A Non-peptide Functional Antagonist of the CCR1 Chemokine Receptor Is Effective in Rat Heart Transplant Rejection*

Richard HorukDagger §, Carol Clayberger||, Alan M. Krensky**, Zhaohui Wang, Hermann-Josef Gröne**, Christian WeberDagger Dagger , Kim S. C. WeberDagger Dagger , Peter J. Nelson§§, Karen May¶¶, Mary Rosser¶¶, Laura Dunning¶¶, Meina Liang¶¶, Brad Buckman¶¶, Ameen Ghannam¶¶, Howard P. Ng¶¶, Imadul Islam¶¶, John G. Bauman¶¶, Guo-Ping Wei¶¶, Sean Monahan¶¶, Wei Xu¶¶, R. Michael Snider¶¶, Michael M. Morrissey¶¶, Joseph HesselgesserDagger , and H. Daniel PerezDagger

From the Departments of Dagger  Immunology and ¶¶ Discovery Research, Berlex Biosciences, Richmond, California 94806, the Departments of  Cardiothoracic Surgery and || Pediatrics, Stanford University, Stanford, California 94305, the ** Department of Experimental Pathology, German Cancer Research Center, Heidelberg D69111, and the Institutes for Dagger Dagger  Prophylaxe der Kreislaufkrankheiten and §§ Medical Poliklinik, University of Munich, Munich D-80336, Germany

Received for publication, August 16, 2000, and in revised form, October 27, 2000



    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Chemokines like RANTES appear to play a role in organ transplant rejection. Because RANTES is a potent agonist for the chemokine receptor CCR1, we examined whether the CCR1 receptor antagonist BX471 is efficacious in a rat heterotopic heart transplant rejection model. Treatment of animals with BX471 and a subtherapeutic dose of cyclosporin (2.5 mg/kg), which is by itself ineffective in prolonging transplant rejection, is much more efficacious in prolonging transplantation rejection than animals treated with either cyclosporin or BX471 alone. We have examined the mechanism of action of the CCR1 antagonist in in vitro flow assays over microvascular endothelium and have discovered that the antagonist blocks the firm adhesion of monocytes triggered by RANTES on inflamed endothelium. Together, these data demonstrate a significant role for CCR1 in allograft rejection.



    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

The classic signs of acute cellular rejection during organ transplantation include the infiltration of mononuclear cells into the interstitium (1). This cellular infiltrate consists mainly of T lymphocytes, monocytes, and macrophages that are recruited from the circulation into the transplanted tissue by chemotactic molecules known as chemokines. Chemokines belong to a large family of small (8-10 kDa) inducible chemotactic cytokines, which are characterized by a distinctive pattern of four conserved cysteine residues (2). Currently over 40 chemokines have been identified and classified into two major groups, CXC and CC, dependent on the number and spacing of the first two conserved cysteine residues. The CXC class members include interleukin (IL-8),1 melanoma growth stimulatory activity, and neutrophil-activating peptide-2, whereas the CC class includes RANTES, monocyte chemotactic protein-1, and MIP-1alpha (macrophage inflammatory protein-1).

A number of studies have provided evidence for a role for RANTES in organ transplant rejection, particularly of the kidney. In a model of reperfusion injury in the rat, RANTES levels were increased over normal levels and remained high for more than a week, correlating with the peak of infiltrating macrophages (3). RANTES protein was detected in infiltrating mononuclear cells, tubular epithelium, and vascular endothelium of renal allograft biopsy specimens from patients with cyclosporin nephrotoxicity but not in normal kidney (1). A recent study suggests that RANTES may play a role in graft atherosclerosis (4). Increased levels of RANTES (both mRNA and protein) were detected in mononuclear cells, myofibroblasts, and endothelial cells of arteries undergoing accelerated atherosclerosis compared with normal coronary arteries. In another recent renal transplant study, the chemokine receptor antagonist Met-RANTES when given with low doses of cyclosporin significantly reduced renal injury including interstitial inflammation mainly by reducing the number of infiltrating monocytes (5). Mechanistically this appeared to be achieved by blocking the firm adhesion of these cells to the inflamed endothelium. In summary, these studies strongly suggest that RANTES, through activation of specific chemokine receptors on mononuclear cells, may play an important role in allograft rejection.

Based on these studies, there is strong evidence in support of the concept that the chemokine RANTES plays an important role in organ transplant rejection. Because RANTES is a ligand for the chemokine receptors CCR1 and CCR5, these receptors, located on circulating mononuclear cells, may be useful therapeutic targets in transplantation biology. These studies therefore provided the rationale for us to establish a protocol to inhibit RANTES-mediated biological activities by developing highly potent and specific nonpeptide CCR1 receptor antagonists. We have previously identified a number of specific highly potent CCR1 antagonists (6, 7) and describe here the ability of one of these compounds, BX471, in combination with low and high doses of cyclosporin, to significantly prolong the survival time of transplanted heart in a rat model.


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Materials-- Unlabeled chemokines were human unless otherwise indicated (Peprotech, Rocky Hill, NJ). 125I-labeled human chemokines were obtained from PerkinElmer Life Sciences.

Cell Lines-- The human embryonic kidney (HEK) 293 cell line was obtained from the American Type Culture Collection and was maintained in RPMI or Dulbecco's modified Eagle's medium containing 10% heat-inactivated fetal bovine serum, 2 mM L-glutamine, penicillin, and streptomycin in a 5% CO2 atmosphere at 37 °C. For binding assays, the cells were harvested and washed once with phosphate buffered saline. Cell viability was assessed by trypan blue exclusion, and cell number was determined by counting the cells in a hemocytometer.

CCR1 Expression Vector-- Human and rat CCR1 cDNA was obtained as described (8) and inserted into a mammalian expression vector containing the SV40 replication origin, the human cytomegaloviral enhancer with the puromycin-N-acetyltransferase gene (puromycin resistance) and hygromycin B gene (hygromycin resistance) similar to that described previously (9).

CCR1-expressing Cells-- HEK 293 cells stably expressing human or rat CCR1 were grown to confluent monolayers in T225-cm2 flasks as described previously (6). Cells were tested for their ability to bind 125I-labeled MIP-1alpha and RANTES and biological responses by changes in intracellular Ca2+ or by microphysiometry.

Chemokine Binding Studies-- The binding assays were performed either in transfected cells or in peripheral blood mononuclear cells by centrifugation methods as described previously (6). Nonspecific binding was determined in the presence of either 100 nM or 1 µM unlabeled ligand. The binding data were curve fitted with the computer program IGOR (Wavemetrics) to determine the affinity and number of sites.

Preparation of Stock Solution of BX471-- A 25 mg/ml sterile saline solution of BX471 in 40% cyclodextrin (Aldrich) was prepared by dissolving the compound into 40% cyclodextrin in saline. The mixture was shaken followed by the addition of 230 µL of concentrated HCl. The mixture was stirred to dissolve the solute. After dissolution was complete (1 h), the pH of the solution was pH 3.3, and 1 M KOH was added to raise the pH to 4.5. The solution was filtered through a 0.45-µm filter and stored at 4 °C.

Determination of Pharmacokinetic Parameters in Rats-- Male Lewis rats (n = 6) were subcutaneously dosed with BX471 (50 mg/kg, three times per day) in a vehicle of 40% cyclodextrin/saline for 7 days. Blood samples were collected by cardiac puncture in EDTA-containing tubes at various times and analyzed for drug levels as described previously (7).

Heterotopic Heart Transplant Rejection (Lewis or ACI Rats)-- Adult male, specific pathogen-free ACI (RT1a) and Lewis (RT1) rats (Charles River, Boston, MA) weighing 200-250 g were used in these studies. Vascularized cardiac allografts were heterotopically transplanted into the abdomen of recipient rats using a modification (10) of the technique of Ono and Lindsay (11). Abdominal allografts were palpated on a daily basis to assess graft function, and rejection was deemed complete when palpable ventricular contractions ceased.

In Vitro Model System of Monocyte Recruitment on Microvascular Endothelium under Physiological Flow Conditions-- The interaction of monocytes with endothelium was studied in laminar flow assays performed essentially as described (5, 12). Briefly, dermal microvascular endothelial cells grown to confluence in Petri dishes were stimulated with IL-1beta (10 ng/ml) for 12 h followed by pre-incubation with RANTES (10 nM) for 30 min at 37 °C just prior to assay. The plates were assembled as the lower wall in a parallel wall flow chamber and mounted on the stage of an Olympus IMT-2 inverted microscope with × 20 and × 40 phase-contrast objectives. Isolated human blood monocytes were isolated by Nycodenz hyperosmolaric gradient centrifugation as described (12) and resuspended at 5 × 105 cells/ml in assay buffer (HBSS) containing 10 mM HEPES, pH 7.4 and 0.5% human serum albumin. Shortly before the assay, 1 mM Mg2+ and 1 mM Ca2+ was added. The cell suspensions were kept in a heating block at 37 °C during the assay and perfused into the flow chamber at a rate of 1.5 dyn/cm2 for 5 min. For inhibition experiments, monocytes were preincubated with BX471 at different concentrations (0.1-10 µM) or a Me2SO control for 10 min at 37 °C. The number of firmly adherent cells after 5 min was quantitated in multiple fields (at least five per experiment) by analysis of images recorded with a long integration JVC 3CCD video camera and a JVC SR L 900 E video recorder and were expressed as cells/mm2. The type of adhesion analyzed was restricted to primary, i.e. direct interactions of monocytes with endothelium.

Histology, Immunohistochemistry, and Morphometry-- The hearts were removed under deep anesthesia, quickly blotted free of blood, weighed, and then processed as needed for histology and immunohistochemistry. The organs were cut into 1-mm slices and either immersion-fixed in 4% formaldehyde in phosphate-buffered saline (PBS), pH 7.35, (PBS: 99 mM NaH2PO4, 108 mM NaH2PO4 and 248 mM NaCl) for 24 h or fixed in methacarn for 8 h and embedded in paraffin. Light microscopy was performed on 3-µm sections stained by periodic acid-Schiff or Goldner-Elastica.

The ED1 monoclonal antibody (Serotec/Camon) was used on methacarn-fixed paraffin-embedded tissue (3 µm) to stain for rat monocytes/macrophage cells. An alkaline phosphatase anti-alkaline phosphatase detection system was used for visualization (Dako). Controls that omitted the first or second antibody for each section tested were negative.

Histopathologic Rejection Grading System (Score: 1-3)-- Rejection in the allogeneic rat heart was graded according to Billingham (13). Mild acute rejection (score: 1) was characterized by a sparse interstitial mononuclear infiltrate often accentuated in perivascular spaces. Moderate acute rejection (score: 2) was a moderately dense perimyocytic mononuclear infiltrate with some myocyte necrosis. Severe acute rejection (score: 3) featured a dense monocytic infiltrate with focal hemorrhage and replacement of myocytes and with occasional endothelialitis of intramural arteries. The rejection score was calculated for every tissue block, and an average score was calculated from the different blocks for every transplanted heart as rejection processes tended to be focal.

Radioimmunoassay for Cyclosporin-- Cyclo-Trac SP-whole blood radioimmunoassay for cyclosporin kits were purchased from DiaSorin (Stillwater, MN). This method employs a specific monoclonal antibody that measures only cyclosporin. A methanol extraction step was performed for the standards, controls, and samples prior to assay. The methanol extracts were then combined with 125I-labeled cyclosporine tracer. A mixture of mouse monoclonal specific to cyclosporin A and the second antibody (donkey anti-mouse) in a single reagent was added. Following a 1-h incubation, the tubes were centrifuged, decanted, and then counted. The amount of radioactivity remaining in the pellet was inversely proportional to the concentration of cyclosporin found in the sample. Each sample was assayed in duplicate, and the variation of the duplicates were < 10%, otherwise the assay for that sample was repeated.


    RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Because RANTES appears to play an important role in organ transplant rejection, its receptor, CCR1, is a prime therapeutic target. Empirical screening of our available compound libraries to discover potential CCR1 antagonists yielded a number of compounds that were potent human CCR1 antagonists (6). One of these molecules BX471 ((R)-N-[5-chloro-2-[2-[4-[(4-fluorophenyl)methyl]-2-methyl-1-piperazinyl]-2-oxoethoxy]phenyl]urea hydrochloric acid salt) had a Ki of 1 nM for the human receptor (7).

The poor affinity of our CCR1 antagonists for mouse CCR1 (data not shown) precluded mouse models of disease. Thus, we tested for receptor binding of BX471 to rat CCR1 receptors by carrying out displacement binding assays with 125I-MIP-1alpha as the ligand. Scatchard analysis of displacement binding studies with BX471 on rat CCR1 revealed that the affinity of the antagonist was 121 ± 60 nM (Fig. 1), ~100 times less effective for rat CCR1 than for human CCR1. In addition BX471 was able to competitively displace radiolabeled RANTES from rat CCR1 with a similar Ki (data not shown). These data demonstrated that although BX471 was not as potent an inhibitor of rat CCR1 as it was for human CCR1, it could nevertheless compete effectively for binding to the rat receptor at higher concentrations. Additional studies with rat peripheral blood mononuclear cells revealed that BX471 was able to displace radiolabeled MIP-1alpha but not MIP-1beta , demonstrating no cross-reactivity for rat CCR5 (data not shown).



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Fig. 1.   The CCR1 antagonist, BX471, displaces radiolabeled MIP-1alpha from rat CCR1. HEK cells transfected with rat CCR1 were incubated with 125I-MIP-1alpha in the presence of increasing concentrations of BX471. The binding reactions were terminated by centrifugation of cells as described previously (6). Binding shown represents specific binding. Nonspecific binding was 10% of total 125I-MIP-1alpha added. The results shown are from a typical experiment (n = 3). Inset shows the Scatchard plot of the displacement data

We showed that BX471 is a functional antagonist of rat CCR1 by measuring its ability to inhibit the MIP-1alpha -induced transient rise in intracellular Ca2+ concentration in cells expressing rat CCR1. We measured the change in intracellular Ca2+ concentration in response to various concentrations of MIP-1alpha by fluorimetry using the indicator Fura-2. In these experiments, increasing concentrations of MIP-1alpha produced a transient rise in intracellular Ca2+ that was inhibited by preincubating the cells briefly with a 10-fold higher concentration of BX471 (data not shown). Thus, BX471 is a potent functional antagonist of the rat CCR1 receptor, capable of inhibiting calcium transients that are mediators of intracellular cell activation.

Based on the studies summarized above, pharmacokinetic studies with BX471 in rats were carried out. Male Lewis rats were subcutaneously dosed with BX471 (50 mg/kg t.i.d.) in a vehicle of 40% cyclodextrin/saline, and blood samples were withdrawn at various times and analyzed for drug levels as described in the legend to Fig. 2. As shown in Fig. 2, peak plasma levels following the subcutaneous administration of BX471 varied between 12 and 27 µM. Absorption was relatively rapid, with significant plasma levels observed at 15 min post-drug. After 8 h (trough time point), plasma drug levels were ~1-2 µM. The plasma half-life ranged between 2-3 h. Though there did not appear to be any pattern of either enhanced clearance or accumulation of the drug on repeated subcutaneous t.i.d.-dosing regimen (50 mg/kg), a considerable amount of variability was observed in the rate and extent of drug absorption on all of the days measured. These studies showed that subcutaneous dosing of BX471 at 50 mg/kg t.i.d. seemed to give adequate drug levels (steady-state BX471 levels observed between 200 and 500 min of each 8-h dosing regimen were 1 to 2 µM) over a 24-h period and allowed us to test the compound in a rat heterotopic heart transplant model.



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Fig. 2.   Plasma concentrations of BX471 following chronic subcutaneous dosing in rats. Male Lewis rats (n = 6) received BX471 in 40% cyclodextrin s.c. t.i.d. for 7 days. Blood plasma levels of BX471 were measured as described previously (7). Data are the mean ± S.E.

RANTES is a ligand for CCR1 and appears to play a role in directing mononuclear cells into transplanted tissue leading to inflammation and rejection (1, 3-5). Thus, we rationalized that a CCR1 antagonist should have some utility in prolonging the survival of organ transplants. We tested this hypothesis directly by asking whether the CCR1 antagonist BX471 was efficacious in a rat heterotopic heart transplant rejection model. The mean allograft survival of animals given BX471 alone was 8.8 ± 1.2 days compared with 6.8 ± 0.8 days for control animals with ACI grafts in LEW recipients (Fig. 3). Data from the survival times of the animals in both studies were statistically evaluated by log rank analysis. The mean survival times of the animals treated with BX471 were statistically significant at the 0.05 level with respect to the survival times of the control groups and log rank analysis of survival test gave a p = 0.0048 for BX471 versus control. Although the increase in survival time for the BX471-treated animals was modest it was statistically significant and consistent with what we had observed in other studies (data not shown).



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Fig. 3.   Survival plots of heart transplant rejection. Cardiac allografts were heterotopically transplanted into the abdomen of recipient rats (n = 10 per group), and the animals were given: (a) 40% cyclodextrin s.c. t.i.d., (b) 50 mg/kg BX471 in 40% cyclodextrin s.c. t.i.d., (c) cyclosporin (CsA) in olive oil by gavage 10 mg/kg once a day for 4 days, (d) cyclosporin in olive oil by gavage 2.5 mg/kg for the duration of the study, (e) as in (c) above plus 50 mg/kg BX471 in 40% cyclodextrin s.c. t.i.d., (f) as in (d) above plus 50 mg/kg BX471 in 40% cyclodextrin s.c. t.i.d. The transplanted hearts were evaluated daily for signs of rejection over the course of the study.

Cyclosporin is a potent immunosuppressive agent that has been used extensively to prevent rejection in organ transplantation (14). It appears to suppress the immune system by inhibiting T cell activation and proliferation, primarily by blocking the activity of the enzyme calcineurin and by stimulating the production of the immunosuppressant TGF-beta (15, 16). However, despite its efficacy as an immunosuppressive agent its use is associated with a progressive loss of renal function, neurotoxicity, and an increased risk of malignancy (17-19). Thus, a reduction in the amount of cyclosporin required to achieve sufficient immunosuppression would be of considerable benefit in transplantion medicine. For this reason we set out to test whether drug combination studies in which animals were treated with BX471 and a subtherapeutic dose of cyclosporin, 2.5 mg/kg, which is by itself ineffective in prolonging transplant rejection, would be more efficacious in prolonging transplantation than animals treated with either cyclosporin or BX471 alone.

The mean allograft survival of animals given 2.5 mg/kg of cyclosporin was 7.3 ± 0.5 days compared with 17.5 ± 5.9 days for animals on the same protocol that were additionally treated with BX471 (Fig. 3). The mean allograft survival of animals given 10 mg/kg of cyclosporin was 12.9 ± 0.7 days compared with 18.4 ± 5.4 days for animals on the same protocol that were additionally treated with BX471 (Fig. 3). The mean survival times of the animals treated with either 2.5 or 10 mg/kg cyclosporin plus the CCR1 antagonist BX471 were statistically significant from the mean survival times of the animals treated with either 2.5 mg/kg or 10 mg/kg cyclosporin alone with values of p = 0.0009 and p = 0.0148, respectively. Light microscopy and immunohistology of the rat hearts for infiltrating monocytes confirmed these survival data. Three days after transplantation the rejection score (Table I), and the extent of monocytic graft infiltration were significantly reduced by the combined therapy of BX471 and cyclosporin A (Figs. 4 and 5). Based on the data from these studies, BX471 given in combination with cyclosporin resulted in a clear increase in efficacy in heart transplantation compared with cyclosporin alone.


                              
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Table I
Rejection score for transplanted rat hearts
Rejection grade was evaluated using the Billingham grading system (13). Cyclosporin was administered at 2.5 mg/kg. BX471 was administered at 50 mg/kg. N = number of animals, n = number of tissue blocks examined per group. Mean ± S.E. is shown.



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Fig. 4.   Light microscopy of allogeneic heart transplants 3 days after transplantation without (A, B) and with (C, D) BX471. A, in nonimmunosuppressed transplants a dense mononuclear infiltrate was observed. Many cardiomyocytes were vacuolated or necrotic. Interstitial edema was pronounced. B, in the cyclosporin-treated rats the inflammatory cell infiltrate was reduced, though still clearly evident, specifically around venules with focal destruction of cardiomyocytes. C, BX471-treated rats showed a focal mononuclear cell infiltrates that were pronounced with similar morphology as to be observed in nonimmunosuppressed transplants. D, BX471- and cyclosporin-treated animals showed well preserved cardiac morphology with sparse mononuclear cell infiltrates. (A-D, HE-stains; objective × 40).



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Fig. 5.   Immunohistologic stain for ED1-positive monocytes/macrophages in allogeneic heart transplants 3 days after transplantation without (A, B) and with (C, D) BX471. A, in nonimmunosuppressed transplants, many cells of the dense mononuclear cell infiltrate consisted of monocytes/macrophages, which were closely juxtaposed to the cardiomyocytes. B, in the cyclosporin-treated rats, the inflammatory cell infiltrate was focal and was composed primarily of ED1-positive cells. C, in the BX471-treated animals the mononuclear cell infiltrate varied significantly, aside from the dense inflammatory cell infiltrates as shown in Fig. 6, areas with moderately dense monocytic infiltrate around venules were seen. D, combined treatment of BX471 and cyclosporin resulted in a dramatic reduction in monocyte/macrophage infiltration into the allogenic rat hearts. (A-D, APAAP reaction in Methacarn-fixed tissue; objective × 20)

Although we have shown that treatment with the CCR1 antagonist BX471 in combination with cyclosporin synergistically increases transplantation survival in a rat heart model compared with treatment with either drug alone, it remains a formal possibility that these data are because of drug/drug interactions that stabilize the blood plasma cyclosporin levels rather than to the true synergism of the drug combination. To determine whether BX471 had any effect on cyclosporin plasma levels, we designed a pharmacokinetic study to assess this. In this study we examined the effect of BX471 on the blood concentration of cyclosporin in the rat after a single oral dose (2.5 mg/kg) of cyclosporin followed by t.i.d. doses of BX471 at 50 mg/kg administered subcutaneously. We used a radioimmunoassay to measure whole blood cyclosporin levels in animals treated with cyclosporin in the presence and absence of BX471. Visual inspection of the time-concentration curves suggested a slight prolongation of elimination half-life of rats treated with BX471 (Fig. 6). However, statistical analysis of the paired groups indicated that there was no significant difference between the two parameters calculated (p-value for AUC was 0.224 and for the t1/2 was 0.317) and thus we can rule out drug/drug interactions as the basis for the extended survivability of the transplanted rat hearts.



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Fig. 6.   Effect of BX471 on cyclosporin levels in rat whole blood. Cyclosporin levels were measured in two groups of six Lewis cannulated rats. The first group received a single oral dose of 2.5 mg/kg cyclosporin diluted in olive oil. The second group received a single oral dose of the same cyclosporin solution followed by subcutaneous injection of BX471 t.i.d. at 50 mg/kg. Whole blood was collected using EDTA as anticoagulant at 0, 1, 2, 4, 6, 8, 12, and 24 h post-dosing. The cyclosporin concentration in these samples were analyzed by the Cyclo-Trac radioimmunoassay in rat whole blood as described under "Experimental Procedures."

To gain insight into the potential mechanisms of action by which the CCR1 antagonist BX471 prolonged the rejection of transplanted rat hearts, we asked whether it could inhibit the firm arrest and diapedesis of monocytes on microvascular endothelium. It has been previously shown that perfused monocytic cells show increased attachment to IL-1beta -activated DMVEC following preincubation with exogenous RANTES for 30 min (5). Treatment of isolated blood monocytes with increasing concentrations of BX471 (0.1-10 µM) showed a dose-dependent inhibition of RANTES-mediated and shear-resistant adhesion on IL-1beta -activated microvascular endothelium in shear flow (Fig. 7A). Consistently, the percentage of monocytes that were found to undergo or maintain rolling interactions was dose dependently increased by pretreatment with BX471, thus serving as an inverse measure for arrest (Fig. 7B). BX471 also inhibited the RANTES-mediated adhesion of T lymphocytes to activated endothelium (data not shown). These data thus strongly suggest that the CCR1 antagonist is a potent antagonist that can specifically inhibit mononuclear cell adhesion to activated endothelium. It is unlikely that the CCR1 antagonist is simply inactivating the cells because e.g. activated T lymphocytes and monocytes treated with the CCR1 antagonist are still able to respond to MIP-1beta in calcium flux experiments (data not shown) presumably by binding and activation of CCR5.



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Fig. 7.   Inhibition of in vitro adhesion of monocytes to activated endothelium by BX471. DMVEC activated with IL-1beta and preincubated with RANTES were inserted in a flow apparatus, and monocytes were perfused at a constant shear of 1.5 dyn/cm2 as described under "Experimental Procedures" and in a previous communication (5). For inhibition assays, monocytes were preincubated with BX471 at indicated concentrations or a Me2SO control for 10 min at 37 °C. A, after 5 min of accumulation, the number of adherent cells was analyzed. Data represent the mean ± S.D. of three individual experiments. B, as an inverse measure of adhesion, the number of monocytes rolling at low shear was assessed in the last 30-s interval of the 5-min period and expressed as the percentage of total interactions within the field. After 5 min of accumulation, the number of adherent cells was quantitated and expressed as cells/mm2. Data represent the mean ± S.D. of three experiments.

The dose-responsive inhibition of monocyte arrest on activated endothelium by BX471 observed here is in line with our previous findings that the CCR1 antagonist BX471 is able to dose responsively inhibit the RANTES- or MIP-1alpha -induced up-regulation of the beta -2 integrin, CD11b (7). A number of studies have revealed that RANTES treatment of monocytes results in an increased expression of CD11b and an up-regulation of integrin avidity for their endothelial immunoglobulin family ligands (12, 20, 21). This appears to enhance the ability of monocytes to bind to endothelial cells, which can be partially blocked with antibodies to integrins (20). These studies suggest that modulation of integrin expression and avidity by chemokines may facilitate the tissue trafficking of monocytes during inflammation.

Two recent studies have demonstrated the important role of CCR1 in organ transplantation. In the first, the efficacy of Met-RANTES, a RANTES receptor antagonist that is thought to work in part through a blockade of CCR1 (5) was examined in a renal transplantation study. Following the transplantation of Fisher RT1lvl rat kidneys into Lewis RT1 rats, the animals treated with Met-RANTES showed a significant reduction in vascular and tubular damage relative to untreated animals. In a more severe rejection model, where Brown-Norway RT1 rat kidneys were transplanted into Lewis RT1 rats, Met-RANTES was found to augment treatment with low dose cyclosporin A to significantly reduce all aspects of renal injury. In a second study, the importance of CCR1 was examined in heart transplantation models in mice carrying a targeted deletion of CCR1(22). In four separate models of allograft survival, a significant prolongation was seen in CCR1(-/--) recipients. In one model, levels of cyclosporin that had marginal effects in CCR1(+/+) mice resulted in permanent allograft acceptance in CCR1(-/-) recipients.

In this study we have shown that inhibition of CCR1 by the receptor-specific antagonist BX471 led to a significant prolongation of cardiac allograft survival (Fig. 3). Furthermore, when the CCR1 antagonist was given in combination with a subnephrotoxic dose of cyclosporin, it markedly enhanced the survival of the transplanted organs (Fig. 3). It appears that the mechanism of action of the CCR1 receptor antagonist stems at least in part from its ability to inhibit the adhesion of activated immune cells to inflamed endothelium (Fig. 7). This may be because of blocking the up-regulation of integrin expression and adhesiveness that leads to imminent monocyte arrest. The ability of BX471 to enhance the effects of low dose cyclosporin treatment has clinical relevance given the dose-dependent nephrotoxicity associated with cyclosporin therapy. A reduction in the amount of cyclosporin required to achieve sufficient immunosuppression could be of considerable benefit not only in transplantation but also in the treatment of other chronic diseases such as psoriasis, allergy, arthritis, and other autoimmune diseases.

A significant clinical advantage of BX471 may lie in its effects directly following transplantation. Early injury to the endothelium, even when it is not lethal, can have serious consequences for survival of the graft. Even moderate damage can lead to the loss of the endothelial function required for adequate perfusion of the graft and result in the enhanced production of proinflammatory cytokines. By limiting immune effector cell emigration and the ensuing endothelial damage during transplantation BX471 may lower the inclination toward the development of more chronic transplant dysfunction and reduce the requirement for immune suppressants such as cyclosporin. These results strongly suggest that therapies directed toward the blockade of chemokine receptors will have a positive effect on solid allograft survival.


    ACKNOWLEDGEMENTS

We thank Babu Subramanyan and Elena Ho for the cyclosporin determinations and Ron Vergona for the BX471 determinations.


    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ To whom correspondence should be addressed: Berlex Biosciences, Dept. of Immunology, 15049 San Pablo Ave., Richmond, CA 94806. E-mail: Horuk@pacbell.net.

Published, JBC Papers in Press, October 27, 2000, DOI 10.1074/jbc.M007457200


    ABBREVIATIONS

The abbreviations used are: IL-8, interleukin-8; RANTES, regulated on activation normal T cell expressed; HEK, human embryonic kidney cells; HBSS, Hanks' buffered saline solution; t.i.d., three times a day; MIP, macrophage inflammatory protein; s.c., subcutaneously.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES


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