Beata Mierzejewska

Current approaches in national kidney paired donation programs

Kidney transplantation is the treatment of choice for patients with end-stage renal disease. While living donors provide anywhere from a small to a large fraction of kidneys for transplantation in different countries, at least one-third of these donors are incompatible with their potential recipients. To overcome these challenges, kidney paired donation (KPD) programs have been established that organize donor exchanges to find matches among the pool of incompatible pairs. Each program has developed its own features to accommodate local needs. Reasons for participating in KPD include blood group incompatibility, sensitization of the recipient against the donor, and the potential for improvement in transplant quality (e.g., age difference or graft size), and tissue compatibility. KPD programs use sophisticated algorithms to find matches among the pool of donor-recipient pairs to create simultaneous 2-way, 3-way, or 4-way exchanges or more complex non-simultaneous chains of transplants. These KPD allocation systems should be medically sound and ethically acceptable according to the principles of equity, utility, and justice. The variety of possible exchanges provided by these algorithms allows for maximizing the number of transplants, increasing the quality of transplants, and accommodating patients who are difficult to match. In this review, we describe several examples of successful KPD programs with diverse organizational approaches. By highlighting the strategies used by these programs to meet the needs of their patient populations, we aim to inspire improvements in existing programs and to provide a framework for expanding KPD to better serve international transplant communities.

Anti-TCRβ mAb induces long-term allograft survival by reducing antigen-reactive T cells and sparing regulatory T cells.

TCR specific antibodies may modulate the TCR engagement with antigen–MHC complexes, and in turn regulate in vivo T cell responses to alloantigens. Herein, we found that in vivo administration of mAbs specific for mouse TCRβ (H57–597), TCRα or CD3 promptly reduced the number of CD4+ and CD8+ T cells in normal mice, but H57–597 mAb most potently increased the frequency of CD4+Foxp3+ Treg cells. When mice were injected with staphylococcal enterotoxin B (SEB) superantigen and H57–597 mAb, the expansion of SEB‐reactive Vβ8+ T cells was completely abrogated while SEB‐nonreactive Vβ2+ T cells remained unaffected. More importantly, transient H57–597 mAb treatment exerted long‐lasting effect in preventing T cell responses to alloantigens, and produced long‐term cardiac allograft survival (>100 days) in 10 out of 11 recipients. While Treg cells were involved in maintaining donor‐specific long‐term graft survival, T cell homeostasis recovered over time and immunity was retained against third party allografts. Moreover, transient H57–597 mAb treatment significantly prolonged survival of skin allografts in naïve recipients as well as heart allografts in skin‐sensitized recipients. Thus, transient modulation of the TCRβ chain by H57–597 mAb exhibits potent, long‐lasting therapeutic effects to control alloimmune responses.

Early acute antibody-mediated rejection of a negative flow crossmatch 3rd kidney transplant with exclusive disparity at HLA-DP.

Donor-specific alloantibodies (DSA) to HLA-DP may cause antibody-mediated rejection (AMR), especially in re-transplants. We describe the immunization history of a patient who received 3 kidney transplants; the 3rd kidney was completely matched except at DPA1 and DPB1. Prior to the 3rd transplant, single antigen bead analysis (SAB) showed DSA reactivity against DPA1 shared by the 1st and 3rd donors, but B and T flow crossmatch (FXM) results were negative. Within 11 days the 3rd transplant underwent acute C4d+ AMR which coincided with the presence of complement (C1q)-binding IgG1 DSA against donor DPA1 and DPB1. Using HLAMatchmaker and SAB, we provide evidence that eplet (epitope) spreading on DPA1 and eplet sharing on differing DPB1 alleles of the 1st and 3rd transplants was associated with AMR. Since weak DSA to DPA1/DPB1 may induce acute AMR with negative FXM, donor DPA1/DPB1 high resolution typing should be considered in sensitized patients with DP-directed DSA.

PD-1-dependent restoration of self-tolerance in the NOD mouse model of diabetes after transient anti-TCRβ mAb therapy

Aims/hypothesisT cells play a major role in the pathogenesis of type 1 diabetes, and there is great interest in developing curative immunotherapies targeting these cells. In this study, a monoclonal antibody (mAb) targeting the T cell receptor β-chain (TCRβ) was investigated for its ability to prevent and reverse disease in mouse models of diabetes.MethodsRIP-OVAhi (C57BL/6-Tg(Ins2-OVA)59Wehi/WehiJ) mice adoptively transferred with ovalbumin-specific T cells (an induced model of diabetes) and NOD mice (a spontaneous model of diabetes) were used to test anti-TCRβ mAb therapy as a means of preventing and reversing type 1 diabetes.ResultsA single dose of anti-TCRβ completely prevented disease in RIP-OVAhi mice without inducing the release of inflammatory cytokines. Transient anti-TCRβ therapy prevented diabetes in 90% of NOD mice and reversed the disease after its onset in 73% of NOD mice. Long after the remission of type 1 diabetes, the anti-TCRβ treated mice were able to reject BALB/c skin allografts with normal kinetics while maintaining normoglycaemia. Treatment did not cause significant reductions in lymphocyte numbers in the spleen or pancreatic lymph nodes, but did result in a decreased percentage of chemokine receptor 9 (CCR9) positive, CD8+ T cells. Notably, anti-TCRβ therapy increased the expression of programmed death 1 (PD-1) on the surface of the T cells; PD-1 expression is important for maintaining anti-TCRβ-induced self-tolerance, as type 1 diabetes recurs in mice following a blockade of PD-1 signalling.Conclusions/interpretationAnti-TCRβ mAb is a safe and effective immunotherapy that results in reduced numbers of CCR9+ T cells, an increased expression of PD-1 on T cells and the restoration of self-tolerance in NOD mice.

Optimizing the use of regulatory T cells in allotransplantation: recent advances and future perspectives.

Apart from clonal deletion of self-reactive T cells in the thymus, Tregs are the major regulators of immune responses in the periphery and maintain a state of self-tolerance free from autoimmune diseases. Due to their inherent suppressive function, Tregs are being explored for their therapeutic potential in preventing autoimmunity and improving survival of allografts. This review provides recent updates on Treg biology and their use in animal as well as clinical models of transplantation. We discuss potential problems that limit the widespread clinical application of Tregs and provide future perspectives on how to optimize their medical use. Special consideration is given to methods by which Tregs should be isolated and expanded in order to facilitate clinical therapies. We also focus on recent discussions of Treg stability and plasticity, with specific insights into preventing the loss of Treg suppression by allotransplant-mediated inflammation.