are ineffective in its absence ( Figure 7) .
  • the rll6/Cys 550 homodimer effectively inhibits LJ-Ibl binding without ristocetin, although the inhibitory effect is further enhanced when ristocetin is added thus reproducing the classic functional abnormality of Type IIB von Willebrand factor.
  • the ability of the 116 kg/mol homodimer to inhibit antibody binding is increased approximately 10 fold as a result of the Trp 550 ⁇ Cys 550 mutation.
  • Example 25 Screening of mutant antithrombotic polypeptide fragments patterned on the residue 441-730 region of mature von Willebrand factor subunit having enhanced affinity for collagen
  • collagen may bind elements within the residue sequence 512-673, or to the residue 597-621 subdomain thereof, when an appropriate disulfide-stabilized tertiary structure is present.
  • the actual binding regions in the 52/48 kg/mol fragment are outside the 512-673 region but require stabilization of a functional conformation by said internal region.
  • vWF-derived antithrombotic polypeptides For the purpose of identifying vWF-derived antithrombotic polypeptides with enhanced collagen binding ability, all or part of a cDNA encoding the 441-730 fragment can be subject to random mutagenesis.
  • the population of resultant mutagenized vWF DNA sequences is then reinserted into pET-3A plasmid, as an Xbal-Hindlll insert, for transformation of host bacterial cells followed by expression therein and large scale screening for desired mutant phenotypes. Mutations giving enhanced binding may then be inserted into mammalian or other eucaryotic host cell constructs for further testing.
  • a large scale screening assay suitable for detecting enhanced affinity of the mutant polypeptides for collagen can be patterned upon the screening assay for GPIb ⁇ binding in Example 16, with appropriate modifications.
  • the mutagenized population of M13mpl8 constructs is cloned into pET-3A plasmid followed by transformation of E.coli BL21(DE3). Partial purification of bacterial inclusion body lysates follows the procedure of Example 16. Contacting of the resultant vWF fragments with ristocetin or botrocetin is omitted. 125 I-monomeric type III collagen is applied to the nitrocellulose instead of ,25 l- GPIb ⁇ as in Example 16. Monomeric type III collagen is prepared according to the procedure of Roth, G.J. et al., Biochemistry, 25, 6357-8361 (1986) and iodinated following the method of Bolton, A.E. and Hunter, W.M. , Biochem.
  • Example 26 Screening of mutant antithrombotic polypeptide fragments patterned on the residue 441-730 region of mature von Willebrand factor subunit having enhanced affinity for glycosaminoglycans or proteoglycans
  • the collagen, and more importantly, the heparin binding domains of antithrombotic polypeptides patterned upon 52/48 kg/mol vWF fragment will prevent the anti-GPIb ⁇ activity of the molecule, such as by causing the polypeptide to be bound at nonspecific "heparin binding sites" throughout the vascular system.
  • the random mutagenesis procedure of this Example could also be used to screen for a mutant binding subsequence having less affinity for glycosaminoglycans (or proteoglycans) or collagen than present in the wild type sequence, thereby providing an additional alternate method of inactivating said binding activities.
  • Example 27 Screening of mutant antithrombotic polypeptide fragments patterned on the A 3 domain of mature von
  • a double stranded cDNA encoding the entire vWF protein (for the pre-propeptide) is amplified in a polymerase chain reaction using synthetic oligonucleotides selected to flank the A 3 domain encoding region, said oligonucleotides carrying also 5' or 3' restriction sequences suitable for creating a vWF insert in the multiple cloning site of M13mpl8.
  • the strategy of Examples 16 and 25 is again applied to generate, by random mutagenesis of subregions of the encoding cDNA, mutant vWF polypeptides with potential enhanced binding activity toward collagen.
  • the collagen binding region of the A 3 domain is stated to comprise residues 948-998 thereof (Roth, G.J. et al., Biochemistry, 25, 8357-8361 (1986)) although it is anticipated that other subdomains of the domain may participate in binding.
  • Example 28 Screening of mutant antithrombotic polypeptide fragments patterned on mature von Willebrand factor subunit having enhanced affinity for the platelet glycoprotein Ilb/IIIa receptor site
  • the screening assay of Example 16 for mutant vWF-derived polypeptides having enhanced platelet GPIb ⁇ binding activity is modified as described below to identify mutant vWF polypeptides having enhanced platelet GPIIb/IIIa receptor binding affinity.
  • the region of vWF cDNA selected for PCR amplification is recommended to encompass a region corresponding to approximately 100 amino acid residues on either side of the Arg*Gly-Asp- Ser sequence (subunit residues 1744-1747).
  • Oligonucleotides for amplification are again designed to contain 5' and 3' terminal restriction sequences so that the cDNA may be inserted into M13mpl8 phage for random mutagenesis.
  • 133,529-539 (1973) is substituted for 125 I-GPIb ⁇ .
  • Applied to the 96-well plates are 50 ⁇ l aliquots of HEPES/BSA containing GPIIb/IIIa at a suitable concentration thereof, such as approximately 0.25 ⁇ g/ml or higher, with a specific activity of between approximately 5 x 10 8 and approximately 5 x 10 10 cpm/mg.
  • the 125 I labelling procedure allows for specific activities varying over many orders of magnitude so that a wide range of receptor (ligand) and vWF fragment concentrations can be interacted.
  • Example 29 Screening of mutant antithrombotic polypeptide fragments patterned on the residue 1-272 region of mature von Willebrand factor subunit having enhanced affinity for glycosaminoglycans and proteoglycans
  • Example 26 The strategy of Example 26 is applied using a suitable amplified cDNA to generate mutant polypeptides derived from the residue 1-272 domain of mature vWF subunit with potential enhanced binding activity toward glycosaminoglycans and proteoglycans.
  • Example 30 Screening of mutant antithrombotic polypeptide fragments patterned on the residue 1-272 region of mature von Willebrand factor subunit having enhanced affinity for factor VIII
  • Examples 16 and 25 The general strategy of Examples 16 and 25 is applied to generate and detect mutant polypeptides patterned on vWF with enhanced binding activity toward factor VIII.
  • Coagulation factor VIII purified by the method of Fulcher, CA. and Zimmerman, T.S., Proc. Natl. Acad. Sci. USA r 79, 1648-1652 (1982) and labelled with 125 I to specific activities comparable to that of the other ligands in Examples 25-29 is used.
  • the I25 I labelling procedure allows for specific activities varying over many orders of magnitude so that a wide range of receptor (ligand) and vWF fragment concentrates can be interacted.

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Abstract

Polypeptide modelé sur un fragment de sous-unité du facteur Willebrand (vWF) mûr de phénotype sauvage comprenant un ou plusieurs sites de liaison à affinité prédéterminée pour un ou plusieurs des ligands sélectionnés dans le groupe formé du collagène, des glycosamineglycanes, des protéoglycanes, de la glycoprotéine plaquettaire Ibα, de la glycoprotéine plaquettaire IIb/IIIa, ou du facteur VIII de caogulation, ledit polypeptide ayant une séquence d'acides aminés modifiée par rapport à celle dudit fragment et une affinité de liaison accrue, par rapport à ladite affinité prédéterminée, pour un ou plusieurs desdits ligands, y compris également un tel polypeptide préparé par mutagenèse d'une séquence d'ADN et modelé sur une sous-unité de vWF mûr de phénotype sauvage, et également un polypeptide de forme purifiée modelé sur un polypeptide parent qui comprend la séquence d'acides aminés de phénotype sauvage de la sous-unité du facteur Willebrand mûr, ou un fragment de ladite sous-unité, et qui comprend également des séquences d'ADN purifiées codant pour ces polypeptides, des plasmides d'expression et des vecteurs d'expression virale contenant les séquences d'ADN, ainsi que des compositions thérapeutiques contenant lesdits polypeptides, efficaces dans le traitement de la thrombose, des méthodes d'utilisation desdites compositions et également la préparation desdits polypeptides par mutagenèse d'une séquence d'ADN de codage ou par modification covalente de vWF de phénotype sauvage.
PCT/US1992/002475 1991-03-27 1992-03-27 Fragments therapeutiques du facteur willebrand WO1992017192A1 (fr)

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WO1993015200A1 (fr) * 1992-01-31 1993-08-05 Rhone-Poulenc Rorer S.A. Polypeptides antithrombotiques, antagonistes de la liaison du vwf aux plaquettes et/ou au sous-endothelium
EP0833659A1 (fr) * 1995-06-07 1998-04-08 Centeon L.L.C. Fragments therapeutiques du facteur von willebrand
EP1147128A1 (fr) * 1999-01-04 2001-10-24 Dyax Corp. Molecules de liaison pour le facteur viii humain et proteines de type facteur viii
WO2002072619A1 (fr) * 2001-03-12 2002-09-19 Ctt Cancer Targeting Technologies Oy Peptides activant l'intégrine $g(a)iib$g(b)3 et leur utilisation
US7691565B2 (en) 1999-01-04 2010-04-06 Dyax Corp. Binding molecules for human factor VIII and factor VIII-like proteins

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CN110624105B (zh) * 2019-09-24 2021-06-11 苏州大学 血管性血友病因子的结构敏感多肽抗原的序列

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Biochemistry, Volume 25, No. 20, issued 07 October 1986, M.A. MASCELLI et al., "Characterization of a Fragment of Bovine von Willebrand Factor that Binds to Platelets", pages 6325-6335, see entire document. *
Biochemistry, Volume 28, issued 17 October 1989, R.K. ANDREWS et al., "Cross-Linking of a Monomeric 39/34-kDa Dispase Fragment of von Willebrand Factor (leu-480/val-481 - gly-718) to the N-Terminal Region of the Alpha-Chain of Membrane Glycoprotein Ib on Intact Platelets with Bis(Sulfosuccinimidyl) Suberate", pages *
Nature, Volume 324, issued 20 November 1986, D.T. BONTHRON et al., "Structure of pre-pro-von Willebrand Factor and its Expression in Heterologous Cells", pages 270-273, see entire document. *
Nucleic Acids Research, Volume 14, No. 17, issued 11 September 1986, D. BONTHRON et al., "Nucleotide Sequence of pre-pro-von Willebrand Factor cDNA", pages 7125-7127, see entire document. *
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See also references of EP0648268A4 *
The Journal of Biological Chemistry, Volume 261, No. 1, issued 05 January 1986, Y. FUJIMURA et al., "von Willebrand Factor. A Reduced and Alkylated 52/48-kDa Fragment Beginning at Amino Acid Residue 449 Contains the Domain Interacting with Platelet Glycoprotein Ib", pages 381-385, see entire document. *
The Journal of Biological Chemistry, Volume 262, No. 4, issued 05 February 1987, Y. FUJIMURA et al., "A Heparin-Binding Domain of Human von Willebrand Factor. Characterization and Localization to a Tryptic Fragment Extending from Amino Acid Residue val-449 to lys-728", pages 1734-1739, see entire document. *
The Journal of Biological Chemistry, Volume 263, No. 34, issued 05 December 1988, H. MOHRI et al., "Structure of the von Willebrand Factor Domain Interacting with Glycoprotein Ib", pages 17901-17904, see entire document. *
The Journal of Biological Chemistry, Volume 264, No. 29, issued 15 October 1989, H. MOHRI et al., "Isolation of the von Willebrand Factor Domain Interacting with Platelet Glycoprotein Ib, Heparin, and Collagen and Characterization of its Three Distinct Functional Sites", pages 17361-17367, see entire document. *
The Journal of Biological Chemistry, Volume 264, No. 33, issued 25 November 1989, D.J. MANCUSO et al., "Structure of the Gene for Human von Willebrand Factor", pages 19514-19527, see entire document. *

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1993015200A1 (fr) * 1992-01-31 1993-08-05 Rhone-Poulenc Rorer S.A. Polypeptides antithrombotiques, antagonistes de la liaison du vwf aux plaquettes et/ou au sous-endothelium
EP0833659A4 (fr) * 1995-06-07 2003-01-15 Centeon L L C Fragments therapeutiques du facteur von willebrand
EP0833659A1 (fr) * 1995-06-07 1998-04-08 Centeon L.L.C. Fragments therapeutiques du facteur von willebrand
JP2010254694A (ja) * 1999-01-04 2010-11-11 Dyax Corp ヒト第viii因子および第viii因子様タンパク質に対する結合分子
JP2002536297A (ja) * 1999-01-04 2002-10-29 ダイアックス コープ. ヒト第viii因子および第viii因子様タンパク質に対する結合分子
EP1147128A4 (fr) * 1999-01-04 2004-10-13 Dyax Corp Molecules de liaison pour le facteur viii humain et proteines de type facteur viii
EP2090582A3 (fr) * 1999-01-04 2009-11-11 Dyax Corp. Molecules de liaison pour le facteur VIII humain et proteines de type facteur VIII
US7691565B2 (en) 1999-01-04 2010-04-06 Dyax Corp. Binding molecules for human factor VIII and factor VIII-like proteins
EP1147128A1 (fr) * 1999-01-04 2001-10-24 Dyax Corp. Molecules de liaison pour le facteur viii humain et proteines de type facteur viii
JP4733272B2 (ja) * 1999-01-04 2011-07-27 ダイアックス コープ. ヒト第viii因子および第viii因子様タンパク質に対する結合分子
US8058017B2 (en) 1999-01-04 2011-11-15 Dyax Corp. Methods and compositions for purifying human factor VIII, factor VIII-like proteins or fragments thereof
JP2013079272A (ja) * 1999-01-04 2013-05-02 Dyax Corp ヒト第viii因子および第viii因子様タンパク質に対する結合分子
US8535892B2 (en) 1999-01-04 2013-09-17 Dyax Corp. Binding molecules for human factor VIII and factor VIII-like proteins
US9156883B2 (en) 1999-01-04 2015-10-13 Dyax Corp. Binding molecules for human factor VIII and factor VIII-like proteins
WO2002072619A1 (fr) * 2001-03-12 2002-09-19 Ctt Cancer Targeting Technologies Oy Peptides activant l'intégrine $g(a)iib$g(b)3 et leur utilisation

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