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Evaluation of recombinant human soluble dimeric tumor necrosis factor receptor for prevention of OKT3-associated acute clinical syndrome

Tumor necrosis factor alpha (TNFa) has been shown to be the primary cytokine responsible for the OKT3-induced acute clinical syndrome (OKT3-ACS). Recombinant human soluble tumor necrosis factor receptor (TNFR:Fc) is a dimer of the p80 TNF receptor, which binds both TNFa and lymphotoxin (LT). Renal allograft recipients undergoing OKT3 therapy for steroid-resistant rejection were randomized to receive OKT3 alone or in combination with TNFR:Fc to determine its safety and efficacy in decreasing the severity of OKT3-ACS and in restoring renal function. Six of 12 patients were given TNFR:Fc prior to each of the first two injections of OKT3. All patients were monitored for manifestations of OKT3-ACS and changes in renal function. In addition, serial serum samples were assayed for TNFa and TNFR:Fc levels (ELISA) and TNFa bioactivity (L929). No adverse side effects were identified in patients receiving TNFR:Fc. Patients treated with TNFR:Fc had significantly fewer symptoms by day 2 of OKT3, and had a lower overall incidence of chills and arthralgias. Renal dysfunction reversed within 24 hr in the TNFR:Fc-treated group in contrast to the 48-72-hr delay in the control group. Antigenic TNFa levels increased in the control group from < 10 pg/ml pre OKT3 to a mean peak level of 30 +/- 13 pg/ml on day 1 and decreased to pretreatment levels by day 2. TNFR:Fc-treated patients had a mean peak TNFa level of 235 +/- 135 pg/ml, suggesting a carrier effect of TNFR:Fc. In contrast, bioactivity was barely detectable (mean 20 +/- 14 pg/ml) in the day 1 samples from TNFR:Fc-treated patients, whereas significant bioactivity (peak mean 60 +/- 35 pg/ml) was detected in sera from control patients. TNF receptor levels reached 600 ng/ml in treated patients and remained elevated for up to 18 days confirming the long half-life of TNFR:Fc. This phase 1 trial demonstrates that TNFR:Fc is well tolerated and may limit the severity of OKT3-ACS. The most significant observation was a more rapid improvement in renal function in the TNFR:Fc-treated patients. The absence of TNFa bioactivity indicates that TNFR:Fc functions as a TNF antagonist. Further evaluation of higher doses of TNFR:Fc in OKT3-treated patients is currently in progress.

Inhibition of the effects of TNF in renal allograft recipients using recombinant human dimeric tumor necrosis factor receptors

Tumor necrosis factor alpha (TNFa) and lymphotoxin (LT) or TNF beta are closely linked cytokines produced by macrophages and activated T lymphocytes, which play important regulatory roles in the immune response to allografts. They have also been implicated as mediators of the adverse reactions observed during OKT3 therapy. Therefore, anti-TNF agents could be useful both for immunosuppression and for limiting the systemic response observed in patients receiving OKT3. Recombinant TNFR:Fc is a fusion protein that binds TNFa and LT, thereby neutralizing their effects in vitro. The present study investigates the potential clinical application of TNFR:Fc in a nonhuman primate renal allograft model. Cynomolgus renal allograft recipients were treated with TNFR:Fc induction therapy alone or in combination with subtherapeutic doses of cyclosporine. Control animals received no immunosuppression or subtherapeutic cyclosporine. TNFR:Fc, administered as the only immunosuppressive agent, successfully prolonged renal allograft survival in the majority of treated animals. The prolongation of allograft survival was even more impressive when TNFR:Fc was combined with subtherapeutic doses of cyclosporine. Onset of rejection was significantly delayed as well in the TNFR:Fc treated groups. No adverse side effects were observed in any of the TNFR:Fc treated animals. Precursor cytotoxic T cells were detected in peripheral blood samples of treated recipients but the level of effector CTLs in vivo was below the threshold of detection. These results demonstrate that TNFR:Fc can be safely administered and is effective in prolonging renal allograft survival and in delaying the onset of rejection when administered alone or in combination with cyclosporine.

Long-term islet allograft function in the absence of chronic immunosuppression : A case report of a nonhuman primate previously made tolerant to a renal allograft from the same donor

UNLABELLED Development of mixed chimerism by donor bone marrow transplantation (DBMT) has led to long-term tolerance of solid organ allografts in nonhuman primates. As an initial attempt to extend this approach to cellular transplant, islet transplant from the same donor was attempted in the recipient previously made tolerant to a kidney allograft. METHODS After the conditioning with ATG, total body irradiation, thymic irradiation, and splenectomy, DBMT was performed followed by 4 weeks of cyclosporine. Kidney transplantation and native nephrectomies were subsequently performed on day 89. After 2.8 years of DBMT, diabetes was induced by streptozocin (STZ) and islets from bone marrow and kidney donor were transplanted without immunosuppression. RESULTS After DBMT, the recipient developed chimerism and no evidence of kidney rejection for more than 1000 days. STZ induced diabetes was reversed after the islet transplantation. Islet biopsies demonstrated insulin staining without rejection. Although the recipient became diabetic 300 days after islet transplantation, viable transplanted islets were found in the liver and under the kidney capsule without any evidence of rejection. CONCLUSION Tolerance with a nonmyeloablative conditioning can allow successful pancreatic islet transplantation without immunosuppression. Because no histological evidence of rejection was identified, recurrent diabetes is presumed to be inadequate islet mass.

In vivo generation of C4d, Bb, iC3b, and SC5b-9 after OKT3 administration in kidney and lung transplant recipients.

BACKGROUND OKT3 monoclonal antibody therapy results in an acute clinical syndrome (ACS) associated with the release of tumor necrosis factor and sequestration of neutrophils in the lungs. We have previously shown that inhibition of tumor necrosis factor does not completely eliminate OKT3-ACS, suggesting that other factors also contribute to the ACS. The current studies analyzed complement activation in vivo during the first hour after OKT3 administration. METHODS Renal (n=4) and lung (n=4) transplant recipients received OKT3 as treatment for rejection and induction therapy, respectively. Complement activation products C4d, Bb, iC3b, and SC5b-9 were measured by ELISA. Hemodynamic parameters were also monitored in the lung transplant recipients. Neutrophil expression of CD11a, CD11b, and CD18 was monitored by flow cytometry. Controls included patients receiving methylprednisolone for rejection (n=4), two adults with adult respiratory distress syndrome who received extracorporeal membrane oxygenation, and normal volunteers (n=5). P values less than 0.05 (*) were considered significant. RESULTS Increases in the plasma levels of C4d, Bb, iC3b, and SC5b-9 were observed in seven of eight patients after OKT3 administration. Mean values (n=8) at 0, 15, and 60 min (in microg/ml) were as follows-C4d: 1.865, 2.644*, and 2.607*; Bb: 0.245, 0.411, and 0.385; iC3b: 10.881, 17.242*, and 15.145*; and SC5b-9: 0.232, 0.269, and 0.302*. An increase in CD11b and CD18 and a decrease of CD11a on neutrophils in parallel with complement activation was observed. In lung transplant recipients, C3 activation correlated with increases in mean pulmonary and central venous pressures (P<0.05). As compared with extracorporeal membrane oxygenation, which activated classical and alternative pathways, OKT3 predominantly activated complement by the classical pathway. Methylprednisolone pulses did not activate complement. CONCLUSIONS Complement activation is an early event after OKT3 administration and is associated with the increased expression of adhesion molecules on neutrophils and with pulmonary hemodynamic changes. Effective therapeutic approaches to the control of early monoclonal antibody side effects may require measures that limit complement activation in addition to reducing cytokine activity.

The effects of OKT4A monoclonal antibody on cellular immunity of nonhuman primate renal allograft recipients.

Significant differences in cellular responses were found among allograft recipients treated with various OKT4A mAb protocols. Recipients of multiple infusion low-dose and 2-bolus OKT4A immunosuppressive regimens regularly showed potent donor-specific cytotoxic CD8+ and CD4+ intragraft T cells and donor-reactive PBMC in MLC tests. In contrast, PBMC isolated from recipients of high-dose OKT4A therapy generally showed very weak or no response to donor-antigens during the later posttransplant periods. Furthermore, an absence of IL2-responsive intragraft cells was found to correlate with stable graft function in these recipients. We conclude that OKT4A mAb, in high doses, can block allosensitization and induce donor-specific nonresponsiveness in vivo. An OKT4A-based therapy, therefore, may have the potential of inducing long-lasting donor-specific immunosuppression, or even tolerance.

A study of tolerance in a concordant xenograft model

Antibody-mediated rejection appears to constitute the major difference between concordant xenografts and allografts in nonhuman primates. Consistent with its known effect on antibody responses, 5-7 addition of DSG to the conditioning regimen has extended concordant primate xenograft survival for up to 6 months after discontinuation of conventional immunosuppression. In contrast to our observations in recipients of renal allografts, donor-specific skin graft rejection can occur and even in long-term recipients may induce rejection of a previously accepted renal xenograft.

Monitoring antidonor alloantibodies as a predictive assay for renal allograft tolerance/long-term observations in nonhuman primates.

Background. In an effort to define reliable assays that might predict postimmunosuppressant-withdrawal development of chronic rejection (CR), despite conditioning for tolerance induction, we evaluated various immunological responses in nonhuman primate renal allograft recipients. Methods. Fourteen Cynomolgus monkeys received low dose total body irradiation, thymic irradiation, antithymocyte globulin, and peritransplant CD154 blockade, followed by a one-month course of cyclosporine. Recipients underwent major histocompatibility complex mismatched kidney transplantation with donor bone marrow infusion (Group A, n=8), without donor cell infusion (Group B, n=2), or with donor splenocyte infusion (Group C, n=4). Results. All Group A recipients developed mixed chimerism and four of them survived long-term without rejection. The remaining four rejected their kidney allografts either chronically or acutely. All recipients in Groups B and C failed to develop chimerism and rejected their allografts. Among various in vitro assays, detection of anti-donor alloantibody (ADA) by flow cytometry (FCM) was the most relevant to long-term outcome. All five recipients that developed both anti-T cell and B cell IgG ADA in Groups A, B and C, developed histological evidence of CR within 200 days of the appearance of ADA. One of two recipients that developed only anti-B cell IgG ADA eventually developed CR over two years following discontinuation of immunosuppression and 1.5 years after ADA development. Another recipient with very low anti-B cell ADA has never developed CR. Conclusion. ADA monitoring with FCM assay appears to be useful in predicting the failure of tolerance prior to the development of functional or histologic abnormalities of the renal allograft.

Biological effects and fate of a soluble, dimeric, 80-kDa tumor necrosis factor receptor in renal transplant recipients who receive OKT3 therapy.

A preliminary clinical study of renal allograft recipients revealed that a dimeric form of the human 80 kDa soluble receptor (sTNFR:Fc) for tumor necrosis factor (TNF) is well tolerated and attenuates the OKT3-induced acute clinical syndrome. The current study determined the in vivo biological effects and fate of sTNFR:Fc in these patients. Serial assessment of both antigenic and biological activities of circulating TNF and sTNFR:Fc have led to the following observations. (1) Although control patients typically responded to the first OKT3 injection with a rapid increase of biologically active TNFalpha, patients on sTNFR:Fc therapy had markedly higher serum TNFalpha antigenic levels, but no detectable bioactivity. Thus, sTNFR:Fc functioned as a potent antagonist, despite its cytokine-carrier effect. (2) Peak sTNFR:Fc levels averaging 800 and 2500 ng/ml were routinely achieved in vivo, using the low-dose (0.05 mg/kg) and high-dose (0.15 mg/kg) protocols. (3) The half-life of circulating sTNFR:Fc was estimated to be approximately 4.4 days, and levels of p80 receptors in treated patients remained significantly above those in control patients for at least 20 days. (4) In vitro blocking studies demonstrated that circulating sTNFR:Fc remained biologically active for 2 weeks. These results demonstrate that under current protocols, significant serum levels of sTNFR:Fc, capable of effectively neutralizing TNF activity over prolonged periods, can be achieved. The persistent OKT3 side effects observed, despite sTNFR:Fc therapy, are therefore likely to be caused by factors other than TNF.

Contributions of Direct and Indirect Alloresponses to Chronic Rejection of Kidney Allografts in Nonhuman Primates

The relative contribution of direct and indirect allorecognition pathways to chronic rejection of allogeneic organ transplants in primates remains unclear. In this study, we evaluated T and B cell alloresponses in cynomolgus monkeys that had received combined kidney/bone marrow allografts and myeloablative immunosuppressive treatments. We measured donor-specific direct and indirect T cell responses and alloantibody production in monkeys (n = 5) that did not reject their transplant acutely but developed chronic humoral rejection (CHR) and in tolerant recipients (n = 4) that never displayed signs of CHR. All CHR recipients exhibited high levels of anti-donor Abs and mounted potent direct T cell alloresponses in vitro. Such direct alloreactivity could be detected for more than 1 y after transplantation. In contrast, only two of five monkeys with CHR had a detectable indirect alloresponse. No indirect alloresponse by T cells and no alloantibody responses were found in any of the tolerant monkeys. Only one of four tolerant monkeys displayed a direct T cell alloresponse. These observations indicate that direct T cell alloresponses can be sustained for prolonged periods posttransplantation and result in alloantibody production and chronic rejection of kidney transplants, even in the absence of detectable indirect alloreactivity.

Monoclonal antibodies in organ transplantation.

Monoclonal antibody (mAb) technology has made possible the production of designer proteins, specifically reactive with almost any conceivable biological molecule. Using these reagents, the surface molecules on cells crucial for allograft rejection have been identified and described in detail. These structures can now be selectively targeted by mAb-based therapy in order to prevent rejection. For instance, the CD3 molecule, expressed on all mature T lymphocytes, triggers T cell activation, a key event in rejection. OKT3, an anti-CD3 mAb, disrupts T cell function and is now the agent of choice for the treatment of severe rejection episodes. MAbs targeting other T cell molecules are currently being investigated. Some of the most promising, the anti-CD4, anti-ICAM-1, and anti-interleukin 2 receptor mAbs, have already induced donor-specific tolerance in rodent models. These hosts accept permanently a genetically incompatible graft after only a limited period of mAb therapy. Interestingly, anti-ICAM-1 also diminishes the ischemic injury of preservation. The development of these new molecular agents, effectively directed to specific cellular targets, will likely play an increasingly important role in future clinical protocols, and perhaps finally provide a means to achieve long-term tolerance in human allograft recipients.