AU620537B2 - Human interleukin-4 muteins - Google Patents
Human interleukin-4 muteins Download PDFInfo
- Publication number
- AU620537B2 AU620537B2 AU10559/88A AU1055988A AU620537B2 AU 620537 B2 AU620537 B2 AU 620537B2 AU 10559/88 A AU10559/88 A AU 10559/88A AU 1055988 A AU1055988 A AU 1055988A AU 620537 B2 AU620537 B2 AU 620537B2
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- Australia
- Prior art keywords
- leu
- thr
- lys
- asp
- arg
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Ceased
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- 101001002709 Homo sapiens Interleukin-4 Proteins 0.000 title claims description 24
- 102000055229 human IL4 Human genes 0.000 title claims description 24
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Description
vice rresiatent V f AU-Al -10559/88 PCI WORLD INTELLECTUAL PROPERTY ORGANIZATION INTERNATIONAL APPLICATION PUB6H2UR 5 3ENT 7 0PERATION TREATY (PCT) (51) International Patent Classification 4 (11) International Publication Number: WO 88/ 04667 C07K 15/00, C2 21/00, 213/0 A (43) International Publication Date: 30 June 1988 (30.06.88) (21) International Application Number: PCT/US87/03 114 Seattle, WA 98102 (US).
(22) International Filing Date: 4 December 1987 (04.1t2.87) (74) Agents: BURNAM, Warren, Jr.; Post Office Box 2326, Arlington, VA 22202 (US) et al.
(31) Priority Application Numbers: 944,472 119,763 (81) Designated States: AT (European patent), AU, BE (European patent), CH (European patent), DE (Euro- (32) Priority Dates: 19 December 1986 (19.12.86) pean patent), DK, FR (European patent), GB (Euro- 12 November 1987 (12.11.87) pean patent), IT (European patent), JP, KR, LU (European patent), NL (European patent), SE (European (33) Priority Country: us patent).
(71) App~licant: IMMUNEX CORPORATION EUS/US]; Published Immunex Building, 51 University Street, Seattle, WA With international search report.
98101 AG18 (72) Inventors: ANDERSON, Dirk, M. 16612 WallingfordA..o 8 UG18 Avenue North, Seattle, WA 98133 COSMAN, David, J. 116 11Ith Avenue East, Number 501, Seat- AUS-TRALIAN tle, WA 98102 DEELEY, Michael, C. 8830
L
GRABSTEIN, Kenneth, H. 5829 Northeast 75th15JL98 Street, Number 443, Seattle, WA 98115 PRICE, ATENTOFC Virginia, L. 2617 Boyer Avenue East, L ATES OFC (54) Title: HUMAN INTERLEUKIN-4 MUTEINS Sequence of GluAaGluAa-hIL-4(Asp62,_ Aspi 29)
GTA
This doctiiflcnt contains the a~meiInenits allowed under Sectior 83 by tile Supervijsing Examiner onl an s:corec for printing hIL-4 mutein---- CCT TTA GAT AAA AGA GAA GCT GAA GCT CAC AAG TGC CAT ATC ACC Pro Leu Asp Lys Arg Giu Ala Giu Ala His Lys Cys Asp Ile Thr TTA CAG GAG ATC ATC AAA ACT TTG AAC AGC CTC ACA GAG CAG AAG Leu Gin Giu Ile Ile Lys Thr Leu Asn Ser Lau Thr Giu Gin Lys ACT CTG TGC ACC GAG ThC Lau Cys Thr Giu 4.nstslI Nhel TTG ACG GTA ACC GAC ATC TTT GCT GCT AGC Lou Thr Val Thir Asp Ile Ph. Ala Alai Se AAG GAC ACA ACT GAG AAG GAA ACC TTC Lys XS Thr Thr Giu Lys Giu Thr Ph.
.PstI TGC AGG _GCT 3~CG ACT GTO Cys Arg Ala Ala Thr Val CTC CGG CAG TTC TAC AGC CAC CAT GAG AAG GAC ACT CGC TGC CTG 270 Leu Arg Gin Phe Tyr See His His Giu Lys ASP Thr Arg Cys Lau GGT GCG ACT GCA CAG CAG TTC CAC AGG CAC AAG CAG CTG ATC CGA 315 GlY Ala Thr Ala Gin Gin Phe His Arg His Lys Gin Lau Ile Arg 105 TTC CTG A.AA CGG CTC GAC AGG AAC CTC TGG GGC CTG GCG GGC TTG 360 Ph. Lau Lys Aeg Lau Asp Arg Asn Lau Tep Giy Lau Ala Gly Lau 120 4.EcoRI 4.Sall AATTCC TGT CCT GTG AAG GAPE GCC CAC CAG TCG ACG TTG GAA AAC 405 Asn See Cys Pro Val Lye Glu Ala a~ Gin S§eer The Lau GiU Asn 135 TTC TTG GAA AGG CTAAAG ACG ATC ATG AGA GAG AAA TAT TCA AAG 450 Ph. Leu Giu Arg Lou Lys Thr Ile Met Arg Glu Lys Tyr Ser Lye 150 TGT TCG AGC TGA 495 Cys Ser Sat End 153 (57) Abstract
I
Recombinant biologically active human IL-4 (rhIL-4) mutant analog proteins in which N-linked glycosylation sites have been inactivated.
WO 88/04667 PCT/US87/03114 1
TITLE
Human Interleukin-4 Muteins BACKGROUND OF THE INVENTION The present invention relates generally to lymphokines, and particularly to recombinant interleukin-4 muteins or analog proteins, which induce clonal expansion and maturation of activated B cells and augment generation of cytotoxic T cells.
B lymphocytes, or B cells, are the precursors of antibody-secreting plasma cells. B cells derive from hematopoietic stem cells located in the bone marrow, via an intermediary cell class known as pre-B cells. B cells are distinguished from pre-B cells by the expression of surface-bound immunoglobulin capable of binding specific antigens. B cells are activated by binding of antigen to membrane receptors, provided that the B cells also interact with specific helper T cells or bind certain soluble growth and differentiation factors. B cell activation is a sequential process involving proliferation and differentiation phases. In the proliferation phase, activated B cell clones multiply to provide an expanded number of cells capable of reacting with the activating antigen. In the differentiation phase, a portion of the activated B cells mature and secrete immunoglobulir as circulating plasma cells.
Separate T lymphocyte-derived cytokines, which were first designated "B cell growth factor" (BCGF) and "B cell differentiation factor" (BCDF), are involved in the regulation of proliferation and differentiation phases. Alternative terms for BCGF include "B cell stimulating factor 1" (BSF-1), and "interleukin-4" the latter now being preferred.
Howard et al., J. Exp. Med. 155:914 (1982), and Farrar et al., J. Immunol. 131:1838 (1983) described a B cell stimulating factor derived from mitogen-stimulated murine T cells which stimulated B cell proliferation. Following this disclosure, a number of laboratories reported similar murine activities in media conditioned by T cell hybridomas, cloned T cells, and normal T cells. See, Roehm et al., J. Exp. Med. 160:679 (1984); Noelle et al., Proc. Natl. Acad.
WO 88/04667 PCT/US87/03114 2 Sci. USA 81:6149 (1984); Oliver et al., Proc. Natl. Acad. Sci. USA 82:2465 (1905); Rabin et al., Proc. Natl. Acad. Sci. USA 82:2935 (1985); and Vitetta et al., J. Exp. Med. 162:1726 (1985).
Purification to homogeneity of a murine BSF-1/IL-4 species was reported by Grabstein et al., J. Exp. Med. 163:1405 (1986).
Isolation of cDNAs encoding proteins having murine BSF-1/IL-4 activity was recently reported by Noma et al., Nature 319:640 (1986) and Lee et al., Proc. Natl. Acad. Sci. USA 83:2061 (1986). Yokota et al., Proc. Natl. Acad. Sci. USA 83:5894 (1986) isolated a human cDNA clone having homology to mouse IL-4. The human cDNA encoded a protein of 153 amino acid residues including a possible signal peptide.
Supernatants of monkey COS-1 cells transfected with this cDNA were capable of inducing proliferation of anti-IgM-exposed human B cells.
This activity is analogous to a known property of murine IL-4 in conjunction with murine B cells.
IL-4 also stimulates growth and differentiation of factor-dependent T cell and myeloid cell classes. Grabstein et al., supra, reported that murine IL-4 induced proliferation of !,urine IL-2-dependent and IL-3-dependent T cell lines. Other studies have indicated that IL-4 stimulates mast cell proliferation and macrophage differentiation.
The availability of significant quantities of purified IL-4 has facilitated studies of B cell ontogeny and function, and illuminated potential therapeutic uses for this lymphokine. Among the uses presently contemplated for recombinant human IL-4 are treatment of immune deficiency diseases characterized by B cell cytopenias, and induction of B cell differentiation as a treatment for certain B cell related lymphocytic leukemias. IL-4 might also be used to induce and maintain continuous cultures of immunoglobulin-secreting B cells to provide a source of human monoclonal antibodies. The present applicant have discovered that IL-4 induces proliferation and differentiation of cytolytic T cells previously exposed to a mitogenic stimulus; this observation indicates that IL-4 can be employed as a therapeutic lymphokine in treatment of viral infection and certain neoplastic conditions.
-i I 1 1 1 2A SUMMARY OF THE INVENTION The present invention is directed to recombinant human IL-4 proteins preferably produced using yeast or recombinant expression systems. The present invention provides a human interleukin-4(hIL-4) analog polypeptide comprising the sequence: Glu Leu Asp Arg Arg Arg Ser Glu Glu Ser Phe Ala Leu Leu Pro Leu Ala His Leu Thr Ala Ala Thr Val Gly Ala Lys Arg Val Lys Lys Thr wherein Lys Glu Ser Leu Thr Leu Glu Ile Cys Gln Lys Arg Ala Asp Ala Met Asp Ile Thr Leu Gin Lys Thr Leu Cys Thr X1 Thr Y 1 Glu Lys Gl Gin Phe Thr Ser His Gin Gin Phe His Arg Arg Asn Leu Trp Gly
X
2 Gin Y2 Thr Leu Gl Arg Glu Lys Tyr Ser Glu Ile Ile Lys Thr Glu Leu Thr Val Thr u Thr Phe Cys His Glu Lys Asp Thr His Lys Gln Leu lle Leu Ala Gly Leu Asn u Asn Phe Leu Lys Cys Ser Ser, any amino acid ksn, Y 1 is
X
1 and X2 are independently with the proviso that X1 and X2 cannot both be Thr, le, o oe• oo oo Val, Glu, Asp, Gin, Gly, or Ala, and Y2 is Ser, Met, Leu, Val, Asp, Gin, Glu, or Asn. Preferred are R44,
T
-7
WTQ
WO 88/04667 PCT/US87/03114 3 The present invention recombinant human IL-4 analog proteins including those having inactivated asparagine-linked 62 129 glycosylation sites, for example, hIL-4 (Asp Asp129). This invention also concerns DNA sequences encoding the muteins, recombinant expression vectors comprising the DNA sequences, and processes for making the muteins comprising culturing microorganisms transformed with the recombinant expression vectors. The present invention also provides a method for inducing proliferation of and lytic activity in a population of antitumor cytolytic T lymphocytes (CTL), comprising contacting T cells with a composition comprising a biologically effective quantity of IL-4 in combination with a physiologically acceptable carrier or diluent. In a related aspect, the present invention provides methods for inducing proliferation and activation of antitumor or antiviral cytolytic T lymphocytes in a mammal, a human, comprising administering a therapeutically effective quantity of a human IL-4 therapeutic composition.
BRIEF DESCRIPTION OF THE FIGURES FIGURE 1 depicts the nucleotide sequence and corresponding amino acid sequence of wild-type native human IL-4.
FIGURE 2 depicts the nucleotide sequence of a DNA sequence 62 129 encoding the hIL-4 mutein GluAlaGluAla-hIL-4(Asp Asp FIGURES 3-5 schematically illustrate the construction of a yeast expression vector for production of the hIL-4 mutein 62 129 GluAlaGluAla-hIL-4(Asp Asp 12).
FIGURE 6 is a plot showing augmentation of cytolytic T cell generation in primary mixed leukocyte cultures (MLC) by IL-4 and IL-2.
FIGURE 7 is a plot illustrating induction of cytolytic activity in long-term MLC by IL-4 and IL-2.
DETAILED DESCRIPTION OF THE INVENTION As detailed herein, a cDNA comprising a nucleotide sequence encoding native human IL-4 was isolated from a cDNA library prepared by reverse transcription of polyadenylated RNA isolated from human -Vi *A Q WO 88/04667 PCT/US87/03114 4 peripheral blood T lymphocytes. Synthetic oligonucleotide probes having sequence homology to N-terminal and C-terminal regions of the native human sequence were employed to screen the library by conventional DNA hybridization techniques. Clones from the library comprising plasmid DNAs which hybridized to the probes were isolated and analyzed by restriction endonuclease cleavage, agarose gel electrophoresis, and additional hybridization experiments ("Southern blots") involving the electrophoresed fragments. After isolating a single clone which hybridized to both the N-terminal and C-terminal oligonucleotide probes, the hybridizing segment was cleaved to provide a smaller restriction fragment bearing the hIL-4 gene, which was then subcloned and sequenced by conventional techniques. The cDNA encoding mature hIL-4 was then digested with selected restriction endonucleases and reassembled using synthetic oligonucleotides providing predetermined codon changes. The resulting mutant cDNA sequence was inserted into a yeast expression vector under control of a particular promoter. The vector was used to transform an appropriate yeast expression strain, which was grown in culture under conditions promoting derepression of the yeast promoter. The resulting yeast-conditioned culture supernatant provided a protein having hIL-4 biological activity, which was purified as described below.
Definitions "Human interleukin-4" and "hIL-4" refer to a human endogenous secretory protein capable of inducing maturation and proliferation of human B cells, which comprises an amino acid sequence which is substantially homologous to all or a significant part of the sequence set forth in FIGURE 1. Other designations for this molecule include "B-cell stimulating factor" and "B-cell growth factor".
"DNA sequence" refers to a DNA polymer, in the form of a separate fragment or as a component of a larger DNA construct, which has been derived from DNA isolated at least once in substantially pure form, in a quantity or concentration enabling identification, manipulation, and recovery of the segment and its component nucleotide sequences by standard biochemical methods, for example, using a cloning vector. "Nucleotide sequence" refers to a heteropolymer of deoxyribonucleotides. "Recombinant expression vector" refers to a h~ 'l WO 88/04667 PCT/US87/03114 plasmid comprising a transcriptional unit comprising an assembly of a genetic element or elements having a regulatory role in gene Sexpression, for example, promoters or enhancers, and a structural or coding sequence which is transcribed into mRNA and translated into protein. Preferably, the transcriptional unit includes a leader sequence enabling extracellular secretion of translated protein by a host cell. "Recombinant expression system" means a combination of an expression vector and a suitable host microorganism. Yeast expression systems, particularly those employing Saccharomyces cerevisiae, are preferred.
"Mutant amino acid sequence" refers to a polypeptide encoded by a nucleotide sequence intentionally made variant from a native sequence. "Mutant protein" or "mutein" means a protein comprising a mutant amino acid sequence. "Substantially homologous," which can refer both to nucleic acid and amino acid sequences, means that a particular subject sequence, for example, a mutant sequence, varies from a reference sequence by one or more substitutions, deletions, or additions, the net effect of which do not result in an adverse functional dissimilarity between reference and subject sequences. For purposes of the present invention, sequences having greater than percent homology and equivalent biological specific activity are to be considered substantially homologous sequences within the scope of the present invention. Sequences having lesser degrees of homology and comparable bioactivity are to be considered equivalents. "Native sequence" refers to an amino acid or nucleic acid sequence which is identical to a wild-type or native form of a gene or protein.
"N-glycosylation site" is defined below. The term "inactivate", as used in defining the present invention, means to alter a selected N-glycosylation site to eliminate amino acid residues enabling covalent bonding of oligosaccharide moieties.
Assays for Human IL-4 Activity Human IL-4 activity can be observed in cultures of human B cells derived, for example, from suspensions of human tonsillar cells.
Enriched B cell populations can be prepared by rosetting T-cells with 2-aminoethylisothiouronium bromide-treated sheep erythrocytes followed by Ficoll-Histopaque (Sigma Chemical Corp., St. Louis, MO, USA) to I! i WO 88/04667 PCT/US87/03114 6 eliminate T cells, and Sephadex G10 filtration to remove monocytes, granulocytes, and activated B cells. Following enrichment, B cell preparations can be frozen in liquid N 2 prior to use.
For assay, frozen B cells are thawed, washed, and cultured at 10 cells per vell in 100 ul of RPMI 1640 medium containing 10% fetal calf serum, 5x10-5M 2-mercaptoethanol, appropriate dilutions of the sample to be tested, and 12.5 pg/ml of F(ab') 2 fragments goat anti human IgM purified by affinity chromatography. Cultures are incubated for 68-72 hours. During the final 16 hours of the incubation period, the cells receive 0.5 uCi 3 H]-thymidine at a specific activity of Ci/mmole. Cultures are then harvested onto glass fiber filters and incorporation of radiolabel determined by scintillation counting.
Details regarding analogous assays for murine IL-4 activity are to be found in the references reviewed by Brooks et al., Methods Enzym. 116:372 (1985).
In assays for hIL-4 activity, units of activity are calculated by reference to the quantity of hIL-4 which induces 50% of maximal thymidine incorporation. For example, if a 100 ul sample generates one-half maximal thymidine incorporation at a dilution of 1:20, one unit is defined as the activity contained in 1/20 of 100 il, or 5 pl. The sample would therefore contain 1000 divided by 5, or 200 units per milliliter (U/ml) of hIL-4 activity.
Nucleotide and Amino Acid Sequences of hIL-4 Proteins The nucleotide and deduced amino acid sequences of a cDNA sequence encoding a wild-type hIL-4 protein are set forth in FIGURE 1.
In FIGURE 1, nucleotides are numbered beginning with the ATG codon corresponding to the N-terminal methionine of the full-length native polypeptide. Similarly, amino acids are numbered from this methionine residue. The native protein includes a leader sequence of 23 or amino acids preceding a histidine residue providing the N-terminus of the mature secreted protein. On the basis of comparison to the murine homologue of hIL-4, His 23 is the predicted N-terminus. However, parallel expression experiments have indicated equivalent biological activity for proteins having His 23 or His25 as the N-terminal amino acid residue.
WO 88/04667 PCT/US87/03114 FIGURE 2 indicates the nucleotide and encoded amino acid sequence of a synthetic gene encoding a hIL-4 mutein, GluAlaGluAla-hIL-4-(Asp Asp129), which represents a preferred embodiment within the scope of the present invention.
Construction of Analog Sequences and Muteins Numerous DNA constructions including all or part of the nucleotide sequence of FIGURE 1, in conjunction with oligonucleotide cassettes comprising additional useful restriction sites, can be prepared as a matter of convenience. This invention concerns certain analog proteins or muteins which are substantially homologous to the native sequence of hIL-4, yet contain one or more intentional amino acid substitutions, deletions, or insertions not adversely affecting activity.
Mutations can be introduced at particular loci by synthesizing oligonucleotides containing a mutant sequence, flanked by restriction sites enabling ligation to fragments of the native sequence. Following ligation, the resulting reconstructed sequence encodes a mutein having the desired amino acid insertion, substitution, or deletion. This approach is illustrated by FIGURES 3-6.
Alternatively, oligonucleotide-directed site-specific mutagenesis procedures can be employed to provide an altered gene having particular codons altered according to the substitution, deletion, or insertion required. Bauer et al., Gene 37:73 (1985); Craik, Biotechniques, January 1985, 12-19; Smith et al., Genetic Engineering: Principles and Methods (Plenum Press, 1981); and U. S.
Patent 4,518,584 disclose suitable techniques, and are incorporated by reference herein.
For either approach, conventional techniques for oligonucleotide synthesis are suitable, for example, the triester synthesis procedures disclosed by Sood et al., Nucl. Acid Res. 4:2557 (1977) and Hirose et al., Tet. Lett. 28:2449 (1978).
In site-specific mutagenesis, a strand of the gene to be altered is cloned into an M13 single-stranded phage or other appropriate vector to provide single-stranded DNA comprising either the sense or antisense strand corresponding to the gene to be altered.
WO 88/04667 PCT/US87/03114 8 This DNA is annealed to a fragment of M13 phage to provide a gapped duplex, which is then hybridized to an oligonucleotide primer. The primer is complementary to the sequence surrounding the codon to be altered, but comprises a codon (or an antisense codon complementary to such codon) specifying the new amino acid at the point where substitution is to be effected. If a deletion is desired, the primer will lack the particular codon specifying the amino acid to be deleted, while maintaining the correct reading frame. If an insertion is desired, the primer will include a new codon, at the appropriate location in the sequence, specifying the amino acid to be inserted.
Preferably, the substitute codon, deleted codon, or inserted codon is located at or near the center of the oligonucleotide.
The size of the oligonucleotide primer employed is determined by the need to optimize stable, unique hybridization at the mutation site with the 5' and 3' extensions being of sufficient length to avoid editing of the mutation by the exonuclease activity of the DNA polymerase employed to fill gaps. Thus, oligonucleotides used in accordance with the present invention will usually contain from about to about 25 bases. Oligonucleotides of greater size are not needed.
The oligonucleotide primer is then hybridized to the gapped duplex having a single-stranded template segment containing the gene to be altered. The primer is then extended along the template strand by reaction with DNA polymerase I (Klenow fragment), T4 DNA polymerase, or other suitable DNA polymerase. The resulting double stranded DNA is then converted to closed circular DNA by treatment with a DNA ligase, for example, T4 DNA ligase, and the resulting heteroduplex employed to transfect a suitable host strain, for example E. coli JM105 (Bethesda Research Laboratories, Gaithersburg, MD, USA).
Replication of the heteroduplex by the host provides progeny of both strands. The transfected cells are then plated to provide plaques, which are screened using a labelled oligonucleotide corresponding to that used in the mutagenesis procedure. Conditions are employed which result in preferential hybridization of the primer to the mutated DNA but not to the progeny of the parent strand. DNA containing the mutated gene is then isolated and spliced into a suitable expression t WO 88/04667 PCT/US87/03114 9 vector, and the vector employed to transform a host strain. The host strain is then grown in culture to provide the analog protein.
The particular mutation strategy forming the basis of the present invention is described below.
Inactivation of N-glycosylation Sites Many secreted proteins acquire covalently attached carbohydrate units following translation, frequently in the form of oligosaccharide units linked to asparagine side chains by N-glycosidic bonds. Both the structure and number of oligosaccharide units attached to a particular secreted protein can be highly variable, resulting in a wide range of apparent molecular masses attributable to a single glycoprotein. Human IL-4 is a secreted glycoprotein of this type. Attempts to express glycoproteins in recombinant systems can be complicated by the heterogeneity attributable to this variable carbohydrate component. For example, purified mixtures of recombinant glycoproteins such as human or murine granulocyte-macrophage colony stimulating factor (GM-CSF) can consist of from 0 to 50% carbohydrate by weight. Miyajima et al., EMBO Journal 5:1193 (1986) reported expression of a recombinant murine GM-CSF in which N-glycosylation sites had been mutated to preclude glycosylation and reduce heterogeneity of the yeast-expressed product.
The presence of variable quantities of associated carbohydrate in recombinant secreted glycoproteins complicates purification procedures, thereby reducing yield. In addition, should the glycoprotein be employed as a therapeutic agent, a possibility exists that recipients will develop allergic reactions to the yeast carbohydrate moieties, requiring therapy to be discontinued. For these reasons, biologically active, homogeneous analogs of immunoregulatory glycoproteins having reduced carbohydrate are desirable for therapeutic use.
Functional mutant analogs of human IL-4 having inactivated N-glycosylation sites can be produced by oligonucleotide synthesis and ligation or by site-specific mutagenesis techniques as described above. These analog proteins can be produced in a homogeneous, reduced-carbohydrate form in good yield using yeast expression systems. The present invention concerns analog forms of human IL-4 t Y~' WO 88/04667 PCT/US87/03114 comprising at least one amino acid substitution, deletion, or insertion inactivating an N-glycosylation site.
N-glycosylation sites in eukaryotic proteins are 1 1 characterized by the amino acid triplet Asn-A where A is any amino acid, and Z is Ser or Thr. In this sequence, asparagine (Asn) provides a side chain amino group for covalent attachment of carbohydrate. Such a site can be eliminated by substituting another amino acid for Asn or for residue Z, deleting Asn or Z, or inserting a non-Z amino acid between A and Z, or an amino acid other than Asn between Asn and A Preferably, substitutions are made conservatively; the most preferred substitute amino acids are those having physicochemical characteristics resembling those of the residue to be replaced. Similarly, when a deletion or insertion strategy is adopted, the potential effect of the deletion or insertion upon biological activity should be considered.
Thus, an analog hIL-4 according to the present invention is a protein having a mutant amino acid sequence which is substantially homologous to the native sequence of hIL-4, whoerein at'least one occurrence Asn-A -Z in the native sequence has been replaced in the mutant sequence by Asn-A 2 -Y or X-A -A where 1 2 3 A A and A are the same or different and can be any amino acid, X is any amino acid not Asn; Y is any amino acid not Z; and Z is Ser or Thr.
Preferably, all occurrences of Asn-A -Z in the native sequence are 2 2 3 replaced in the mutant sequence by Asn-A -Y or X-A -A Referring now to the sequence of hIL-4 set forth in FIGUR3 1, it can be seen that the native protein contains two putative N-glycosylation sites, the first being the triplet AsnThrThr beginning at residue 62, and the second being AsnGlnSer beginning at residue 129. Appropriately conservative substitute amino acids for Asn include Asp, Gin, Glu, Ala, Gly, Ser, and Thr, of which Asp, Gin, and Glu are preferred. Where Z is Ser, appropriate substitutes are Met, Leu, Ile, Val, Asp, Gln, Glu, or Asn; of which Met, Leu, Ile, and Val are preferred. Where Z is Thr, conservative substitutions are Val,
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WO 88/04667 PCT/US87/03114 11 Glu, Asp, Gin, Gly, or Ala, preferably Val, Glu, Asp or Gin.
In the context of the present invention, preferred substitutions to inactivate the hIL-4 N-glycosylation sites are substitution of Val for 64 62 129 Thr or Asp for Asn and Asp for Asn Other conservative amino acid substitutions could be made to provide protein lacking N-glycosylation sites. Muteins bearing such substitution are considered to be equivalents of those specifically disclosed and claimed herein. Ranking substitute amino acids by order of preference for substitution at these positions provides the following Table 1: Table 1: hIL-4 Amino Acid Substitutions Position: 62 64 129 131 Wild type: Asn Thr Asn Ser Most preferred: Asp Val Asp Met Second Order of Glu Glu Glu Leu preference: Gin Gin Gin lie Asp Val Third Order of Ala Gly Ala Asp preference: Gly Ala Gly Gin Ser Ser Glu Thr Thr Asn Deletion or Substitution of Cysteine Residues The present invention also contemplates muteins of hIL-4 in which cysteine residues not essential to biological activity have been deleted or replaced with other amino acids to eliminate sites for intermolecular crosslinking or incorrect intramolecular disulfide bond formation. The native sequence of hIL-4 comprises six cysteine residues, at positions 27, 48, 70, 89, 122, and 151 (see FIG. 1), The first five cysteines have counterparts in the murine homologue, while the last cysteine does not. Thus, the last residue is an appropriate candidate for substitution or deletion.
Site specific mutagenesis or oligonucleotide substitution procedures can be employed to delete particular cysteine residues, or provide conservative substitutions. Preferred amino acids for substitution are neutral amino acids such as Gly, Ala, Val, Leu, lie, Y I s WO 88/04667 PCT/US87/03114 12 Tyr, Phe, His Trp, Ser, Thr, or Met. Of the foregoing, Ser and Thr are preferred.
Inactivation of KEX2 Protease Recognition Sites Appropriate mutagenesis procedures can also be employed to inactivate KEX2 protease processing sites by deletion, addition, or substitution of residues to alter Arg-Arg, Arg-Lys, or Lys-Arg pairs in a manner eliminating the occurrence of adjacent basic residues. It should be noted that Lys-Lys pairings are considerably less susceptible to KEX2 cleavage, and conversion of Arg-Lys or Lys-Arg to Lys-Lys represents a conservative approach to inactivating KEX2 sites.
The resulting muteins are less susceptible to cleavage by the KEX2 protease at locations other than the a-factor leader sequence where cleavage upon secretion is intended.
Referring to FIG. 1, a Lys-Arg pairing occurs at position 123 of the hIL-4 native sequence. Substitution of a non-Arg amino acid 123 124 for Lys2 or Arg provides a mutant hIL-4 free of internal Arg-Arg, Lys-Arg, or Arg-Lys KEX2 processing sites. Comparison with the mouse 123 IL-4 sequence suggests that deletion of Lys is a conservative mutagenesis strategy, and is therefore preferred. Alternatively, Lys 124 can be substituted for Arg Modification of Yeast KEX2 Protease Recognition Sites A preferred expression system for the IL-4 proteins of this invention employs the yeast a-factor leader sequence to induce secretion of recombinant protein by a yeast host. Ideally, this system is configured such that the yeast KEX2 protease cleaves the t-factor leader from the N-terminus of the desired protein upon secretion. An a-factor leader-hIL-4 protein construction having a Lys-Arg KEX2 protease site immediately adjacent to the N-terminal His residue of wild-type was not always cleaved upon secretion by recombinant yeast. When the tetrapeptide sequence Glu-Ala-Glu-Ala was inserted between the Lys-Arg KEX2 recognition site and the N-terminus of hIL-4, more efficient cleavage at the KEX2 site was achieved. The resulting product is an hIL-4 protein having the tetrapeptide Glu-Ala-Glu-Ala at the N-terminus. Potentially, these TGT TCG AGC TGA 495 Cys Ser Sea End 153 (57) Abstract I Recombinant biologically active human IL-4 (rhIL-4) mutant analog proteins in which N-linked glycosylation sites have been inactivated.
I WO 88/04667 PCT/US87/03114 13 residues could be removed in vivo in a yeast strain capable of over-expressing the yeast STE13 gene product, dipeptidyl aminopeptidase A, which cleaves N-terminal Glu-Ala pairs. However, the presence of the Glu-Ala-Glu-Ala sequence at the N-terminus has not been observed to provide any significant difference in the biological activity of the analog relative to the wild-type protein.
Protein Expression in Recombinant Yeast Systems As noted previously, yeast is preferred for expression of analog and native forms of recombinant human IL-4. An exemplary expression vector is pBC104 (ATCC 67,232) which contains DNA sequences from pBR322 for selection and replication in E. coli (Apr gene and origin of replication) and yeast DNA sequences including a glucose-repressible alcohol dehydrogenase 2 (ADH2) promoter. The ADH2 promoter has been described by Russell et al., J. Biol. Chem. 258:2674 (1982) and Beier et al., Nature 300:724 (1982). Plasmid pBC104 also comprises the Trpl gene as a selectable marker and the 2p origin of replication. Adjacent to the promoter is the a-factor leader sequence enabling secretion of heterologous proteins from a yeast host. The a-factor leader sequence is modified to contain, near its 3' end, an Asp 718 (KpnI) restriction site to facilitate fusion of this sequence to foreign genes. pBC104 also comprises a cDNA insert encoding wild-type hIL-4. Details regarding the construction of this plasmid are provided below.
Alternative expression vectors are yeast vectors which comprise an a-factor promoter, for example pYafHuGM (ATCC 53157), which bears the wild-type human GM-CSF gene. Others are known to those skilled in the art. The construction of pYaHuGM is described in published European Patent Application EP-A-183,350.
Selection of appropriate yeast strains for transformation will be determined by the nature of the selectable markers and other features of the vector. Appropriate S. cerevisiae strains for transformation by pBC104 or pYaHuGM, and various constructions derived from those vectors, include strains X2181-1B, available from the Yeast Genetic Stock Center, Berkeley, CA, USA [see below], having the genotype a trpl gall adel his2; J17 (ATCC 52683; a his2 adel trp metl4 ura3); and IL166-5B (ATCC 46183; a hisl trpl). A particularly 2i Aaummmh J q WO 88/04667 PCT/US87/03114 14 preferred expression strain, XV2181, is a diploid formed by mating two haploid strains, X2181-1B, available from the Yeast Genetic Stock Center, Department of Biophysics and Medical Physics, University of California, Berkeley, CA 94702, USA; and XV617-1-3B, available from the Department of Genetics, University of Washington, Seattle, VA 98105, USA, or Immunex Corporation, 51 University Street, Seattle, WA 98101, USA. A suitable transformation protocol is that described by Hinnen, et al., Proc. Natl. Acad. Sci. USA 75:1929 (1978), selecting for Trp+ transformants in a selective medium consisting of 0.67% yeast nitrogen base, 0,5% casamino acids, 2% glucose, 10 ug/ml adenine and ug/ml uracil.
Host strains comprising pBC104 or other constructions comprising the ADH2 or a-factor promoters are grown for expression in a rich medium consisting of 1% yeast extract, 2% peptone, and 1% glucose supplemented with 80 pg/ml adenine and 80 ug/ml uracil.
Derepression of the ADH2 promoter occurs upon exhaustion of medium glucose.
Purification of rhIL-4 Proteins Recombinant human IL-4 proteins resulting from fermentation of yeast strains can be purified by single or sequential reversed-phase HPLC steps on a preparative HPLC column, by methods analogous to those described by Urdal et al., J. Chromatog. 296:171 (1984), and Grabstein et al., J. Exp. Med. 163:1405 (1986).
For example, yeast-conditioned medium containing rhIL-4 can be filtered through a 0.45 u filter and initially purified by batch adsorption and elution from a cation exchange matrix, for example, S-Sepharose. Pooled fractions from the batch adsorption/elution step can then be pumped, at a flow rate of 100 ml/min, onto a 5 cm x 30 cm column packed with 10-20 u reversed phase silica (Vydac, The Separations Group, Hesperia, CA, USA). The column can be equilibrated in 0.1% trifluoroacetic acid in water prior to the application of the yeast-conditioned medium and then flushed with this solvent following application of the medium to the column until the optical absorbance at 280 nm of the effluent approaches baseline values. At this time, a gradient of 0.1% trifluoroacetic acid in acetonitrile can be established that leads from 0 to 60-100% Solvent B at a rate of change ,i Air i, WO 88/04 i i 1 I-' 667 -i PCT/US87/03114 of 1-2% per minute and at a flow rate of 100 ml/min. At a suitable time (10-20 minutes) following initiation of the gradient, one minute fractions are collected and aliquots of the fractions analyzed for protein content by polyacrylamide gel electrophoresis and fluorescamine protein determination. Additional HPLC or cation-exchange chromatographic steps can be employed if indicated.
Utility HIL-4 proteins represent promising therapeutic agents for treatment of immune deficiencies and neoplastic conditions. In such therapy, a hIL-4 protein in the form of a purified composition comprising the protein in combination with a physiologically acceptable carrier or diluent is administered by continuous parenteral infusion, subcutaneous injection, or other suitable means at an dosage rate effective to induce proliferation of B-cells and/or T-cells.
Suitable dosages for IL-4 therapy, as indicated by animal studies, are from 0.1 to 100 pg/kg body weight per day. Alternatively, the protein can be used in forms of adoptive immunotherapy wherein particular immune cell classes are isolated, expanded in vitro in the presence of a hIL-4 protein, and readministered with additional hIL-4 as means of inducing tumor regression. Optionally, hIL-4 proteins can be used in conjunction with human interleukin-2.
These approaches to cancer therapy are suggested by the observation that purified murine IL-4 enhances the generation of cytolytic T lymphocytes in primary mixed leukocyte cultures, and induces cytolytic activity in populations of mixed leukocytes previously exposed to antigen from allogeneic cells.
Cytolytic T lymphocytes (CTL), also known as cytotoxic or effector T cells, are receptor-bearing, antigen-specific lymphocytes.
Alloreactive CTL lyse target cells that display major histocompatibility gene complex (MHC) antigens identical to those of the allogeneic cells used to stimulate or induce the cytolytic cells.
CTL specific for viral and/or tumor antigens are "restricted" in their recognition of antigens, in that antigen-bearing target cells must also display MHC antigens identical to those of the CTL themselves.
CTL control viral replication by killing cells expressing virus-associated membrane antigens, and have also been indirectly
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1 -I -~Fln WO 88/04667 PCT/US87/03114 16 implicated in immune surveillance and destruction of certain neoplastic cell types.
CTL generation is studied most simply in mixed leukocyte cultures (MLC), wherein lymphocytes from genetically dissimilar (allogeneic) individuals are cocultured to induce T cell proliferation. Such T cells are specific for foreign MHC antigens, (present on cells of one individual and not the other) and are referred to as alloreactive T cells. CTL activation and differentiation require participation by CTL precursor cells, T "helper" cells, and accessory cells of monocyte/macrophage lineage.
CTL response is initiated upon antigen recognition by particular T cell populations; epoosure to appropriate antigen triggers lymphokine receptor expression on CTL precursors and lymphokine secretion by helper T cells. Lymphokine binding by CTL precursors induces proliferation and presumably differentiation of antigen-activated CTL precursors to a cytolytic state. However, a CTL precursor need not necessarily proliferate in order to attain its cytolytic potential; the ability to kill is apparently a differentiated function.
The T cell mediated lytic cycle begins with cell-to-cell contact between a viable effector cell and a target cell bearing the appropriate determinant. Unlike natural killer (NK) cells, which direct cytolytic activity to a broad spectrum of target cells without 1 an overt requirement for antigen activation, CTL lyse with discriminating specificity. Following contact and adhesion of effector and target, a so-called "lethal hit" is administered, in which membrane permeability of the target is disrupted. This event results in osmotic swelling and the ultimate loss of cytoplasm. The effector cell retains the ability to recognize and lyse additional target cells.
The growth and differentiation of CTL is regulated by soluble growth hortones, of which interleukin-2 (IL-2) is considered to be of prime importance. It has now been found that IL-4 also profoundly influences the generation of functionally active CTL. In particular, IL-4 acts as a potent helper factor for the generation of CTL in primary mixed leukocyte culture (MLC) and induces cytolytic activity in in vitro primed, MLC memory populations. Direct comparison of I i i
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.T Q t 1 1 i i 1 WO 88/04667 PCT/US87/03114 17 purified recombinant IL-4 and IL-2 has revealed IL-4 to be more potent than IL-2 in augmenting CTL generation in primary MLC. The two lymphokines differ in that IL-2, but not IL-4, induces a lytic population in cultures of unprimed cells in the absence of an overt antigenic stimulus. The specificity of cytolysis induced by IL-4 may have important therapeutic ramifications; the efficacy of adoptive immunotherapy may be enhanced if side effects attributable to introduction of non-specific lymphokine-activated killer (LAK) cells in IL-2 LAK therapy) are reduced.
In related observations, recombinant IL-4 has been shown to effectively induce proliferation of mitogen-activated T-cells, thymocytes, memory T cells, and alloreactive T-cell clones of different functional subtypes, including CTL. IL-4 has been found to b" e as effective a stimulus as IL-2 for inducing proliferation of mitogen-activated murine spleen cells bearing the Lyt2+ surface antigen. Thus, it is apparent that IL-4 is an important regulator of T cell growth and function.
The following discussion is intended to provide additional details regarding particular aspects of the present invention. In the experiments described below, standard molecular biological techniques were followed as described in Maniatis et al., Molecular Cloning: A Laboratory Manual (Cold Spring Harbor Laboratory, 1982) for the restriction enzyme digestion of DNA, purification of DNA fragments by gel electrophoresis, ligation of DNA fragments, transformation into E.
coli (strain RR1 was used throughout), and analysis and verification of constructs by restriction enzyme digestion.
Example 1: Isolation of cDNA encoding Wild-Type hIL-4 and Expression of Active Protein Using a Yeast Expression System Synthetic oligonucleotides were constructed complimentary to SN and C terminal coding region sequences of human IL-4. The N-terminal probe had the sequence 5'-CAGTTGGGAGGTGAGACCCAT-3', while the C-terminal probe had the sequence 5'-TCAGCTCGAACACTTTGAATA-3'.
The method of synthesis was a standard automated triester method substantially similar to that disclosed by Sood et al., Nucleic Acids Res. 4:2557 (1977) and Hirose et al., Tet. Lett. 28:2449 (1978).
i WO 88/04667 PCT/US87/03114 18 Following synthesis, the oligonucleotide was deblocked and purified by Sephadex G-50 chromatography followed by preparative gel electrophoresis. The oligonucleotides were terminally radiolabelled with 3P using 32 -ATP and T4 polynucleotide kinase by standard techniques, such as those disclosed by Maniatis et al., Molecular Cloning: A Laboratory Manual (Cold Spring Harbor Laboratory 1982), for use as screening probes.
A cDNA library was constructed by reverse transcription of polyadenylated mRNA isolated from total mRNA extracted from human peripheral blood T lymphocytes (PBT) stimulated with phytohemagglutinin (PHA) and phorbol 12-myristate 13-acetate (PMA)..
The cDNA was rendered double-stranded using DNA polymerase I and T4 DNA polymerase, methylated with EcoRI methylase to protect EcoRI cleavage sites within the cDNA from subsequent cleavage with EcoRI, ligated to EcoRI linkers, digested with EcoRI to remove all but one copy of the linkers at each end of the cDNA, and ligated to EcoRI-cut and dephosphorylated arms of bacteriophage Xgtl0 (Huynh et al., DNA Cloning: A Practical Approach, Glover, ed., IRL Press pp 49-78). The ligated DNA was packaged into phage particles to generate a library of 2.5 x 106 recombinants. 5 x 105 recombinants were plated on E. coli strain C600hfl- and screened by standard plaque hybridization techniques with the labeled oligonucleotide probes. Three positively hybridizing clones were isolated from the PBT library. These were plaque purified and used to prepare bacteriophage DNA which was digested with EcoRI. The digests were electrophoresed on an agarose gel, blotted onto nylon filters, and retested for hybridization of the fragments to the two oligonucleotide probes. One clone contained a DNA segment which positively hybridized to both probes. This DNA segment, containing an internal EcoRI cleavage site, was isolated by partial digestion with EcoRI followed by preparative agarose gel electrophoresis, then subcloned into an EcoRI-cut derivative of the standard cloning vector pBR322 (pGembl) containing a polylinker having a unique EcoRI site, a BamH1 site and numerous other unique restriction sites. The resulting plasmid was designated pGembl:hIL-4.
351 An exemplary vector substantially similar to pGembl is described by Dente et al., Nucleic Acids Research 11:1645 (1983).
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i li V y WO 88/04667 PCT/US87/03114 19 Following transformation of a suitable E. coli host strain, plasmid DNA was purified by standard techniques, then cut with EcoRV and BamH1. The resulting fragment was ligated to Asp718 and BamH1-cut pBC(CSF-1) and the following linker fragment, which provides the KEX2 oa-factor processing site and the initial four amino acids of hIL-4 25 having a His amino terminus: GTA CCT TTG GAT AAA AGA CAC AAG TGC GAT GA AAC CTA TTT TCT GTG TTC ACG CTA Leu Asp Lys Arg His Lys Cys Asp The KEX2 protease cleaves the peptide immediately following the Arg residue. This construct was designated pBC104.
In substantially similar fashion, pBC103 was prepared by ligating the hIL-4 EcoRV-BamH1 fragment, Asp718 and BamHl-cut pBC(CSF-1), and the following oligonucleotide fragment, which encodes an additional His-Gly located immediately following the KEX2 cleavage 25 site and preceding His GTA CCT TTG GAT AAA AGA CAC GGA CAC AAG TGC GAT GA AAC CTA TTT TCT GTG CCT GTG TTC ACG CTA Leu Asp Lys Arg His Gly His Lys Cys Asp The resulting expression vectors, designated pBC103 and pBC104, were amplified in E. coli and then employed to transform yeast strain XV2181 by the procedures previously referenced. The transformed yeast were grown in nutrient media under conditions 2 promoting derepression of the ADH2 promoter, and the resulting conditioned medium assayed for hIL-4 activity using goat anti-human IgM F(ab) 2 fragments as coactivator. These assays indicated a medium activity of 43,427 U/ml for media conditioned by pBC104-transformed XV2181, and 46,149 U/ml for media conditioned by pBC103-transformed S XV2181.
Example 2: Construction of DNA Sequence Encoding Analog hIL-4 The two asparagine-linked glycosylation sites present in the 62 129 natural hIL-4 protein (Asn 62 and Asn 129 were removed by changing the codons at these positions to ones that encode aspartic acid. This Si,_ i i; re WO 88/04667 PCT/US87/03114 prevents N-linked glycosylation, or even hyperglycosylation, of the secreted protein by yeast cells, thereby enabling production of a more homogeneous product. The N-linked glycosylation sites in the hIL-4 cDNA described above (pBC104) were inactivated by replacing portions of the cDNA with synthetic oligonucleotides containing the desired nucleotide changes, as described below.
A cloning vector (pGembl:hIL-4) comprising the wild-type hIL-4 cDNA sequence shown in FIGURE 1 was digested with the restriction enzymes EcoRV, which cleaves after nucleotide 12 of mature hlL-4, and BamHl, which cleaves downstream from the hIL-4 cDNA in the polylinker region of the vector. The approximate 550 base pair hIL-4 cDNA fragment was subcloned into the pBR322-derived vector pPL-3 by digesting this vector with EcoRV and BamHl (see FIGURE The resulting plasmid was designated L225.
A DNA fragment from L225 containing the hIL-4 cDNA was then subcloned into the pBR322-derived vector pGEM-3 (Promega Biotec, Madison, WI, USA) by digesting plasmid L225 with Clal of the hIL-4 cDNA), treating with T4 DNA polymerase to form blunt ends, then digesting with Sstl to the hIL-4 cDNA in the polylinker region) to remove the cDNA-containing fragment. The vector pGEM-3 was digested with HindIII, treated with T4 DNA polymerase to form blunt ends, then digested with Sstl. The resulting plasmid was designated L257. This plasmid was used to perform the oligonucleotide replacement mutagenesis described below. All references to numbering of amino acid residues or nucleotides are in accordance with the numbering of FIGURE 1, in which residues and nucleotides are numbered from the N-terminus of the full length translation product, including the putative native signal peptide.
The codon encoding asparagine at position 62 was changed to a codon encoding aspartic acid as follows. Plasmid L257 was digested with HincII, which cuts at nucleotide 152, and PstI, which cuts at nucleotide 211. The resulting vector fragment was isolated and ligated to the following oligonucleotide A: i I C TGC CAT TGG CTG TAG AAA CGA CGA TCG TTC CTG...
Thr Val Thr Asp Ile Phe Ala Ala Ser Lys Asp ACA ACT GAG AAG GAA ACC TTC TGC A TGT TGA CTC TTC CTT TGG AAG Thr Thr Glu Lys Glu Thr Phe Cys.
The underlined nucleotides above represent changes from the wild type cDNA sequence. Only the A/T to G/C change at nucleotide 184 results in a codon specifying an amino acid change (Asn 62 to Asp 62 The other five base changes do not alter the amino acid sequence, but introduce restriction sites (BstEII and NheI) to facilitate identification of the altered sequence.
The codon encoding the asparagine residue at position 129 was similarly changed to codon encoding aspartic acid by replacing the DNA fragment from the EcoRl site (nucleotide 360) to the RsaI site (nucleotide 393) in the hIL-4 cDNA with the following synthetic oligonucleotide B: AAT TCG TGT CCT GTG AAG GAA GCC GAC CAG TCG GG ACA GGA CAC TTC CTT CGG CTG GTC AGC Asn Ser Cys Pro Val Lys Glu Ala As Gln Ser The underlined nucleotides represent changes from the wild-type cDNA sequence. Only the A/T to G/C change at position 385 results in an 129 129 codon specifying an amino acid change (Asn to Asp The other base changes introduce a SalI restriction site without altering the amino acid sequence. The plasmid derived from plasmid L257 carrying both codon changes was designated pBC132.
Example 3: Construction of a Yeast Expression Vector for the hIL-4 Analog GluAlaGluAla-hIL-4-(Asp-62, Asp-129) To prepare a yeast expression vector for the mutein, a DNA 62 129 fragment encoding hIL-4(Asp Asp 12 was removed from the pBC132 vector by digestion with EcoRV and SstI, manipulated as described below, and inserted into the yeast expression vector pIXY120. pIXY120 is substantially identical to pBC104, except for its heterologous insert. As noted below, pBC104 can be used in place of pIXY120 for expression of the muteins of the present invention.
OnyteATt hneatpsto 8 eut na r i WO 88/04667 PCT/US87/03114 22 The yeast expression vector pIXY120 (FIGURE 4) includes DNA sequences from the following sources: 1. From the E. coli vector pBR322, the large SphI (nucleotide 562) to EcoRI (nucleotide 4361) restriction fragment which includes the origin of replication and the ampicillin-resistance marker for selection in E. coli.
2. From the yeast S. cerevisiae, DNA fragments include the TRP-1 gene as a selectable marker in yeast; the yeast 2 micron origin of replication; and the S. cerevisiae ADH2 promoter; and an 85 amino acid signal peptide derived from the gene encoding the secreted peptide a-factor (See Brake et al., Proc. Natl. Acad. Sci. USA 81:4642 (1984); Kurjan and Herskowitz, Cell 30:933 (1982); and U.S. Patent 4,546,082). An Asp718 restriction site was introduced at nucleotide 237 in the a-factor signal peptide to facilitate its fusion to heterologous genes. The T residue at nucleotide 241 was changed to a C residue by oligonucleotide-directed in vitro mutagenesis.
3. A synthetic oligonucleotide containing multiple cloning sites was inserted from the Asp718 site (amino acid 79) near the 3' end of the a-factor signal peptide to a Spel site contained in the 2P sequences:
GTACCTTTGGATAAAAGAGACTACAAGGACGACGATGACAAGAGGCCTCCATGGATCCCCCGGGACA
I GAAACCTATTTTCTCTGATGTTCCTGCTGCTACTGTTCTCCGGAGGTACCTAGGGGGCCCTGTGATC 4. A 514 bp DNA fragment derived from the single-stranded bacteriophage fl containing the origin of replication and intergenic region. This fragment is inserted at the Nrul site in the pBR322 DNA sequences. The presence of the fl origin of replication allows generation of single-stranded copies of 'the vector when transformed into appropriate (male) strains of E. coli and superinfected with bacteriophage fl. This capability facilitates DNA sequencing of the vector and allows the possibility of doing in vitro mutagenesis.
The yeast expression vector pIXY120 was digested with the restriction enzyme Asp718, which cleaves near the 3' end of the a-factor leader peptide (nucleotide 237), and BamHI, which cleaves in the polylinker. The large vector fragment was purified and ligated to the following two DNA fragments, as depicted in FIGURE 4: 4. WO 88/04667 PCT/US87/03114 23 1. The hIL-4 cDNA fragment from the EcoRV site (nucleotide 136 of mature hIL-4) to the BamHI site to the hlL-4 cDNA in the Gembl:hIL-4 polylinker) obtained from plasmid Gembl:hIL-4.
2. The following synthetic oligonucleotide linker 1, which regenerates the 3' end of the a-factor leader peptide and fuses it in frame to the 5' four amino acids of hIL-4. This oligonucleotide also encodes an eight amino acid identification peptide fused to the N-terminus of hIL-4. This fusion to the hIL-4 protein allowed its detection with specific antibody and was used initially for monitoring the expression and purification of hIL-4.
GTA CCT TTG GAT AAA AGA GAC TAC AAG GAC GAC GAT GAC AAG CAC AAG TGC GAT GA AAC CTA TTT TCT CTG ATG TTC CTG CTG CTA CTG TTC GTG TTC ACG CTA Pro Leu Asp Lys Arg Asp Tyr Lys Asp Asp Asp Asp Lys His Lys Cys Asp a-factor---- identification peptide----41 hIL-4---4 This plasmid, designated pIXY118 (FIGURE 5) contains the wild type hIL-4 gene under control of the glucose repressible ADH2 promoter. The a-factor leader peptide allows secretion of hIL-4 from the yeast cells. Proteolytic processing of the a-factor leader occurs after the Lys-Arg residues (amino acids 83 and 84) of the a-factor S leader.
To create a yeast expression vector containing the hlL-4 gene without the consensus N-linked glycosylation sites, plasmid pIXY 118 was digested with EcoRI, which cleaves 5' to the ADH2 promoter, and SstI, which cleaves 3' to the hIL-4 gene (FIGURE The large vector fragment was purified and ligated to the following DNA fragments: 1. The EcoRI to EcoRV DNA fragment from pIXY118 carrying the ADH2 promoter, the a-factor leader sequences and the first four amino acids of hIL-4 (this was necessary because of an SstI site in this fragment).
2. The hIL-4 cDNA insert contained in plasmid pBC132 from the EcoRV site (from nucleotide 13 of mature hIL-4) to the SstI site to the hIL-4 cDNA).
The resulting plasmid was designated pIXY133. It contained the hIL-4 gene with the Asp 62 and Asp129 codon changes and the eight 10 te exresion nd urifcatin o hIL4.
hi pasid dsigatd IXHS(FGUE 5 cntin teil WO 88/04667 PCT/US87/03114 24 amino acid fusion peptide at the N-terminus in the yeast expression vector.
The final yeast expression plasmid is identical to plasmid pIXY133 except for the oligonucleotide linker sequences used to fuse the hIL-4 cDNA to the a-factor leader (oligonucleotide 2, FIGURE 6).
This yeast expression plasmid was constructed as described below and shown in FIGURE 6: The yeast expression vector pIXY120 was cleaved with the restriction enzymes Asp718 and BamHI as described above. The large vector fragment was ligated together with the following DNA fragments: 62 129 a hIL-4 (Asp Asp cDNA fragment derived from plasmid pIXY133 from EcoRV (at nucleotide 13) to the BamHI site to the hIL-4 cDNA) and a synthetic oligonucleotide (oligonucleotide 2, FIGURE 6) regenerating the 3' end of the a-factor leader peptide from the Asp718 site (the amino acids Pro-Leu-Asp-Lys-Arg-Glu-Ala-Glu-Ala) and fusing it in-frame to the N-terminal four amino acids of hIL-4 to the EcoRV site. The sequence of this oligonucleotide is set forth below: GTA CCT TTG GAT AAA AGA GAA GCT GAA GCT CAC AAG TGC GAT GA AAC CTA TTT TCT CTT CGA CTT CGA GTG TTC ACG CTA Pro Leu Asp Lys Arg Glu Ala Glu Ala His Lys Cys Asp hIL-4 4 The resulting plasmid was designated pIXY157 (FIGURE 6).
This vector, when present in yeast, allows glucose-regulated expression and secretion of a non-glycosylated mutant hIL-4. The hIL-4 that is recovered contains the four amino acids Glu-Ala-Glu-Ala at the N-terminus due to lack of processing by the yeast protease dipeptidyl-amino-peptidase A. The large portion of the m-factor leader is proteolytically removed after the Lys-Arg residues (amino acids 83 and 84 of the leader) by the product of the KEX2 gene.
The foregoing rather lengthy route can be shortcut by excising an EcoRV-BamHI IL-4 cDNA-containing fragment from pBC104, and digesting the fragment and reassembling it as an EcoRV-SstI fragment as described above using synthetic oligonucleotides to alter the asparagine-linked glycosylation sites. pBC104 can also be cut with EcoRI and SstI, and with EcoRI and EcoRV as described above for iL I T.T 1. tl <,i WO 88/04667 PCT/US87/03114 pIXY118, to generate vector EcoRI-SstI and EcoRI-EcoRV fragments which can be ligated together with the reassembled mutant IL-4 EcoRV-SstI fragment. This construct can then be cut with As718 and BamHI and the resulting vector fragment ligated to an EcoRV-BamIII fragment from the same plasmid comprising the IL-4 analog gene, and the foregoing synthetic oligonucleotide 2, to generate a yeast expression vector for GluAlaGluAla-hIL-4(Asp Asp 29 which is identical to pIXY157.
Example 4: Fermentation of Yeast and Analog Protein Purification Yeast containing the expression plasmid encoding the hIL-4 analog protein GluAlaGluAla-hIL-4-(Asp 62 Asp 129 were maintained on YNB-trp agar plates stored at 4°C. New plates were prepared from frozen glycerol stocks once a week.
A preculture was started by inoculating several isolated recombinant yeast colonies into one liter of YNB-trp medium (6.7 g/L Yeast Nitrogen Base, 5 g/L casamino acids, 40 mg/L adenine, 160 mg/L uracil, and 200 mg/L tyrosine), and grown overnight in two 2-liter flasks at 30 C with vigorous shaking. By morning the culture was saturated, in stationary phase, at an OD600 of 2 to 7.
Two 10 liter fermenters were cleaned and sterilized, then filled to 80% of their working capacity with 12/50 YEP medium (12 g/L yeast extract, 50 g/L peptone) and maintained at 30°C with 500-600 rpm agitation and 10-16 LPM aeration. The inoculum was added. After two hours of growth a nutrient feed of 50% glucose was begun at a rate such that 50 g/L is added over a period of 10-12 hours. The nutrient feed was then shifted to 50% ethanol added to a total of 10 ml/L over 6 hours.
Total elapsed time of fermentation was approximately hours. The final optical density (600nm) ranged from 30 to 45. The fermenters were cooled to 20°C, and the harvesting procedure begun.
First, the pH was adjusted to 8.0 by the addition of 5M NaOH. The fermenter contents were harvested into a clean carboy. The yeast beer was then filtered through a Millipore Pellicon filter system equipped with a 0.45 micron filter cassette, and collected in a sterile 10 L carboy.
\rze glceo stck 1 -0C ,n r wee WO 88/04667 PC1/US87/03114 26 The GluAlaGluAla-hIL-4(Asp 62 Asp29) mutein (IL-4 mutein) in the filtered yeast supernatants was purified by batch absorption on S-Sepharose gel, washing with 50mM f-alanine pH 4.0 and 50mM HEPES pH 7.4, elution with a solution of 0.5M NaCl and 50mM HEPES pH 7.4, high performance liquid chromatography (HPLC), application to a MONO-S column, and dialysis against 100mM Tris.
In the first step, the IL-4 mutein contained in the yeast beer was bound to S-Sepharose gel by batch absorption. In a typical run, 400 ml of S-Sepharose gel slurry (1 volume gel:l volume 0-alanine pH 4.0) was added to a volume of 10 L of yeast beer. The pH of this solution was adjusted to pH 3.6 by adding 2N HC1. The solution was then stirred for 10 minutes, and the gel allowed to settle for 30 minutes. The supernatant was decanted through a sintered glass funnel, and the gel slurry containing the recombinant hIL-4 mutein was retained in the funnel.
The gel was washed with 500 ml of 50mM p-alanine pH followed by two 1 L washes with 50mM HEPES pH 7.4. The IL-4 mutein is then eluted from the gel by five 200 ml washes with a solution of NaC1 and 50mM HEPES pH 7.4. S-Sepharose elutions 1 through 3, containing the highest concentrations of the IL-4 mutein, were pooled, sterile filtered, and stored at 4°C until HPLC processing. Elutions from the 4th and 5th washes, containing <10% of the IL-4 mutein, were pooled separately, sterile filtered, and stored at 4 C. Samples from the crude yeast beer, unbound fraction, each of the three washes, and eluate from pooled fractions 1-3 and 4-5 were tested for the presence of IL-4 by immunodot blot and SDS-PAGE. Protein concentration in the pooled eluates was determined by BCA Assay. S-Sepharose fractions were collected until 100 L of yeast beer were processed. At that time, a pool of all elutions from washes 1-3 (as described above) was applied to a 5cm x 30cm column packed with 15-20p C-4 reversed phase silica using the Waters LC-500 HPLC equilibrated in 0.1% trifluoroacetic acid (TFA)/pyrogen free water. The C-4 column was washed with 1 L of a solution of 0.1% TFA/pyrogen free water. The fractions containing recombinant hIL-4 were then applied to the column and eluted with a gradient of 0.1% TFA in acetonitrile at a rate of change of 2% per minute and a flow rate of 100 ml per minute.
I I I I
I
.WO 88/04667 PCT/US87/03114 27 Peak fractions from C-4 RPC column were pooled and 1/10 volume of 0.5M O-alanine pH 4 was added. A sample was taken and then the pool was applied to a 20 ml MONO-S column (1.6 cm x 10 cm,- Pharmacia) at 7 ml/minute. After sample application, the column was washed with 100 ml of 50mM Tris pH 7.4, and the IL-4 mutein was eluted with a linear gradient of 1 M NaCl, 100mM Tris pH 8. Peak fractions of IL-4 were then pooled and dialyzed against 100mM Tris pH 8 overnight at 40C, then sterile filtered. Upon completion of manufacturing and purification, the to al bulk active product was pooled and stored in sterile polyethylene tubes at 4 C. The specific 62 129 activity of the purified hIL-4(Asp Asp by the BCGF assay was 7 3.1 10 units per mg.
Example 5: Induction of Cytolytic Activity in Mixed Leukocyte Culture IL-4 has been shown to stimulate proliferation of certain factor-dependent, non-B lineage cell lines that are normally responsive to IL-2 or to the myeloid growth factor, IL-3. See Grabstein et al., J. Exp. Med. 163:1405 (1986) and Lee et al., Proc.
Natl. Acad. Sci. USA 83:2061 (1986). To demonstrate that IL-4 also affects primary T cell populations, particularly with regard to the generation of functionally active T cells, its effects on the generation of CTL in mixed leukocyte cultures (MLC) were assessed.
MLC were established with a suboptimal concentration of C57BL/6 splenic responding cells and allogeneic, irradiated DBA/2 splenic stimulating cells. Five days after culture initiation, lytic activity against 5Cr-labeled P815 murine (DBA/2 origin) tumor target cells was measured.
Murine IL-4 cDNA was cloned from a library made from sized mRNA of phorbol myristate acetate stimulated EL4 thymoma cells using the cDNA sequence published by Lee et al., Proc. Natl. Acad. Sci. USA 83:2061 (1986). A full length cDNA was subcloned into a yeast expression vector which included pBR322 sequences, the TRP1 gene of yeast for tryptophan selection, the yeast 2p origin of replication and the yeast alcohol dehydrogenase 2 (ADH2) promoter and a-factor leader sequences sufficient to direct synthesis and secretion. The expression plasmid was transformed into yeast strain 79 trpl-1,
FL
WO 88/04667 PCT/US87/03114 28 V leu2-2) selecting for Trp transformants. Cultures were grown for purification by inoculating 1 liter of rich medium yeast extract, 2% peptone, 2% glucose) and growing the cultures at 30 0 C to stationary phase. PMSF and pepstatin A were added at the time of harvest. Cells were removed by centrifugation and filtration thli-ugh a 0.45 pm cellulose acetate filter. rIL-4 was purified to homogeneity from yeast supernatant by five cycles of high performance liquid chromatography (HPLC) using solvent systems previously described by Urdal et al., J. Chromatography 296:171 (1984). Homogeneous recombinant and natural murine IL-4 exhibit identical specific activities of 2.0 x 105 U/pg, as measured in the B cell proliferation assay described below.
MLC incorporating 5 x 105 C57BL/6 murine spleen cells and 5 x 6 gamma irradiated (2,500r) DBA/2 murine splenic stimulating cells were initiated in 16 mm diameter culture wells containing 2 ml culture medium. The culture medium was Dulbecco's Modified Eagle's Medium (DMEM) containing 5% fetal bovine serum (FBS), 5 x 10 M 2-mercaptoethanol and additional amino acids, substantially as disclosed by Cerottini et al., J. Exp. Med. 140:703 (1974). Cultures were supplemented at initiation with homogeneous natural murine IL-4 (nIL-4) at 2 ng/ml, recombinant human IL-2 at 10 ng/ml, or medium.
Five days after culture initiation, lytic activity was tested by incubating, in duplicate 200 ul volumes, varying ratios of effector cells and 51Cr labeled P815 target cells (2 x 10 3 cells/well) in 96 well v-bottom microtiter plates. After a 3.5 hr incubation, plates were centrifuged and 150 pi supernatant from each well were harvested and counted in a gamma counter. The results obtained are indicated in 51 FIG. 6. In FIG. 6, reported percent specific 51Cr release was determined as 100 x [cpm (experimental) cpm (spontaneous)] [cpm (maximum) cpm (spontaneous)] where spontaneous release (118 cpm) was determined by incubating P815 in medium and maximum release (801 cpm) by incubating P815 in 1N HC1. One lytic unit (LU) was defined as the number of cells required to achieve 50% lysis of 2 x 103 P815 target cells and is determined from the dose-response curve. Percent recovery equals the number of cells recovered at day 5 as a percentage of the initial number of responding cells cultured.
WO 88/04667 PCT/US87/03114 29 Cultures supplemented at initiation with 2 ng/ml of homogeneous, natural IL-4 exhibited approximately 50-fold greater cytolytic activity, on a per cell basis, than control cultures in which exogenous IL-4 was not present, and 100-fold more activity on a per culture basis. Cultures supplemented with 10 ng/ml rIL-2, as expected, also exhibited higher levels of CTL activity than control cultures, but the lytic activity was 7-fold less than that which developed in IL-4 supplemented cultures. Cytolytic T lymphocyte generated in MLC supplemented with either IL-4 or IL-2 were alloantigen specific, since lytic activity directed against target cells syngeneic with the responding cell populations was 2% of that directed against the specific allogeneic target (data not shown).
These data indicate that IL-4 is a potent helper factor for the generation of alloreactive cytolytic T lymphocytes.
Example 6: Induction of Cytolytic Activity in Memory T Cell Populations MLC populations that have been cultured for extended periods of time gradually lose CTL activity but can be re-induced to express high level cytolytic activity by exposure to either allogeneic cells or culture supernatant. To test the effects of IL-4 on such MLC memory populations, cells obtained from day 14 C57BL/6 anti-DBA/2 primary MLC were cultured in the presence of recombinant IL-2 or IL-4 and resultant cytolytic activity was measured three days later.
Mixed leukocyte cultures were established with 25 x C57BL/6 spleen cells and 25 x 10 6 irradiated (2500r) DBA/2 splenic stimulating cells in 25 cm 2 flasks, 20 ml total volume. Fourteen days after initiation, cells were harvested from primary cultures and 5 x 105 cells were re-cultured in Costar 16 mm culture wells in 2 ml volumes containing recombinant murine IL-4 at 1 ng/ml, recombinant human IL-2 at 0.5 ng/ml, or medium. Three days later, culture contents were tested for lytic activity against 51Cr-labeled P815 target cells. Spontaneous release in this experiment was 204 cpm, while maximum release was 1,829 cpm.
As shown in FIG. 7, exposure of the cells to either in cellular proliferation and induction of high lymphokine resulted in cellular proliferation and induction of high 44 WO 88/04667 PCT/US87/03114 kc level cytolytic activity. Lytic activity generated in cultures incubated with IL-4 was approximately 100 fold higher than that observed in control cultures incubated in medium (FIG. and higher than the activity of the day 14 population before exposure to exogenous lymphokine (data not shown). CTL activity induced by IL-4 in these cultures, as in primary MLC, was antigen-specific (data not shown). Thus, IL-4, like IL-2, induces expression of antigen-specific cytolytic activity in once-activated, resting memory T cell populations without the need for further antigenic stimulation.
Example 7: Dose-Response Comparison of IL-4 and IL-2 To test directly the relative efficiencies of recombinant IL-4 and IL-2 in their capacity to augment CTL generation, multiple concentrations of homogeneous recombinant IL-4 or IL-2 were added to allogeneic primary mixed leukocyte cultures and resultant lytic activity was measured five days later.
In this experiment, mixed leukocyte cultures (MLC) were established with 2 x 10 6 C57BL/6 spleen cells and 5 x 106 irradiated (2500r) spleen cells from either DBA/2 (allogeneic) or C57BL/6 (syngeneic) and supplemented with varying doses of recombinant IL-4 or 51 IL-2. Lytic activity against Cr labeled P815 was assessed on day as above. Spontaneous release of radiolabel averaged 125 cpm, while the maximum release observed was 886 cpm.
Although both lymphokines augmented cell proliferation and CTL activity, the levels of lytic activity that developed in cultures containing optimal doses of IL-4 were approximately 3-4 fold higher than that observed in cultures supplemented with optimal doses of IL-2. In addition, at suboptimal lymphokine doses, approximately less IL-4 than IL-2 was required to obtain equivalent amounts of lytic activity. These data indicate that, in mixed leukocyte cultures established with this allogeneic strain combination, IL-4 is a more potent helper factor for generating CTL from unprimed precursors than IL-2. Since approximately equal numbers of cells were recovered in allogeneic MLC supplemented with IL-2 or IL-4, the data may reflect either higher CTL frequency or individual CTL with greater lytic activity.
-1 j i ,i o i WO 88/04667 PCT/US87/03114 31 Table 2: Effects of IL-4 and IL-2 on generation of cytolytic activity in allogeneic and syngeneic primary mixed leukocyte culture (MLC).
Culture A. Allogeneic MLC B. Syngeneic MLC Supplement Recovery LU/Culture Recovery LU/Culture Medium 55 4 21 <1 rIL-2,ng/ml 3 101 23 185 44 102 99 30 119 37 10 90 37 48 4 1 61 12 33 <2 1 73 7 22 <1 2 79 6 30 <1 rIL-4,ng/ml 2 5 10 85 95 18 <1 65 124 15 <1 1 63 79 17 <1 10-1 53 12 20 <1 2 66 6 16 <1 The data presented above and in Examples 6 and 7 demonstrate that IL-4 induces both proliferation and cytolytic activity in primary and memory MLC populations, revealing a novel regulatory mechanism for CTL generation.
Example 8: Induction of Thymocyte proliferation Thymocytes were obtained from female C57BL/6J mice, 6-10 weeks of age, and cultured at 1.5 x 106 cells/well in 200 ul volumes of RPMI 1640 containing 5% FBS, culture supplements as described above, and in the presence or absence of 0.25% PHA-M (Gibco Laboratories, Grand Island, NY) and either recombinant human IL-2 or murine IL-4, as indicated in Table 3, below. Cultures were pulsed with 2.0 uCi of 3 H]thymidine (75 Ci/mmole) during the last 18 hours of a 72 hour culture period, harvested onto glass fiber filters and incorporated radioactivity determined.
I
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WO 88/04667 PCT/US87/03114' 32 Both rIL-2 and rIL-4 were used at 10 ng/ml. Results are expressed in Table 3, below, as the mean cpm the standard deviation) of triplicate cultures.
Table 3: Stimulation of thymocyte proliferation by rIL-4 Culture Additive cpm s.d.) none 320 (41) rIL-4 11,183 (639) rIL-2 60,014 (5707) PHA 2,050 (184) PHA rIL-4 83,162 (7548) PHA rIL-2 138,955 (9019) These results indicate that IL-4, in the presence and absence of a comitogenic stimulus, induces proliferation of thymocytes. In the presence of added mitogen, proliferation is considerably (7x) enhanced.
Example 9: Stimulation of Memory T Cell Proliferation by IL-4 Memory T cells were generated in 14 day primary MLC. Primary MLC were established with 25 x 10 6 C57BL/6 spleen cells and 25 x 106 i irradiated (2500r) DBA/2 splenic stimulating cells in 25 cm flasks containing 20 ml of culture medium. The culture medium was Dulbecco's Modified Eagle's Medium (DMEM) containing 2% fetal bovine serum (FBS), -5 x 10 M 2- mercaptoethanol and additional amino acids, substantially as disclosed by Cerottini et al., J. Exp. Med. 140:703 (1974). For secondary MLC, 5 x 105 cells recovered from day 13 6 primary MLC were cultured with 5 x 10 irradiated (2500r) DBA/2 spleen cells in 16 mm culture wells containing 2 ml culture medium. These cells were then tested for proliferation in response to rIL-4 (4 ng/ml) or rIL-2 (4 ng/ml) either before or three days after restimulation with allogeneic cells, by incubating 10 cells/well in 96 well flat bottom plates containing 200 pl/well culture medium and the indicated additive. Cultures were pulsed for the last 18 hours of a 72 hour culture period with 1.0 uCi of 3 H]thymidine (75 Ci/mmole, New England Nuclear, Boston, MA) and then harvested onto glass fiber filters. Incorporation of radioactivity was measured by liquid i-
S
;1: tr ii i I w:E vrj WO 88/04667 PCT/US87/03114 scintillation spectrometry. Results are expressed in Table 4, below, as the mean cpm the standard deviation) of triplicate cultures.
Table 4: Response to rIL-4 of Resting and Activated Memory T cells Culture Additive none rIL-4 rIL-2 Day 14 Primary MLC 497 (426) 2,422 (161) 32,871 (4051) Day 3 Secondary MLC 631 (253) 61,246 (3895) 36,776 (3971) The foregoing results indicate a distinction between the proliferation-inducing effects of IL-4 and IL-2. Unlike IL-4, IL-2 is capable of inducing proliferation of cells late in the culture cycle without reactivation by antigen. However, when restimulated by alloantigen memory cells are significantly more responsive to added IL-4 than added IL-2.
I
-33A- Comparative Example 10: Comparative Yeast Expression Experiment The experiments compare yields of IL-4 polypeptides expressed in S cervisiae transformed with expression vectors pIXY 104 and pIXY 157.
pIXY 104 and pIXY 157 are identical expression vectors having an ADH2 promoter sequence, an a-factor leader sequence and a hIL-4 structural gene sequence. The only difference between the expression vectors is the sequence of the hIL-4 polypeptide. pIXY 104 encodes the wild type hIL-4 sequence and pIXY 157 encodes a hIL-4 analog polypeptide having a Glu-Ala-Glu-Ala tetrapeptide at the N-terminus and altered 62 129 glysocylation sites (Asp Asp Yeast strain XV2181 was transformed with either pIXY 104 or pIXY 157 by standard techniques to form a transformed yeast strain. The transformed yeast strains were streaked onto selective plates (YNB-trp) to serve as a source of fresh inoculum. Liquid cultures (5 ml YPD medium containing 1% glucose) were innoculated from the selected plates to a starting cell density of 0.45 to 0.50 A600 units and grown at S 30 0 C with vigorous shaking for 20 hours to a final A600 of to 11. The cultures were centrifuged to remove yeast cells, and filtered by sterile methods through a 0.45 micron filter.
The filtered supernatants were analysed by ELISA to determine the amount of hIL-4 polypeptide or analog polypeptide and by a biological assay to determine IL-4 biological activity.
The amount of hIL-4 polypeptide (wild type or analog) in the supernatants were an average of 6.77 x 10 pg/ml for pIXY 6 104 and 2.57 x 10 pg/ml for pIXY 157. The results are shown as Table The biological assay measures proliferative activity of a CTLL cell line. The CTLL cell line was transformed with human IL-4 receptor and proliferates when stimulated by hIL-4 polypeptides to measure IL-4 biological activity. Biological <S s -MW/3488U i I_ to a standard curve. The results are as follows: Sample Units/ml pIXY 157 49195 pIXY 157 53901 pIXY 104 10212 pIXY 104 15488 plXY 157 94794 pIXY 157 79658 pIXY 104 12342 pIXY 104 16535 The ELISA and biological assay data indicate that the hIL-4 analog polypeptide encoded by pXY 157 is biologically active and expressed in greater concentrations than the hIL-4 wild type polypeptide encoded by pL5Y 104.
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Table 5 Determined Values of hIL-4 polypeptide by ELISA 24 74-1 SAMPLE UNCORRECTED DILUTION CORRECTED MEAN VALUE VALUE PG/ML FACTOR VALUE PGIML PG/ML PIXY 104 1160 625 725007 696164 1:625 571 1250 713659 274 2500 684015 132 5000 661975 PIXY 104 501 1600 801323 740856 1:1,600 226 3200 723187 118 6400 755392 53 12800 683520 (50 25600 PIXY 104 137 5000 685210 593255 1:5.000 50 10000 501300 <50 20000 PIXY 104 <50 50000 <2500000 1: 50,000 AVERAGE 676758 PIXY 157 )1600 1250 1:625 1064 2500 2660213 2623326 517 5000 2586440 PIXY 157 )1l600 1600 1:1,600 819 3200 2619574 2570266 418 6400 2675251 199 12800 2548378 25600 2437862 51200 -W-J 3488U -3 3D- Table 5 :Determined Values of hIL-4 polypeptide by ELISA (continued) 2474-1 SAMPLE UNCORRECTED DILUTION CORRECTED MEAN VALUE VALUE PG/ML FACTOR VALUE PG/ML PG/ML PIXY 157 579 5000 2894795 2518588 1:5,000 253 10000 2534730 106 20000 2126240 K 50 40000 PIXY 157 (50 50000 <2500000 1: 50,.000 AVERAGE 2570727
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Claims (14)
1. A human interleukin-4 (hL-4) analog polypeptide comprising the .,equence: Glu Ala Glu Ala His Lys Cys Asp lie Thr Leu Gin Glu Ile Ile Lys Thr Leu Asn Ser Leu Thr Glu Gln Lys Thr Leu Cys Thr Glu Leu Thr Val Thr Asp Ile Phe Ala Ala Ser Lys X 1 Thr YI Glu Lys Glu Thr Phe Cys Arg Ala Ala Thr Val Leu Arg Gin Phe Thr Ser His His Glu Lys Asp Thr Arg Cys Leu Gly Ala Thr Ala Gln Gin Phe His Arg His Lys Gin Leu Ile Arg Phe Leu Lys Arg Leu Asp Arg Asn Leu Trp Gly Leu Ala Gly Leu Asn Ser Cys Pro Val Lys Glu Ala X2 Gln Y2 Thr Leu Glu, Asn Phe Leu Glu Arg Leu Lys Thr Ile Met Arg Glu Lys Tyr Ser Lys Cys Ser Ser, wherein X1 and X2 are independently any amino acid with the proviso that X1 and X2 cannot both be Asn, Y1 is Thr, Val, Glu, Asp, Gin, Gly, or Ala, and Y2 is Ser, Met, Leu, lie, Val, Asp, Gin, Glu, or Asn. The hL-4 analog polypeptide of claim i wherein X1 is Asp.
3. The hIL-4 analog polypeptide of claim 1 wherein X2 is Asp.
4. The hlL-4 analog polypeptide of claim 1 wherein Xi and X2 are Asp, Y1 is Thr and Y2 is Ser. A pharmaceutical composition for inducing proliferation of and lytic activity in a population of antitumor cytolytic T lymphocytes, comprising Scontacting T cells with a pharmaceutical composition comprising a biologically effective quantity of a hlL-4 analog polypeptide according to claim 1 in combination with a physiologically acceptable carrier or diluent.
6. A DNA sequence encoding a hL-4 analog polypeptide according to any of claims 1-4. .Y.
7. A recombinant expression vector comprising a DNA sequence according to claim 6.
8. A process for preparing a hIL-4 analog polypeptide comprising culturing a microorganism transformed with a recombinant expression vector according to claim 7 under conditions promoting expression.
9. A method for inducing proliferation of and lytic activity in a population of cytolytic T lymphocytes, comprising contacting T cells with a composition comprising a biologically effective amount of a hIL-4 analog polypeptide according to any of claims 1-4 in combination with a physiologically acceptable carrier or diluent. The method according to claim 9 wherein the lymphocytes are previously activated by exposure to virus-associated antigen.
11. The method according to claim 9 wherein the lymphocytes are previously activated by exposure to tumor antigen.
12. The method according to claim 9 wherein the lymphocytes are induced and expanded ex vivo and readministered to the patient in adoptive immunotherapy.
13. A method for inducing proliferation and activation of antitumor or antiviral cytolytic T lymphocytes in a mammal, comprising administering a therapeutically effective amount of a hIL-4 analog polypeptide according to any of claims 1-4.
14. An antiviral composition comprising a biologically effective amount of a hlL-4 analog polypeptide according to any of claims 1-4 in combination with a physiologically acceptable carrier or diluent. An antitumor composition comprising a biologically effective amount of a hIL-4 analog polypeptide according to any of claims 1-4 in combination with a physiologically acceptable carrier or diluent. 1' r{ r -i L: E
16. An antitumor composition according to claim further comprising a therapeutically effective amount of T lymphocytes expanded ex vivo in the presence of IL-4 or IL-2.
17. A human interleukin-4(hIL-4) analog polypeptide according to claim 1 substantially as hereinbefore described with reference to the examples. DATED: 14 October 1991 PHILLIPS ORMONDE FITZPATRICK Patent Attorneys for: IMMUNEX CORPORATION ot r U 'DMW/34 8 8U WO 88/04667 PCT/US87j031 14 WO 88/04667 PCr/US87jO3114 116 FIG. 1: Sequence of Native hIL-4 ATG Met G CA Al a TTA Leu ACT Th r AAG Lys CTC Leu GGT Gly TTC Phe AAT Asn TTC Phe TGT Cys GGT Gly TGT Cy s CAG Gin CTG Leu AAC Asn CGG Arg GCG Al a CTG Leu TCC S e r CTC Leu GCC Al a GAG Glu TGC Cys ACA Thr CAG Gin ACT Thr AAA Lys TGT Cys ACC TCC Thr Ser GGC AAC Gly Asn ATC ATC Ile Ile ACC GAG Thr Giu ACT GAG Thr Glu TTC TAG Phe Tyr GCA CAG Ala Gin CGG CTC Arg Leu CCT GTG irro Vai CAA Gin TTT Phe AA Lys TTG Leu AAG Lys AGC Se r CAG Gin GAC Asp AZAG Lys CTG CTT CCC CCT CTG Leu GTC Val ACT Th r ACC Th r GAA Glu CAC His TTC Phe AGG Arg GAA Glu Leu CAC His TTG Leu GTA Val ACC Th r CAT His CAC His AAC Asn GCC Al a Pro GGA Gly AAC Asn ACA Th r TTC Phe GAG Giu AGG Ar g CTC Leu AAC Asn Pro CAC His AGC Se r GAC Asp TGC Cy s AAG, Lys CAC H-iis TGG Trp CAG Gin Leu AAG Lys CTC Leu ATC Ile AGG Arg GAG Asp AAG Ly s GGC Gly AGT Ser TTG Phe TGC Cy s ACA Thr TTT Phe GCT Al a ACT Th r CAG Gin CTG Leu ACG Th r TTC Phe GAT Asp GAG Giu GCT Al a GCG Ala CGC Arg CTG Leu GCG Ala TTG Leu TAT CTG Leu AT C Ile CAG Gin GCC Al a ACT Th r TGC Gys AT C Ile GGC Gly GAA Glu T CA CTA Leu ACC Th r AAG Lys TCC Se r GTG Val1 GTG Leu CGA Arg TTG Leu A.AC Asn AAG, is 135 180 225 270 315 105 360 120 405 135 450 150 495 153 TTG Leu TCG Se r GAA AGG Giu Arg AGC TGA Ser End CTA AAG ACG ATG ATG AGA GAG AAA Leu Lys Thr Ile Met Arg Giu Lys Tyr Ser Lys FIG. 1 I I_ n 14 WO 88/04667 WO 8804667PCr/US87/031 14 216 FIG. 2: Sequence of GluAlaGluAla-hIL-4(Asp62, Asp129) G TA hIL-4 mute 4 CCT TTA GAT AAA AGA GAA GCT GA-A GCT CAC AAG TGC CAT ATC ACC Pro Leu Asp Lys Arg Giu Ala Glu Ala His Lys Cys Asp Ile Thr TTA CAG GAG ATC ATG AAA ACT TTG AAC AGC CTC ACA GAG GAG AAG Leu Gin Glu Ile Ile Lys Thr Leu Asn Ser Leu Thr Giu Gin Lys ,BstEII NheI ACT CTG TGC ACC GAG TTG ACG GTA ACC GAC ATC TTT OCT GCTAGC Thr Leu Cys Thr Giu Leu Thr Val Thr Asp Ile Phe Ala Ala Sger 4.PstI AAG GAC ACA ACT GAG A.AG GAA ACC TTC TGC AGG GCT GCG ACT GTG Lys Asp Thr Thr Giu Lys Giu Thr Phe Cys Arg Ala Ala Thr Vai CTC CGG CAG TTC TAG AGG CAC CAT GAG AAG GAC ACT CGC TGG GTG Leu Arg Gin Phe Tyr Ser His His Giu Lys Asp Thr Arg Gys Leu GGT GGG ACT GGA CAG GAG TTG GAG AGG GAG AAG GAG GTG ATC CGA Gly Ala Thr Ala Gin Gin Phe His Arg His Lys Gin Leu Ile Arg TTG GTG AAA GGG GTG GAG AGO AAC GTG TOG GG CTG GO GGC TTG Phe Leu Lys Arg Leu Asp Ara Asn Leu Trp Giy Leu Ala Gly Leu 135 180 225 270 315 105 360 120 405 135 450 150 495 153 4-EcoRI AAT TCC Asn Ser 4-Sall TOT GCT GTG AAO GAA GGG GAG GAG TCG AG TTG GA.A AAG Gys Pro Vai Lys Oiu Ala Asp Gin Ser Thr Leu Glu Asn TTC TTG GAA AGO GTA AAG AG ATG ATO AGA GAG AAA TAT TGA AAG Phe Leu Glu Arg Leu Lys Thr Ile Met Arg Giu Lys Tyr Ser Lys TOT TGG AGG TGA Cys Ser Ser End FIG. 2 SUBS-TIUTE caHZET WO 88/04667 316 Barn HI Ist I ,BomHI PCT/US87/031 14 pBR332 PL promnoter Barn HI RY C/o I I EcoY +Bam HI cVector C-a IT4 Polyrn erase -,Sst I lam HI I (C/al1) EcoRY SOtI pGEM-3 L 257 (C/Ol N 1 SO 9 (Hind MI) -N2 T4 Po/ymerase -"-Sst I Vector pGEM -3 p BC 132 0/ (C/al) SOtL (Hind Xl) D 2 EcoRY D 62 oIi gon ucleotide and B Replacement FIG. 3 SUBST1TUTk* SPIET j WO 88/04667 416 Gembi: HuIL-4 Eco RY+ PCT/US87/03 114 Ap pBR32 ort pIXY12O ADH2 promoter 2p EcoRI xfcorlae Barn HI Asp 718 Asp 718 Bom HI Vector promoter Barni HI Sstl I a-factor ftjilb SstI Asp 718 Eco RY Synthetic oligonucleotide -1 Eco EcoRltEcoRY pIXY133 Ec R1% FIG. If _Asp _tmc L 1 J% S EE 2 ~WO 88/04667 PCT/US87/031 14 516 Ecoo RI EcoRY 62 E012 EEcoRRI Bar HIOL-44BmH Asp 78 Ss FIG. 5 Eco RY Asp 718 Eco RY Synthetic ol igonucleotide -29 SUSSTITUT'I" SHEET I U WO 88046 WO 8804667PCr/US87/03 114 CULTURE SUPPLEMENT o MEDIUM %616 LUI RECOVERY CULTURE FIG. 6 92 ui CZ CL) A-II 0.3 1 3 10 30 100 LYMPHOCYTE: TARGET CELL RATIO 100 i FIG. 7 -e H 40 H CULTURE SUPPLEMENT o MEDIUM rBSF-f A rIL-2 RECOVERY 45 0.6 LU! CULTURE Ci- 0.3 1 3 10 30 LYMPHOCYTE: TARGET CELL RATIO 100 <11il 7 I fl[ 0li U nlz1 88U "I I r i i ~LIIP~PI-- L 4 INTERNATIONAL SEARCH REPORT P 87/ PCT/US87/03114 International Application No I. CLASSIFICATION OF SUBJECT MATTER (if several classification symbols apply, indicate all) According to International Patent Classification (IPC) or to both National Classification and IPC IPC(4): C07K. 13/00;C12P 21/00,21/02;C.12N 15/00,1/00;A61K 37/00 1TS rT. n/ l A'/cAQ 7nl 1' 7 n. ci A /1 1 LT u t U I U.l I L i 3 L 1 It L. II. FIELDS SEARCHED Minimum Documentation Searched Classification System I Classification Symbols U.S. 530/351; 435/68,70,172.3,320; 514/12 Documentation Searched other than Minimum Documentation to the Extent that such Documents are Included In the Fields Searched COMPUTER SEARCH, CAS, BIOSIS APS: INTERLEUKIN-.4-MUTEINS, GYCOSYLATI.ON III DOCUMENTS CONSIDERED TO BE RELEVANT Category Citation of Document, G1 with indication, where appropriate, of the relevant passages T Relevant to Claim No. Id Y Nature, Vol. 319, issued 20 Feb. 1986 (London, England), (NOMA ET AL), "Cloning of cDNA encoding the murine IgGl induction factor by a novel strategy using SP6 promoter", pages
640-646. Y Proc. Natl. Acad. Sci. USA, Vol. 83, 1-16 issued April 1986, (Washington, (LEE ET AL), "Isolation and Character- ization of a mouse interleukin cDNA clone that expresses B-cell stimulatory factorlactivities and T-cell- and mast-cell-stimulating activites," pages2061- 2 06 5 Y Pro. Natl. Acad. Sci. USA, Vol. 83, 1-16 issued August 1986, (Washington, (YOKOTA ET AL), "Isolation and characterization of a human interleukin cDNA clone, homologous to mouse B-cell stimulatory factor 1, that expresses B-cell-and T-cell stimulating act- ivities," pages 5894-5898. SSpecial categories of cited documents: t1 later document published after the International filing date documen dening the eneral tate f the art hich is not or priority date and not In conflict with the application but document dening the general sae o the artcited to understand the principle or theory underlying the considered to be of particular relevance invention earlier document but published on or after the international document of particular relevance; the claimed invention filing date cannot be considered novel or cannot be considered to document which may throw doubts on priority clalm(s) or involve an Inventive step which is cited to establish the publication date of another document of particular relevance; the claimed Invention citation or other special reason (as specified) cannot be considered to involve an nventive step when the document referring to an oral disclosure, use, exhibition or document Is combined with one or more other such docu- other means ments, such combination being obvious to a person skilled document published prior to the international filing date but in the art. later than the priority date claimed document member of the same patent family IV. CERTIFICATION Date of the Actual Completion of the International Search a Date of Mailing of this International Search Report s 21 January 1988 1 7 MAR 1988 International Searching Authority I Signature of Authorlu .Offctfr o ISA/US Avin Tanenholtz Form PCT/ISA/210 (second sheet) (May 1986) -r i i 488U I S International Appication~ No, C/ S3/ 3 1 Ill. DOCUMENTS CONSIDERED TO BE RELEVANT (CONTINUED FROM THE SECOND SHEET) Category Citation of Document,.1 with Indication, where appropriate, of the relevant passage$ I I Relevant to Claim No 11 US, A, 4,518,584 (MARK ET AL), 21 May 1985, see particularly Col. 20, lines 19-60. The EMBO Journal, Vol. 5, issued June 1986, (Oxford, England), (MIYAJIMA ET AL), Expression of murine and human granulocyte- macrophage colony stimulating factors in S. cerevisiae: mutagenesis of the potential glycosylation sites," pages 1193-1197. 1-16 1-16 Fairm PCT/ISA/21 0 (extra shoo it) (May 1986)
Applications Claiming Priority (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US94447286A | 1986-12-19 | 1986-12-19 | |
US944472 | 1986-12-19 | ||
US11976387A | 1987-11-12 | 1987-11-12 | |
US119763 | 1987-11-12 |
Publications (2)
Publication Number | Publication Date |
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AU1055988A AU1055988A (en) | 1988-07-15 |
AU620537B2 true AU620537B2 (en) | 1992-02-20 |
Family
ID=26817674
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
AU10559/88A Ceased AU620537B2 (en) | 1986-12-19 | 1987-12-04 | Human interleukin-4 muteins |
Country Status (3)
Country | Link |
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EP (1) | EP0335900A4 (en) |
AU (1) | AU620537B2 (en) |
WO (1) | WO1988004667A1 (en) |
Families Citing this family (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
PT83761B (en) * | 1985-11-19 | 1989-06-30 | Schering Biotech Corp | METHOD FOR THE PRODUCTION OF INTERLEUQUIN-4 OF MAMIFERO |
GB2218420B (en) * | 1988-04-12 | 1992-07-15 | British Bio Technology | Synthetic gene encoding interleukin 4 |
EP0378827A1 (en) * | 1988-12-21 | 1990-07-25 | Schering Corporation | Use of interleukin-4 for lowering blood glucose levels and/or effecting weight reduction |
EP0454736A4 (en) * | 1989-01-20 | 1993-05-12 | The University Of Melbourne | Fibrinolysis |
US5494662A (en) * | 1992-04-27 | 1996-02-27 | Ono Pharmaceutical Co., Ltd. | Stimulator for bone formation |
DE4423131A1 (en) * | 1994-07-01 | 1996-01-04 | Bayer Ag | New hIL-4 mutant proteins as antagonists or partial agonists of human interleukin 4 |
US6028176A (en) * | 1996-07-19 | 2000-02-22 | Bayer Corporation | High-affinity interleukin-4 muteins |
MY124565A (en) * | 1996-07-19 | 2006-06-30 | Bayer Corp | High-affinity interleukin-4-muteins |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
AU6733487A (en) * | 1985-11-19 | 1987-06-02 | Schering Biotech Corporation | Mammalian interleukin-4 |
AU7314887A (en) * | 1986-05-19 | 1988-01-07 | Immunex Corp. | B-cell stimulating factor |
AU2257488A (en) * | 1987-07-29 | 1989-03-01 | Schering Biotech Corporation | Purification of human interleukin-4 expressed in escherichia coli |
Family Cites Families (1)
Publication number | Priority date | Publication date | Assignee | Title |
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US4518584A (en) * | 1983-04-15 | 1985-05-21 | Cetus Corporation | Human recombinant interleukin-2 muteins |
-
1987
- 1987-12-04 EP EP19880900410 patent/EP0335900A4/en not_active Withdrawn
- 1987-12-04 WO PCT/US1987/003114 patent/WO1988004667A1/en not_active Application Discontinuation
- 1987-12-04 AU AU10559/88A patent/AU620537B2/en not_active Ceased
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
AU6733487A (en) * | 1985-11-19 | 1987-06-02 | Schering Biotech Corporation | Mammalian interleukin-4 |
AU7314887A (en) * | 1986-05-19 | 1988-01-07 | Immunex Corp. | B-cell stimulating factor |
AU2257488A (en) * | 1987-07-29 | 1989-03-01 | Schering Biotech Corporation | Purification of human interleukin-4 expressed in escherichia coli |
Also Published As
Publication number | Publication date |
---|---|
AU1055988A (en) | 1988-07-15 |
EP0335900A4 (en) | 1990-12-27 |
EP0335900A1 (en) | 1989-10-11 |
WO1988004667A1 (en) | 1988-06-30 |
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