AU6122894A - Method for modulating transendothelial migration of cells promoting inflammation, and related methods of measurement thereof - Google Patents
Method for modulating transendothelial migration of cells promoting inflammation, and related methods of measurement thereofInfo
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- AU6122894A AU6122894A AU61228/94A AU6122894A AU6122894A AU 6122894 A AU6122894 A AU 6122894A AU 61228/94 A AU61228/94 A AU 61228/94A AU 6122894 A AU6122894 A AU 6122894A AU 6122894 A AU6122894 A AU 6122894A
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Description
METHOD FOR MODULATING TRANSENDOTHELIAL
MIGRATION OF CELLS PROMOTING INFLAMMATION,
AND RELATED METHODS OF MEASUREMENT THEREOF
The research leading to the present invention was funded in part by Grant Nos. HL-46849 and AI24775 from the National Institutes of Health. The government may have certain rights in the invention.
TECHNICAL FIELD OF THE INVENTION
The present invention relates generally to the migration of leukocytes and like cells across the endothelium, and more particularly, to the modulation of such transmigration and its effect on inflammation.
BACKGROUND OF THE INVENTION
Inflammation is the response of vascularized tissues to infection or injury. Clinically it is accompanied by four classic signs: redness, heat, pain and swelling. Its course may be acute or chronic.
At the cellular level, inflammation involves the adhesion of leukocytes (white blood cells) to the endothelial wall of blood vessels and their infiltration into the surrounding tissues (Harlan, 1985). Acute inflammation is characterized by the adhesion and infiltration of polymorphonuclear leukocytes (PMN) (Harlan, 1987 and Malech and Gallin, 1987). PMN accumulation in the tissues begins between two and one half to four hours after an inflammatory stimulus and reaches its peak or ceases at about one to two days (Bevilacqua and Gimbrone, 1987). Chronic inflammation is characterized by the adhesion and infiltration of other leukocytes, especially monocytes and lymphocytes. Leukocytes leave the circulation by binding to the luminal surface of the vascular endothelium then migrating between tightly apposed endothelial cells into the body tissues (Marchesi, 1961; Marchesi and Florey, 1960). This process is constitutive in some situations. For example, monocytes exit the circulation at a low frequency to become tissue macrophages
(van Furth, 1986). Circulating lymphocytes enter lymph nodes by binding to and migrating across the specialized high endothelial venules (HEV) in lymphoid tissue (Lasky, 1992; Stoolman, 1989). This process involves recognition and binding of L-selectin to specialized, lymph node restricted counter-receptors on the HEV (Gallatin et al., 1983; Gallatin et al., 1986). During the process of inflammation leukocytes emigrate in large numbers into the inflammatory site, by recognizing and binding to cytokine induced cell adhesion molecules (CAMs) on the endothelium (Springer, 1990; Osborn, 1990; Pober and Cotran, 1990). A related process may occur during early atherogenesis when monocytes selectively emigrate into the subintima of affected arteries (Ross, 1986).
In normal inflammation, the infiltrating leukocytes phagocytize invading organisms or dead cells, and play a role in tissue repair and the immune response. However, in pathologic inflammation, infiltrating leukocytes can cause serious and sometimes lethal damage. Rheumatoid arthritis and atherosclerosis are examples of chronic inflammatory diseases in which mononuclear leukocytes infiltrate the tissues and cause damage (Hough and Sokoloff, 1985 and Ross, 1986). Multiple organ failure syndrome, adult respiratory distress syndrome (ARDS), and ischemic reperfusion injury are acute inflammations in which infiltrating PMNs cause the damage (Harlan, 1987 and Malech and Gallin, 1987). In multiple organ failure syndrome, which can occur after shock such as that associated with severe burns, PMN-mediated damage exacerbates the injury. In ARDS, the influx of leukocytes acutely and chronically contributes to interstitial inflammation that results in pulmonary failure. In ischemic reperfusion injury, which occurs when tissue cut off from the supply of blood is suddenly perfused with blood (for example after heart attack, stroke, or limb re-attachment), PMN adhesion causes serious tissue damage (Harlan, 1987).
Adult respiratory distress syndrome (ARDS) can result from both infectious and non-infectious causes; either results in similar pathology as a consequence of PMN emigration. In pneumococcal meningitis mortality can be directly correlated with
the amount of meningeal inflammation (McAllister et al., J. Infect. Dis. , 132:355- 360, 1975). Thus, a method of dampening inflammation during the course of therapy with an antibiotic would be advantageous in treating infections, particularly endotoxic shock and ARDS associated with infection.
The above are examples of some specific diseases and pathologies where leukocyte emigration into tissues underlies or is the cause of detrimental pathology. Previous studies have focused on leukocyte adhesion, and on the assumption that leukocyte adhesion is the first step in infiltration, investigators have until now focused attention on the mechanism of leukocyte binding to the endothelial cell surface. Studies show that binding is mediated by cell-surface molecules on both endothelial cells and leukocytes that act as receptor and ligand (Harlan et al. , 1987; Dana et al., 1986; and Bevilacqua et al., 1987a).
During the course of inflammation, certain inflammatory agents can act on the leukocytes, making them hyperadhesive for endothelium. Known inflammatory agents include leukotriene-B4 (LTB4), complement factor 5a (C5a), and formyl-methionyl-leucyl-phenylalanine (FMLP). These agents activate a group of proteins now known as J^ integrins. The β2 integrins are dimers of the CD 11 and CD18 proteins. One of the 1 integrins, CDlla/CD18 (also called LFAl) binds to a receptor on endothelial cells called ICAM1 (intercellular adhesion moleculel). Investigators have shown that monoclonal antibodies (mAbs) to β2 integrins inhibit PMN adhesion to endothelium in vitro (Harlan, et. al. 1985. Blood 66: 167), and these same or similar antibodies were subsequently demonstrated to block the same process in vivo (Arfors, et al. 1987. Blood 69:338.; also see Tedder et. al. 1988; and Todd, 1989). However, much less is known about the adhesion of monocytes and lymphocytes.
Other inflammatory agents act directly on endothelial cells to substantially augment leukocyte adhesion. These agents include the cytokines interleukin-1 (IL-1), and tumor necrosis factor (TNF), as well as the bacterial endotoxin, lipopolysaccharide
(LPS). For example, IL-1 has been shown to stimulate adhesion of PMN, monocytes, and the related cell lines HL-60 (PMN-like) and U937 (monocyte-like), to human endothelial cell monolayers. The action is both time-dependent and protein-synthesis dependent (Bevilacqua et al. , 1987a; Bevilacqua et al., 1987b; and Bevilacqua et al., 1985).
These cytokines may have one of several effects on endothelial cells vis a vis surface adhesion molecules. They may induce de novo synthesis of adhesion molecules, such as in the case of IL-1 and TNF, inducing expression of E-selectin and VCAMl (Osborn, 1990). They may also augment expression of pre-existing adhesion molecules such as the effect of these two cytokines on ICAM1. They may cause redistribution of pre-existing adhesion molecules from an intracellular compartment to the cell surface by degranulation, as in the case for the surface expression of P-selectin after stimulation of endothelial cells by thrombin or histamine.
The study of adhesion molecules has extended to the identification of a particular molecule known as platelet/endothelial cell adhesion molecule- 1 or PECAM- 1 (PECAM), first identified by Newman et al. (1990), Science, 247:1157-1264, and in PCT Publication No. WO 91/10683, by the Blood Center of Southeastern Wisconsin, Inc., published 25 July 1991. The sequence of PECAM is identified and recombinant human PECAM-1 (rhPECAM-1) is disclosed. The primary thrust of the disclosure, including reference to antibodies to PECAM- 1, relates to the activity of the discovered molecule as it relates to the potential binding of platelets to endothelial cell membranes. Thus, the use and activity of PECAM was disclosed from the perspective of platelet surface recognition and binding.
While the foregoing research dealt in gross with the concept of endothelial cell binding as a component of the recruitment and movement of leukocytes to the situs of an infection and potential inflammation, there has been no disclosure of the role of PECAM- 1 in the transmigration of leukocytes and like cells across the
endothelium. Prior to the present disclosure, the exact nature of such transmigration was largely a matter of speculation; and accordingly, consideration had not yet been given to the modulation of leukocyte migration across the endothelium.
The present inventor has studied cellular migration across the intercellular zone of the endothelium, and in Muller et al. (1989), J. Exp. Med. , 170:399-414, generated a murine monoclonal antibody against human endothelial cell membrane proteins that were present in greater concentrations at the junction between endothelial cells. At that time, however, there was no indication as to the exact role played by the plasmalemmal proteins that were identified, nor could there be any sense of the role that an antibody thereto might play.
Further work on PECAM identified potential adhesive mediators in vitro. For example, in Albelda et al. (1991), J. Cell Biol. , 114(5): 1059-1068, a further review was made of PECAM- 1 and indication presented that PECAM- 1 appears to mediate cell-cell adhesion. While Albelda et al. indicated the concentration of PECAM- 1 at intracellular junctions and the general conclusion that PECAM- 1 may be involved in cell-cell adhesion, the specific mechanism of such role remained unclear. That is, Albelda et al. speculated that PECAM-1 operated in a homophilic, calcium-dependent manner, and thus in distinction to other immunoglobulin superfamily molecules that have exhibited homophilic aggregation (Id. at 1066). As a result, the exact mechanism of operation of PECAM and, consequently, the role, if any, that it may play in endothelial cell adhesion remained unclear.
Schimmenti et al (1992), J. Cell. Phys. , 153:417-428, drew on the findings of Albelda et al. as to the role of PECAM-1 in cell-cell adhesion, and investigated the role of PECAM- 1 as a cell adhesion molecule in its effect on the migration of PECAM-transfected 3T3 cells with respect to each other (Id. at 418). The findings of Schimmenti et al. that PECAM- 1 inhibited the rate of sheet migration
were cumulative with those of Albelda et al. and did not extend beyond the interactions between endothelial cells.
Further clarification of the role played by PECAM was not achieved in Muller et al. (1992), J. Exp. Med. , 175:1401-1404, where experimentation using stably transfected L cells in a PECAM-dependent aggregation assay yielded the conclusion that PECAM-dependent aggregation appeared heterophilic, and affected by magnesium and calcium cation presence. Despite these studies on the adhesive activity of PECAM- 1, there was no further physiologic role for the molecule proposed.
Muller et al. (1992), J. Exp. Med. , 176:819-828, described the study of binding and transmigration of monocytes by means of an in vitro assay which primarily examined the activity of Mo transendothelial migration across unactivated endothelial monolayers and concluded that tight apical surface binding was the rate-limiting step for such migration, and that antibodies against the U2 integrin chain CD 18 would serve to block a substantial portion of this tight apical surface binding. The studies of Muller et al. focused primarily on monocyte migration and concluded that the adhesion involving the β2 integrins is the primary event that must precede monocyte TEM. As such, the authors concluded that the
CD11/CD18 complex and its receptors appeared to be responsible for the majority of adhesion.
Bogen et al., in "Association of Murine CD31 with transmigrating lymphocytes following antigenic stimulation", (1992) Am. J. Pathol , 141:843-854, discuss the preparation of a monoclonal antibody identified as 2H8, and the incubation of a supernatant containing this antibody with reactive murine lymph nodes. This antibody has been used by the present inventor in certain of the experiments herein. Using immunocytochemistry procedures, the authors sought to determine the effect of 2H8 and its antigen, CD31 in relation to transmigrating lymphocytes. The bulk of the data presented in Bogen et al. is directed to the demonstration of
the 2H8 antibody and its recognition of the murine form of CD31 (PECAM). Part of the data attempt to demonstrate that following immunization, the number of lymphocytes in draining lymph nodes that react with 2H8 increases. However, there is no demonstration that CD31 has any causal role in this process, or is anything other than a marker of a lymphocyte subset.
Bogen et al. in fact, offer evidence that teaches away from the present invention. For example, they provide immunoelectron microscopic data (See Bogen et al. , Figures 4 and 5) that are interpreted as demonstrating that lymphocytes express less PECAM as they come closer to migrating across endothelial cell boundaries. This is consistent with the attribution to PECAM of a negative regulatory role in transmigration, as it suggests that lymphocytes have to rid themselves of PECAM before transmigration can take place.
While Bogen et al. broadly suggest that PECAM is somehow involved in lymphocyte binding or transmigration across the lymph node and endothelium, the evidence in support of this suggestion is at best, circumstantial. There are no direct experiments seeking to determine whether the observation made with the monoclonal antibody is specific to PECAM, or whether such effects would occur with any other surface molecule. There is no direct evidence demonstrating that lymphocytes without PECAM cannot migrate, nor is there evidence that an anti- PECAM antibody or soluble recombinant PECAM will block binding or transmigration of the lymphocytes.
Similarly, other investigators have observed transendothelial migration with in vitro models employing human umbilical vein endothelial cells and human leukocytes, but have used these models to study adhesion molecules other than PECAM. These studies demonstrated that these adhesion molecules were important for apical rolling or adhesion in vitro, and were subsequently borne out by in vivo studies. Several examples include: Purified P-selectin adherent to glass was demonstrated to mediate a weak adhesion resulting in "rolling" of leukocytes
on that surface under conditions of flow, reminiscent of the rolling behavior of leukocytes on an endothelial surface at a site of inflammation (Lawrence et al. , 1991). Subsequently, P-selectin deficient mice were found to have a deficiency in rolling (Mayadas et al., 1993). Furthermore, anti-selectin reagents were demonstrated to block rolling in several other in vivo models (Ley et al., 1991; von Andrian et al. 1991). Antibodies against the leukocyte integrin CD11/CD18 complex were demonstrated to block tight apical adhesion of human leukocytes to human endothelial cells (Harlan, et al. 1985) in vitro. The same or similar antibodies also prevented this adhesion in vivo (Arfors et al. 1987). Furthermore, persons with a genetic deficiency in the CD 18 molecule have a phenotype that would be predicted from the in vitro experiments (Bowen et al, 1982; Beatty et al. 1984). Similarly, the findings of Hakkart et al. (1990), Smith et al. (1989), and Beesley et al. (1979) are cumulative with those discussed above. Although these authors studied transendothelial migration, the prior art did not contemplate the process of transendothelial migration as requiring separate adhesion molecules for the apical adhesion and the transmigration steps. Specifically, none of the data resulting from these or any of the studies discussed above even suggested, let alone perceived, a positive role for PECAM in intercellular migration of leukocytes, monocytes or lymphocytes, and consequently none sought to evaluate this concept. Thus, none of their methods would be adequate to study or quantitate TEM as presently understood by the advancement in knowledge disclosed in the present application.
The role of PECAM was first enunciated by the present applicant in parent United States Application Serial No. 08/003,258 filed January 12, 1993 and copending herewith, and in the corresponding publication by Muller et al. 1993 J. Exp. Med. 178:449-460. Recent characterization of the murine homologue of PECAM-1 afforded the opportunity to confirm the in vivo activity of this molecule that had been identified and embodied in the said parent Application. Specifically, and as described in greater detail hereinafter and in the corresponding in press manuscript by applicant and others (Bogen et. al. Monoclonal antibody to murine PECAM- 1
(CD31) blocks acute inflammation in vivo., J. Exp. Med. , 1994), experiments were performed utilizing an in vivo model of inflammation. Cloning of the murine homologue of PECAM- 1 (Xie and Muller, 1993) revealed a predicted amino acid sequence with 79% homology to human CD31. L cells transfected with murine PECAM- 1 cDNA aggregated in a PECAM- 1 -dependent manner, similar to human PECAM- 1 transfectants. A monoclonal antibody (mAb) raised in hamsters that recognizes the murine form of CD31 (Bogen et al., 1992) blocked this aggregation (Xie and Muller, 1993).
Against the backdrop of the studies that preceded the filing of applicant's parent application, the mechanism of transendothelial migration and its connection with other cellular events involving adhesion, as all of these events contribute to leukocyte migration and consequent inflammation, was unknown. A need therefore existed to further elucidate these events and from such discoveries to propose new and effective means for the control of inflammatory events and the concomitant measurement and surveillance of such activities including the development of effective drug protocols. It is to these purposes that the present invention is directed.
SUMMARY OF THE INVENTION
The present invention concerns a method and associated agents and compositions for modulating the transmigration of cells such as leukocytes into sites of acute and/or chronic inflammation during infectious or non-infectious conditions, the method comprising administering a therapeutic amount of an agent or composition selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-1), and active fragments thereof.
PECAM activity antagonists may comprise materials such as molecules, including small organic or inorganic molecules, polypeptides and fragments of same, that are
structurally unrelated to PECAM or anti-PECAM antibodies, but which work through, or have as a basis of their therapeutic action the ability to interfere with the function of PECAM as defined herein. Such antagonists could interact with PECAM wherever found, and may accordingly interact with the leukocyte or the endothelial cell.
A specific anti-PECAM antibody comprises the monoclonal antibody hec7 and particularly the antibody prepared from Hybridoma hec7.2 deposited with the American Type Culture Collection on December 23, 1992 and assigned ATCC Accession No. HB 11227, and/or active fragments thereof. Hybridoma hec7.2 is one of four identical subclones, hec7.1-hec7.4, that have been prepared by the inventor, and the invention is accordingly intended to extend in its scope to the use of any one of these subclones.
Additionally, this invention concerns a method and associated materials for inhibiting the ingress of leukocytes into tissues in patients suffering from either acute or chronic conditions which are associated with undesirable inflammation, by administration of a therapeutic amount of one of the agents of the present invention to a patient in need of such therapy. The preferred antibodies are as set forth above.
This invention also concerns a method and associated materials for eliminating or reducing inflammation in a patient wherein the patient is being administered an anti-infective agent for an infectious disease, which comprises the administration prior to, along with or after the anti-infective agent of a therapeutic amount of one of the present agents. Dosage forms combining an anti-infective agent and a therapeutic amount of the present agent are also described.
The present invention also extends to a method and associated assays for measuring and monitoring transendothelial migration for the purposes of diagnosing an alteration in PECAM function, the method comprising disposing a
quantity of a cellular agonist such as leukocytes, serum or plasma taken from a patient under such examination, along a monolayer of human endothelial cells grown from cultured HEC. The cells are maintained in contact with the monolayer for approximately 1 hour, which should be sufficient for normal transmigration to take place. The monolayers are then fixed, stained with AgNO3 and Wright Giemsa stain, and thereafter subjected to Normarski or Hoffman optics to spatially visualize the exact location of cells disposed within the intercellular EC junctions, after which the results are compared to a predetermined continuum of such measurements developed from subjects ranging in condition from normal to the presence of the condition or conditions under diagnosis or observation. The manner in which the cells are labeled may vary and includes radiolabeling of the leukocytes or by the use of colorimetric tracers. The method may also be automated as disclosed in greater detail herein. The invention also contemplates a receptor assay within its scope, where all manner of antigens or other agents recognized by the PECAM receptor of the HEC may be identified and their activity measured.
The invention further includes a method for detecting idiopathic or known stimuli on the basis of their ability to modulate PECAM function or expression. In particular, stimuli could be identified and detected by their ability to either stimulate or suppress TEM by leukocytes such as monocytes and polymorphonuclear cells. For example, in this method, samples of endothelial cells could be treated with/exposed to a number of known modifying agents such as anti-PECAM reagents, cytokines or the like, as a control, while parallel cellular samples could be treated with or exposed to an extract of material believed to contain such a stimulus. The respective samples could then be incubated, and thereafter, control leukocytes applied to the HEC monolayers and assayed for the presence and/or extent of TEM that occurs.
The assay of the invention provides a precise quantitation of leukocyte transmigration that can equally precisely predict the efficacy if any, of a drug
being evaluated as a potential modulator of inflammation or of the related pathological state. Accordingly, the invention extends to methods and associated assays and kits for diagnosing the likelihood of the development of alterations in PECAM function or expression, or the conditions that may cause them, or result from them, and for testing potential therapeutic agents such as drugs that may be useful as modulators of such inflammation or such conditions, and particularly, inflammation and conditions causing same wherein the deleterious condition or pathology results from the transendothelial migration of leukocytes, such as monocytes, neutrophils, lymphocytes, eosinophils and/or basophils.
It is thus an object of the present invention to provide a method of inhibiting the influx of leukocytes, including monocytes, neutrophils and lymphocytes into tissues during infectious or non-infectious conditions which comprises the administration of a therapeutic amount of one of the present agents to a patient in need of such therapy.
It is a further object of this invention to provide a method for measuring the migration of leukocytes across the endothelium by placement of a quantity of said leukocytes in contact with a cellular substrate replicating said endothelium, and applying to said substrate a quantity of the agents of the present invention, and thereafter measuring the extent and spatial location of said leukocytes migration through said substrate.
It is a still further object of this invention to diagnose the likelihood of an alteration in PECAM expression and/or function in the tissues and organs of patients caused by infectious or non-infectious conditions by performance of the method of measuring as aforesaid.
It is a yet further object of this invention to provide and use an assay for the identification of drugs and other therapeutic agents that may serve as modulators of inflammation in the tissues and organs of patients caused by infectious or non-
infectious conditions, which assay is based on the method of measuring as aforesaid.
It is a yet further object of this invention to treat inflammation in the tissues and organs of patients having an inflammation caused by infectious or non-infectious conditions by administration of a therapeutic amount of one of the present agents to a patient in need of such therapy.
It is a still further object of this invention to treat conditions that are attributable or exist at least in part to inadequate leukocyte migration by the administration of materials that function as promoters of transendothelial migration by the enhancement of PECAM activity.
Another object of the present invention is to afford a method of treating a patient afflicted with a condition presenting concomitant acute inflammation, such as endotoxic shock or adult respiratory distress syndrome, by administering a therapeutic amount of an anti-PECAM antibody or soluble recombinant PECAM, or active fragments thereof, whereby the amount of the influx of leukocytes into the affected tissue is eliminated or greatly reduced.
It is a still further object of this invention to eliminate or reduce the influx of leukocytes into the tissues or other organs of a patient, incident to the administration to the patient of an anti-infective agent for an infectious disease, by administering a therapeutic amount of one of the agents of the present invention prior to, concurrent with, or after, the administration of the anti-infective agent, thereby eliminating or reducing inflammation.
Other objects and advantages will become apparent from a consideration of the ensuing description which proceeds with reference to the following illustrative drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGURE 1 is a composite of photomicrographs showing that anti-PECAM antibody blocks transendothelial passage of monocytes. Peripheral blood mononuclear cells (PBMC) were incubated with hec7 mAb (a) or isotype-matched control mAb (b,c), washed free of unbound antibody and added to confluent HEC monolayers at 37°C. After one hour, monolayers were washed three times in 1 mM EGTA in HBSS to remove loosely adherent leukocytes, stained with silver nitrate and Wright-Giemsa, then examined by Nomarski interference optics, a) In the hec7 treated sample, most monocytes (Mo) remain tightly attached to the HEC surface in association with the intercellular junctions, which stain black with silver nitrate. These Mo are all in a focal plane at the apical surface of the HEC monolayer. By contrast, control Mo have all transmigrated. No monocytes are in focus in the plane of the apical surface of the monolayer (b), but they can all be visualized in various focal planes in the collagen gel below the monolayer (c). White arrows point to two such Mo in the corresponding photomicrographs (b) and (c). Bar = 200μm.
FIGURE 2 is a composite of scanning electron micrographs depicting that hec7 anti-PECAM mAb blocks migration of monocytes through the intercellular junction. PBMC were incubated for one hour in complete medium containing hec7 or control mAb at 20 μg/ml, then washed in EGTA, fixed and prepared for scanning electron microscopy. Control monolayers (a) were virtually devoid of apical monocytes, whereas monolayers exposed to hec7 treated PBMC were carpeted with Mo (b), most of which appeared to be bound over the intercellular junctions. At higher magnification in tilted specimens (c), many of the hec7- treated Mo could be seen to be extending pseudopods into the junction, although the major portion of the cell remained on the apical surface.
FIGURE 3 shows that anti-PECAM mAb hec7 significantly blocks transendothelial migration of Mo, whether pre-bound or added at the start of co-culture. PBMC
were incubated with hec7 (anti-PECAM) or control (anti-CD 14) mAb at 20 μg/ml for 30 min on ice (hatched bars), washed free of unbound antibody, and added to HEC monolayers. Alternatively, equal numbers of PBMC were added to HEC in the presence of the same concentrations of mAb (open bars). Incubation proceeded for 1 hr. at which time cells were processed as in Experimental Procedures, and the percentage of the cells remaining associated with the monolayer that had transmigrated was assessed. The data displayed is the mean ± standard deviation of six replicates for each experimental sample.
FIGURE 4 shows that hec7 is as effective as polyclonal anti-PECAM at blocking TEM. PBMC were added to HEC monolayers in the presence of 20 μg/ml hec7 or anti-CD14, or a 1:100 dilution of rabbit anti-PECAM serum or preimmune serum. Transmigration proceeded for 1 hour, and cells were processed as in Figure 3.
FIGURE 5 shows that hec7 Fab as well as IgG significantly blocks TEM at low concentrations. Equal numbers of PBMC were added to HEC monolayers and the transmigration assay was carried out for 1 hr at 37°C in medium M199 (M199) or M199 supplemented with either anti-CD14 mAb 3C10 at 30 μg/ml (3C10) or hec7 IgG or Fab at the indicated concentrations.
FIGURE 6 shows that the blockage of transmigration is specific for anti-PECAM mAb. Other mAb that bind to Mo surface antigens do not block TEM. Equal numbers of PBMC were added to HEC monolayers for 1 hr. in M199 containing the indicated mAb at 20μg/ml. Only hec7 significantly decreases transmigration of Mo.
FIGURES 7A and 7B show that hec7 does not decrease chemotaxis of Mo or PMN. PBMC or PMN were isolated and resuspended in M199 + 0.1 % HSA with or without hec7 IgG or Fab at 10 μg/ml (a) or hec7 Fab at the indicated concentrations (b). Leukocytes were then added to collagen gels impregnated with
a) M199 or formylnorleucyl-leucyl-phenylalanine (fNLLP), or b) normal culture medium or infranate from confluent HEC cultures. After incubation for 1 hr. at 37°C, chemotaxis was quantitated as described in Experimental Procedures.
FIGURE 8 is a graph illustrating that inhibition of TEM by hec7 is long-lasting and reversible. PBMC were added to HEC in culture medium containing hec7 (closed squares) or control mAb (closed circles) and the percent of transmigration assessed at time points up to 1.5 hours. At 1.5 hours, one set of hec7-treated cultures was washed three times in M199 and returned to culture in control culture medium (open squares). Transmigration was assessed in the usual manner in six replicate cultures for each sample.
FIGURE 9 shows the results of the control experiments wherein hec7 and heel Fab fragments remain concentrated in the intercellular junctions. Normal culture medium supplemented with Fab fragments of hec7 (anti-PECAM) or heel at 20 μg/ml was added to subconfluent HEC and replaced with successive feedings as the cells came to confluence over one week. The monolayers were washed extensively, then incubated successively in FITC-labeled rabbit anti-mouse IgG at 1:100 in culture medium (for hec7) or rabbit anti-mouse IgG 1:400 followed by rhodamine-conj ugated swine anti-rabbit IgG at 1: 100 dilution before fluorescence microscopy, a) Fluorescence image of HEC allowed to come to confluence in the presence of hec7 Fab demonstrates hec7 Fab fragments concentrated in the intercellular junction, b) Fluorescence image of HEC that came to confluence in the presence of heel Fab is very similar to the appearance of hec7-treated monolayers.
FIGURE 10 shows that transmigration can be blocked by anti-PECAM treatment of either Mo or HEC junctions. HEC monolayers were cultured under standard conditions (Control) or in the presence of hec7 or heel Fab as described in the legend to Figure 9. PBMC were resuspended in M199 containing control mAb 3C10 (open bars) or hec7 (black bars) both at 20 μg/ml, or recombinant soluble
PECAM (sPECAM, hatched bars) at 1 or 10 μg/ml, and transmigration proceeded for 1 hr. hec7 blocked TEM equivalently whether it was added to the Mo or the HEC, and there was no additional blockade when the two arms were combined (hec7 Fab/hec7). Soluble recombinant PECAM blocked as well as hec7, and again, was not additive with hec7 Fab bound to the HEC (hec7 Fab/sPECAM).
FIGURE 11 depicts the expression and isolation of recombinant soluble PECAM. COS-1 cells transfected with the soluble PECAM plasmid (T) or control plasmid (C) or HEC (E) were metabolically labeled, and culture supernates (s) or cell lysates (1) were subjected to immunoprecipitation with hec7, as described in
Methods. The fluorogram of the SDS-PAGE gel shows authentic PECAM present in the HEC lysates, but not the supernate. Transfected COS cells secrete a heavily-labeled protein of Mr « 90 kD, as expected; a smaller precursor band is detected in the detergent lysates of these cells. No protein is recognized in the control COS samples.
FIGURE 12 shows that hec7 blocks transmigration of Mo across cytokine activated HEC. HEC were activated by culturing in the presence of 10 ng/ml TNFα for 3 hours to induce VCAM-1 and upregulate ICAM-1. PBMC were added in the presence of hec7 or 3C10 mAb at 20 μg/ml, and transmigration was allowed to proceed for 1 hour.
FIGURE 13 shows that anti-PECAM reagents block transmigration of neutrophils. HEC monolayers were cultured in the presence of 10 ng/ml TNFα for 2 hours to induce the expression of L-selectin as well as VCAM-1 and to enhance ICAM-1 expression (Muller and Weigl, 1992). PMN were resuspended in warm M199 supplemented with 3C10 or hec7 at 20 μg/ml, preimmune serum or rabbit anti- PECAM serum at 1: 100, or recombinant soluble PECAM at 10 μg/ml, and added to the activated HEC monolayers for 1 hour.
FIGURE 14 is a series of graphs demonstrating that anti-PECAM mAb blocks leukocyte emigration. Mice were injected via lateral tail vein with the indicated dose of mAb, normal hamster IgG (NHIgG), or Dulbecco's PBS (DPBS) in 0.1 ml of DPBS. Four hours later all mice except the "No Thio" controls were injected intraperitoneally with 1 ml of thioglycoUate, as described in Methods. Peritoneal cells were harvested 20 hours after the thioglycoUate challenge. 2H8 - hamster anti-mouse PECAM (CD31); 5C6 - rat anti-mouse Mac-1 (CDllb). The graphs depict the mean and standard error of the mean for each group. (Three mice per group.) Data are expressed as the total numbers of recovered leukocytes or PMN, or as the concentrations of these cells in the peritoneal lavage fluid.
FIGURES 15 A and 15B each present two graphs showing that anti-PECAM- 1 mAb blocks leukocyte emigration in response to thioglycoUate injection. Peritoneal cells were harvested at 24 h from mice that had received 250 μg of the indicated mAb, normal hamster IgG (N. Ham. IgG), or DPBS (None), i.v., at time zero and thioglycoUate or DPBS i.p. at 4 h. Two experiments, representative of seven, are shown. AKR/J mice were used in experiment 1 presented in Figure 15A, while CD2FJ mice were used in experiment 2 (Figure 15B). Anti-PECAM-1 and anti-CD lib mAb block influx of PMN and mononuclear cells. Bars indicate mean ± s.e.m. for each group (five mice/group).
FIGURES 16A-16E demonstrate that mesenteric venules from anti-PECAM-1 treated mice show increased numbers of intraluminal leukocytes in apparent contact with the endothelium. Mice treated with anti-PECAM- 1 mAb as in Fig. 15 revealed a high proportion of leukocytes (predominantly PMN, arrowheads) in random sections in contact with the endothelium (Figure 16A), while mice treated with the nonblocking anti-CD18 mAb showed rare leukocytes on the endothelial surface (Figure 16B), despite the fact that many had transmigrated. Immunoperoxidase staining of frozen sections of mesenteric tissue demonstrated that the anti-PECAM- 1 mAb injected 24 hours previously was still localized to endothelial cells in vascular structures (arrow, Figure 16C), while anti-CD 18 mAb
(Figure 16D) stained only occasional stellate cells in the crypts (arrowheads) and lamina propria (not shown) of the bowel, but not blood vessels (arrow). In Figure 16E, the quantitation of over 400 leukocytes in 10 random venular profiles from each of 5 mice per group was graphically presented and revealed that only the anti-PECAM- 1 mAb group had significant numbers of leukocytes remaining in contact with the endothelium. Data are expressed as the percent of total intravascular leukocytes apparently in contact with the venular wall (open bars) and as the number of profiles counted (out of 10 per mouse) that bore > 1 adherent leukocyte. These data are converted to a percentage. The mean ± s.d. for groups of five mice is shown. (a,b) x 415, (c,d) x 260. Arrows in (a) and (b) point to endothelial nuclei. L = venular lumen, S = small bowel serosal surface, C = intestinal crypts.
FIGURES 17A and 17B illustrate the relative paucity of mononuclear cells in the subcapsular sinus of the draining mesenteric nodes in anti-PECAM-1 treated mice. Mesenteric lymph nodes from thioglycollate-treated mice were fixed and sectioned as described in Methods. Figure 17A shows the subcapsular sinus (asterisk, vertical lines define width of sinus) of a representative node from mice treated with Normal Hamster IgG. Note the large numbers of mononuclear cells within the sinus, indicating their recent arrival via afferent lymphatics. Figure 17B shows relatively few mononuclear cells in the same area from a mouse treated with 2H8 anti-PECAM- 1, correlating with the decreased total peritoneal cells recovered from peritoneal lavage. Both panels x 80.
DETAILED DESCRIPTION
In accordance with the present invention, certain terms appearing herein shall have the following meanings.
An "agonist" is a chemical agent, compound, antigen or like material that mimics or promotes certain activity of a cellular colony, antigen, antibody, or other
moiety, while an "antagonist" is an agent, compound, or like material that counteracts, inhibits or blocks such activity. The term "antagonist" specifically extends herein to those materials including compounds, agents other than antibodies to PECAM, molecules including small molecules, polypeptides, fragments of these, and the like, that are structurally unrelated to PECAM, that inhibit PECAM activity, and by so doing, exhibit therapeutic activity as is proposed for the agents of the present invention. Further examples of "antagonists" include, but are not limited to, fusion proteins wherein PECAM- 1 or portions thereof are covalently connected tin series to portions of immunoglobulins, complement regulatory proteins, or other molecules in order to confer on the PECAM antagonists additional biological properties such as longer biological halflife, increased affinity for their ligands, or the ability to be targeted to certain locations in the body.
The term "antagonists" also contemplates alternatively glycosylated forms of PECAM- 1, which differ on the basis of posttranslational modification of the core protein and may be so modified naturally or through appropriate biochemical manipulation in vitro. Such alternative glycoforms may differ in biological activity, biological halflife, tissue distribution, and function. Also contemplated as such antagonists are compounds of the glycosaminoglycan class and carbohydrates having similar structure. PECAM- 1 is known to have a glycosaminoglycan binding site in the second immunoglobulin loop. Furthermore, this site is at or close to the site on PECAM- 1 believed to be responsible for the function of PECAM-1 in transendothelial migration. (See Example 12, infra.) Therefore, it is contemplated that glycosaminoglycans, including as representative examples, but not limited to heparin and heparan sulfate, would bind to PECAM- 1 in this region and serve as antagonists of biological activity.
An "antibody" is any immunoglobulin, including antibodies and fragments thereof, that binds a specific epitope. The term encompasses, inter alia, polyclonal,
monoclonal, and chimeric antibodies, the last mentioned described in further detail in U.S. Patent Nos. 4,816,397 and 4,816,567.
An "antibody combining site" is that structural portion of an antibody molecule comprised of heavy and light chain variable and hypervariable regions that specifically binds antigen.
The phrase "monoclonal antibody" in its various grammatical forms refers to an antibody having only one species of antibody combining site capable of immunoreacting with a particular antigen. A monoclonal antibody thus typically displays a single binding affinity for any antigen with which it immunoreacts. A monoclonal antibody may also be engineered as a molecule having a plurality of antibody combining sites, each immunospecific for a different antigen; e.g., a bispecific (chimeric) monoclonal antibody.
"Fragments of monoclonal antibodies" means the conventional Fab and F(ab')2 fragments, as well as any chimeric or synthetic forms of antibody recognizing and binding to PECAM- 1, including humanized antibodies and fragments thereof. Fab and F(ab')2 fragments are prepared by the proteolytic reaction of papain and pepsin, respectively, on substantially intact antibody molecules by methods that are well-known. See for example, U.S. Patent No. 4,342,566 to Theofilopolous et al. Fab' antibody molecule portions are also well-known and are produced from F(ab')2 portions followed by reduction of the disulfide bonds linking the two heavy chain portions as with mercaptoethanol, and followed by alkylation of the resulting protein mercaptan with a reagent such as iodoacetamide.
"Fragments of PECAM- 1" means any portions of the molecule having the same amino acid sequence as intact PECAM-1 or being comprised of such portions. This would include, but is not limited to, soluble recombinant forms of PECAM- 1 such as the one described herein, polypeptides corresponding to isolated immunoglobulin domains of PECAM- 1 or parts thereof, and polypeptides
corresponding to immunoglobulin domains of PECAM- 1 or parts thereof combined with other such peptides derived from the sequence of PECAM- 1 linked in a linear or three dimensional manner that is different from their relationship in intact PECAM- 1. Also contemplated as "Fragments of PEC AM- 1" are any of the alternative glycoforms (as defined above) of the molecules aforementioned.
The term "active fragments" where appearing in the Specification and Claims, refers to fragments as generally defined herein that exhibit activity that is the same as the antibodies/antagonists to PECAM, or in the converse, exhibit the same activity as those promoters of PECAM activity, both as contemplated by the present invention. "Active fragments" likewise contemplates and includes within its scope soluble fragments of PECAM, soluble fragments of any antibodies thereto, or soluble fragments of antagonists thereof where appropriate.
"Leukocytes" wherever appearing herein including the Specification and Claims, refers to any and all classes of circulating white blood cells, including neutrophils (polymorphonuclear leukocytes (PMN)), monocytes, lymphocytes, eosinophils, and basophils, as well as malignant variants thereof that might occur in leukemia and lymphoma, in the absence of specific reference to cells of a particular class.
"Inflammation" refers to the response of viable vascularized tissue to injury and in particular to the influx of circulating leukocytes into such tissues, either in an acute or chronic manner. Examples of inflammation include, but are not limited to, foci of infection, autoimmune injury such as a rheumatic joint or diabetic Islet of Langerhans, myocardial infarction, graft rejection, atherosclerosis, wound healing, granulomatous reactions and idiopathic inflammatory conditions.
"PECAM" will be used interchangeably with "PECAM- 1".
"Transendothelial migration" will be used interchangeably with "transmigration" and the abbreviation "TEM" to refer to the process whereby leukocytes move
across the endothelial cell lining of blood vessels by squeezing between the apposed endothelial cells. This is a well-accepted stage in the process of inflammation.
The phrase "pharmaceutically acceptable" refers to molecular entities and compositions that are physiologically tolerable and do not typically produce an allergic or similar untoward reaction, such as gastric upset, dizziness and the like, when administered to a human.
The phrase "therapeutically effective amount" is used herein to mean an amount sufficient to cause by at least about 30 percent, more preferably by at least 50 percent, most preferably by at least 90 percent, a clinically significant change in the movement of leukocytes to a site of inflammation.
The present invention derives from investigations with a previously described human endothelial culture system to begin to dissect the process of leukocyte transmigration at the molecular level, as part of the further elucidation of the mechanism of inflammation. Several selectins and integrins are known to contribute to the binding of leukocytes to the endothelium. Underlying the present invention, a molecule known as platelet endothelial cell adhesion molecule or PECAM- 1, has been found to be crucial to the process of transmigration through intercellular junctions, and consequently, represents a significant focus at which to intervene therapeutically in inflammation, as well as other events characterized by leukocyte movement.
Accordingly, an aspect of the invention relates to the discovery of an agent comprising a material selected from the group consisting of antibodies to PECAM, including a monoclonal antibody to PECAM, recombinant soluble PECAM, antagonists of PECAM activity, and active fragments of any of these, that may be administered to modulate or control the transendothelial migration of cellular agonists of inflammation such as monocytes or PMN. As demonstrated herein,
the anti-PECAM antibody, for example, blocks leukocyte migration by from about 70 to about 90%. Moreover, the antibody blocks if it is used to pretreat the leukocytes or the endothelial junctions, suggesting that PECAM mediates homophilic adhesion between leukocytes and endothelial cells. If endothelium is activated with cytokines, anti-PECAM still blocks migration of both monocytes and neutrophils. Anti-PECAM does not block chemotaxis of either cell type in standard assays. As discussed in greater detail later on herein, light and electron microscopy reveal that leukocytes inhibited in transmigration remain tightly bound to the apical surface of the endothelial cell and precisely over the intercellular junction.
This invention relates in a first aspect to inhibiting the influx of cellular agonists of inflammation such as leukocytes, into tissues and organs as a result of infectious or non-infectious conditions by the administration of a therapeutic amount of an agent capable of modulating transendothelial migration of such cellular agonists, to a patient in need of such therapy. Cellular agonists contemplated by the present invention include monocytes (Mo), neutrophils (PMN), certain subtypes of T lymphocytes and a larger fraction of activated T lymphocytes, as well as certain malignant myeloid and lymphoid cell lines, all of which may express PECAM- 1.
As noted above, inflammation may result from any of a variety of infective agents, including gram-positive and gram-negative bacteria as well as viruses, parasites and fungi, or may arise from a non-infectious source such as trauma. For example, included infections are those which are susceptible to treatment with beta-lactam antibiotics, such as influenza, meningitis, pneumococcal infections, streptococcal infections, salmonella; certain bacillus, and the like. Particular infectious agents comprise Haemophilus influenzae B; N. meningitides b; Streptococcus pneumoniae; Escherichia coli; Staphylococcus epidermidus; Staphylococcus aureus; group B Streptococci; and Pseudomonas aeruginosa.
The inflamed tissues or organs which are the target of the present invention can likewise be any body tissue or organ susceptible to inflammation by the above- described agents. The present invention is accordingly adaptable to the treatment, for example, of the lung, central nervous system, kidney, joints, endocardium, eyes and ears.
Similarly, the present invention is also applicable to inflammation arising from causes other than infections, such as from artificial implants or allografts, ARDS precipitated by burns, surgery, toxic chemicals, fracture of bones, or other trauma.
In certain patients, a potential problem with the chronic use of a monoclonal antibody, such as hec7 may exist. This effect may be ameliorated or obviated by using active fragments of the monoclonal antibody so as to minimize the amount of foreign protein injected. Another alternative is to prepare a chimeric antibody in which the binding region of the antibody hec7 is combined with the constant regions of human immunoglobulin, or using soluble rhPECAM or active fragments thereof.
A further aspect of the present invention is that of reducing or eliminating the influx of leukocytes in iatrogenically induced inflammation such as may occur with the administration of an anti-infective agent. The method comprises the administration prior to, along with, or after the anti-infective agent of a therapeutic amount of one of the agents of the present invention to a patient in need of such therapy. As stated earlier, a preferred agent is soluble recombinant human PECAM-1.
For example, it has been suggested that leukocyte migration plays a role in the development of gastritis associated with the administration of non-steroidal antiinflammatory agents (NSAIDS). Thus, a potential therapy would comprise administration of an effective dose of anti-PECAM reagent to a patient dependent
on this class of anti-inflammatory compounds. As another example, due to the mechanism of their therapeutic activity, anti-infective agents, and particularly beta- lactam antibiotics, cause additional inflammation as a result of their therapeutic effect. Although such anti-infective agents sterilize a given infection, they cause release of toxic products, for example, the cell wall and/or endotoxin of the infecting agent. Such bacterial components initiate an inflammatory response, often most acute in the lung. It is this inflammation which contributes significantly to the lung damage that is the long-term consequence of many infections.
Reduction or elimination of inflammation in inflammatory diseases results in a diminution of the organ damage that often accompanies such disease states. Since the agents of the present invention possess the ability to block movement of leukocytes, they are uniquely suited to treat both non-infectious causes and infectious causes. Representative non-limiting instances or conditions where chronic inflammation may occur due to either infectious or non-infectious causes, and consequently, where the administration of the present agents may be beneficial, include the following: the sequelae of organ transplantation or tissue allograft; atherosclerosis (arteriosclerosis); diseases known or hypothesized to be autoimmune in nature, including, but not limited to: multiple sclerosis, systemic lupus erythematosus, rheumatoid arthritis, Sjogren's Syndrome, progressive systemic sclerosis (scleroderma), ankylosing spondylitis, polymyositis, dermatomyositis, pemphigus, pemphigoid, Type I diabetes mellitus, myasthenia gravis, Hashimoto's thyroiditis, Graves' disease, Goodpasture's disease, mixed connective tissue disease, sclerosing cholangitis, inflammatory bowel disease including Crohn's Disease (regional enteritis) and ulcerative colitis, pernicious anemia, and some of the inflammatory dermatoses; the interstitial pneumonias, including, but not limited to: usual interstitial pneumonitis, asbestosis, silicosis, berylliosis, talcosis, the various forms of coal pneumoconiosis, all other forms of pneumoconiosis, sarcoidosis (in the lung and in any other organ), desquamative interstitial pneumonia, lymphoid interstitial pneumonia, giant cell interstitial
pneumonia, cellular interstitial pneumonia, extrinsic allergic alveolitis, Wegener's granulomatosis and related forms of angiitis; arteritis (including, but not limited to temporal arteritis and polyarteritis nodosa); inflammatory dermatoses not presumed to be autoimmune; chronic active hepatitis; and delayed-type hypersensitivity reactions (e.g. poison ivy dermatitis).
Corresponding conditions presenting instances of acute inflammation are also capable of treatment by the therapeutic methods of the present invention. The following non-limiting examples are included: pneumonia or other respiratory tract inflammation due to any cause; Adult Respiratory Distress Syndrome (ARDS) from any etiology; encephalitis, with inflammatory edema; immediate hypersensitivity reactions including, but not limited to, asthma, hayfever, cutaneous allergies, acute anaphylaxis; arteritides including, but not limited to temporal arteritis and polyarteritis nodosa; diseases involving acute deposition of immune complexes, including, but not limited to, rheumatic fever, post-infectious (e.g., post-Streptococcal) glomerulonephritis, acute exacerbations of Systemic Lupus Erythematosus; pyelonephritis; cellulitis; cystitis; acute cholecystitis, conditions producing transient ischemia anywhere along the gastrointestinal tract, bladder, heart, or other organ, especially those prone to rupture; allograft rejection in the acute time period following allogeneic organ or tissue transplantation.
Due to the ability of the present agents to reduce or eliminate the iatrogenic influx of leukocytes into organs in a infectious disease caused by the administration of an anti-infective agent, the agents can be combined in a single unit dosage form with the anti-infective agent for convenience of administration. Such dosage form is most preferably an intravenous dosage form since most anti-infective agents, particularly the beta-lactam antibiotics, are available in a suitable chemical form for parenteral administration, such as via the intravenous route. This is also a viable route of administration for the present agents. Typically, the anti-infective agent and the agent can be combined in a single ampoule solution. Where this is not possible, the anti-infective agent and the agent can be packaged separately and
mixed just prior to injection. Administration can likewise be via a mixture with any standard intravenous solution, i.e., normal saline. Likewise, the present agents may be self-administered on a regulated basis as a form of chronic therapy, and preferably via local or oral administration.
The amount of anti-infective agent in the dosage form is dependent upon the particular anti-infective agent being utilized and the particular infection being treated. The amount of the present agent utilized in a dosage form can range from about 1 to about 1,000 mg, with 10-100 mg per dosage unit being highly preferred. Dosages can be administered one to four times daily, with continued therapy for as long as the infection persists. The method of administering the dosage unit may, of course, be varied by the treating physician due to patient condition and the severity of the infectious disease being treated.
An additional therapeutic protocol in accordance with the present invention is predicated on the activation and mobilization of leukocytes, monocytes and lymphocytes to treat infection or a like deleterious condition, in instances where the host exhibits immune incapacity or dysfunction related to leukocyte inaction. Since the invention demonstrates that PECAM is necessary for transendothelial migration, agents that augment or enhance PECAM function or activity may be able to ameliorate these conditions. Accordingly, appropriate compositions containing PECAM or like promoters of transendothelial migration, or agents or drugs that augment or enhance PECAM expression, function, or activity could be administered to the patient or host in need of such treatment. Promoters of PECAM would include leukocytes that have functional PECAM expressed or otherwise disposed on their surfaces in greater amounts. Delivery of additional PECAM could be by promotion of increased expression via increasing translation or transcription, by delivery of PECAM to the leukocyte surface via liposome encapsulation, or by like alternative measures all contemplated within the scope of the invention. The method of administration would include those known
procedures, including parenteral techniques as are conventionally used by skilled medical personnel. Dosages and protocol of administration would likewise vary.
Representative conditions that would benefit from this protocol are as follows: chronic inflammatory conditions, (especially in an immunocompromised host), such as tuberculosis; any acute and/or chronic inflammatory process in a person suffering from AIDS or immunocompromised due to chemotherapy, radiotherapy to the bone marrow, leukemia, or congenital immune system dysfunction; wound healing in skin, especially of stasis ulcers in a diabetic or person suffering from limb ischemia, healing of gastric and duodenal peptic ulcers; healing of a wound, ulceration, or any lesion characterized by destruction of the parenchyma and/or underlying stroma of any organ or tissue in which normal healing must proceed through granulation tissue, necessitating the influx of chronic inflammatory cells. Also included are acute conditions due to infectious organisms or non-infectious causes, especially in an immunocompromised host (e.g. a patient on chronic high dose steroids, following cancer chemotherapy, suffering from AIDS or leukemia), such as, meningitis, encephalitis, uveitis, cellulitis, pneumonitis, pleuritis, pneumonia, pericarditis, myocarditis, endocarditis, sinusitis, pharyngitis, retinitis, otitis, esophagitis, gastritis, acute infectious enteritis, ascending cholangitis, hepatitis, pyelonephritis, cystitis, urethritis, stasis ulcers and stasis dermatitis, abscess formation in any tissue due to infections, including those arising from pneumococci, Haemophilus influenzae B, N. meningitides b and Escherichia coli, group B Streptococcus, Staphylococci and Pseudomonas.
As discussed earlier, the agents capable of modulating transendothelial leukocyte migration, their analogs, binding partner(s) or other ligands or agents exhibiting either mimicry or antagonism to the agents, may be prepared in pharmaceutical compositions, with a suitable carrier and at a strength effective for administration by various means to a patient having a tissue infection or other pathological derangement such as immune system dysfunction involving leukocytes, including neutrophils, monocytes and lymphocytes, for the treatment thereof. A variety of
administrative techniques may be utilized, among them topical applications as in ointments or on surgical and other topical appliances such as, surgical sponges, bandages, gauze pads, and the like, as well as orally active formulations. Also, such compositions may be administered by parenteral techniques such as subcutaneous, intravenous and intraperitoneal injections, including delivery in an irrigation fluid used to wash body wound areas, catheterizations and the like. Average quantities of the agents may vary and in particular should be based upon the recommendations and prescription of a qualified physician or veterinarian.
Representative therapeutic compositions useful in practicing the therapeutic methods of this invention may include, in admixture, a pharmaceutically acceptable excipient (carrier) and one or more of a transendothelial migration modulator (agent)/modulator (agent) antagonist, or analog thereof, as described herein as an active ingredient. Particular therapeutic compositions may further include an effective amount of the agent/agent antagonist or analog thereof, and one or more of the following active ingredients: an antibiotic, a steroid. Exemplary formulations are presented in Example 12, later on herein.
As stated earlier, the invention further includes a method for detecting idiopathic or known stimuli on the basis of their ability to modulate transendothelial migration via PECAM. In particular, invasive stimuli could be identified and detected by their ability to either stimulate or suppress TEM by cellular agonists such as leukocytes. Accordingly, these agonists, one of the agents of the invention, or binding partners thereto, could be utilized in a variety of diagnostic protocols. The noted materials may be labeled with a detectible label and employed in an assay such as the transmigration assay of the present invention, for example, to monitor or determine patient status, or to investigate and evaluate possible new drugs.
Exemplary diagnostic protocols are set forth below by way of illustration and not limitation. These protocols extend from the direct examination of a particular
sample to the preparation and comparison of plural samples and corresponding controls and the correlation of the results as between the former and the latter, respectively, and in direct comparison with each other. In this way, direct diagnosis, as well as monitoring and drug discovery are contemplated and covered.
A first protocol relates broadly to a method for measuring transendothelial migration of leukocytes, comprising:
A. providing a test substrate from a colony of human endothelial ceils;
B. obtaining a biological sample from said mammal believed to contain a quantity of said leukocytes;
C. incubating the biological sample of Step B. with said test substrate for a period of time sufficient for the transmigration of said leukocytes to occur; and
D. examining the incubated material of Step C. by counting the position and number of said leukocytes adhering to the intercellular regions in said test substrate.
A second protocol covers a method for measuring transendothelial migration in a mammal and the role of PECAM therein, and comprises: A. providing a test substrate from a colony of human endothelial cells;
B. obtaining a biological sample from said mammal containing leukocytes;
C. incubating an aliquot portion of the biological sample of Step B. with said test substrate for a period of time sufficient for the transmigration of said leukocytes to occur in the absence of PECAM antagonists;
D. preparing a control by incubating a further aliquot portion of the biological sample of Step B. with said test substrate and with an agent capable of modulating the transendothelial migration of leukocytes, said agent selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-l), agonists of PECAM activity, and active fragments thereof, for a period of time equal to that of Step C; and
E. measuring said PECAM function in terms of transendothelial migration of said leukocytes by examining the incubated material of Step C. and comparing the results to the incubated material of Step D.
A third protocol extends to a method for detecting circulating modulators of PECAM function in a mammal, and comprises:
A. providing a test substrate from a colony of human endothelial cells;
B. obtaining a biological sample from said mammal selected from the group consisting of plasma, serum and other bodily fluids; C. preparing at least one test incubation by incubating a quantity of leukocytes from the same or another mammal, with and without an aliquot portion of the biological sample of Step B. and with said test substrate for a period of time sufficient for the transmigration of said leukocytes to occur in the absence of PECAM antagonists; D. preparing at least one control by incubating a further aliquot portion of leukocytes from the test mammal or another mammal with said test substrate and with and/or without an agent capable of modulating the transendothelial migration of leukocytes, said agent selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-l), agonists of PECAM activity, and active fragments thereof, for a period of time equal to that of Step C; and
E. measuring said PECAM function in terms of transendothelial migration of said leukocytes by examining the incubated material of Steps C. and D., comparing between the Step C. test incubations, and between the Step D. controls, and comparing the said test incubations to the said controls.
For example, well known immunological procedures that are useful herein may utilize either the cellular agonists, the present agents or their respective antagonists or other binding partners labeled with a detectable label. In each instance, the cellular agonist or TEM modulator forms a complex with a binding partner and one member of the complex is labeled with a detectable label. The fact that a
complex has formed and, if desired, the amount thereof, can be determined by known methods applicable to the detection of labels.
The labels most commonly employed for these studies are radioactive elements, enzymes, chemicals which fluoresce when exposed to ultraviolet light, and others.
A number of fluorescent materials are known and can be utilized as labels. These include, for example, fluorescein, rhodamine and auramine. An example of a conjugate would be fluorescent anti-PECAM antibody, prepared in goats and conjugated with fluorescein through an isothiocyanate.
The cellular agonist or TEM modulator or its binding partner(s) can also be labeled with a radioactive element or with an enzyme. The radioactive label can be detected by any of the currently available counting procedures. The preferred isotope may be selected from Η, 14C, 32P, 35S, 36C1, 51Cr, 57Co, 58Co, 59Fe, 90Y, *Tc, In, 125I, 131I, and ,86Re.
Enzyme labels are likewise useful, and can be detected by any of the presently utilized colorimetric, spectrophotometric, fluorospectrophotometric, amperometric or gasometric techniques. The enzyme is conjugated to the selected particle by reaction with bridging molecules such as carbodiimides, diisocyanates, glutaraldehyde and the like. Many enzymes which can be used in these procedures are known and can be utilized. The preferred are peroxidase, β-glucuronidase, β-D-glucosidase, β-D-galactosidase, urease, glucose oxidase plus peroxidase and alkaline phosphatase. U.S. Patent Nos. 3,654,090; 3,850,752; and 4,016,043 are referred to by way of example for their disclosure of alternate labeling material and methods.
A particular assay system developed and utilized in accordance with the present invention, is known as a receptor assay. In a receptor assay, the material to be assayed is appropriately labeled and then certain cellular or solid phase
biochemical targets are incubated with a quantity of both the labeled and unlabeled material after which binding studies are conducted to determine the extent to which the labeled material binds specifically to the cell receptors. In this way, differences in affinity between materials can be ascertained. In a commonly used variation, a material to which the molecule in the test sample to be detected and assayed binds is attached to a solid surface, the test sample applied, and after appropriate incubation and washing, the amount of that molecule bound is determined by adding a labeled detector and quantitating with reference to a known standard.
Accordingly, a purified quantity of either a cellular agonist such as leukocytes or a TEM modulator may be radiolabeled, after which binding studies would be carried out. Solutions would then be prepared that contain various quantities of labeled and unlabeled material, whether cellular agonist or TEM modulator, and HEC cell samples would then be inoculated and thereafter incubated. The resulting cell monolayers are then washed, soiubiiized and then counted in a gamma counter for a length of time sufficient to yield a standard error of <5%. These data are then subjected to Scatchard analysis after which observations and conclusions regarding material activity can be drawn. While the foregoing is exemplary, it illustrates the manner in which a receptor assay may be performed and utilized, in the instance where the cellular binding ability of the assayed material may serve as a distinguishing characteristic.
In a further embodiment of this invention, commercial test kits suitable for use by a medical specialist may be prepared to measure the extent of transendothelial leukocyte migration in a particular mammalian host. In accordance with the testing techniques discussed above, one class of such kits will contain at least the labeled TEM modulator or respective binding partner, for instance an antagonist specific thereto, a predetermined standard with which to calibrate and evaluate the response, and directions, of course, depending upon the method selected. The kits may also contain peripheral reagents such as buffers, stabilizers, instructions for
the labeling of the patient's leukocytes, etc. Also, and as stated earlier herein, the methods described herein may be used to test potential drugs by their ability to interact with the cellular agonists and/or the TEM modulators, to exert an effect on transendothelial migration and concomitant inflammation.
In a further embodiment of the invention, the transendothelial migration of certain cells may be measured and monitored, to determine the likelihood that a patient may respond to PECAM therapy, or to test potential drugs useful to control inflammation by modulating TEM. A particular method for the measurement of TEM is disclosed herein that offers a precise quantitation that is achieved by the visual technique described above and illustrated in the Examples appearing later on herein. The illustrated assay is an in vitro assay of transmigration of human leukocytes across human endothelial cell monolayers, that has been developed to reflect many of the conditions present in vivo. The endothelial cells in this model are phenotypically similar to endothelial cells lining blood vessels in the body, and express PECAM-1 at the junctions between them under resting as well as cytokine-activated conditions.
A corresponding assay of lymphocyte transmigration across HEC may be performed employing an appropriate lymphocyte cellular model. In particular, activated T cells, and cells such taken from myeloid and lymphoid tumor cell lines (see Ohto et al., 1985; Goyert et al., 1986) are known to express PECAM on their surfaces, and would serve in this capacity.
Quantitation of transmigration may be performed using Hoffman Modulation
Contrast Optics, directly visualizing the individual HEC monolayers and counting the percentage of leukocytes on top of, stuck within, or transmigrated through the HEC monolayer. At the end of the assay, the monolayers are washed with EGTA, then DPBS, then stained with silver nitrate to outline of the HEC junctions. This makes it even easier to define the plane of HEC monolayer and to discern which leukocytes are trapped between HEC. The monolayer is then fixed
in 10% neutral buffered formalin or 2% glutaraldehyde in cacodylate buffer and stained with Wright-Giemsa stain. The Hoffman optics make it possible to discern precisely the spatial orientation of the leukocytes with respect to the HEC monolayer. Leukocytes above and below the HEC monolayer (i.e. entering into the collagen gel on top of which the HEC monolayer is grown) are distinguished, for example, by any of three procedures described in the Experimental Methods, and are counted in several random fields (for larger culture dishes) or in the central field in each well of a 96- well culture plate (for reproducibility). Data are expressed as the percentage of leukocytes below the HEC monolayer.
The above assay of the present invention is capable of automated performance. For example, the IgG coated sheep erythrocytes (E-IgG) described above in the resetting assay, could be labeled with a fluorescent tag (e.g. Carboxyfluorescein succinimidyl ester (CFSE)) and fluorescence retained by the monolayer is proportional to the number of E-IgG rosetted, i.e., the number of apical leukocytes remaining. Fluorescence is read automatically on all the wells in the culture plate by means of a standard fluorescence plate reader (Millipore Cytofluor 2300).
Alternately, the E-IgG are prelabeled with a radioactive tag such as 51Cr or "'Indium oxyquinoline (Muller and Weigl, 1992) and the retained radioactivity is proportional to the number of E-IgG rosetted, i.e. , the number of apical leukocytes remaining. Radioactivity is assessed by means of a gamma counter, either by removing the cultures physically into tubes for counts or using a gamma counter adapted for directly reading from 96- well tissue culture plates.
In a further alternate protocol, the culture is lysed hypotonically or in nonionic detergent, and retained E-IgG are quantitated by assay of erythrocyte-specific markers, such as hemoglobin by a direct chemical measurement or Band 3 by an immunoassay.
Apical leukocytes may be assessed by their ability to bind non-permanent markers other than E-IgG. These could include, but are not limited to: a) polystyrene latex beads tagged with a fluorescent or radioactive label and conjugated to antibodies or ligands that will specifically bind to one or more of the leukocyte classes-monocytes, neutrophils, lymphocytes. b) magnetic microspheres tagged with a fluorescent or radioactive label and conjugated to antibodies or ligands that will specifically bind to one or more of the leukocyte classes-monocytes, neutrophils, lymphocytes. c) phospholipid vesicles with a fluorescent or radioactive label incorporated and bearing on their surfaces antibodies or ligands that will specifically bind to one or more of the leukocyte classes, e.g., monocytes, granulocytes, lymphocytes, or subsets thereof.
The antibodies or ligands that could be used in the assay include, but are not limited to: anti-CD45 for all classes of leukocytes, anti-CD 14 for monocytes or PMN, anti-CD3 for T lymphocytes, anti-CD4 for CD4+ T cells, anti-CD8 for CD8+ T cells, anti-CD16 for monocytes, PMN, and natural killer cells, anti- human IgG for B cells, etc. The automated assay is carried out as described above for fluorescently or radioactively labeled E-IgG.
The following non-limiting examples illustrate the methods and preparations of the present invention. The materials and experimental methods are presented first. Naturally, the specific materials and techniques set forth hereinafter are exemplary only and may vary, so that the following is presented as illustrative but not restrictive of the present invention.
EXPERIMENTAL PROCEDURES (MATERIALS AND METHODS^
FOR EXAMPLES 1-8
Cells Human umbilical vein endothelial cells (HEC) were isolated and cultured on collagen gels as described (Muller et al., 1989). In some experiments HEC were
activated by culturing in the presence of recombinant human TNFα (10 μg/ml in culture medium) for the times indicated in the figure legends. TNFα induces the expression of endothelial cell adhesion molecules like E-selectin (Bevilacqua et al.1987) and VCAM-1 (Osborn et al.1989), which are not otherwise expressed by HEC in this culture system (Muller and Weigl, 1992). Peripheral blood mononuclear cells (PBMC) and polymorphonuclear leukocytes (PMN) were isolated from venous blood freshly drawn from healthy volunteers as described (Muller and Weigl, 1992).
Antibodies
Mouse monoclonal antibody (mAb) hec7 an IgG2a that binds to human PECAM- 1 was raised as described (Muller et al., 1989). Hybridoma hec7 was deposited with the American Type Culture Collection, Rockville, MD, on December 23, 1992 and has been assigned ATCC Accession No. HB 11227. As mentioned earlier, Hybridoma hec7.2, one of four identical viable subclones designated hec7.1 - hec7.4, was specifically deposited. MAb heel is an IgG2a raised in this laboratory from the same original fusion. It recognizes a junctionally restricted HEC integral membrane protein distinct from PECAM. Clones secreting both mAb were adapted to growth in serum-free medium (Nutridoma NS, Boehringer Mannheim Biochemicals, Indianapolis, IN) and IgG selectively precipitated by ammonium sulfate. IgG was redissolved, dialyzed in PBS, and sterilized by membrane filtration. Fab and F(ab')2 fragments were produced by incubating with immobilized papain and pepsin, respectively (Pierce Chemical Co., Rockford, IL). Undigested antibody and Fc fragments were removed by passage over Protein A- Sepharose (Pharmacia, Piscataway, NJ). SDS-polyacrylamide gel electrophoresis (SDS-PAGE) performed under non-reducing conditions verified that the fragments were properly cut. SDS-PAGE of overloaded samples demonstrated that all IgG and active fragment samples were pure; no extraneous bands were present on Coomassie blue stain.
Other mAb used in this study, their antigens, and sources were: IB4 and 3C10, anti-CD18 and CD14, respectively, from Dr. S.D. Wright, The Rockefeller University; W6/32, anti-Class I MHC, from American Type Culture Collection; 9.3C9 (=9.3CF10), anti-MHC Class II (HLA-DR and HLA-DQ) raised in this Department (ATCC No. HB 180); LB-2, anti-ICAM-1, from Dr. Edward Clark, University of Washington, Seattle, and 3G8, anti-Fc7RIII, from Medarex, W. Lebanon, NH. Rabbit anti-PECAM serum and preimmune serum were generated against PECAM- 1 purified from platelets (Albelda et al., 1991).
Recombinant soluble PECAM- 1
A cDNA encoding a form of PECAM containing the signal sequence and 5 1/2 of the 6 extracellular immunoglobulin loops was constructed from an existing full- length PECAM cDNA clone in the vector pcDM8 (Muller et al., 1992). This plasmid was cut with restriction enzymes Hindlll and Nhel, the 1850 bp fragment encoding the external domain of PECAM was purified on an agarose gel, and ligated to a gel-purified 4056 bp fragment of pcDMδ previously digested with Hindlll and Xbal representing the entire vector minus the multiple cloning domain from the first Xbal site to the Hindlll site. Since Xbal and Nhel general the same sticky ends, successfully annealed plasmids contain the fragment of DNA encoding truncated PECAM inserted in pcDMδ in the proper orientation for expression. Unique BamHl sites in both PECAM and pcDM8 allowed verification of this by restriction digest of transformed E. coli MC 1061/p3. Purified plasmid was obtained from these cultures on CsCl gradients by standard methods (Sambrook et al., 1989).
COS-1 cells (American Type Culture Collection) were transiently transfected by electroporation of 107 cells in 0.5 ml Dulbecco's Modified Eagle's Medium (DMEM) with 20μg plasmid in a gene pulser (Bio-Rad Laboratories, Richmond, CA) at 240mV, 960 μF, 4 mm path length cuvettes. The electroporated cells were plated in DMEM + 10% FCS overnight, passed by trypsinization the next day to help remove dead cells and replated in DMEM + 10% FCS. Expression of
soluble PECAM was checked by immunoprecipitation from conditioned medium and immunofiuorescence of COS cells on day 3.
Purification of recombinant soluble PECAM An immunoaffinity matrix was made by covalently coupling hec7 mAb to Affi-gel 10 (Bio-Rad Laboratories) at a concentration of 3.8 mg/ml, according to the manufacturer's directions. Conditioned medium was collected on day 5 from COS-1 cells transiently transfected with the construct described above, centrifuged free of cells, and passed over a 3 ml column of hec7-Affi-gel at 0.3 ml/min. The column was washed with 10 columns of SA buffer, 8 volumes of detergent buffer, and 20 volumes of SA buffer (Muller and Gimbrone, 1986).
Soluble PECAM was eluted in 5 ml of 0.05 M diethylamine pH 11.5, neutralized quickly with 1 M Tris pH 8, and dialyzed overnight against PBS. The dialysate was concentrated using a Centricon® 30 microconcentrator (Amicon Division, Beverly, MA). Purity was assessed by SDS-PAGE followed by Coomassie blue or silver nitrate stain. Protein concentration was determined using the BCA assay (Pierce Chemicals). Forty micrograms of recombinant soluble PECAM were purified from approximately 350 ml of conditioned medium.
Metabolic labeling, immunoprecipitation. and SDS-PAGE
These procedures were performed as previously described (Muller et al., 1989).
Any variations unique to these experiments are described in the Figure legends.
Transendothelial migration assay
A significant variation of the recently published method (Muller and Weigl, 1992) was used. Briefly, purified PBMC or PMN were resuspended to 2 or lxlOVml, respectively, in warm medium 199 (M199) or complete culture medium (20% normal human serum in M199) and allowed to settle on confluent monolayers of HEC grown in 96-well trays on hydrated collagen gels. In most experiments anti- PECAM mAb, other anti-PECAM reagents, or control mAb were also added at
the same time. Transendothelial migration was allowed to proceed at 37°C, usually for one hour. The original procedure called for inverted centrifugation of the culture in the presence of EGTA to separate transmigrated cells from those merely bound to the apical HEC surface. In order to preserve maximum optical resolution, this step was replaced by three manual washes in 1 mM EGTA, followed by three manual washes in DPBS (Dulbecco's PBS with Ca++ and Mg++). In some experiments the monolayers were then stained with AgNO3 to visualize the intercellular junctions (Muller et al., 1989). The monolayers and remaining leukocytes were then fixed in 2.5% glutaraldehyde in 0.1M sodium cacodylate buffer, pH 7.4. Prior to quantitative analysis the monolayers were stained with Wright-Giemsa.
Three separate methods were used to quantitate transendothelial migration. All three gave similar results when used to analyze the same experiment. The method described first gave somewhat better resolution; hence, most of the quantitative data presented herein are from experiments where this method was used. 1) IgG coated sheep erythrocytes in cold M199 were added to the transmigration assay at the end of the experiment, just before the glutaraldehyde fixation step, along with PMA (or fMLP for neutrophils) to fully activate leukocyte FC receptors (Wright, 1986). After incubation for 30 min at 4°C, nonbound erythrocytes were washed off, the culture was fixed in glutaraldehyde, and the entire culture system consisting of the HEC monolayer, collagen gel, and all associated leukocytes was transferred intact to a glass slide, and examined at 500X by Nomarski optics. Leukocytes were scored as apical if they were in the focal plane above the HEC monolayer and bound (rosetted) more than 3 Ig coated sheep red cells. 2) Each well of the 96-well tray was centered in turn over the low power objective of an inverted microscope, and the central field in each well was subsequently examined at 400X using Hoffman modulation contrast optics (Hoffman, 1977) and the silver stained HEC junctions to sharply define the apical surface of the monolayer. All leukocytes in focus on the apical surface were scored as non-transmigrated. This included those with a small pseudopod extending into the junction. Those
leukocytes in focus below the plane of the monolayer were scored as transmigrated. 3) The entire culture system was removed from the well, as for No. 1 above, and random fields examined at 500X under Nomarski interference optics, scoring apical and transmigrated leukocytes as for No. 2 above. Data are expressed as percent of total cells viewed that had transmigrated; in most samples there were roughly 100 total leukocytes viewed in each field. The mean and standard deviation of at least six replicate cultures are presented. The Figures show representative experiments; all experiments were repeated at least three and usually more than six times with similar results.
Quantitation of Scanning Electron Micrographs
Following the transmigration assay carried out as described above, cultures were fixed in 2.5% EM grade glutaraldehyde in 0.1 M sodium cacodylate buffer, pH=7.4 (Polysciences, Warrington, PA). The fixed HEC monolayer, associated leukocytes and collagen gel were physically removed from the 96-well tray and processed for scanning EM by critical point drying and gold coating as described (Phillips and Bourinbaiar, 1992). Specimens were examined on an ETEC Scanning Electron Microscope. For quantitative evaluation, each specimen was centered in the beam at low power (ca. 20X magnification), then monocytes were counted in at least ten random, non-overlapping 1,000X fields (each field approximately 10,323 μm2) at or near the center. Apical monocytes were observed as large, mostly spread cells with at least one pseudopod. Cells resembling lymphocytes were seen only rarely on the apical surface in the one hour and three hour specimens. At five hours apically adherent lymphocytes were observed at the same density (approximately two per field) in control and anti-PECAM treated specimens, and were not counted. Data are expressed as mean ± standard deviation number of apical monocytes per 1000X field.
Chemotaxis assay Hydrated collagen gels identical to those used for culture were impregnated with chemoattractant by incubation with 200 μl of chemoattractant solution overnight at
37° in the tissue culture incubator. Control experiments using fluorescently labeled IgG demonstrated that equilibration occurred within six hours (t -45 min) for both accumulation within and elution from the gel. Such gels were washed three times with M199. Leukocytes resuspended to lOVml in ml99 plus 0.1% human serum albumin were added to the wells (100 μl/well), and migration into the gels was allowed to proceed for one hour. Cells that had not entered the gel were removed by inverted centrifugation in EGTA (Muller and Weigl, 1992). The collapsed gels were stained with Wright-Giemsa and leukocytes trapped within it were counted in the central 200X field of each well. Data are presented as the mean number of leukocytes ± standard deviation of six replicate wells.
EXAMPLE 1
Anti-PECAM antibodies bound to monocytes block transendothelial migration. These studies employed a slight variation of the monocyte-selective in vitro transmigration assay recently reported (Muller and Weigl, 1992). In this assay, when freshly isolated human peripheral blood mononuclear cells (PBMC) are added to confluent monolayers of resting human umbilical vein endothelial cells (HEC), monocytes selectively and quantitatively migrate across while lymphocytes show little binding and virtually no transmigration without the need to purify monocytes from PBMC.
PBMC isolated from normal donors were incubated for 20 min at 4°C with anli- PECAM-1 mAb hec7 (Muller et al., 1989) or isotype matched control mAb, washed free of unbound antibody, and added to HEC monolayers in the standard transmigration assay (Muller and Wiegl, 1992). As previously reported (Muller and Weigl, 1992), after 40 to 60 minutes of incubation, all of the monocytes (Mo) in the control samples had transmigrated the HEC monolayer, while lymphocytes remained unbound or loosely attached and were easily removed by the washes in 1 mM EGTA. All of the Mo in the samples treated with anti-PECAM antibodies also resisted the multiple washes in EGTA and remained with the HEC monolayer.
However, in contrast to the control samples in which Mo had clearly transmigrated (Figs, lb, lc, and (Muller and Weigl, 1992)), most of the Mo treated with anti- PECAM antibodies remained bound to the apical surface of the HEC monolayers, accumulating at the intercellular junctions (Fig. la).
This phenomenon was investigated at the ultrastructural level. Scanning electron microscopy of HEC monolayers exposed to control and hec7 treated PBMC for up to five hours revealed a dramatic difference. While only rare control Mo were observed on the monolayer surface (Fig. 2a), numerous hec7 treated Mo remained attached to the apical surface of the monolayer (Fig. 2b). Higher power views revealed that these Mo were well attached and mostly spread on the endothelial surface, where they were associated with intercellular junctions between apposing HEC. Most appeared to have at least a pseudopod in the junction (Fig. 2c).
EXAMPLE 2
Quantitation of the inhibition of transmigration
The position of Mo in such monolayers was quantitated with respect to the surface of the HEC monolayer using Hoffman modulation contract optics (Hoffman, 1977) and/or Nomarski optics to define the plane of the monolayer. In some experiments, monocytes remaining on the apical surface of the monolayer were distinguished from transmigrated Mo that remained close to the basal HEC surface by their ability to rosette antibody coated sheep erythrocytes via their Fc receptor (Wright, 1986). Data obtained with all three methods were similar.
PBMC were incubated on ice for 30 min with hec7 (anti-PECAM mAb) or control mAb at 20 μg/ml, washed free of unbound mAb and added to HEC monolayers. After one hour at 37°C virtually all of the control Mo were clearly well below the HEC, whereas less than 20% of anti-PECAM-treated Mo had transmigrated (Fig. 3). In over 80 separate experiments, hec7 usually inhibited Mo transmigration by 70 to 90%. The same results were obtained when the transmigration assay was
carried out in the continuous presence of antibodies (Fig. 3). Previous results have demonstrated that hec7 mAb added to HEC monolayers that have already achieved confluence does not disrupt junctions. Therefore, it is presumed that the effect in this experiment of the mAb continuously present is solely on the Mo.
Monoclonal antibody hec7 at 10 to 20 μg/ml was as effective as a 1:100 dilution of rabbit anti-PECAM serum at blocking TEM (Fig. 4). Anti-PECAM mAb hec7 blocked TEM significantly at doses as low as 1 μg/ml, with maximum effect seen at around 10 μg/ml. The effect of hec7 was not mediated via an effect on the monocyte Fc receptor. Fab [and F(ab')2 fragments, data not shown] fragments of hec7 also demonstrated significant inhibitory activity in the 1 to 10 μg/ml range (Fig. 5).
The blockade of transendothelial migration was specific for PECAM- 1. Several other mAb against monocyte surface antigens (including mAb against Class I MHC antigen, Class II MHC, FC receptor, and CD14) used at the same concentration failed to affect TEM (Fig. 6). Monoclonal antibody IB4 against CD 18, the leukocyte β2 integrin chain, blocked adhesion of Mo to the HEC by about 70%, as previously found (Muller and Weigl, 1992); however, those Mo that remained associated with the monolayer in the presence of IB4 transmigrated apparently normally.
EXAMPLE 3
Anti-PECAM mAb does not affect chemotaxis
Inhibition of TEM in system was not due to the effect of the mAb on monocyte chemotaxis. A chemotaxis assay was developed involving the migration of leukocytes into bare collagen gels impregnated with chemoattractant. Control experiments (not shown) demonstrated that molecules as large as fluoresceinated IgG equilibrated in such gels within six hours. Migration of unactivated Mo into such gels is negligible (Fig. 7).
Mo added to gels impregnated with formylated peptide migrate into the gels in a dose-dependent manner, similar to that seen in a more conventional Boyden chamber assay (Muller and Weigl, 1992). Incubation of the PBMC with mAb hec7 had no effect on this chemotaxis, nor did it have any effect on the low level of random migration into the gel in the absence of chemoattractant. Similarly migration of neutrophils (PMN) to a variety of chemoattractants was unaffected by these concentrations of hec7 mAb (Fig. 7).
EXAMPLE 4
The effect of hec7 mAb on transmigration is long lasting, but reversible. Inhibition of TEM by hec7 was maintained in culture for at least six hours (the longest time point tested) when PBMC were in the continued presence of the mAb (Figure 8). However, upon removal of hec7 from the supernate of such cultures, the blockade of transmigration was eliminated, and Mo began transmigrating after an hour. By one and one-half hours after return to control medium all Mo had transmigrated (Fig. 8). Thus, anti-PECAM mAb is not merely slowing down the transmigration process, and is not permanently affecting the monocyte' s ability to recognize and respond to important signals required for TEM.
EXAMPLE 5
hec7 monoclonal antibody bound to PECAM in the HEC junctions blocks monocyte transmigration Greater than 85% of the PECAM on cultured HEC is concentrated in the intercellular junctions (Muller 1989). However, in this location it is poorly, if at all accessible to hec7 mAb applied to the apical surface of live, confluent monolayers. Indeed, hec7 and several other mAb recognizing membrane proteins on the endothelial cell surface (including ICAM-1) failed to block transmigration when HEC monolayers were preincubated with these mAb for 1 hr. at 37°C, then washed free of unbound antibody prior to addition of the PBMC (Data not shown.)
In order to study the role that PECAM in the HEC junctions might play in the process of TEM, a method was devised to deliver hec7 to the intercellular junctions (see Methods). The addition of hec7 Fab fragments to subconfluent HEC increased the time required to achieve confluence relative to replicate control cultures, as expected (Muller, 1992; Albelda, et al., 1990). However, once the monolayer became confluent, it was indistinguishable from control monolayers by phase microscopy. Immunofluorescence microscopy performed on live monolayers localized hec7 Fab fragments to the junctions between adjacent HEC (Fig. 9a).
When untreated PBMC or PBMC in the presence of control mAb was added to such monolayers (Fig. 10, central group "hec7 Fab"), transmigration was blocked. In the experiment shown in Figure 10, as well as in several similar experiments, the degree of inhibition of TEM was equivalent to that which could be achieved by hec7 IgG added to the same donor's PBMCs on control monolayers (Fig. 10, left group "Control"). The effect of hec7 Fab was not merely a steric effect due to clogging the intercellular junction with antibody fragments.
As a control for this, HEC monolayers were cultured in the presence of Fab fragments of mAb heel, heel is a mAb raised in this laboratory that recognizes a novel integral membrane protein of 130 kD that, like PECAM-1, is enriched in the junctions of HEC, but unlike PECAM, is not expressed on leukocytes or platelets. Furthermore, heel is an isotype match for hec7.
Fab fragments of heel also accumulated in HEC intercellular junctions (Fig. 9b). However, heel Fab pretreatment had no effect on transmigration of untreated monocytes (Fig. 10, right group "heel Fab"). Of note, no greater inhibition of transmigration was achieved when hec7 IgG was added to monocytes exposed to hec7 Fab pre-treated monolayers (Fig. 10, filled bar, hec7 Fab group) than was achieved by adding this anti-PECAM reagent to either the monocytes (Fig. 10, filled bars, control and heel Fab groups) or the HEC (Fig. 10, open bar, hec7 Fab group) alone. This is consistent with the interpretation that hec7 is blocking an interaction in which PECAM on the monocyte is binding in a homophilic manner with PECAM on the endothelial cell.
The blockade of transmigration by hec7 Fab is not due to Fab leaking out of the HEC monolayer or subendothelial collagen and binding to monocyte PECAM. In control experiments Fab-pretreated HEC cultures were processed in an identical manner to those used in the experiments of Fig. 10. Supernatant was collected from these cultures after an hour at 37°C and used to resuspend freshly isolated PBMC, which were then subjected to the transmigration assay. Neither supernate from control or hec7 Fab treated cultures inhibited transmigration of Mo (96.8 + 2.6% and 97.6 ± 2.3% transmigration, respectively).
EXAMPLE 6
Recombinant soluble PECAM blocks transendothelial migration of leukocytes If hec7 were interfering with transmigration by binding to monocyte and/or endothelial cell PECAM and blocking either or both sides of a homophilic
adhesion, it might be possible to use a soluble form of the molecule to compete with endothelial PECAM for the Mo and thus block transmigration. To test this hypothesis, a soluble recombinant form of PECAM- 1 was prepared that was truncated in the middle of the sixth immunoglobulin domain. This construct, expressed in COS cells is secreted into the medium and migrates in SDS-PAGE gels at the predicted Mr of 90 kD (Fig. 11). Soluble PECAM was purified on a hec7-Sepharose affinity column from culture medium conditioned by COS cells transiently transfected with this construct. The purified material runs as a single band at the expected position on SDS-PAGE.
Soluble PECAM at concentrations as low as 1 μg/ml significantly inhibits the transmigration of monocytes when added to PBMC in the standard assay (Fig. 10, hatched bars, control group and heel Fab). Concentrations of 10 μg/ml consistently inhibited as well as optimal concentrations of hec7 IgG, in some experiments (not shown) blocking TEM down to 10% of control values. The presence of soluble PECAM in the incubation medium did not augment the inhibition of transmigration effected by hec7 Fab in the HEC junctions (Fig. 10, hatched bar, hec7 Fab), consistent with the hypothesis that soluble PECAM is blocking a homophilic PECAM-PECAM interaction.
EXAMPLE 7
Anti-PECAM mAb blocks transmigration of Mo across cytokine activated HEC monolayers. The in vitro transmigration assay used in this study employs HEC monolayers that are not activated by exogenous cytokines nor endotoxin. The endothelial cells do not express cytokine inducible adhesion molecules like VCAM-1 or E-selectin and have basal levels of ICAM-1 (Muller and Weigl, 1992). When such monolayers are induced by cytokines to express such adhesion molecules, transmigration of Mo is even more rapid than under basal conditions, with 100% of Mo entering the subendothelial collagen within 20 to 30 min (unpublished data). It was therefore
of interest to determine whether hec7 would have as dramatic effect on monocytes transmigrating under these conditions. As can be seen in Figure 12, it does.
EXAMPLE 8
Anti-PECAM reagents block transmigration of neutrophils Neutrophils (PMN) also bear surface PECAM (Ohto et al., 1985; Goyert et al., 1986; Stockinger et al., 1990), although hec7 does not bind to the form displayed by PMN as well as it binds HEC and Mo (unpublished observations). Neutrophils do not migrate readily across resting HEC monolayers in this system (Muller and Weigl, 1992). However, they do transmigrate cytokine-activated monolayers readily (unpublished). After 1 hour 97% of PMNs in the presence of control antibody had migrated below the TNFα-activated HEC monolayer. hec7 MAb blocked transmigration by about 40%, consistent with its relatively weak binding to the neutrophil form of this molecule. However, a polyclonal rabbit antiserum against PECAM and soluble recombinant PECAM at 10 μg/ml blocked transmigration down to below 20% of control levels (Fig. 13). Thus, PECAM apparently plays a similar role in the transmigration of neutrophils as it does for monocytes.
MATERIALS AND METHODS FOR EXAMPLES 9-11
Animals Female mice of the CD2F, strain weighing approximately 20 g. were purchased from Charles River Laboratories (Boston, MA) and housed at The Rockefeller University Laboratory Animal Research Center. Female mice of the AKR/J strain were purchased from Jackson Laboratories (Bar Harbor, ME) and housed at the Boston University School of Medicine Laboratory Animal Science Center. All animal procedures had been approved by the Rockefeller University and Boston University School of Medicine IACUCs. Animals were handled according to guidelines set forth in the "Guide for the Care and Use of Laboratory
Animals" and the "Animal Welfare Act. " Mice were housed together in standard cages and allowed free access to mouse chow and water.
Monoclonal Antibodies Monoclonal antibody (mAb) 2H8 hamster anti-murine PECAM-1 was produced as described (Bogen et al. 1992) and purified by HPLC using a JT Baker ABx semi-preparative column, loading in 25 mM 2-[N- Morpholino]ethanesulfonic acid (MES), pH 5.7, and eluting with a linear 10%- 60% gradient of 500 mM NHjSO + 5 mM KH2PO4, pH 6.7, according to the manufacturer's recommendations. Purification of the 2H8 mAb under denaturing conditions resulted in an antibody preparation that was less effective in vivo. The 2H8 mAb was negative for endotoxin by the Limulus amebocyte lysate assay (Sigma, St. Louis, MO). The hamster anti-murine CD 18 mAb 2E6 was originally raised at Rockefeller University (Metlay et al. 1990) and was donated by Endogen, Inc. (Boston, MA). Hybridoma lines producing mAb 5C6 (rat anti-murine CD lib) (Rosen and Gordon 1987) were generously provided by Dr. Hugh Rosen (Merck, Sharp & Dohme Research Laboratories, Rahway, NJ); IgG was purified from cell supernatant as previously described (Muller et al. 1993). Normal hamster IgG was purchased from Jackson Immuno Research Laboratories, Inc. (West Grove, PA). All mAb were demonstrated to recognize their specific antigens by flow cytometry and/or immunohistochemistry.
Immunohistochemistry Leukocytes were isolated from buffy coats of blood collected by cardiac puncture in heparinized syringes. Red blood cells were lysed by resuspension of the buffy coat pellet in 9 volumes of pyrogen-free distilled water for 60 sec on ice. One volume of 10X PBS was added, the suspension was centrifuged, and the pellet containing leukocytes was washed in HBSS. Frozen sections of mouse tissue, or cytospin preparations of isolated peripheral blood leukocytes or peritoneal exudate cells, were stained by indirect immunoperoxidase histochemistry as previously described (Muller et al. 1989; Bogen et al. 1992). Briefly, endogenous peroxidase activity was quenched by reaction with H2O2, the sections were incubated with primary mAb diluted in PBS/ovalbumin for 30 min at
room temperature, washed in PBS/ovalbumin, then incubated in a 1:200 dilution of horseradish peroxidase-conj ugated goat anti-hamster IgG (Accurate Scientific, Westbury, NY) for 30 min at room temperature before washing and developing with diaminobenzidine-H2O2.
Experimental Procedure The emigration of PMN into the mouse peritoneal cavity in response to intraperitoneal (i.p.) injection of thioglycoUate broth is a well- established model of acute inflammation (Lewinsohn et al. 1987; Watson et al. 1991). Mice were injected i.v. via the lateral tail vein with the various monoclonal antibodies diluted in Dulbecco's phosphate buffered saline (DPBS) to a final volume of approximately 100 μl. Some control mice received DPBS alone or an equivalent dose of normal hamster IgG. Four hours later, mice were injected i.p. with 1 ml of 4% Brewer's thioglycoUate broth (Difco, Detroit, MI). Twenty four hours after the mAb injection, mice were sacrificed by exposure to CC Peritoneal cells were recovered into tubes on ice by lavage with 5 ml of divalent cation-free Hanks' Balanced Salt Solution (HBSS, Gibco, Grand Island, NY) using standard techniques (Muller et al. 1980). Heparinized blood was coUected by cardiac puncture or from the retro-orbital sinus. Peritoneal cell counts and peripheral white blood cell counts were performed (employing Unopette erythrocyte lysis kits, Fisher Scientific, Pittsburgh, PA) on samples from each mouse using a hemacytometer. Differential counts were performed on Wright/Giemsa stained cytospin preparations (for peritoneal cells) and peripheral blood smears.
The abdominal and thoracic cavities were inspected for signs of gross pathology. The mesenteric lymph nodes were harvested and fixed in 4% paraformaldehyde, 2% glutaraldehyde in 0.1M sodium phosphate buffer, pH = 7.4. The liver and spleen were excised intact and weighed. These organs, along with the majority of the small and large bowel were fixed in neutral buffered formalin. Representative regions were embedded in paraffin or methyl methacrylate. Sections were cut and stained with hematoxylin and eosin (H&E).
EXAMPLE 9
The previous examples demonstrated that PECAM- 1 is required for the migration of monocytes and neutrophils across resting and cytokine-activated HEC in a quantitative in vitro assay of transmigration (MuUer et al., 1993), and prompted the observation and conclusions that PECAM is a central actor in inflammation and other conditions where leukocyte migration occurs in response to invasive stimuU such as infection.
In the following experiments, a murine model of acute peritonitis was used to test whether intravenously (i.v.) administered anti-murine PECAM- 1 mAb would block acute inflammation. The results presented below demonstrate that anti-PECAM- 1 mAb inhibits emigration of neutrophils (PMN) and mononuclear leukocytes to nearly background levels establishing PECAM- 1 as an important adhesion molecule in the inflammatory response.
Monoclonal antibody against murine PECAM- 1 blocks acute inflammation.
To test whether PECAM- 1 plays a critical role for acute inflammation in vivo, the hamster anti-murine PECAM- 1 mAb 2H8 (Bogen et al., 1992) or appropriate positive or negative control mAb, was administered intravenously (i.v.), four hours prior to the intraperitoneal (i.p.) injection of thioglycoUate broth (Figures 14 and 15.) In this well-established model of acute peritonitis, intraperitoneal thioglycoUate induces an influx of neutrophils into the peritoneal cavity within the first two hours (Lewinsohn et al., 1987; Watson et al., 1991). The degree of inflammation was measured by peritoneal lavage 20 hours after thioglycoUate injection. In seven out of seven experiments performed, the anti-PECAM-1 mAb prevented the emigration of leukocytes into the peritoneal cavity. Several representative experiments are shown in Figures 14 and 15. Two particular experiments are presented in Figures 15A and 15B.
In all cases, the effect of anti-PECAM- 1 mAb was comparable to that of the positive control mAb 5C6 (anti-CDllb), which had previously been shown to block acute inflammation in this model (Rosen and Gordon, 1987). Production and purification of active Fab or F(ab')2 fragments of 2H8 proved technically problematic. Therefore, in the experiment shown in Fig. 15B and other similar experiments, a hamster anti-mouse CD18 (2E6) served as a control, since it binds tightly to murine leukocytes, but is a relatively weak blocker of integrin function (Metlay et al., 1990). The failure of this mAb to block emigration rules against nonspecific or Fc-mediated effects of bound mAb being responsible for the block seen with anti-PECAM-1 mAb. Immunostaining of peripheral blood from mice treated with 2E6 demonstrated that leukocytes still bound readily detectable levels of this mAb at the time of sacrifice (data not shown).
Figures 14 and 15 separately report data on the PMN exudate and the total exudate cells (including lymphocytes and macrophages). The decrease in PMN accumulation produced by the anti-PECAM-1 mAb is particularly dramatic, since these ceUs are not normally resident in the peritoneal cavity. Additional experiments revealed that significant suppression of inflammation by mAb 2H8 was achieved at doses as low as 50 μg/mouse (the lowest dose tested-Fig. 14), and suppression was maintained for at least 48 hours (not shown). This time course is similar to that described with anti-CDllb blockade (Rosen and Gordon, 1987) and significantly longer than the four-hour suppression seen in this model by blockade of L-selectin (Watson et al.), or knockout of P-selectin (Mayadas et al., 1993).
EXAMPLE 10
Anti-PECAM- 1 mAb appears to arrest emigration of adherent leukocytes Administration of these antibodies did not lower the circulating leukocyte count. In fact, at the time of sacrifice, there was a granulocytosis in those mice that had received anti-PECAM- 1 mAb (Table I), consistent with the hypothesis that PMN were being recruited into the circulation, but blocked from emigrating to the site
of inflammation. Histologic examination revealed no abnormal accumulations of leukocytes in the spleens or livers (not shown). Absolute platelet counts were not performed, but no difference in platelet numbers or appearance on peripheral blood smears was seen among the experimental groups.
Table I
Peripheral blood leukocyte counts for experiment in Figure 15.
ThioglycoUate Antibody WBC (cells/μl)' Differential fP/L/MV Experiment 1 (AKR J strain)
+ N. Ham. IgG8 4,438 + 169 36/59/5
None 4,963 ± 699 19/75/6 + Anti-PECAM (2H8) 4,548 ± 242 62/35/3
+ Anti-CDllb (5C6) 2,838 ± 234 20/65/15 Experiment 2 (CD2F, strain)
+ Anti-CD18 (2E6) 9,640 ± 1270 28/65/7
None 12,260 ± 1970 11/77/12 + Anti-PECAM (2H8) 16,060 ± 2750 59/33/8
+ Anti-CDllb (5C6) 11,580 ± 3460 20/74/6
'Peripheral white blood cell count. Data expressed as mean ± standard error of mean.
♦Percentages of polymorphonuclear leukocytes
(neutrophUs)/lymphocytes/monocytes from > 100 cells counted. Note that a normal mouse WBC differential count is dominated by lymphocytes. Mice receiving thioglycoUate displayed increased percentages of myeloid forms, including immature forms, which are grouped with the neutrophils. 8N. Ham. IgG = Normal Hamster IgG
Histologic examination of the mesenteries of the mice receiving anti-PECAM- 1 mAb showed increased numbers of intravascular PMN in the venules compared
with controls. These PMN appeared to be in contact with the endothelial surface (Figure 16), but were inhibited from migrating across the vascular wall, analogous to the block of transmigration observed in vitro (MuUer et al., 1993). Figure 16A shows one of the more extreme examples of this phenomenon encountered; however, about 60% of random mesenteric venular profiles in anti-PECAM- 1- treated mice appeared to bear adherent leukocytes (Fig. 16E). This phenomenon was seen in postcapUlary venules, as well as sUghtly larger venules, which are also sites of emigration of PMN (Cotran, 1965). Since the chances of finding a truly nonadherent leukocyte adjacent to the endotheUum was less likely in these larger diameter venules, ten random sections of such venules (50-150 μm diameter) were examined on coded slides from each mouse, and leukocytes in contact with the vessel wall or free in circulation were counted. Only rare leukocytes contacted the endothelium in control (no thioglycoUate) animals or in animals receiving mAb other than 2H8 (Figures 16B and 16E). There was variability among venules, but overall, 34% of all leukocytes seen in the venules of the anti-PECAM- 1-treated mice were in apparent contact with the endothelium. Immunohistologic examination of these mice demonstrated anti-PECAM- 1 mAb was still specifically retained by endothelium in vascular structures, including mesenteric venules. Since these vessels are found in fatty tissue and therefore are cut poorly by frozen section, this phenomenon is demonstrated on vessels within the bowel wall
(Figures 16C,D). Residual 2H8 on circulating PMN could not be detected using immunoperoxidase techniques. However, this could be due to turnover of PMN during the 24 hr. and/or shedding of murine PECAM- 1 from PMN membranes.
EXAMPLE 11
Anti-PECAM- 1 mAb blocks emigration of mononuclear cells Significant numbers of mononuclear cells as well as PMN are recruited to the peritoneal cavity by 20 hours after thioglycoUate injection. Figures 14 and 15 demonstrate that the increase in peritoneal exudate cells is not accounted for by the
increase in PMN alone. Anti-PECAM- 1 mAb 2H8 also blocked the influx of mononuclear cells into the peritoneum (Fig. 15, right).
To determine if PECAM- 1 blockade affected mononuclear cell trafficking, the mesenteric lymph nodes draining the peritoneal cavity were examined. The peritoneal cavity is drained by, among other lymphatic beds, the mesenteric plexus. Peritoneal mononuclear cells in the afferent lymphatics would enter draining lymph nodes via the subcapsular sinus. Examination of mesenteric nodes revealed large numbers of mononuclear cells entering via the subcapsular sinus in mice stimulated with thioglycoUate, but relatively few in the subcapsular sinuses of mice given anti-PECAM- 1 mAb prior to thioglycoUate (Figure 17). The paucity of mononuclear cells in the subcapsular sinus is a direct reflection of the block of mononuclear cell entry into the peritoneal cavity. These data are in agreement with those of Figures 14 and 15, and selectively represent the mononuclear cell fraction. PMN do not recirculate into the draining lymphatics in general and were not seen in the subcapsular sinuses of the lymph nodes of these mice.
Furthermore, in some experiments, the thioglycollate-elicited peritoneal exudate cell count was lower for anti-PECAM- 1 treated mice than for control mice not stimulated with thioglycoUate (Figure 14 and Figure 15, right). This suggested that PECAM- 1 may be required for the constitutive trafficking of mononuclear cells through the peritoneum as well as for the thioglycollate-elicited emigration.
In an in vitro model using human leukocytes and endothelial cells, anti-PECAM- 1 mAb or soluble recombinant PECAM- 1 did not affect attachment, but blocked transmigration of monocytes and PMN (Muller et al., 1993), which remained tightly adherent to the apical surface over the intercellular junctions, the site at which endothelial PECAM- 1 is concentrated (Muller et al., 1989). The function of PECAM- 1 in transendothelial migration was distal to the selectin-mediated rolling and the β2 integrin-mediated tight adhesion to the apical surface of the venular endothelium.
The results of the present study (see especially, Figure 16) suggest that PECAM- 1 plays a similar role in vivo, since leukocytes blocked from entering the peritoneal cavity by anti-PECAM- 1 mAb were apparently arrested on the luminal surface of the venular endothelium. The arrest on the endotheUal surface is presumed to be transient, since the vast majority of the luminal surface of the affected venules was free of leukocytes, and the granulocytosis was persistent. The block of emigration effected by anti-PECAM- 1 mAb appears to involve a different mechanism than the block by anti-CDllb. In the latter case, no granulocytosis was seen in the peripheral blood, and, although PMN emigration into the peritoneum was inhibited, leukocytes were not seen in apparent contact with the venular wall. This is consistent with the proposed role of β2 integrins in mediating the tight adhesion to the endothelial surface (von Andrian et al., 1991; Lawrence et al., 1991; Lo et al., 1991).
In the in vitro model, leukocyte transmigration could be blocked equaUy well by treating either the leukocytes or the endothelial cells with anti-PECAM- 1 reagents. We do not know whether the 2H8 mAb is blocking leukocyte transmigration by blocking PECAM-1 on leukocytes, endothelium, or both.
Since anti-PECAM- 1 mAb blocked emigration of mononuclear cells as well as PMN in vivo, PECAM- 1 may mediate a function common to all leukocyte types that is necessary for the process of transendothelial migration. In addition, the inhibition was effected at a low dose of anti-PECAM- 1 mAb (50 μg/mouse in certain experiments) and lasted up to 48 hours following a single injection. These observations support the role of PECAM- 1 as a suitable molecule to target in anti- inflammatory therapy.
The above results further demonstrate the activity of PECAM in an in vivo setting. The murine model of peritonitis that was presented in Example 9 confirmed the role of PECAM- 1/CD31 in inflammation that demonstrated in Examples 1-8. The monoclonal antibody specific for murine PECAM- 1 injected intravenously four
hours prior to the intraperitoneal injection of thioglycoUate broth blocked leukocyte emigration into the peritoneal cavity for up to 48 hours. This block was particularly evident for neutrophils. Control monoclonal antibodies, including one that bound to murine CD18 without blocking its function, failed to block emigration when used at the same or higher concentrations. The decreased emigration seen with the anti-PECAM- 1 antibody was not due to neutropenia or neutrophil sequestration in the lung, spleen, or other organs; peripheral blood leukocyte counts were not diminished in these mice. In the mesenteric venules of the mice treated with anti-PECAM- 1 monoclonal antibody, leukocytes were frequently seen in association with the luminal surface of the vessel, but did not appear to emigrate. Thus, the requirement for PECAM- 1 in the transendothelial migration of leukocytes previously seen in an in vitro model holds true in this in vivo model of acute inflammation.
In addition, certain findings recently published by Vaporciyan and co-workers (Vaporciyan, et al., (1993) Science, 262:1580-1582) further corroborate the premise and conclusions of the present invention. Based on the results of Muller et al (1993) and unpublished data outlined above that demonstrated a critical role for PECAM-1 in transendothelial migration, Vaporciyan et al. studied PECAM- 1 activity in three distinct models of inflammation, and found that in all three models, PECAM demonstrated an active role in the promotion of neutrophil migration. (See references 9 and 19 of Vaporciyan et al., 1993).
Specifically, the authors prepared a rabbit polyclonal antibody reactive with human PECAM- 1 and cross-reactive with rat PECAM- 1, and after establishing its specificity, tested its activity in two compartments in rats, in its effect on neutrophil accumulation induced by glycogen introduced into the peritoneal cavity, and the deposition of immunoglobulin G (IgG) immune complexes in the lung, and on human skin transplanted onto mice with severe combined immunodeficiency disease (SCID). In the first model, the anti-PECAM-1 antibody was injected intravenously into the rats at the time of glycogen instillation and periodically
thereafter, and blocked glycogen-induced peritoneal neutrophil accumulation by 75%. In the second model, the antibody was infused intravenously at 30 minute intervals commencing 2.5 hours after initiation of immune complex injury, and again, a 75% reduction in neutrophil recruitment was observed. The skin grafts of the third model were challenged with TNF-α four weeks after transplantation, and those grafts receiving the antibody exhibited a reduction in neutrophil recruitment and movement. The results of these tests both corroborate the present findings regarding PECAM's activity and further confirm the therapeutic utility of the modulators of the present invention.
EXAMPLE 12
Since it has been shown that a soluble form of PECAM- 1 comprising a portion of the external domain of the molecule is effective at inhibiting transendothelial migration of leukocytes (Figures 10 and 13, and Muller et al., 1993), and since it is known that the inhibitory mAb hec7 binds to PECAM- 1 between Domains 1 and 2 of the molecule (unpublished data), it is feasible that smaller polypeptide fragments, for example corresponding to Domains 1 and 2 of PECAM could be used to inhibit transendothelial migration when appropriately delivered to the host.
As one example of such a use, polypeptides corresponding to the ligand binding domain of PECAM- 1 or, for example, a 210 amino acid peptide encompassing Domains 1 and 2 of PECAM-1, would be administered parenterally to a patient afflicted with a flare-up of a chronic inflammatory condition (e.g. Systemic Lupus Erythematosis). It would be expected that the soluble peptide would interfere with PECAM-PECAM interactions of leukocytes and endothelial cells, such that transendothelial migration is inhibited and the leukocytes, unable to cross the endothelial junctions into the sites of inflammation, return to the circulation after a brief period of arrest on the apical surface of the endothelium (just as occurred when anti-PECAM mAb was administered parenterally in a murine model of inflammation, Figures 14-16). It would be expected that the deleterious effects of
the inflammatory flare-up (e.g. renal damage) would be ameliorated. This could be monitored, for example, in this instance, by standard clinical measurements of renal function.
Furthermore, it is envisioned that one or more molecules being structurally unrelated to PECAM- 1 but either mimicking the structure of its active domain or complementary to it might inhibit PECAM function by binding to it or competitively inhibiting the binding of the natural ligand. Changes in secondary structure of adhesion molecules have been demonstrated in some cases to be crucial for these molecules to function. Therefore, if such a situation is found for PECAM- 1, molecules found to inhibit or promote the formation or retention of the appropriate structural changes may be used to block or augment PECAM function, respectively. Such blocking or augmenting molecules may be peptides, small organic molecules, and inorganic molecules, e.g. metal ions and complexes thereof. The aforementioned are nonlimiting examples of how molecules other than anti-PECAM antibodies or full-length soluble PECAM- 1 may be used in accordance with the present invention.
EXAMPLE 13
The following are representative formulations that may be administered in the practice of the therapeutic methods of the present invention.
Intravenous Formulation I Ingredient cefotaxime monoclonal antibody hec7 dextrose USP sodium bisulfite USP edetate disodium USP water for injection q.s.a.d.
Intravenous Formulation V
Ingredient mg/ml rhPECAM-l 10.0 sodium bisulfite USP 3.2 disodium edetate USP 0.1 water for injection q.s.a.d. 1.00 ml
As indicated earlier, the present invention is applicable to the treatment of a variety of inflammatory disease states including infectious diseases where active infection exists at any body site, such as in the instance of meningitis. Also included are conditions such as secondary inflammations whether acute or chronic, that may occur at a site of antigen deposition that is secondary to a primary infection at a distant body site, and exemplary specific conditions would also include meningitis, as weU as encephalitis, arthritis, uveitis, colitis, such as inflammatory bowel/Crohn's disease, glomerulonephritis, dermatitis, and psoriasis. Also included is the inflammation that results from alterations in leukocyte movement during infection such as adult respiratory distress syndrome associated with sepsis.
Other inflammatory disease states include immune disorders and conditions involving T-cell and/or macrophage attachment recognition; such as, acute and delayed hypersensitivity, graft vs. host disease; primary auto-immune conditions such as pernicious anemia; infection related auto-immune conditions such as Type I diabetes mellitus; flares during rheumatoid arthritis; diseases that involve leukocyte diapedesis, such as multiple sclerosis; antigen-antibody complex mediated diseases including certain of the secondary infection states listed above; and transplant rejection. Inflammation due to toxic shock or trauma such as adult respiratory distress syndrome and reperfusion injury; and that which is due to tumorous conditions such as leukocyte dyscrasias and metastasis, is likewise included within the scope hereof.
In addition to the above, the present invention is applicable to the inhibition of leukocyte transmigration in the instances of non-disease states and in particular, for diagnostic and therapeutic purposes; such as to prevent the ingress of leukocytes during the introduction of a dye or image enhancer into tissue, or to allow the selective entry of a therapeutic drug in the instance of chemotherapy; or to enhance the harvesting of leukocytes from patients.
The following is a listing of certain of the publications referred to in abbreviated fashion in the foregoing specification.
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This invention may be embodied in other forms or carried out in other ways without departing from the spirit or essential characteristics thereof. The present disclosure is therefore to be considered as in all respects illustrative and not restrictive, the scope of the invention being indicated by the appended claims, and all changes which come within the meaning and range of equivalency are intended to be embraced therein.
Claims (46)
1. A method of modulating the transendothelial migration (TEM) of leukocytes into sites of acute and or chronic inflammation in a mammal during infectious or non-infectious conditions, comprising administering a TEM modulating amount of an agent selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-l), and active fragments thereof.
2. A method according to Claim 1 wherein the anti-PECAM antibody is anti- PECAM- 1.
3. A method according to Claim 1 wherein the anti-PECAM antibody is monoclonal antibody hec7, or active fragments thereof.
4. A method according to Claim 3 wherein the monoclonal antibody or fragment thereof is prepared from Hybridoma hec7.2, ATCC Accession No. HB 11227.
5. A method according to Claim 1 wherein the transendothelial migration of leukocytes is associated with an infection.
6. A method according to Claim 1 wherein the transendothelial migration of leukocytes is associated with a non-infectious trauma.
7. A method according to Claim 1 wherein the transendothelial migration of leukocytes is associated with endotoxic shock.
8. A method according to Claim 1 wherein the transendothelial migration of leukocytes is associated with adult respiratory distress syndrome.
9. A method according to Claim 5 wherein the infection is associated with a disease state selected from the group consisting of meningitis, encephalitis, arthritis, uveitis, colitis, dermatitis, and adult respiratory distress syndrome.
10. A method according to Claim 1 wherein the transendothelial migration of leukocytes results from a condition selected from the group consisting of the sequelae of organ transplantation or tissue allograft; atherosclerosis (arteriosclerosis); multiple sclerosis, systemic lupus erythematosus, rheumatoid arthritis, Sjogren's Syndrome, progressive systemic sclerosis (scleroderma), ankylosing spondylitis, polymyositis, dermatomyositis, pemphigus, pemphigoid, Type I diabetes mellitus, myasthenia gravis, Hashimoto's thyroiditis, Graves' disease, Goodpasture's disease, mixed connective tissue disease, sclerosing cholangitis, inflammatory bowel disease including Crohn's Disease (regional enteritis) and ulcerative colitis, pernicious anemia, inflammatory dermatoses; usual interstitial pneumonitis, asbestosis, silicosis, berylliosis, talcosis, the various forms all forms of pneumoconiosis, sarcoidosis (in the lung and in any other organ), desquamative interstitial pneumonia, lymphoid interstitial pneumonia, giant cell interstitial pneumonia, cellular interstitial pneumonia, extrinsic allergic alveolitis, Wegener's granulomatosis and related forms of angiitis; arteritis; temporal arteritis and polyarteritis nodosa); inflammatory dermatoses not presumed to be autoimmune; chronic active hepatitis; delayed-type hypersensitivity reactions (e.g. poison ivy dermatitis); pneumonia or other respiratory tract inflammation due to any cause; Adult Respiratory Distress Syndrome (ARDS) from any etiology; encephalitis, with inflammatory edema; immediate hypersensitivity reactions including, but not limited to, asthma, hayfever, cutaneous allergies, acute anaphylaxis; arteritides including, but not limited to temporal arteritis and polyarteritis nodosa; diseases involving acute deposition of immune complexes, including, but not limited to, rheumatic fever, acute and/or chronic glomerulonephritis due to any etiology, including specifically post-infectious (e.g. , post-Streptococcal) glomerulonephritis, acute exacerbations of Systemic Lupus Erythematosus; pyelonephritis; cellulitis; cystitis; acute cholecystitis; and conditions producing transient ischemia anywhere along the gastrointestinal tract, bladder, heart, or other organ, especially those prone to rupture; allograft rejection in the acute time period foUowing allogeneic organ or tissue transplantation.
11. A method according to Claim 1 for inhibiting the transendothelial migration of leukocytes for the treatment of inflammation and conditions causally associated therewith.
12. A method according to Claim 1 for promoting the transendothelial migration of leukocytes for the amelioration of an immunocompromised state in said mammal.
13. A method according to Claim 1 wherein the transendothelial migration of leukocytes results from an iatrogenic state.
14. A method of treating inflammation in the tissues and organs of patients caused by infectious or non-infectious conditions, comprising administering a therapeutic amount of an agent selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM- 1 (rhPECAM-l), and active fragments thereof, to a patient in need of such therapy.
15. A method according to Claim 14 wherein the anti-PECAM antibody is anti- PECAM-1.
16. A method according to Claim 14 wherein the anti-PECAM antibody is monoclonal antibody hec7, or active fragments thereof.
17. A method according to Claim 16 wherein the monoclonal antibody or fragment thereof is prepared from Hybridoma hec7.2, ATCC Accession No. HB 11227.
18. A method according to Claim 14 wherein said agent is administered intravenously.
19. A method according to Claim 14 wherein said agent is administered orally.
20. A method according to Claim 14 wherein said agent is administered parenterally.
21. A method according to Claim 14 wherein the inflammation is associated with an infection.
22. A method according to Claim 14 wherein the inflammation is associated with a non-infectious trauma.
23. A method according to Claim 14 wherein the inflammation is associated with endotoxic shock.
24. A method according to Claim 21 wherein the infection is associated with a disease state selected from the group consisting of meningitis, encephalitis, arthritis, uveitis, colitis, dermatitis, and adult respiratory distress syndrome.
25. A method according to Claim 14 wherein the inflammation results from a condition selected from the group consisting of the sequelae of organ transplantation or tissue allograft; atherosclerosis (arteriosclerosis); multiple sclerosis, systemic lupus erythematosus, rheumatoid arthritis, Sjogren's Syndrome, progressive systemic sclerosis (scleroderma), ankylosing spondylitis, polymyositis, dermatomyositis, pemphigus, pemphigoid, Type I diabetes mellitus, myasthenia gravis, Hashimoto's thyroiditis, Graves' disease, Goodpasture's disease, mixed connective tissue disease, sclerosing cholangitis, inflammatory bowel disease including Crohn's Disease (regional enteritis) and ulcerative colitis, pernicious anemia, inflammatory dermatoses; usual interstitial pneumonitis, asbestosis, silicosis, berylliosis, talcosis, the various forms all forms of pneumoconiosis, sarcoidosis (in the lung and in any other organ), desquamative interstitial pneumonia, lymphoid interstitial pneumonia, giant cell interstitial pneumonia, cellular interstitial pneumonia, extrinsic allergic alveolitis, Wegener's granulomatosis and related forms of angiitis; arteritis; temporal arteritis and polyarteritis nodosa); inflammatory dermatoses not presumed to be autoimmune; chronic active hepatitis; delayed-type hypersensitivity reactions (e.g. poison ivy dermatitis); pneumonia or other respiratory tract inflammation due to any cause; Adult Respiratory Distress Syndrome (ARDS) from any etiology; encephalitis, with inflammatory edema; immediate hypersensitivity reactions including, but not limited to, asthma, hayfever, cutaneous allergies, acute anaphylaxis; arteritides including, but not limited to temporal arteritis and polyarteritis nodosa; diseases involving acute deposition of immune complexes, including, but not limited to, rheumatic fever, acute and/or chronic glomerulonephritis due to any etiology, including specifically post-infectious (e.g., post-Streptococcal) glomerulonephritis, acute exacerbations of Systemic Lupus Erythematosus; pyelonephritis; cellulitis; cystitis; acute cholecystitis; and conditions producing transient ischemia anywhere along the gastrointestinal tract, bladder, heart, or other organ, especially those prone to rupture; allograft rejection in the acute time period following allogeneic organ or tissue transplantation.
26. A method in accordance with Claim 14 for eliminating or reducing inflammation in a patient wherein the patient is being administered an anti- infective agent, which further comprises administering a therapeutic amount of an agent effective to modulate the transendothelial migration of leukocytes prior to, concurrent with, or after, the administration of the anti-infective agent, to a patient in need of such therapy, wherein said agent is selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-l), and active fragments thereof.
27. A method according to Claim 26 wherein the anti PECAM antibody is anti- PECAM-1.
28. A method according to Claim 26 wherein the anti-HEC antibody is monoclonal antibody hec7, or active fragments thereof.
29. A method according to Claim 26 wherein the anti-infective agent is a beta- lactam antibiotic.
30. A method according to Claim 26 wherein the agent is administered intravenously.
31. A method according to Claim 26 wherein the agent is administered orally.
32. A method according to Claim 26 wherein the inflammation is associated with endotoxic shock.
33. A method according to Claim 26 wherein the inflammation is associated with adult respiratory distress syndrome of an infectious origin.
34. A method according to Claim 26 wherein the inflammation is associated with a disease state selected from the group consisting of meningitis, encephalitis, arthritis, uveitis, colitis, ARDS, and dermatitis.
35. A method according to Claim 26 wherein the inflammation results from a condition selected from the group consisting of the sequelae of organ transplantation or tissue allograft; atherosclerosis (arteriosclerosis); multiple sclerosis, systemic lupus erythematosus, rheumatoid arthritis, Sjogren's Syndrome, progressive systemic sclerosis (scleroderma), ankylosing spondylitis, polymyositis, dermatomyositis, pemphigus, pemphigoid, Type I diabetes mellitus, myasthenia gravis, Hashimoto's thyroiditis, Graves' disease, Goodpasture's disease, mixed connective tissue disease, sclerosing cholangitis, inflammatory bowel disease including Crohn's Disease (regional enteritis) and ulcerative colitis, pernicious anemia, inflammatory dermatoses; usual interstitial pneumonitis, asbestosis, sUicosis, beryUiosis, talcosis, the various forms all forms of pneumoconiosis, sarcoidosis (in the lung and in any other organ), desquamative interstitial pneumonia, lymphoid interstitial pneumonia, giant cell interstitial pneumonia, cellular interstitial pneumonia, extrinsic allergic alveolitis, Wegener's granulomatosis and related forms of angiitis; arteritis; temporal arteritis and polyarteritis nodosa); inflammatory dermatoses not presumed to be autoimmune; chronic active hepatitis; delayed-type hypersensitivity reactions (e.g. poison ivy dermatitis); pneumonia or other respiratory tract inflammation due to any cause; Adult Respiratory Distress Syndrome (ARDS) from any etiology; encephalitis, with inflammatory edema; immediate hypersensitivity reactions including, but not Umited to, asthma, hayfever, cutaneous allergies, acute anaphylaxis; arteritides including, but not limited to temporal arteritis and polyarteritis nodosa; diseases involving acute deposition of immune complexes, including, but not limited to, rheumatic fever, acute and/or chronic glomerulonephritis due to any etiology, including specifically post-infectious (e.g., post-Streptococcal) glomerulonephritis, acute exacerbations of Systemic Lupus Erythematosus; pyelonephritis; cellulitis; cystitis; acute cholecystitis; and conditions producing transient ischemia anywhere along the gastrointestinal tract, bladder, heart, or other organ, especially those prone to rupture; allograft rejection in the acute time period following allogeneic organ or tissue transplantation.
36. A method for measuring transendothelial migration of leukocytes, comprising: A. providing a test substrate from a colony of human endothelial cells; B. obtaining a biological sample from said mammal believed to contain a quantity of said leukocytes; C incubating the biological sample of Step B. with said test substrate for a period of time sufficient for the transmigration of said leukocytes to occur; and D. examining the incubated material of Step C by counting the position and number of said leukocytes adhering to the intercellular regions in said test substrate.
37. A method for measuring transendothelial migration in a mammal, and the role of PECAM therein, comprising: A. providing a test substrate from a colony of human endothelial cells; B. obtaining a biological sample from said mammal containing leukocytes; C incubating an aliquot portion of the biological sample of Step B. with said test substrate for a period of time sufficient for the transmigration of said leukocytes to occur in the absence of PECAM antagonists; D. preparing a control by incubating a further aliquot portion of the biological sample of Step B. with said test substrate and with an agent capable of modulating the transendothelial migration of leukocytes, said agent selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-l), agonists of PECAM activity, and active fragments thereof, for a period of time equal to that of Step C; and E. measuring said PECAM function in terms of transendothelial migration of said leukocytes by examining the incubated material of Step C and comparing the results to the incubated material of Step D.
38. A method for detecting circulating modulators of PECAM function in a mammal, comprising: A. providing a test substrate from a colony of human endothelial cells; B. obtaining a biological sample from said mammal selected from the group consisting of plasma, serum and other bodily fluids; C preparing at least one test incubation by incubating a quantity of leukocytes from the same or another mammal, with and without an aliquot portion of the biological sample of Step B. and with said test substrate for a period of time sufficient for the transmigration of said leukocytes to occur in the absence of PECAM antagonists; D. preparing at least one control by incubating a further aliquot portion of leukocytes from the test mammal or another mammal with said test substrate and with and/or without an agent capable of modulating the transendothelial migration of leukocytes, said agent selected from the group consisting of antibodies to PECAM, antagonists of PECAM activity, recombinant human PECAM-1 (rhPECAM-l), agonists of PECAM activity, and active fragments thereof, for a period of time equal to that of Step C; and E. measuring said PECAM function in terms of transendothelial migration of said leukocytes by examining the incubated material of Steps C and D., comparing between the Step C test incubations, and between the Step D. controls, and comparing the said test incubations to the said controls.
39. The method according to Claims 37 or 38 wherein the biological sample is taken from a mammal in which inflammation is believed to be likely to develop, is suspected to be developing, or is ongoing, and an alteration in PECAM function is suspected.
40. The method according to Claims 37 or 38 wherein the time of incubation of Steps C and D. is a period of time insufficient for transendothelial migration of leukocytes to occur in the absence of PECAM agonists, and wherein said method extends to the detection and/or measurment of the presence and amount of said PECAM agonists.
41. The method according to Claims 37 or 38 wherein said control is prepared by the performance of said method with a material selected from the group consisting of a biological sample taken from a normal mammal that has been incubated with the agent of Step D., a biological sample taken from a normal mammal that has not been incubated with the agent of Step D, and standardized leukocytes with a known alteration in PECAM activity incubated with and/or without the agent of Step D.
42. The method according to Claims 37 or 38 wherein the biological sample taken from the mammal under test is incubated with a biological sample selected from a biological sample taken from a normal mammal, and a biological sample containing abnormal leukocytes known to have an abnormality in PECAM function, and wherein the control of Step D. is prepared with known inhibitors and/or activators of PECAM function incubated with normal leukocytes.
43. The method according to Claims 37 or 38 wherein the biological sample is taken from a mammal in which inflammation and/or a condition known to cause inflammation is present, and said method is performed regularly and periodically to monitor any alterations in PECAM function during the course and intensity of said inflammation and/or said condition in said mammal.
44. The method according to Claims 37 or 38 comprising a method for assessing the likelihood of the development of inflammmation and/or significant transendothelial migration.
45. The method according to Claims 37 or 38 wherein in Step C, the biological sample is incubated with and without a prospective drug or agent believed to be capable of modulating transendothelial migration, as well as with said test substrate, and said method comprises an assay for screening said drug or said agent to determine the efficacy thereof generally and/or to determine such efficacy in the treatment of a particular patient.
46. The method according to Claims 37 or 38 further comprising incubating a drug and/or a therapeutic agent in combination with the said biological sample and the said test substrate for monitoring the effects of said drug and/or said agent on other conditions or agents known to affect said transendothelial migration.
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- 1994-01-12 WO PCT/US1994/000416 patent/WO1994015641A1/en active Search and Examination
- 1994-01-12 AU AU61228/94A patent/AU6122894A/en not_active Abandoned
- 1994-01-12 EP EP94907806A patent/EP0675735A1/en not_active Withdrawn
- 1994-01-12 HU HU9502116A patent/HUT73462A/en unknown
-
1998
- 1998-05-21 AU AU67998/98A patent/AU6799898A/en not_active Abandoned
Also Published As
Publication number | Publication date |
---|---|
EP0675735A1 (en) | 1995-10-11 |
KR960700071A (en) | 1996-01-19 |
WO1994015641A1 (en) | 1994-07-21 |
JPH08505855A (en) | 1996-06-25 |
CA2153776A1 (en) | 1994-07-21 |
HU9502116D0 (en) | 1995-09-28 |
HUT73462A (en) | 1996-08-28 |
AU6799898A (en) | 1998-07-16 |
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