Hongsi Jiang

Tacrolimus and cyclosporine differ in their capacity to overcome ongoing allograft rejection as a result of their differential abilities to inhibit interleukin-10 production.

Background. Accumulated evidence from clinical transplantation has suggested that tacrolimus-based treatment can reverse ongoing allograft rejection in patients treated with cyclosporine (CsA)-based immunosuppression, even when a high dose of antirejection rescue therapy has failed. This evidence prompted us to investigate whether these two compounds, which share an in vitro mechanism, would differ in their abilities to regulate in situ cellular and molecular events during ongoing allograft rejection. Methods. The equivalent effective doses of tacrolimus (3.2 mg/kg/day) and CsA (10 mg/kg/day), when administered orally to Lewis rats for 10 days (day 0–9), were predetermined and defined as the ability of the drug to induce a similar survival of Brown Norway rat heart allografts with an equal suppression of intragraft interleukin (IL)-2 mRNA expression. To investigate the ability of each drug to rescue ongoing allograft rejection, Lewis recipients of Brown Norway rat heart grafts were left untreated for the first 5 days after transplantation. Tacrolimus or CsA was then administered at the equivalent effective dose for 10 days (days 5–14). Heart grafts and blood samples, harvested on days 3, 5, 7, and 10, were analyzed by reverse transcriptase-polymerase chain reaction, real-time quantitative polymerase chain reaction, ELISA, and immunohistology. Results. Ongoing allograft rejection was found to be rescued by tacrolimus but not by CsA at the equivalent dose (median survival time: untreated, 6 days; tacrolimus, 18 days; and CsA, 7 days). A significant suppression of local intragraft IL-10 mRNA expression and serum protein production along with a dramatic down-regulation of functional CD8+ T and NKR-P1a+ natural killer cell local infiltration by means of decreased of cytotoxic factor release, including granzyme B and perforin 1, was found to be associated with tacrolimus but not CsA treatment. However, both drugs inhibited other immune cells (CD4+ T cell, ED2+ macrophage) and cytokines (IL-1&bgr;, IL-2, IL-4, IL-6, IL-12, interferon-&ggr;, transforming growth factor-&bgr;, and tumor necrosis factor-&agr;) at almost the same levels. The inability of CsA to overcome ongoing allograft rejection could be rescued by cotreating recipients with neutralizing anti-IL-10 antibody on day 5 and day 6 after transplantation: anti-IL-10 antibody alone did not show such an effect. Conclusions. Inhibition of IL-10 production is a critical factor in the ability of tacrolimus to reverse ongoing allograft rejection.

Microarray-based gene expression profiles of allograft rejection and immunosuppression in the rat heart transplantation model.

Background. Gene expression profiling has the potential to produce new insights into complex biologic systems. To test the value of complement DNA arrays in identifying pathways involved in organ transplant rejection, we examined the gene expression profiles of rat heart allografts from recipients treated with or without immunosuppression to prevent acute allograft rejection. Methods. Heterotopic heart transplantation was performed using ACI or Lewis donors and Lewis recipients. Recipients were treated with tacrolimus (Tac) or cyclosporine (CsA) at the equivalent effective doses, and graft hearts were harvested on days 3, 5, and 7. A commercial microarray was used to measure gene expression levels of 588 genes in day 5 grafts. Selected genes were analyzed by reverse transcriptase-polymerase chain reaction. Results. The expression levels of 118 genes were perturbed in the untreated allograft in comparison with the isograft control, of which 77 genes were categorized as candidate genes for Tac- or CsA-mediated immunosuppression or both, and 41 as genes associated with other pathways. Among the 77 candidate genes, 55 genes shared the same response to suppression by both drugs, including inducible nitric oxide synthase, interferon-&ggr;, and interferon regulatory factor 1. Drug-specific effects were observed in 22 genes: Fourteen genes were exclusively reversed by Tac and eight by CsA. Conclusions. Gene expression profiling reveals a large variety of genes affected during acute rejection, indicating that multiple metabolic pathways, including immune and nonimmune responses, are involved in the local graft rejection events. The differences and similarities of the gene expression profiles relative to the two immunosuppressants may provide more detailed therapeutic approaches for optimal immunosuppression.

Deletion of DOCK2, a regulator of the actin cytoskeleton in lymphocytes, suppresses cardiac allograft rejection

Allograft rejection is induced by graft tissue infiltration of alloreactive T cells that are activated mainly in secondary lymphoid organs of the host. DOCK2 plays a critical role in lymphocyte homing and immunological synapse formation by regulating the actin cytoskeleton, yet its role in the in vivo immune response remains unknown. We show here that DOCK2 deficiency enables long-term survival of cardiac allografts across a complete mismatch of the major histocompatibility complex molecules. In DOCK2-deficient mice, alloreactivity and allocytotoxicity were suppressed significantly even after in vivo priming with alloantigens, which resulted in reduced intragraft expression of effector molecules, such as interferon-γ, granzyme B, and perforin. This is mediated, at least in part, by preventing potentially alloreactive T cells from recruiting into secondary lymphoid organs. In addition, we found that DOCK2 is critical for CD28-mediated Rac activation and is required for the full activation of alloreactive T cells. Although DOCK2-deficient, alloreactive T cells were activated in vitro in the presence of exogenous interleukin-2, these T cells, when transferred adoptively, failed to infiltrate into the allografts that were transplanted into RAG1-deficient mice. Thus, DOCK2 deficiency attenuates allograft rejection by simultaneously suppressing multiple and key processes. We propose that DOCK2 could be a novel molecular target for controlling transplant rejection.

Tacrolimus versus cyclosporin A: a comparative study on rat renal allograft survival

Although tacrolimus has been studied in a wide variety of experimental animal models, we are the first group to systematically study the effect of tacrolimus on rat renal allograft survival, as primary therapy and as anti‐rejection therapy, in comparison with cyclosporin A (CyA). Renal grafts were transplanted from BN to LEW rats. Tacrolimus and CyA were administrated orally from day 0 for 50 days as primary therapy after grafting. Allografts were rejected after a median survival time (MST) of 8 days. Both tacrolimus und CyA significantly prolonged renal allograft survival, in a dose‐dependent manner compared with the allograft controls. The most effective dose was 3.2 mg/kg, per day for tacrolimus, and 10 mg/kg per day for CyA. There was no significant difference in renal function between the group treated with the most effective dose of tacrolimus and the CyA‐treated group. The percentage of detectable serum IL‐2 level was 45 % in the allograft control group, but was undetectable in groups treated with the most effective dose of tacrolimus or CyA at days 3 and 6 after grafting. On the other hand, no side effects were noted in recipient rats by daily inspection, body weight change, and histological studies, although minimal tubular vacuolation was encountered in the group treated with CyA 32 mg/kg per day. In addition, the most effective doses of tacrolimus and CyA were studied as anti‐rejection therapy. All of the 5 recipients treated with tacrolimus from days 2–14, and 3 of the 5 treated from days 4–16 after grafting, survived for more than 50 days. However, the MST was 19 days for recipients treated with CyA from days 2–14, and 13 days for those treated from days 4–16 after grafting. In summary, tacrolimus as primary therapy induced rat renal allograft survival with renal function and side effects comparable with those of CyA. Interestingly, when both agents were used as anti‐rejection therapy, tacrolimus, but not CyA, could significantly overcome ongoing renal allograft rejection in the rat.

A blocking anti-CD28-specific antibody induces long-term heart allograft survival by suppression of the PKC theta-JNK signal pathway.

This study investigated the effects of a blocking anti-CD28 antibody (Anti-CD28-PV1-IgG3) in vitro and in vivo. Anti-CD28-PV1-IgG3, a hamster-mouse chimeric antibody against murine CD28, which does not provide CD28-positive signaling during TCR-driven T cell activation, enabled long-term survival of heart allografts across a complete mismatch of the MHC in rats. Among the T cell signaling proteins tested in the spleens from recipients, we found that recipients treated with anti-CD28-PV1-IgG3 exhibited suppression of alloantigen-initiated proximal TCR signaling events, including Lck, Zap70, Vav, and PI3K expression, and their PKC&thgr;- and JNK-regulated expression/activation. This leads to attenuation of intragraft T cell infiltration and expression of T cell effector molecules. These results indicate that targeting the CD28 receptor with a blocking antibody leads to long-term allograft survival by reducing activation of alloantigen-mediated key signaling events in T cells that might be crucial for full T cell activation.

Microarray gene expression profiling of chronic allograft nephropathy in the rat kidney transplant model

Whole genome gene expression profiles were correlated with renal function and histology in a well-established animal model of chronic allograft nephropathy (CAN). Kidneys of F344 rats were transplanted into LEW recipients treated with a brief dose of FK506 (BFK). Blood and urine samples were collected weekly. Kidney grafts were harvested at an early (day 6) or late (days 30-90) phase after transplantation. BFK kidney grafts showed remarkable changes in function, histology, and gene expression profiles when compared to the isograft controls. In the early phase, renal function and histology were barely affected, yet the expression levels of 225 genes were significantly changed, reflecting both immune and non-immune pathways. In the late phase, however, 826 genes were affected in the BFK kidney grafts, including genes in the pathways of extracellular matrix and cell adhesion. Of these genes, 214 appear to be key factors for development of CAN, since they were affected at both early and late phases, including genes involved in the immune response, the inflammatory response, apoptosis, and metabolism. Kinetic studies with gene expression profiling can identify genes involved in the progressive development of chronic allograft rejection, leading to more detailed therapeutic approaches or useful biomarkers in clinical transplantation.

Mechanism analysis of long-term graft survival by monocarboxylate transporter-1 inhibition.

Background. Monocarboxylate transporter (MCT)-1, a member of a family of molecules, transports monocarboxylates such as lactate. Inhibiting MCT-1 leads to long-term graft survival in rodent heart transplantation and induces tolerance. We evaluated an MCT-1 inhibitor, AS2495674, in a rat heart transplant model and analyzed its underlying mechanism. Methods. AS2495674 was tested on rat lymphocytes to determine its effect on lactate accumulation, proliferation, and immunoglobulin production. The effect of AS2495674 on graft survival was tested on the Brown Norway to Lewis rat strain combination with a second heart transplantation to test donor-specific suppression. Histology and ex vivo analyses were done to examine the AS2495674 effects on the immune response. Results. In vitro, AS2495674 resulted in lactate accumulation, inhibited lymphocyte proliferation, and prevented immunoglobulin production. AS2495674 induced long-term allograft survival with little evidence of chronic rejection and induced donor-specific suppression. Evaluation of the allograft and peripheral T lymphocytes from the AS2495674 group compared with that of vehicle showed (1) decreased donor-specific T lymphocyte response, (2) more forkhead box P3+ (Foxp3+) and CD45RA+ cells in the allograft, (3) higher gene expression of chemokines and chemokine receptors in the allograft, and (4) preferential inhibition of Foxp3− cells with little or no effect on Foxp3+ cells. Conclusions. AS2495674 prevents acute rejection, reduces features of chronic rejection, and induces tolerance. Our data suggest that the mechanism of AS2495674 involves generating a tolerogenic graft environment by preferentially targeting T effector cells while sparing the generation of T regulatory cells.

Absence of Activation-induced Cytidine Deaminase, a Regulator of Class Switch Recombination and Hypermutation in B Cells, Suppresses Aorta Allograft Vasculopathy in Mice.

Background Antibody-mediated rejection is caused in part by increasing circulation/production of donor-specific antibody (DSA). Activation-induced cytidine deaminase (AID) is a key regulator of class switch recombination and somatic hypermutation of immunoglobulin in B cells, yet its role in antibody-mediated transplant rejection remains unclear. We show here that AID deficiency in mice enables suppression of allograft vasculopathy (AV) after aorta transplantation, a DSA-mediated process. Methods Splenocytes from C57BL/6 J (B6) AID−/− mice were used for determining in vitro proliferation responses, alloreactivity, cell surface marker expression, and antibody production. BALB/c mouse aortas were transplanted into B6 AID−/− mice with or without FK506 treatment. Blood and aorta grafts were harvested on day 30 after transplantation and were subjected to DSA, histological, and immunohistological analyses. Results The AID−/− splenocytes were comparable to wild type splenocytes in proliferation responses, alloreactivity, and expression of cell surface markers in vitro. However, they completely failed to produce immunoglobulin G, although they were not impaired in immunoglobulin M production relative to controls. Furthermore, BALB/c aorta grafts from B6 AID−/− recipient mice on day 30 after transplantation showed reduced signs of AV compared to the grafts from B6 wild type recipient mice which had severe vascular intimal hyperplasia, interstitial fibrosis, and inflammation. Treatment with FK506 produced a synergistic effect in the grafts from AID−/− recipients with further reduction of intimal hyperplasia and fibrosis scores. Conclusions The AID deficiency inhibits DSA-mediated AV after aorta transplantation in mice. We propose that AID could be a novel molecular target for controlling antibody-mediated rejection in organ transplantation.