Single dose anti-CD4 monoclonal antibody for induction of tolerance to cardiac allograft in high- and low-responder rat strain combinations

A highly reproducible cervical cuff technique for rat-to-mouse heterotopic heart xenotransplantation

Xenotransplantation is an effective way to solve the problem of donor shortage in clinical transplantation. However, clinical use of xenotransplantation is currently limited due to immunological challenges such as acute vascular rejection and cell-mediated rejection. To finally surpass this immunological barrier, more preclinical research is needed into the molecular mechanisms of rejection and the possible effects of new immunosuppressants. Our aim was to create a refined, highly reproducible protocol to establish the most suitable rat-to-mouse heterotopic heart transplantation model using the cuff technique.

Immunogenicity and functional evaluation of iPSC-derived organs for transplantation

Whether physiologically induced pluripotent stem cell (iPSC)-derived organs are immunogenic and can be used for transplantation is unclear. Here, we generated iPSC-derived skin, islet, and heart representing three germ layers of the body through 4n complementation and evaluated their immunogenicity and therapeutic efficacy. Upon transplantation into recipient mice, iPSC-derived skin successfully survived and repaired local tissue wounds. In diabetic mouse models, explanted iPSC-derived islets effectively produced insulin and lowered blood glucose to basal levels. iPSC-derived heart grafts maintained normal beating for more than 3 months in syngeneic recipients. Importantly, no obvious immune rejection responses against iPSC-derived organs were detected long after transplantation. Our study not only demonstrates the fundamental immunogenicity and function of iPSC derivatives, but also provides preclinical evidence to support the feasibility of using iPSC-derived skin, islet, and heart for therapeutic use.

Inhibition of accelerated rejection mediated by alloreactive CD4⁺ memory T cells and prolonged allograft survival by arsenic trioxide

The aim of this study was to evaluate and determine the potential mechanisms of As₂O₃ in accelerated rejection mediated by alloreactive CD4⁺ memory T cells. Vascularized heterotopic cardiac transplantation from C57BL/6 mice to nude mice (pre-transferred CD4⁺ memory T cells) was performed on Day 0, and As₂O₃ was administered to recipient mice from Day 0 to 10. As a result, As₂O₃ could reduce the proliferation of allo-primed CD4⁺ memory T cells in vitro in MLR and the baseline rate of proliferation was restored by the addition of exogenous IL-2. In vivo, compared with the control[+] group, the mean survival time of cardiac allografts in the As₂O₃ group was prolonged from 5.8 ± 0.7 to 14.2 ± 2.5 days. Five days after transplantation, the relative gene expression of IL-2, IFN-γ and Foxp3 was reduced in the grafts by As₂O₃ treatment, but the expression of IL-10 and TGF-β was increased. Correspondingly, the proportions of CD4⁺ T cells, CD4⁺ memory T cells and regulatory T cells (Tregs), both in recipient spleens and lymph nodes, were lowered. These results indicate the potential of As2O3 as a novel immunosuppressant targeting CD4⁺ memory T cells.

Immunosuppressive properties of a series of novel inhibitors of the monocarboxylate transporter MCT-1

We have recently described the immunosuppressive properties of AR-C117977 and AR-C122982, representatives of a group of compounds identified as inhibitors of lactate transporters (monocarboxylate transporters; MCTs). These compounds demonstrate the potential therapeutic usefulness of inhibiting MCT-1, but their physical and metabolic properties made them unsuitable for further development. We have therefore tried to find analogues with similar immunosuppressive efficacy and a more suitable profile for oral administration. Five analogues of AR-C117977 were synthesised and screened for binding to the transporter, for inhibition of proliferation of both human and rat lymphocytes, for in vivo activity in a model of graft-versus-host (GvH) response in the rat, and in high- and low-responder cardiac transplant models in the rat. There was a good correlation between levels of binding of the five analogues to MCT and their inhibition of lymphocyte proliferation in human and rat cells. Furthermore, activity in both the GvH response and the cardiac transplant models correlated well with the determined concentrations of test compound in plasma. These findings on new analogues of MCT-1 inhibitors have taken us further towards defining the pharmacokinetic properties that may help to identify future drug candidates among inhibitors of MCT-1.

Combined application of blocking antibodies and MicroRNA interference in inhibiting CD44 expression

BACKGROUND

We sought to explore the effect of CD44 targeting on the tolerance to memory cell-mediated graft rejection.

METHODS

We developed a cardiac transplantation model in nude mice and administered anti-CD44 monoclonal antibodies (mAbs) to these mice. Then, we used anti-CD44 mAb and CD44-interfering microRNA (miRNA) to inhibit CD44 expression in vitro.

RESULTS

The median survival time (MST) associated with multiple intraperitoneal injections was >100 days, whereas that associated with CD4(+) Tm cells blocked CD44 and that associated with a single intraperitoneal injection of anti-CD44 mAb was 11 and 10.3 days, control group was 5.5 days. The inhibition effect of the anti-CD44 mAb in 3T3 cells significantly reduced with cell proliferation. Used CD44 miRNA in 3T3 cells, the most obvious inhibition effect of mRNA appeared at 48 hours after transfection and the inhibition decreased subsequently. In combination, antibody-mediated blocking and miRNA showed some synergistic effects.

CONCLUSION

The inhibition of CD44 can significantly prolong the MST in memory models. The inhibition effect of combined application showed limitations with regard to cell proliferation and duration of action, but the short-term synergistic effect of the combined approach was stronger than the effects of individual approaches.

Monoclonal antibody treatment to prolong the secondary cardiac allograft survival in alloantigen-primed mice

We have previously shown that costimulation blockade using a combination of monoclonal antibodies (mAbs) - CTLA4Ig, antibodies to CD154, LFA-1, and OX40L - can induce tolerance of cardiac allografts in mice with adoptively transferred CD4(+) memory T cells [1]. However, the effect of costimulatory blockade in secondary allograft rejection has not been studied. B6 mice that rejected BALB/c skin grafts for more than 4 weeks (defined as alloantigen-primed mice) were used as recipients. The recipient mice were treated with the mAbs to CD154, LFA-1, OX40L, and CD122 on days 0, 2, 4, and 6 after the secondary transplantation of BALB/c heart. The mean survival time (MST) of secondary cardiac allografts in rats treated with antibodies to CD154 and LFA-1 (2-antibodies approach) and those treated with antibodies to CD154, LFA-1, OX40L, and CD122 (4-antibodies approach) was greater than that of the controls (MST = 6.7 days, 22.2 days, and 3.2 days, respectively). The 4-antibodies approach prevented lymphocytic infiltration in the grafts, inhibited memory T-cells proliferation in the spleen, increased IL-10 secretion in the serum, and enhanced the expression of CD4(+) Foxp3(+) regulatory T cells (Tregs) in spleen. Expression levels of alloreactive antibodies were high in the recipient mice of experimental and control groups. Inhibiting the memory T cells by costimulation blockade extended allograft survival in secondary transplant models but could not induce tolerance of graft. Alloreactive antibodies may participate in alloresponse and play an important role in secondary cardiac allograft rejection.

The recall alloresponse following retransplantation is more intense compared with the T cell memory-transfer model

The presence of alloreactive memory T cells in recipient is a critical handicap to achieving transplantation tolerance. To make a mouse model that can as closely as possible mimic the presensitized transplant patient is important for research on this subject. Thus, we developed a novel retransplant model and compared the alloresponse in this model with that in the memory T cells-transfer model (transfer control). Mean survival time of allograft was compared between 3 groups, including blank transplant control, memory transfer control and retransplant groups. Cellular rejection activity in allografts was evaluated via HE staining of cardiac graft section. Proliferation and differentiation of the alloreactive effector T cells were assayed by in vitro mixed lymphocyte reaction and flow cytometry, respectively. Real-time quantitive RT-PCR was used to assess gene expression of cytokines and surum IFN-gamma was measured via ELISA. It showed that the median survival time of allograft in retransplant recipients was significantly shortened compared to that of transfer control, and it was the same in rejection score of graft. Moreover, proliferation and differentiation of the alloreactive effector T cells were more intensive in retransplant recipients than that in transfer control, which was confirmed by in vitro mixed lymphocyte reaction and by flow cytometry of the splenocytes for detecting CD44highCD62L- memory/effector phenotype cells. Furthermore, activation of CD4+ memory T cells is reflected by high level of surum IFN-gamma and the intensive gene expression of IFN-gamma and IL-2 at cardiac allograft in retransplant recipients. Collectively, the recall alloresponse in retransplantation is more intensive than that in a memory-transfer setting, and this retransplant model is closer to the clinic situation than the memory-transfer model in rodents.

An N-(alkylcarbonyl)anthranilic acid derivative prolongs cardiac allograft survival synergistically with cyclosporine A in a high-responder rat model

We investigated the immunosuppressive effects of the dihydroortate dehydrogenase (DHODH) inhibitor compounds ABR-222417 and ABR-224050 from Active Biotech (Sweden). We verified the inhibitory effects of these compounds on the proliferation of CD4(+) and CD8(+) T-cells in vivo by using superantigen staphylococcus enterotoxin A (SEA)-mediated proliferation test. To evaluate their efficacy, the compounds were screened in a low-responder heart allograft transplantation model in rats [heart from Piebald Virol Glaxo (PVG) transplanted to Dark Agouti (DA)]. The immunosuppressive effects of the compounds were then investigated in a high-responder model (DA to PVG). Treatment with ABR-222417 (30 mg/kg) was more efficient than that with ABR-224050 (10 mg/kg), and the former provided a longer graft median survival time (MST, 29.5 days) than the latter (MST, 18.5 days). Furthermore, there was a marked increase in graft survival time (53 days) when low doses of ABR-222417 and cyclosporine A (CsA) were used in combination. No sign of tolerability problems was detected using this combination or when ABR-222417 was used singly at a higher dose. Furthermore, T-cell proliferation studies in vitro support that the anti proliferative effect of ABR-222417 is caused by inhibition of de novo pyrimidine synthesis, which is the consequence of DHODH inhibition. These results show that ABR-222417 had marked immunosuppressive effects on the heart allograft transplantation and that it exerts an even more powerful inhibitory effect on graft rejection when used in combination with CsA, with good tolerability.

Operational tolerance in nonvascularized transplant models induced by AR-C117977, a monocarboxylate transporter inhibitor

AR-C117977, a monocarboxylate transporter inhibitor, reduces immune responses both in vitro and in vivo, maintains long-term graft survival, and induces operational tolerance. To evaluate the immunosuppressive limitations of AR-C117977, this study was performed in nonvascularized transplant models noted for their refractive response to standard immunosuppressive agents. Rat skin was transplanted from DA(RT1avl) into PVG(RT1c) and the reverse. Mouse islet allotransplantation was performed with BALB/c H2d donors and C57Bl/6J H2b recipients. In the skin graft model, AR-C117977 monotherapy was associated with long-term skin graft survival in one rat strain combination. AR-C117977 and cyclosporine A (CsA) in combination resulted in significant prolongation of graft survival in both rat strains. CsA monotherapy did not prevent acute rejection in either strain. Islet allograft survival was moderately prolonged with CsA or AR-C117977. AR-C117977 is an efficient immunosuppressive drug in stringent rodent transplant models and further studies are warranted.

The specific monocarboxylate transporter-1 (MCT-1) inhibitor, AR-C117977, induces donor-specific suppression, reducing acute and chronic allograft rejection in the rat

BACKGROUND

In a search for immunosuppressive drugs having novel mechanisms, monocarboxylate transporter (MCT-1) inhibitors were identified that markedly inhibited immune responses. Here, we report the effects of AR-C117977, a potent MCT-1 inhibitor, on alloimmune responses in the rat.

METHODS

In vitro activity was determined in a rat mixed lymphocyte response (MLR). In vivo activity was tested in a graft versus host response (GVHR) and in both high (DA to PVG) and low (PVG to DA) responder cardiac allograft models. To assess induction of donor-specific suppression recipients of allogeneic hearts surviving longer than 100 days received a second transplant either of the same donor strain or a third-party donor strain. Effects on chronic graft rejection were assessed histologically by evaluating vasculopathy in long-term surviving grafts and in an obliterative bronchiolitis (OB) model.

RESULTS

AR-C117977 inhibited the rat MLR and was more potent than cyclosporin A (CsA). In the rat GVHR model, AR-C117977 gave a dose-related inhibition. In the high responder cardiac allograft model, graft survival in excess of 100 days was achieved with AR-C117977 compared with 20 days with CsA and all the long-term survivors exhibited donor-specific suppression on retransplantation. In the low responder model, both AR-C117977 and CsA induced survival in excess of 100 days. Histology of the long-term surviving grafts suggested reduced vasculopathy associated with chronic rejection. Furthermore, AR-C117977 inhibited the occlusion of transplanted trachea in a OB model.

CONCLUSION

This report describes a MCT-1 specific inhibitor having immunosuppressive activity on alloimmune responses and inducing donor-specific suppression.

[Total glucosides of peony as adjuvant therapy for prevention of cardiac allograft rejection in rats]

OBJECTIVE

To evaluate the role of total glucosides of peony (TGP) as adjuvant therapy for prevention of cardiac allograft rejection in rats.

METHODS

Rats with cardiac allograft were randomly divided into control group, tacrolimus-treated group, TGP-treated group and tacrolimus plus TGP-treated group. Graft survival time was observed. Allografts in some cases were examined by histological study seven days after transplantation. At the same time, the levels of CD4(+) and CD8(+) T cell subsets in peripheral blood were examined by using flow cytometry; the hepatic function and renal function of recipients were also tested.

RESULTS

The graft survival time of the tacrolimus-treated group and tacrolimus plus TGP-treated group was (11.14+/-1.57) d and (13.57+/-1.99) d, respectively. The graft survival time of the tacrolimus plus TGP-treated group was longer than that of the tacrolimus-treated group (P<0.05). The histological study showed that the rejection of the tacrolimus plus TGP-treated group was slighter than that of the tacrolimus-treated group. The levels of CD4(+) T cell subset in the peripheral blood of the tacrolimus-treated and tacrolimus plus TGP-treated groups were (38.71+/-5.15)% and (32.43+/-4.39)% respectively 7 days after transplantation. The level of CD4(+) T cell subset in the tacrolimus plus TGP-treated group was lower than that in the tacrolimus-treated group (P<0.05). The level of CD8(+) T cell subset and the hepatic and renal function had no significant differences between the tacrolimus-treated group and the tacrolimus plus TGP-treated group.

CONCLUSION

Effects of tacrolimus plus TGP in prevention of rejection are better than tacrolimus monotherapy in rats with cardiac allograft and without increasing side effects.

The immunomodulator Linomide: role in treatment and prevention of autoimmune diabetes mellitus

Insulin-dependent diabetes mellitus (IDDM) is considered to be an autoimmune disorder characterized by destruction of the pancreatic beta-cells by auto-reacting lymphocytes. An attractive therapeutic approach to this disease would be to abrogate the autoimmune process at an early stage, thus preserving a critical mass of pancreatic beta-cells necessary for maintenance of normal glucose tolerance. Linomide (quinoline-3-carboxamide, Roquinimex, LS 2616), is a novel, orally absorbed, immunomodulatory drug that has been shown to be effective in various models of autoimmunity without causing non-specific immunosuppression. In this review, we describe the efficacy of Linomide for ameliorating the autoimmune process and diabetes in the non-obese diabetic (NOD) model of IDDM when administered at early stages of the disease. We also show that advanced disease in the NOD mouse can be treated effectively by combining Linomide with therapeutic modalities designed to increase pancreatic beta-cell mass. Subsequent clinical studies have shown that Linomide preserves beta-cell function in individuals with new-onset IDDM. Based on these data, Linomide or derivatives thereof might be useful for treatment of human IDDM.

Tolerance or rejection: A delicate balance as judged by exposure of heart-transplanted rats to the immunomodulator Linomide

When applied in rodent transplant models most immunosuppressive drugs yield adequate graft protection for as long as the drug is given, and permanent graft survival is often induced. The immunomodulator, Linomide, previously shown to stimulate T cells and prevent apoptosis, usually reduces or abolishes both tolerance induction and the graft-protective effect of the immunosuppressive drug. By chance, we observed that Linomide alone exerted a modest but unequivocal graft-protective effect in the BN to WF strain combination. This finding was analysed by simple genetic mapping of rat strains. Untreated WF recipients kept BN grafts for a median of 8 days, whereas Linomide treatment prolonged graft survival to 12. 5 days (P = 0.0001). In control groups (DA to LEW, BN to LEW, DA to WF and WF to BN), median graft survival was 5.5-7 days irrespective of whether Linomide was given. However, the BN to F1 (LEW x WF) combination also manifested slightly longer graft survival in the presence of Linomide. F1 (BN x WF) to WF grafts survived a median of 15 days without Linomide and 46 days with Linomide treatment. Both in the presence and absence of Linomide, two of the control graft combinations [F1 (BN x DA) to WF and F1 (BN x WF) to BN] manifested 6-7-day graft survival. Taken together, our results suggest a delicate balance between unresponsiveness and rejection, while a single agent (Linomide) may either cause on its own long-term survival of allografts in one setting or rejection despite optimal immunosuppression in another setting.

Antithymocyte globulin and cyclosporin A are synergistic in an experimental transplantation tolerance model in the rat

The aim of the present investigation was to study the possible synergistic effect between cyclosporin A (CsA) and antithymocyte globulin (ATG), using the potent immunostimulator, Linomide. DA rats were transplanted with a PVG/c heart to the neck vessels, and the recipients were treated for 10 days with oral CsA (10mg/kg), oral Linomide (160mg/kg) and/or ATG, which was given as a single dose of either 0.02 ml, 0.1 ml or 0.2 ml prior to transplantation. Rats given a combination of ATG and Linomide or CsA and Linomide were used as controls. Synergism between CsA and ATG was tested using the two immunosuppressive drugs given in combination in order to override the challenge of Linomide. CsA or ATG treatment alone resulted in rats with long-term surviving grafts. Addition of Linomide to CsA-treated recipients was followed by early graft rejection. Similarily, Linomide triggered rejection in rats given a low dose of ATG and in recipients given a high dose of ATG if Linomide treatment was prolonged to 21 days. The combination of ATG, CsA and 21 days of Linomide resulted in a significantly prolonged graft survival compared with either ATG + Linomide or CsA + Linomide. These findings demonstrate the synergistic capacity of ATG and CsA in combined immunosuppressive therapy.

Malononitrilamides 715 and 279 prolong rat cardiac allograft survival, reverse ongoing rejection, inhibit allospecific antibody production and interact positively with cyclosporin

A77 1726 is a malononitrilamide (MNA) and the active metabolite of leflunomide, which has been extensively investigated and shown to be a potent immunosuppressive drug. However, the half-life of A77 1726 is about 15-18 days in humans and leflunomide is therefore currently being developed for the treatment of autoimmune disease and not for transplantation. Search for analogues has led to the discovery of MNA 715 and 279, derivatives of A77 1726. Previous experimental experience of these compounds is still limited. The aim of the present study was to verify the efficacy of these MNAs concerning prevention and reversal of rejection, inhibition of antibody production and interaction with cyclosporin A (CsA). Heterotopic cardiac transplantation in DA to PVG rats was used. Subgroups of rats were given either CsA, MNA 715 or MNA 279 for 10 days, starting at either day 0 or day 4, or received no treatment. Titres of allospecific immunoglobulin M (IgM) and immunoglobulin G (IgG) were quantified by flow cytometry. Ten days of induction with MNA 715 or 279 produced significantly longer graft survival than in controls. Treatment from day 4 onwards, when acute rejection was established, rescued all grafts. Allospecific production of IgM or IgG was absent during MNA induction and was suppressed in animals receiving a rescue course of MNA. The transplant model was potentiated by addition of the immunomodulator quinolone-3-carboxamide (Linomide), which eliminates the effect of CsA and other immunosuppressants. The combined treatment with MNA and CsA was successful in overcoming the challenge of Linomide, demonstrating the additive effects of the two drugs. In conclusion, MNA 715 and 279 were shown to be potent immunosuppressants, preventing and reversing acute allograft rejection, inhibiting and suppressing allospecific antibody production, and the drugs interacted positively with CsA.

The effects of leflunomide and cyclosporin A on rejection of cardiac allografts in the rat

Leflunomide is a new low molecular weight immunosuppressive drug which inhibits the enzymes dehydroorotate-dehydrogenase and protein tyrosine kinase, both of which are important components in the immune response. As the mechanisms of action of leflunomide and cyclosporin A (CsA) are different, we postulated a synergistic effect of the two drugs and tested graft survival following leflunomide administration alone or in combination with CsA in a rat cardiac transplantation model. Low- and high-responder rat strain combinations were used in parallel and the experiments were performed both with and without challenge with Linomide, an immunomodulator which promotes graft rejection in this model. In the low-responder rat strain combination (Piebald Virol Glaxo graft to Dark Agouti recipient; PVG to DA), graft survival appeared to be a dichotomous variable, being characterized by tolerance or early rejection. Leflunomide (10 or 5 mg/kg) given for 10 days induced tolerance and CsA did likewise; the addition of Linomide abolished the immunosuppressive effect of leflunomide but not that of CsA. In the high-responder combination (DA to PVG), no tolerance was seen and graft survival was moderately prolonged both after leflunomide and after CsA treatment; the addition of Linomide to CsA or to leflunomide (5 mg/kg) abolished the immunosuppressive effect of the drugs. However, when CsA-Linomide or leflunomide-Linomide were supplemented with the second immunosuppressive drug, leflunomide or CsA respectively, graft survival was significantly prolonged (P < 0.001 in both cases). This suggests leflunomide and CsA have additive potential.