Contrasting effects of B cell depletion on CD4+ and CD8+ memory T cell responses generated after transplantation

Alloreactive memory T cells play a key role in transplantation by accelerating allograft rejection and preventing tolerance induction. Some studies using µMT mice, which are constitutionally devoid of B cells, showed that B cells were required for the generation of memory T cells after allotransplantation. However, whether B cell depletion in normal adult mice has the same effect on memory responses by CD4⁺ and CD8⁺ T cells activated after transplantation has not been thoroughly investigated. In this study, we tested the effect of anti‐CD20 antibody‐mediated B cell depletion on CD4⁺ and CD8⁺ memory T cell alloresponses after skin transplantation in wild‐type mice. We found that B cell depletion prevented the development of memory alloresponses by CD4⁺ T cells but enhanced that of CD8⁺ memory T cells. Next, we tested the influence of B cell depletion on hematopoietic chimerism. In OT‐II CD4⁺ anti‐OVA TCR transgenic mice sensitized to ovalbumin antigen, B cell depletion also impaired allospecific memory T cell responses and thereby enhanced donor hematopoietic chimerism and T cell deletion after bone marrow transplantation. This study underscores the complexity of the relationships between B and T cells in the generation and reactivation of different memory T cell subsets after transplantation.     

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.     

Tracking of TCR‐Transgenic T Cells Reveals That Multiple Mechanisms Maintain Cardiac Transplant Tolerance in Mice

Solid organ transplantation tolerance can be achieved following select transient immunosuppressive regimens that result in long‐lasting restraint of alloimmunity without affecting responses to other antigens. Transplantation tolerance has been observed in animal models following costimulation or coreceptor blockade therapies, and in a subset of patients through induction protocols that include donor bone marrow transplantation, or following withdrawal of immunosuppression. Previous data from our lab and others have shown that proinflammatory interventions that successfully prevent the induction of transplantation tolerance in mice often fail to break tolerance once it has been stably established. This suggests that established tolerance acquires resilience to proinflammatory insults, and prompted us to investigate the mechanisms that maintain a stable state of robust tolerance. Our results demonstrate that only a triple intervention of depleting CD25⁺ regulatory T cells (Tregs), blocking programmed death ligand‐1 (PD‐L1) signals, and transferring low numbers of alloreactive T cells was sufficient to break established tolerance. We infer from these observations that Tregs and PD‐1/PD‐L1 signals cooperate to preserve a low alloreactive T cell frequency to maintain tolerance. Thus, therapeutic protocols designed to induce multiple parallel mechanisms of peripheral tolerance may be necessary to achieve robust transplantation tolerance capable of maintaining one allograft for life in the clinic.     

Neutrophil extracellular trap fragments stimulate innate immune responses that prevent lung transplant tolerance

Neutrophil extracellular traps (NETs) have been shown to worsen acute pulmonary injury including after lung transplantation. The breakdown of NETs by DNAse‐1 can help restore lung function, but whether there is an impact on allograft tolerance remains less clear. Using intravital 2‐photon microscopy, we analyzed the effects of DNAse‐1 on NETs in mouse orthotopic lung allografts damaged by ischemia‐reperfusion injury. Although DNAse‐1 treatment rapidly degrades intragraft NETs, the consequential release of NET fragments induces prolonged interactions between infiltrating CD4⁺ T cells and donor‐derived antigen presenting cells. DNAse‐1 generated NET fragments also promote human alveolar macrophage inflammatory cytokine production and prime dendritic cells for alloantigen‐specific CD4⁺ T cell proliferation through activating toll‐like receptor (TLR) — Myeloid Differentiation Primary Response 88 (MyD88) signaling pathways. Furthermore, and in contrast to allograft recipients with a deficiency in NET generation due to a neutrophil‐specific ablation of Protein Arginine Deiminase 4 (PAD4), DNAse‐1 administration to wild‐type recipients promotes the recognition of allo‐ and self‐antigens and prevents immunosuppression‐mediated lung allograft acceptance through a MyD88‐dependent pathway. Taken together, these data show that the rapid catalytic release of NET fragments promotes innate immune responses that prevent lung transplant tolerance.     

Origin of Enriched Regulatory T Cells in Patients Receiving Combined Kidney–Bone Marrow Transplantation to Induce Transplantation Tolerance

We examined tolerance mechanisms in patients receiving HLA‐mismatched combined kidney–bone marrow transplantation (CKBMT) that led to transient chimerism under a previously published nonmyeloablative conditioning regimen (Immune Tolerance Network study 036). Polychromatic flow cytometry and high‐throughput sequencing of T cell receptor‐β hypervariable regions of DNA from peripheral blood regulatory T cells (Tregs) and CD4 non‐Tregs revealed marked early enrichment of Tregs (CD3⁺CD4⁺CD25^highCD127^lowFoxp3⁺) in blood that resulted from peripheral proliferation (Ki67⁺), possibly new thymic emigration (CD31⁺), and, in one tolerant subject, conversion from non‐Tregs. Among recovering conventional T cells, central memory CD4⁺ and CD8⁺ cells predominated. A large proportion of the T cell clones detected in posttransplantation biopsy specimens by T cell receptor sequencing were detected in the peripheral blood and were not donor‐reactive. Our results suggest that enrichment of Tregs by new thymic emigration and lymphopenia‐driven peripheral proliferation in the early posttransplantation period may contribute to tolerance after CKBMT. Further, most conventional T cell clones detected in immunologically quiescent posttransplantation biopsy specimens appear to be circulating cells in the microvasculature rather than infiltrating T cells.     

Alefacept Promotes Immunosuppression‐Free Renal Allograft Survival in Nonhuman Primates via Depletion of Recipient Memory T Cells

Renal allograft tolerance has been achieved in MHC‐mismatched primates via nonmyeloablative conditioning beginning 6 days prior to planned kidney and donor bone marrow transplantation (DBMT). To extend the applicability of this approach to deceased donor transplantation, we recently developed a novel‐conditioning regimen, the “delayed protocol” in which donor bone marrow (DBM) is transplanted several months after kidney transplantation. However, activation/expansion of donor‐reactive CD8⁺ memory T cells (TMEM) occurring during the interval between kidney and DBM transplantation impaired tolerance induction using this strategy. In the current study, we tested whether, Alefacept, a fusion protein which targets LFA‐3/CD2 interactions and selectively depletes CD2^highCD8⁺ effector memory T cells (TEM) could similarly induce long‐term immunosuppression‐free renal allograft survival but avoid the deleterious effects of anti‐CD8 mAb treatment. We found that Alefacept significantly delayed the expansion of CD2^high cells including CD8⁺ TEM while sparing naïve CD8⁺ T and NK cells and achieved mixed chimerism and long‐term immunosuppression‐free renal allograft survival. In conclusion, elimination of CD2^high T cells represents a promising approach to prevent electively the expansion/activation of donor‐reactive TEM and promotes tolerance induction via the delayed protocol mixed chimerism approach.

     

Memory T cell–mediated rejection is mitigated by FcγRIIB expression on CD8+ T cells

Donor‐reactive memory T cells generated via heterologous immunity represent a potent barrier to long‐term graft survival following transplantation because of their increased precursor frequency, rapid effector function, altered trafficking patterns, and reduced reliance on costimulation signals for activation. Thus, the identification of pathways that control memory T cell survival and secondary recall potential may provide new opportunities for therapeutic intervention. Here, we discovered that donor‐specific effector/memory CD8⁺ T cell populations generated via exposure to acute vs latent vs chronic infections contain differential frequencies of CD8⁺ T cells expressing the inhibitory Fc receptor FcγRIIB. Results indicated that frequencies of FcγRIIB‐expressing CD8⁺ donor‐reactive memory T cells inversely correlated with allograft rejection. Furthermore, adoptive T cell transfer of Fcgr2b^?/? CD8⁺ T cells resulted in an accumulation of donor‐specific CD8⁺ memory T cells and enhanced recall responses, indicating that FcγRIIB functions intrinsically to limit T cell CD8⁺ survival in vivo. Lastly, we show that deletion of FcγRIIB on donor‐specific CD8⁺ memory T cells precipitated costimulation blockade‐resistant rejection. These data therefore identify a novel cell‐intrinsic inhibitory pathway that functions to limit the risk of memory T cell–mediated rejection following transplantation and suggest that therapeutic manipulation of this pathway could improve outcomes in sensitized patients.     

TIGIT regulates apoptosis of risky memory T cell subsets implicated in belatacept-resistant rejection

Belatacept confers increased patient and graft survival in renal transplant recipients relative to calcineurin inhibitors, but is associated with an increased rate of acute rejection. Recent immunophenotypic studies comparing pretransplant T cell phenotypes of patients who reject versus those who remain stable on belatacept identified three potential “risky” memory T cell subsets that potentially underlie belatacept-resistant rejection: CD4⁺ CD28⁺ T_EM, CD8⁺ CD28^null, and CD4⁺ CD57⁺ PD1⁻ subsets. Here, we compared key phenotypic and functional aspects of these human memory T cell subsets, with the goal of identifying additional potential targets to modulate them. Results demonstrate that TIGIT, an increasingly well-appreciated immune checkpoint receptor, was expressed on all three risky memory T cell subsets in vitro and in vivo in the presence of belatacept. Coculture of human memory CD4⁺ and CD8⁺ T cells with an agonistic anti-TIGIT mAb significantly increased apoptotic cell death of all three risky memory T cell subsets. Mechanistically, TIGIT-mediated apoptosis of risky memory T cells was dependent on FOXP3⁺ Treg, suggesting that agonism of the TIGIT pathway increases FOXP3⁺ Treg suppression of human memory T cell populations. Overall, these data suggest that TIGIT agonism could represent a new therapeutic target to inhibit belatacept-resistant rejection during transplantation.     

IL‐22 is required for the induction of bronchus‐associated lymphoid tissue in tolerant lung allografts

Long‐term survival after lung transplantation remains profoundly limited by graft rejection. Recent work has shown that bronchus‐associated lymphoid tissue (BALT), characterized by the development of peripheral nodal addressin (PNAd)‐expressing high endothelial venules and enriched in B and Foxp3⁺ T cells, is important for the maintenance of allograft tolerance. Mechanisms underlying BALT induction in tolerant pulmonary allografts, however, remain poorly understood. Here, we show that the development of PNAd‐expressing high endothelial venules within intragraft lymphoid follicles and the recruitment of B cells, but not Foxp3⁺ cells depends on IL‐22. We identify graft‐infiltrating gamma‐delta (γδ) T cells and Type 3 innate lymphoid cells (ILC3s) as important producers of IL‐22. Reconstitution of IL‐22 at late time points through retransplantation into wildtype hosts mediates B cell recruitment into lymphoid follicles within the allograft, resulting in a significant increase in their size, but does not induce PNAd expression. Our work has identified cellular and molecular requirements for the induction of BALT in pulmonary allografts during tolerance induction and may provide a platform for the development of new therapies for lung transplant patients.     

Selective CD28 Blockade Results in Superior Inhibition of Donor‐Specific T Follicular Helper Cell and Antibody Responses Relative to CTLA4‐Ig

Donor‐specific antibodies (DSAs) are a barrier to improved long‐term outcomes after kidney transplantation. Costimulation blockade with CTLA4‐Ig has shown promise as a potential therapeutic strategy to control DSAs. T follicular helper (Tfh) cells, a subset of CD4⁺ T cells required for optimal antibody production, are reliant on the CD28 costimulatory pathway. We have previously shown that selective CD28 blockade leads to superior allograft survival through improved control of CD8⁺ T cells relative to CTLA4‐Ig, but the impact of CD28‐specific blockade on CD4⁺ Tfh cells is unknown. Thus, we identified and characterized donor‐reactive Tfh cells in a murine skin transplant model and then used this model to evaluate the impact of selective CD28 blockade with an anti‐CD28 domain antibody (dAb) on the donor‐specific Tfh cell–mediated immune response. We observed that the anti‐CD28 dAb led to superior inhibition of donor‐reactive CXCR5⁺PD‐1^high Tfh cells, CD95⁺GL7⁺ germinal center B cells and DSA formation compared with CTLA4‐Ig. Interestingly, donor‐reactive Tfh cells differentially upregulated CTLA4 expression, suggesting an important role for CTLA4 in mediating the superior inhibition observed with the anti‐CD28 dAb. Therefore, selective CD28 blockade as a novel approach to control Tfh cell responses and prevent DSA after kidney transplantation warrants further study.     

Disruption of Transplant Tolerance by an “Incognito” Form of CD8 T Cell–Dependent Memory

Several approaches successfully achieve allograft tolerance in preclinical models but are challenging to translate into clinical practice. Many clinically relevant factors can attenuate allograft tolerance induction, including intrinsic genetic resistance, peritransplant infection, inflammation, and preexisting antidonor immunity. The prevailing view for immune memory as a tolerance barrier is that the host harbors memory cells that spontaneously cross‐react to donor MHC antigens. Such preexisting “heterologous” memory cells have direct reactivity to donor cells and resist most tolerance regimens. In this study, we developed a model system to determine if an alternative form of immune memory could also block tolerance. We posited that host memory T cells could potentially respond to donor‐derived non‐MHC antigens, such as latent viral antigens or autoantigens, to which the host is immune. Results show that immunity to a model nonself antigen, ovalbumin (OVA), can dramatically disrupt tolerance despite undetectable initial reactivity to donor MHC antigens. Importantly, this blockade of tolerance was CD8⁺ T cell–dependent and required linked antigen presentation of alloantigens with the test OVA antigen. As such, this pathway represents an unapparent, or “incognito,” form of immunity that is sufficient to prevent tolerance and that can be an unforeseen additional immune barrier to clinical transplant tolerance.     

Impact of Human Mutant TGFβ1/Fc Protein on Memory and Regulatory T Cell Homeostasis Following Lymphodepletion in Nonhuman Primates

Transforming growth factor β1 (TGFβ1) plays a key role in T cell homeostasis and peripheral tolerance. We evaluated the influence of a novel human mutant TGFβ1/Fc (human IgG4 Fc) fusion protein on memory CD4⁺ and CD8⁺ T cell (Tmem) responses in vitro and their recovery following antithymocyte globulin (ATG)–mediated lymphodepletion in monkeys. TGFβ1/Fc induced Smad2/3 protein phosphorylation in rhesus and human peripheral blood mononuclear cells and augmented the suppressive effect of rapamycin on rhesus Tmem proliferation after either alloactivation or anti‐CD3/CD28 stimulation. In combination with IL‐2, the incidence of CD4⁺CD25^hiFoxp3^hi regulatory T cells (Treg) and Treg:Th17 ratios were increased. In lymphodepleted monkeys, whole blood trough levels of infused TGFβ1/Fc were maintained between 2 and 7 μg/mL for 35 days. Following ATG administration, total T cell numbers were reduced markedly. In those given TGFβ1/Fc infusion, CD8⁺ T cell recovery to predepletion levels was delayed compared to controls. Additionally, numbers of CD4⁺CD25^hiCD127^lo Treg increased at 4–6 weeks after depletion but subsequently declined to predepletion levels by 12 weeks. In all monkeys, CD4⁺CD25^hiFoxp3^hi Treg/CD4⁺IL‐17⁺ cell ratios were reduced, particularly after stopping TGFβ1/Fc infusion. Thus, human TGFβ1/Fc infusion may delay Tmem recovery following lymphodepletion in nonhuman primates. Combined (low‐dose) IL‐2 infusion may be required to improve the Treg:Th17 ratio following lymphodepletion.     

Regulatory B Cell‐Dependent Islet Transplant Tolerance Is Also Natural Killer Cell Dependent

Immunologic tolerance to solid organ and islet cell grafts has been achieved in various rodent models by using antibodies directed at CD45RB and Tim‐1. We have shown that this form of tolerance depends on regulatory B cells (Bregs). To elucidate further the mechanism by which Bregs induce tolerance, we investigated the requirement of natural killer (NK) and NKT cells in this model. To do so, hyperglycemic B6, μMT, Beige, or CD1d^?/? mice received BALB/c islet grafts and treatment with the tolerance‐inducing regimen consisting of anti‐CD45RB and anti‐TIM1. B6 mice depleted of both NK and NKT cells by anti‐NK1.1 antibody and mice deficient in NK activity (Beige) did not develop tolerance after dual‐antibody treatment. In contrast, transplant tolerance induction was successful in CD1d^?/? recipients (deficient in NKT cells), indicating that NK, but not NKT, cells are essential in B cell–dependent tolerance. In addition, reconstitution of Beige host with NK cells restored the ability to induce transplant tolerance with dual‐antibody treatment. Transfer of tolerance by B cells from tolerant mice was also dependent on host Nk1.1⁺ cells. In conclusion, these results show that regulatory function of B cells is dependent on NK cells in this model of transplantation tolerance.     

Donor plasmacytoid dendritic cells modulate effector and regulatory T cell responses in mouse spontaneous liver transplant tolerance

We assessed the role of donor liver non-conventional plasmacytoid dendritic cells (pDCs) in spontaneous liver transplant tolerance in a fully MHC-mismatched (C57BL/6 (H2^b) to C3H (H2^k)) mouse model. Compared with spleen pDCs, liver pDCs expressed higher levels of DNAX-activating protein of 12 kDa and its co-receptor, triggering receptor expressed by myeloid cells 2, and higher ratios of programed death ligand-1 (PD-L1):costimulatory CD80/CD86 in the steady state and after Toll-like receptor 9 ligation. Moreover, liver pDCs potently suppressed allogeneic CD4⁺ and CD8⁺ T cell proliferative responses. Survival of pDC-depleted livers was much poorer (median survival time: 25 days) than that of either untreated donor livers or pDC-depleted syngeneic donor livers that survived indefinitely. Numbers of forkhead box p3 (FoxP3)⁺ regulatory T cells in grafts and mesenteric lymph nodes of mice given pDC-depleted allogeneic livers were reduced significantly compared with those in recipients of untreated livers. Graft-infiltrating CD8⁺ T cells with an exhausted phenotype (programed cell death protein 1⁺, T cell immunoglobulin and mucin domain-containing protein 3⁺) were also reduced in recipients of pDC-depleted livers. PD1-PD-L1 pathway blockade reversed the reduction in exhausted T cells. These novel observations link immunoregulatory functions of liver interstitial pDCs, alloreactive T cell exhaustion, and spontaneous liver transplant tolerance.     

Pathogen Stimulation History Impacts Donor‐Specific CD8+ T Cell Susceptibility to Costimulation/Integrin Blockade–Based Therapy

Recent studies have shown that the quantity of donor‐reactive memory T cells is an important factor in determining the relative heterologous immunity barrier posed during transplantation. Here, we hypothesized that the quality of T cell memory also potently influences the response to costimulation blockade‐based immunosuppression. Using a murine skin graft model of CD8⁺ memory T cell–mediated costimulation blockade resistance, we elicited donor‐reactive memory T cells using three distinct types of pathogen infections. Strikingly, we observed differential efficacy of a costimulation and integrin blockade regimen based on the type of pathogen used to elicit the donor‐reactive memory T cell response. Intriguingly, the most immunosuppression‐sensitive memory T cell populations were composed primarily of central memory cells that possessed greater recall potential, exhibited a less differentiated phenotype, and contained more multi‐cytokine producers. These data, therefore, demonstrate that the memory T cell barrier is dependent on the specific type of pathogen infection via which the donor‐reactive memory T cells are elicited, and suggest that the immune stimulation history of a given transplant patient may profoundly influence the relative barrier posed by heterologous immunity during transplantation.     

In Vivo Mobilization and Functional Characterization of Nonhuman Primate Monocytic Myeloid‐Derived Suppressor Cells

Increasing evidence from small animal models shows that myeloid‐derived suppressor cells (MDSCs) can play a crucial role in inhibiting allograft rejection and promoting transplant tolerance. We identified CD3^?CD20^?HLA‐DR^?CD14⁺CD33⁺CD11b⁺ cells in peripheral blood of healthy rhesus macaques. These putative monocytic MDSCs constituted 2.1% ± 1.7% of lin^?HLA‐DR^? peripheral blood mononuclear cells. Administration of granulocyte‐macrophage colony‐stimulating factor (CSF) and granulocyte CSF increased their incidence to 5.3% ± 3.4%. The total number of MDSCs that could be flow sorted from a single whole rhesus leukapheresis product was 38 ± 13 × 10⁶ (n = 10 monkeys). Freshly isolated or cryopreserved MDSCs from mobilized monkeys incorporated in cultures of anti‐CD3– and anti‐CD28–stimulated autologous T cells markedly suppressed CD4⁺ and CD8⁺ T cell proliferation and cytokine secretion (interferon γ, IL‐17A). Moreover, these MDSCs enhanced CD4⁺CD25^hiFoxp3⁺ regulatory T cell (Treg) expansion while inhibiting proliferation of activated memory T cells and increasing Treg relative to effector and terminally differentiated memory T cells. Inhibition of arginase‐1, but not inducible nitric oxide synthase activity, partially reversed the inhibitory effect of the MDSCs on CD8⁺ T cell proliferation. Consequently, functional MDSCs can be isolated from nonhuman primates for prospective use as therapeutic cellular vaccines in transplantation.

     

Donor‐Specific CD8+Foxp3+ T Cells Protect Skin Allografts and Facilitate Induction of Conventional CD4+Foxp3+ Regulatory T Cells

CD4⁺ regulatory T cells play a critical role in tolerance induction in transplantation. CD8⁺ suppressor T cells have also been shown to control alloimmune responses in preclinical and clinical models. However, the exact nature of the CD8⁺ suppressor T cells, their induction and mechanism of function in allogeneic transplantation remain elusive. In this study, we show that functionally suppressive, alloantigen‐specific CD8⁺Foxp3⁺ T cells can be induced and significantly expanded by stimulating naïve CD8⁺ T cells with donor dendritic cells in the presence of IL‐2, TGF‐β1 and retinoic acid. These CD8⁺Foxp3⁺ T cells express enhanced levels of CTLA‐4, CCR4 and CD103, inhibit the up‐regulation of costimulatory molecules on dendritic cells, and suppress CD4 and CD8 T cell proliferation and cytokine production in a donor‐specific and contact‐dependent manner. Importantly, upon adoptive transfer, the induced CD8⁺Foxp3⁺ T cells protect full MHC‐mismatched skin allografts. In vivo, the CD8⁺Foxp3⁺ T cells preferentially traffic to the graft draining lymph node where they induce conventional CD4⁺Foxp3⁺ T cells and concurrently suppress effector T cell expansion. We conclude that donor‐specific CD8⁺Foxp3⁺ suppressor T cells can be induced and exploited as an effective form of cell therapy for graft protection in transplantation.     

Association of Higher CD4+CD25highCD127low,FoxP3+, and IL‐2+ T Cell Frequencies Early After Lung Transplantation With Less Chronic Lung Allograft Dysfunction at Two Years

Regulatory T cells (Treg) can regulate alloantigens and may counteract chronic lung allograft dysfunction (CLAD) in lung transplantation. We analyzed Treg in peripheral blood prospectively and correlated percentages of subpopulations with the incidence of CLAD at 2 years. Among lung‐transplanted patients between January 2009 and July 2011, only patients with sufficient Treg measurements were included into the study. Tregs were measured immediately before lung transplantation, at 3 weeks and 3, 6, 12, and 24 months after transplantation and were defined as CD4⁺CD25^high T cells and further analyzed for CTLA4, CD127, FoxP3, and IL‐2 expressions. Between January 2009 and July 2011, 264 patients were transplanted at our institution. Among the 138 (52%) patients included into the study, 31 (22%) developed CLAD within 2 years after transplantation. As soon as 3 weeks after lung transplantation, a statistically significant positive association was detected between Treg frequencies and later absence of CLAD. At the multivariate analysis, increasing frequencies of CD4⁺CD25^highCD127^low, CD4⁺CD25^highFoxP3⁺ and CD4⁺CD25^highIL‐2⁺ T cells at 3 weeks after lung transplantation emerged as protective factors against development of CLAD at 2 years. In conclusion, higher frequencies of specific Treg subpopulations early after lung transplantation are protective against CLAD development.     

Uremia‐Associated Premature Aging of T Cells Does Not Predict Infectious Complications After Renal Transplantation

Patients with end‐stage renal disease have prematurely aged T cell systems. We tested whether T cell aging parameters were associated with the risk of infections after renal transplantation (RTx). We studied 188 patients over 1 year. Peripheral T cells were analyzed before and at 3 and 6 mo after RTx for frequency of recent thymic emigrants, relative telomere length and differentiation status. These parameters were related to the occurrence of opportunistic and serious infections. Overall, 84 patients developed an infection. In this group, 50 developed an opportunistic infection and 53 developed a serious infection. T cell aging parameters assessed before RTx were not associated with infection risk. The memory T cells showed a decrease within the first 3 mo in both groups (p < 0.001). The CD4⁺ memory T cells increased between 3 and 6 mo within the infection group (p = 0.015). The number of CD8⁺ memory T cells increased in both groups (p < 0.001) but reached baseline levels only in the infection group. In the infection group, the CD8⁺CD28^null T cell percentage increased between 3 and 6 mo (p = 0.024), tending to be higher than at baseline (p = 0.061). These differences in post‐RTx dynamics resulted from infections. Parameters of uremia‐associated premature aging of peripheral T cells do not predict posttransplant infections.