Induction of regulatory T cells from mature T cells by allogeneic thymic epithelial cells in vitro

The ability of thymic epithelial cells (TEC) to re‐educate mature T cells to be regulatory T cells has not been addressed. In the present study, this issue was directly investigated by co‐culturing of mature T cells and allo‐TECs. B6 macrophage cell line 1C21‐cultured BALB/c splenocytes responded to B6 antigens in vitro. However, BALB/c splenocytes precultured with B6‐derived TECs 1‐4C18 or 1C6 did not proliferate to B6 antigens, but responded to rat antigens. Exogenous interleukin‐2 (IL‐2) failed to revise the unresponsiveness of these T cells. Allo‐TEC‐cultured T cells predominantly expressed Th2 cytokines (IL‐4 and IL‐10). B6 TEC‐cultured BALB/c splenocytes markedly inhibited the immune responses of naïve BALB/c splenocytes to B6 antigens, but not to rat or the third‐party mouse antigens. BALB/c nude mice that received naïve syngeneic splenocytes rejected B6 or rat skin grafts by 17 days postskin grafting; however, co‐injection of B6 TEC‐cultured BALB/c splenocytes significantly delayed B6 skin graft rejection (P < 0.01), with the unchanged rejection of rat skin grafts. These studies demonstrate that allo‐TECs are able to ‘educate’ mature T cells to be regulatory cells, and suggest that regulatory cells derived from mature T cells by TECs may play an important role in T cell tolerance to allo‐ and auto‐antigens.     

Rat Cytomegalovirus Vaccine Prevents Accelerated Chronic Rejection in CMV‐Naïve Recipients of Infected Donor Allograft Hearts

Cytomegalovirus accelerates transplant vascular sclerosis (TVS) and chronic rejection (CR) in solid organ transplants; however, the mechanisms involved are unclear. We determined the efficacy of a CMV vaccine in preventing CMV‐accelerated rat cardiac allograft rejection in naïve recipients of CMV+ donor hearts. F344 donor rats were infected with RCMV 5 days prior to heterotopic cardiac transplantation into CMV‐naïve or H₂O₂‐inactivated RCMV‐vaccinated Lewis recipients. Recipients of RCMV‐infected donor hearts rejected at POD59, whereas vaccinated recipients exhibited a significantly prolonged time to rejection‐POD97, similar to recipients of uninfected donor hearts (POD108). Although all of the donor hearts were preinfected, the vaccinated recipients had lower graft and PBMC viral loads at POD 7 compared to unvaccinated controls. Adoptive T cell and passive antibody transfers from vaccinated Lewis rats into naïve recipients demonstrate that both T‐cell and B‐cell arms of the adaptive immune response provide protection against CMV‐accelerated rejection. Similar findings were obtained when testing three different adjuvants in passive transfer experiments. We have determined that the timing of the vaccine prior to transplantation and the specific adjuvant play critical roles in mediating anti‐viral responses and promoting graft survival. CMV vaccination prior to transplantation may effectively increase graft survival.     

Differential Role of Naïve and Memory CD4+ T‐Cell Subsets in Primary Alloresponses

The T cell response to major histocompatibility complex (MHC) alloantigens occurs via two main pathways. The direct pathway involves the recognition of intact allogeneic MHC:peptide complexes on donor cells and provokes uniquely high frequencies of responsive T cells. The indirect response results from alloantigens being processed like any other protein antigen and presented as peptide by autologous antigen‐presenting cells. The frequencies of T cells with indirect allospecificity are orders of magnitude lower and comparable to other peptide‐specific responses. In this study, we explored the contributions of naïve and memory CD4⁺ T cells to these two pathways. Using an adoptive transfer and skin transplantation model we found that naive and memory CD4⁺ T cells, both naturally occurring and induced by sensitization with multiple third‐party alloantigens, contributed equally to graft rejection when only the direct pathway was operative. In contrast, the indirect response was predominantly mediated by the naïve subset. Elimination of regulatory CD4⁺CD25⁺ T cells enabled memory cells to reject grafts through the indirect pathway, but at a much slower tempo than for naïve cells. These findings have implications for better targeting of immunosuppression to inhibit immediate and later forms of alloimmunity.     

Uremia‐associated immunological aging is stably imprinted in the T‐cell system and not reversed by kidney transplantation

The uremia‐induced inflammatory environment in end‐stage renal disease (ESRD) patients is associated with premature T‐cell aging resulting in a defective T‐cell immunity. As kidney transplantation (KTx) reduces the pro‐inflammatory environment, we hypothesized that KTx would rejuvenate the aged T‐cell system. As aging parameters, we determined in 70 KTx recipients the differentiation status by immunophenotyping, thymic output by the T‐cell receptor excision circle (TREC) content together with CD31⁺ naïve T‐cell numbers and the relative telomere length (RTL) as a measure for proliferative history at pre‐KTx, 3, 6 and 12 months post‐KTx. In addition, T‐cell function was determined by measuring the proliferative capacity and percentages of cytokine‐producing cells. Directly post‐KTx, memory T‐cell numbers were diminished but restored to pre‐KTx values at 12 months, except for CD4⁺EM T cells. The RTL of (memory) CD4⁺ and CD8⁺ T cells did not change. In contrast, TREC content and CD31⁺ naïve T‐cell numbers were stable post‐KTx although the RTL of naïve CD4⁺ and CD8⁺ T cells decreased implying homeostatic proliferation of naïve cells, in response to a temporary decrease in memory cells. The T‐cell function was not improved post‐KTx. Our findings demonstrate that the uremia‐associated aged phenotype is stably imprinted in the T‐cell system and not reversed by KTx.     

Postdepletion Lymphocyte Reconstitution During Belatacept and Rapamycin Treatment in Kidney Transplant Recipients

Belatacept is used to prevent allograft rejection but fails to do so in a sizable minority of patients due to inadequate control of costimulation‐resistant T cells. In this study, we report control of costimulation‐resistant rejection when belatacept was combined with perioperative alemtuzumab‐mediated lymphocyte depletion and rapamycin. To assess the means by which the alemtuzumab, belatacept and rapamycin (ABR) regimen controls belatacept‐resistant rejection, we studied 20 ABR‐treated patients and characterized peripheral lymphocyte phenotype and functional responses to donor, third‐party and viral antigens using flow cytometry, intracellular cytokine staining and carboxyfluorescein succinimidyl ester–based lymphocyte proliferation. Compared with conventional immunosuppression in 10 patients, lymphocyte depletion evoked substantial homeostatic lymphocyte activation balanced by regulatory T and B cell phenotypes. The reconstituted T cell repertoire was enriched for CD28⁺ naïve cells, notably diminished in belatacept‐resistant CD28^? memory subsets and depleted of polyfunctional donor‐specific T cells but able to respond to third‐party and latent herpes viruses. B cell responses were similarly favorable, without alloantibody development and a reduction in memory subsets—changes not seen in conventionally treated patients. The ABR regimen uniquely altered the immune profile, producing a repertoire enriched for CD28⁺ T cells, hyporesponsive to donor alloantigen and competent in its protective immune capabilities. The resulting repertoire was permissive for control of rejection with belatacept monotherapy.

     

Pretransplant Immediately Early‐1‐Specific T Cell Responses Provide Protection for CMV Infection After Kidney Transplantation

Cytomegalovirus (CMV) infection is still a major complication after kidney transplantation. Although cytotoxic CMV‐specific T cells play a crucial role controlling CMV survival and replication, current pretransplant risk assessment for CMV infection is only based on donor/recipient (IgG)‐serostatus. Here, we evaluated the usefulness of monitoring pre‐ and 6‐month CMV‐specific T cell responses against two dominant CMV antigens (IE‐1 and pp65) and a CMV lysate, using an IFN‐γ Elispot, for predicting the advent of CMV infection in two cohorts of 137 kidney transplant recipients either receiving routine prophylaxis (n = 39) or preemptive treatment (n = 98). Incidence of CMV antigenemia/disease within the prophylaxis and preemptive group was 28%/20% and 22%/12%, respectively. Patients developing CMV infection showed significantly lower anti‐IE‐1‐specific T cell responses than those that did not in both groups (p < 0.05). In a ROC curve analysis, low pretransplant anti‐IE‐1‐specific T cell responses predicted the risk of both primary and late‐onset CMV infection with high sensitivity and specificity (AUC > 0.70). Furthermore, when using most sensitive and specific Elispot cut‐off values, a higher than 80% and 90% sensitivity and negative predictive value was obtained, respectively. Monitoring IE‐1‐specific T cell responses before transplantation may be useful for predicting posttransplant risk of CMV infection, thus potentially guiding decision‐making regarding CMV preventive treatment.     

Both CD45RA+ and CD45RO+ human CD4+ T cells drive direct xenogeneic T‐cell responses against porcine aortic endothelial cells

Kim CH, Oh K, Kim D‐E, Lee SB, Yang JH, Lee G, Cho J, Lee D‐S. Both CD45RA⁺ and CD45RO⁺ human CD4⁺ T cells drive direct xenogeneic T‐cell responses against porcine aortic endothelial cells. Xenotransplantation 2010; 17: 224–232. © 2010 John Wiley & Sons A/S. Abstract: Background: Xenogeneic cellular immune responses are mediated by either direct or indirect pathways depending on the participation of donor or host antigen presenting cells, respectively. The contribution of direct response of human T cells, especially memory T cells, to porcine antigen presenting cells is currently unknown. Here, we sought to determine whether human peripheral blood memory/activated phenotype T cells are directly responsive to porcine endothelial cells. Methods: Porcine aortic endothelial cells (PAECs) were prepared from Yorkshire or miniature pigs. Highly purified human T cells, including naïve and memory/activated phenotype cells, were incubated with PAECs with or without the addition of exogenous cytokines. T‐cell proliferation and T‐cell receptor (TCR) Vβ usage in response to PAECs were analyzed. Results: Both CD8⁺ and CD4⁺ T cells responded directly to PAECs and exhibited exclusive responsiveness to SLA class I and class II molecules, respectively. Naïve and memory/activated phenotype CD4⁺ T cells responded against PAECs, whereas only naïve phenotype CD8⁺ T cells contributed to such a response. In addition, both populations of xenogeneic human CD4⁺ T cells exhibited similar and diverse Vβ usage. Conclusion: Due to the considerable contribution of human CD45RO⁺CD4⁺ T cells to the xenoreactivity against PAECs, effective control of xenogeneic memory/activated T‐cell responses would significantly affect long‐term survival of transplanted grafts.     

Siplizumab selectively depletes effector memory T cells and promotes a relative expansion of alloreactive regulatory T cells in vitro

Siplizumab, a humanized anti‐CD2 monoclonal antibody, has been used in conditioning regimens for hematopoietic cell transplantation and tolerance induction with combined kidney‐bone marrow transplantation. Siplizumab‐based tolerance induction regimens deplete T cells globally while enriching regulatory T cells (Tregs) early posttransplantation. Siplizumab inhibits allogeneic mixed‐lymphocyte reactions (MLRs) in vitro. We compared the impact of siplizumab on Tregs versus other T cell subsets in HLA‐mismatched allogeneic MLRs using PBMCs. Siplizumab predominantly reduced the percentage of CD4⁺ and CD8⁺ effector memory T cells, which express higher CD2 levels than naïve T cells or resting Tregs. Conversely, siplizumab enriched proliferating CD45RA^? FoxP3^HI cells in MLRs. FoxP3 expression was stable over time in siplizumab‐containing cultures, consistent with enrichment for bona fide Tregs. Consistently, high‐throughput TCRβ CDR3 sequencing of sorted unstimulated and proliferating T cells in MLRs revealed selective expansion of donor‐reactive Tregs along with depletion of donor‐reactive CD4⁺ effector/memory T cells in siplizumab‐containing MLRs. These results indicate that siplizumab may have immunomodulatory functions that may contribute to its success in tolerance‐inducing regimens. Our studies also confirm that naïve in addition to effector/memory T cells contribute to the allogeneic MLR and mandate further investigation of the impact of siplizumab on alloreactive naïve T cells.     

Memory T Cells in Transplantation: Generation, Function, and Potential Role in Rejection

The adaptive immune system is endowed with long‐lived memory to recall previous antigen encounters and respond more effectively to them. Memory immune responses are mediated by antigen‐specific memory T lymphocytes that exhibit enhanced function compared with naïve T cells that have never encountered antigen. While the generation of memory T cells specific for pathogens is beneficial in providing protective immunity, memory T cells specific for alloantigens can be deleterious to the recipient of a transplanted organ. In graft rejection, memory T cells mediate accelerated, ‘second‐set’ rejection and their presence has been associated with increased propensity for early rejection. Recent findings have demonstrated that alloreactive memory T cells can be generated via exposure to alloantigens, as well as stimuli that are cross‐reactive with alloantigens, and are therefore likely present in ‘naïve’ individuals. This review focuses on the characteristics of memory T cells which make them of special interest to the transplant community, including differential activation requirements, broad homing properties, and resistance to tolerance induction. The multiple ways in which memory T cells can contribute to early and late graft rejection are discussed, as well as potential targets for combating alloreactive memory to be considered in the future design of tolerance induction strategies.     

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.     

Complexity of anti-immunosenescence strategies in humans

Abstract: Immunosenescence is characterized by three main aspects: (i) the shrinkage of the T cell repertoire and the accumulation of oligoclonal expansions (megaclones) of memory/effector cells directed toward ubiquitary infectious agents; (ii) the involution of the thymus and the exhaustion of naïve T cells; and (iii) a chronic inflammatory status called inflamm‐aging. We present here possible strategies to counteract these main aspects of immunosenescence in humans with particular attention to the reduction of antigenic load by pathogens, such as CMV, and the normalization of intestinal microflora, the possible utilization of IL‐7 to reverse thymic involution, the purging of megaclones, the forced expression of CD28 on T lymphocytes, the reduction of inflamm‐aging and the administration of nutrients such as vitamin D. Possible drawbacks of all these strategies are discussed. Finally, the complexity of a rejuvenation approach is stressed, with particular attention to the inhibitory role played by the “old microenvironment” on the performance of progenitor cells, the best candidate to counteract the decline in regenerative potential characteristic of organs and tissues from old organisms.     

Lymphodepletion and Homeostatic Proliferation: Implications for Transplantation

Control of the alloimmune response requires elimination and/or suppression of alloreactive immune cells. Lymphodepleting induction therapies are increasingly used to accomplish this goal, both as part of tolerance induction protocols or to reduce the requirements for maintenance immunosuppression in the peritransplant setting. However, it is well recognized that lymphopenia induces compensatory proliferation of immune cells, generally termed ``homeostatic proliferation,'' which favors the emergence of memory T cells. Paradoxically therefore, the result may be a situation that favors graft rejection and/or makes tolerance difficult to achieve or sustain. Yet all depletion is not alike, particularly with respect to the timing of reconstitution and the types of cells that repopulate the host. Thus, to design more effective induction strategies it is important to understand the homeostatic mechanisms, which exist to maintain a balanced repertoire of naïve and memory T and B cells in the periphery and how they respond to lymphodepletion. Here we will review the biology of homeostatic proliferation stimulated by lymphopenia, the effects of specific depleting agents on reconstitution of the T‐ and B‐cell immune repertoire, drawing from both from animal models and human experience, and potential strategies to enhance allodepletion while minimizing the adverse effects of homeostatic proliferation.     

Regulatory T cells in immune‐mediated renal disease

Regulatory T cells (Tregs) are CD4+ T cells that can suppress immune responses by effector T cells, B cells and innate immune cells. This review discusses the role that Tregs play in murine models of immune‐mediated renal diseases and acute kidney injury and in human autoimmune kidney disease (such as systemic lupus erythematosus, anti‐glomerular basement membrane disease, anti‐neutrophil cytoplasmic antibody‐associated vasculitis). Current research suggests that Tregs may be reduced in number and/or have impaired regulatory function in these diseases. Tregs possess several mechanisms by which they can limit renal and systemic inflammatory immune responses. Potential therapeutic applications involving Tregs include in vivo induction of Tregs or inducing Tregs from naïve CD4+ T cells or expanding natural Tregs ex vivo, to use as a cellular therapy. At present, the optimal method of generating a phenotypically stable pool of Tregs with long‐lasting suppressive effects is not established, but human studies in renal transplantation are underway exploring the therapeutic potential of Tregs as a cellular therapy, and if successful may have a role as a novel therapy in immune‐mediated renal diseases.     

Primed allospecific T cells prevent the effects of costimulatory blockade on prolonged cardiac allograft survival in mice.

Costimulatory blockade can induce long‐term allograft survival in naïve animals, but may not be as effective in animals with previously primed immune repertoires. We attempted to induce long‐term graft survival in B10.D2 recipients of B10.A cardiac allografts using donor‐specific transfusion (DST) plus anti‐CD40 ligand antibody (αCD40L). Recipients were either naïve mice, or mice previously primed to B10.A or third party alloantigens through engraftment and rejection of skin transplants. Untreated naïve mice rejected cardiac transplants by day 15 and contained a high frequency of primed, donor‐reactive T cells. Donor‐specific transfusion/αCD40L treatment of naïve animals induced long‐term graft survival associated with low frequencies of donor‐reactive T cells. Previous priming of donor‐specific T cells through rejection of B10.A, but not third party, skin grafts prevented the effects of DST/αCD40L on prolonging survival of B10.A hearts. Moreover, adoptive transfer of CD3+, CD4+ or CD8+ T cells from B10.A skin‐graft‐primed animals prevented the effects of DST/αCD40L. The data demonstrate that animals with immune repertoires containing previously primed, donor‐reactive T cells are resistant to the effects of costimulatory blockade. The findings have important implications for ongoing, costimulatory blockade‐based trials in humans, whose T‐cell repertoires are known to contain memory alloreactive T cells.     

Tertiary Lymphoid Tissues Generate Effector and Memory T Cells That Lead to Allograft Rejection

Tertiary lymphoid tissues are lymph node‐like cell aggregates that arise at sites of chronic inflammation. They have been observed in transplanted organs undergoing chronic rejection, but it is not known whether they contribute to the rejection process by supporting local activation of naïve lymphocytes. To answer this question, we established a murine transplantation model in which the donor skin contains tertiary lymphoid tissues due to transgenic expression of lymphotoxin‐α(RIP‐LTα), whereas the recipient lacks all secondary lymphoid organs and does not mount primary alloimmune responses. We demonstrate in this model that RIP‐LTα allografts that harbor tertiary lymphoid tissues are rejected, while wild‐type allografts that lack tertiary lymphoid tissues are accepted. Wild‐type allografts transplanted at the same time as RIP‐LTα skin or 60 days later were also rejected, suggesting that tertiary lymphoid tissues, similar to secondary lymphoid organs, generate both effector and memory immune responses. Consistent with this observation, naive T cells transferred to RIP‐LTα skin allograft but not syngeneic graft recipients proliferated and differentiated into effector and memory T cells. These findings provide direct evidence that tertiary lymphoid structures perpetuate the rejection process by supporting naïve T‐cell activation.     

Donor-specific indirect pathway analysis reveals a B-cell-independent signature which reflects outcomes in kidney transplant recipients

To investigate the role of donor‐specific indirect pathway T cells in renal transplant tolerance, we analyzed responses in peripheral blood of 45 patients using the trans‐vivo delayed‐type hypersensitivity assay. Subjects were enrolled into five groups—identical twin, clinically tolerant (TOL), steroid monotherapy (MONO), standard immunosuppression (SI) and chronic rejection (CR)—based on transplant type, posttransplant immunosuppression and graft function. The indirect pathway was active in all groups except twins but distinct intergroup differences were evident, corresponding to clinical status. The antidonor indirect pathway T effector response increased across patient groups (TOL < MONO < SI < CR; p < 0.0001) whereas antidonor indirect pathway T regulatory response decreased (TOL > MONO = SI > CR; p < 0.005). This pattern differed from that seen in circulating naïve B‐cell numbers and in a cross‐platform biomarker analysis, where patients on monotherapy were not ranked closest to TOL patients, but rather were indistinguishable from chronically rejecting patients. Cross‐sectional analysis of the indirect pathway revealed a spectrum in T‐regulatory:T‐effector balance, ranging from TOL patients having predominantly regulatory responses to CR patients having predominantly effector responses. Therefore, the indirect pathway measurements reflect a distinct aspect of tolerance from the recently reported elevation of circulating naïve B cells, which was apparent only in recipients off immunosuppression.     

Clinical consequences of circulating CD28‐negative T cells for solid organ transplantation

CD28 is an important costimulatory molecule expressed on T cells, interacting with CD80 and CD86 on antigen‐presenting cells. All naïve T cells express CD28, but memory T cells may become CD28 negative (CD28neg) as a result of repetitive cell divisions, the influence of TNF‐alpha, and infection with cytomegalovirus. This results in accumulation of CD28neg T cells, which may constitute >50% of the total circulating T‐cell population in the elderly. The frequency of CD28neg T cells is associated with diseases such as cancer, autoimmunity, and atherosclerosis in which they may act as either effector or suppressor cells. This functional heterogeneity probably underlies the finding that the CD8posCD28neg T‐cell population harbors effector cells mediating acute allograft rejection, but also suppressor cells. The CD4posCD28neg T cells are predominantly considered to be a nonclassical risk factor for atherosclerotic disease, and their contribution to alloreactivity is less clear. CD28neg T cells depend on IL‐15 for their proliferation, and they have increased the expression of specific costimulatory molecules, such as NK receptors, TNF‐alpha receptor family members, and the adhesion/costimulatory molecule CD2. Targeting these costimulatory pathways presents potential therapeutic options to block allograft rejection mediated by CD28neg T cells which are resistant to belatacept.     

Clinical validation of a novel enzyme‐linked immunosorbent spot assay‐based in vitro diagnostic assay to monitor cytomegalovirus‐specific cell‐mediated immunity in kidney transplant recipients: a multicenter,longitudinal, prospective,observational study

Impaired cytomegalovirus (CMV)‐specific cell‐mediated immunity (CMV‐CMI) is a major cause of CMV reactivation and associated complications in solid‐organ transplantation. Reliably assessing CMV‐CMI is desirable to individually adjust antiviral and immunosuppressive therapy. This study aimed to evaluate the suitability of T‐Track^® CMV, a novel IFN‐γ ELISpot assay based on the stimulation of peripheral blood mononuclear cells with pp65 and IE‐I CMV proteins, to monitor CMV‐CMI following kidney transplantation. A prospective longitudinal multicenter study was conducted in 86 intermediate‐risk renal transplant recipients. CMV‐CMI, CMV viral load, and clinical complications were monitored over 6 months post‐transplantation. Ninety‐five percent and 88–92% ELISpot assays were positive pre‐ and post‐transplantation, respectively. CMV‐specific response was reduced following immunosuppressive treatment and increased in patients with graft rejection, indicating the ability of the ELISpot assay to monitor patients' immunosuppressive state. Interestingly, median pp65‐specific response was ninefold higher in patients with self‐clearing viral load compared to antivirally treated patients prior to first viral load detection (P < 0.001), suggesting that reactivity to pp65 represents a potential immunocompetence marker. Altogether, T‐Track^® CMV is a highly sensitive IFN‐γ ELISpot assay, suitable for the immunomonitoring of CMV‐seropositive renal transplant recipients, and with a potential use for the risk assessment of CMV‐related clinical complications (ClinicalTrials.gov Identifier: NCT02083042).     

The Changed Balance of Regulatory and Naive T Cells Promotes Tolerance after TLI and Anti‐T‐Cell Antibody Conditioning

The goal of the study was to determine how the changed balance of host naïve and regulatory T cells observed after conditioning with total lymphoid irradiation (TLI) and antithymocyte serum (ATS) promotes tolerance to combined organ and bone marrow transplants. Although previous studies showed that tolerance was dependent on host natural killer T (NKT) cells, this study shows that there is an additional dependence on host CD4⁺CD25⁺ Treg cells. Depletion of the latter cells before conditioning resulted in rapid rejection of bone marrow and organ allografts. The balance of T‐cell subsets changed after TLI and ATS with TLI favoring mainly NKT cells and ATS favoring mainly Treg cells. Combined modalities reduced the conventional naïve CD4⁺ T cells 2800‐fold. The host type Treg cells that persisted in the stable chimeras had the capacity to suppress alloreactivity to both donor and third party cells in the mixed leukocyte reaction. In conclusion, tolerance induction after conditioning in this model depends upon the ability of naturally occurring regulatory NKT and Treg cells to suppress the residual alloreactive T cells that are capable of rejecting grafts.     

Primary Cytomegalovirus Infection Significantly Impacts Circulating T Cells in Kidney Transplant Recipients

Cytomegalovirus (CMV) infection profoundly affects the T cell compartment and is associated with alterations in T cell aging parameters and generation of cytotoxic CD4⁺CD28null T cells. Hence, the effect of a primary CMV infection post–kidney transplantation (KT) on the peripheral T cell compartment was examined. As aging parameters, we determined the T cell differentiation status, T cell receptor excision circle (TREC) content, CD31⁺ naïve T cell numbers and relative telomere length (RTL) pre‐KT and 12 months post‐KT. CMV‐seronegative KT recipients, receiving a kidney from a CMV‐seropositive donor (D+/R?) were compared to D+/R+ KT recipients. Eleven out of the 22 D+/R? KT recipients had CMV viremia post‐KT. They developed CMV‐specific CD4⁺ and CD8⁺ T cells and their T cell compartment shifted towards a more differentiated memory phenotype with expansion of CD4⁺CD28null and CD8⁺CD28null cells. One year post‐KT, the CD8⁺ T cell count was almost doubled compared to nonviremic D+/R? and D+/R+ KT recipients. In addition, the RTL of the CD8⁺ T cell was significantly lower and both the TREC content and CD31⁺ naïve T cell numbers significantly decreased. Moreover, primary CMV infection was associated with a negative impact on glomerular filtration rate. In conclusion, primary CMV infection has a substantial impact on the number and phenotype of peripheral T cells and may negatively affect renal allograft function.