Virologic and Immunologic Monitoring of Cytomegalovirus to Guide Preemptive Therapy in Solid‐Organ Transplantation

Control of human cytomegalovirus (HCMV) infection during the posttransplant period was investigated in 134 solid‐organ transplant recipients by monitoring in parallel virologic and immunologic parameters for at least 1 year of follow‐up. Virologic monitoring was achieved by determining HCMV DNAemia with real‐time PCR, using the threshold of 300 000 DNA copies/mL blood as a cutoff for starting preemptive therapy. Immunologic monitoring included measurement of HCMV‐specific CD4+ and CD8+ T cells by cytokine flow cytometry, using HCMV‐infected dendritic cells as a stimulus. HCMV infection was diagnosed in 110 (82%) and required treatment in 49 (36%) patients. At 12 months after transplantation ‘protective’ immunity (≥0.4 CD4+ and CD8+ HCMV‐specific T cells/μL blood) was achieved in 115/129 (89%) patients. During the entire study period, 122 patients reconstituting HCMV‐specific CD4+ and CD8+ T‐cell immunity at 60 days posttransplant onward were able to control HCMV infection, except for one patient who developed HCMV disease because of a rejection episode. Patients reconstituting HCMV‐specific CD8+ only did not control HCMV infection. In conclusion, the presence of both HCMV‐specific CD4+ and CD8+ T cells ≥ 0.4/μL blood appears to be protective against HCMV disease. This result does not apply to patients undergoing antirejection treatment, or reconstituting HCMV‐specific CD8+ T cells only.     

Prospective Analysis of Human Cytomegalovirus DNAemia and Specific CD8+ T Cell Responses in Lung Transplant Recipients

In lung transplant recipients (LuTRs), human cytomegalovirus (HCMV) DNAemia may be associated with HCMV disease and reduced survival of the allograft. Because T cells are essential for controlling HCMV replication, we investigated in this prospective study whether the kinetics of plasma HCMV DNA loads in LuTRs are associated with HCMV‐specific CD8+ T cell responses, which were longitudinally assessed using a standardized assay. Sixty‐seven LuTRs were monitored during the first year posttransplantation, with a mean of 17 HCMV DNA PCR quantifications and 11.5 CD8+ T cell tests performed per patient. HCMV‐specific CD8+ T cell responses displayed variable kinetics in different patients, differed significantly before the onset of HCMV DNAemia in LuTRs who subsequently experienced episodes of DNAemia with high (>1000 copies/mL) and low plasma DNA levels (p = 0.0046, Fisher's exact test), and were absent before HCMV disease. In HCMV‐seropositive LuTRs, high‐level DNAemia requiring preemptive therapy occurred more frequently when HCMV‐specific CD8+ T cell responses fluctuated, were detected only after HCMV DNA detection, or remained undetectable (p = 0.0392, Fisher's exact test). Thus, our data indicate that HCMV‐specific CD8+ T cells influence the magnitude of HCMV DNAemia episodes, and we propose that a standardized measurement of CD8+ T cell immunity might contribute to monitoring the immune status of LuTRs posttransplantation.     

A prospective longitudinal analysis of cytomegalovirus (CMV)‐specific CD4+ and CD8+ T cells in kidney allograft recipients at risk of CMV infection

Cytomegalovirus (CMV)‐specific cellular immunity is essential in controlling CMV infection after transplantation. We investigated whether CMV‐specific T cell levels predict CMV DNAemia after kidney transplantation. Using cytokine‐flow cytometry, we enumerated interferon‐γ producing CMV‐specific CD4+ and CD8+ T cells at serial time points among CMV‐mismatched (D+/R?) and seropositive (R+) kidney recipients who received 3 months of valganciclovir prophylaxis. Among 44 patients, eight (18%) developed CMV DNAemia at a mean (±SD) time of 151 (±33) days after transplantation, including two (5%) with CMV syndrome and three (7%) with tissue‐invasive CMV disease. Cox proportional hazards regression analysis showed that CMV mismatch (D+/R?) status (HR: 13, 95% CI: 1.6–106.4; P = 0.02) and diabetes mellitus (HR: 5.6; 95%CI: 1.1–27.9; P = 0.03) were significantly associated with CMV DNAemia. In contrast, the percentage or change‐over‐time in CMV‐specific CD4+ [pp65 (P = 0.45), or CMV lysate (P = 0.22)] and CD8+ [pp65 (P = 0.43), or IE‐1 (P = 0.37)] T cells were not significantly associated with CMV DNAemia. CMV‐specific T cell assays have limited clinical utility among CMV R+ kidney recipients who received valganciclovir prophylaxis. On the other hand, the clinical utility of CMV‐specific T cell assays will need to be assessed in a larger cohort of CMV D+/R? kidney recipients who remain at high‐risk of delayed‐onset CMV disease.     

Characterization of HCV‐Specific CD4+Th17 Immunity in Recurrent Hepatitis C–Induced Liver Allograft Fibrosis

Hepatitis C virus (HCV) recurrence with accelerated fibrosis following orthotopic liver transplantation (OLT) is a universal phenomenon. To evaluate mechanisms contributing to HCV induced allograft fibrosis/cirrhosis, we investigated HCV‐specific CD4+Th17 cells and their induction in OLT recipients with recurrence utilizing 51 HCV+ OLT recipients, 15 healthy controls and 9 HCV‐ OLT recipients. Frequency of HCV specific CD4+ Tcells secreting IFN‐γ, IL‐17 and IL‐10 was analyzed by ELISpot. Serum cytokines and chemokines were analyzed by LUMINEX. Recipients with recurrent HCV induced allograft inflammation and fibrosis/cirrhosis demonstrated a significant increase in frequency of HCV specific CD4+Th17 cells. Increased pro‐inflammatory mediators (IL‐17, IL‐1β, IL‐6, IL‐8 and MCP‐1), decreased IFN‐γ, and increased IL‐4, IL‐5 and IL‐10 levels were identified. OLT recipients with allograft inflammation and fibrosis/cirrhosis demonstrated increased frequency of Foxp3+ regulatory T cells (Tregs) that inhibited HCV specific CD4+Th1 but not Th17 cells. This suggests that recurrent HCV infection in OLT recipients induces an inflammatory milieu characterized by increased IL‐6, IL‐1β and decreased IFN‐γ which facilitates induction of HCV specific CD4+Th17 cells. These cells are resistant to suppression by Tregs and may mediate an inflammatory cascade leading to cirrhosis in OLT recipients following HCV recurrence.     

LFA‐1 Antagonism Inhibits Early Infiltration of Endogenous Memory CD8 T Cells into Cardiac Allografts and Donor‐Reactive T Cell Priming

Alloreactive memory T cells are present in virtually all transplant recipients due to prior sensitization or heterologous immunity and mediate injury undermining graft outcome. In mouse models, endogenous memory CD8 T cells infiltrate MHC‐mismatched cardiac allografts and produce IFN‐γ in response to donor class I MHC within 24 h posttransplant. The current studies analyzed the efficacy of anti‐LFA‐1 mAb to inhibit early CD8 T cell cardiac allograft infiltration and activation. Anti‐LFA‐1 mAb given to C57BL/6 6 (H‐2^b) recipients of A/J (H‐2^a) heart grafts on days –1 and 0 completely inhibited CD8 T cell allograft infiltration, markedly decreased neutrophil infiltration and significantly reduced intragraft expression levels of IFN‐γ‐induced genes. Donor‐specific T cells producing IFN‐γ were at low/undetectable numbers in spleens of anti‐LFA‐1 mAb treated recipients until day 21. These effects combined to promote substantial prolongation (from day 8 to 27) in allograft survival. Delaying anti‐LFA‐1 mAb treatment until days 3 and 4 posttransplant did not inhibit early memory CD8 T cell infiltration and proliferation within the allograft. These data indicate that peritransplant anti‐LFA‐1 mAb inhibits early donor‐reactive memory CD8 T cell allograft infiltration and inflammation suggesting an effective strategy to attenuate the negative effects of heterologous immunity in transplant recipients.     

High‐Quality CMV‐Specific CD4+ Memory Is Enriched in the Lung Allograft and Is Associated With Mucosal Viral Control

The maintenance of CMV‐specific T cell memory in lung transplant recipients (LTRs) is critical for host defense and allograft durability, particularly in donor⁺/recipient^? (D⁺R^?) individuals who demonstrate increased mortality. We studied CD4⁺ and CD8⁺ CMV‐specific memory responses to phosphoprotein 65 (pp65) in a prospective cohort of 18 D⁺R^? LTRs, from bronchoalveolar lavage (BAL)‐obtained lung mononuclear cells (LMNC) and PBMC. Unexpectedly, pp65‐specific CD4⁺ and CD8⁺ IFN‐γ memory responses from LMNC were similar, in contrast to persistent CD8⁺ predominance in PBMC. Unlike the pulmonary CD8⁺ predominance during acute primary infection, compartmental equalization occurred in the CMV‐specific CD8⁺ memory pool during chronic infection, whereas CMV‐specific CD4⁺ memory was enriched in the bronchoalveolar space. Moreover, CMV‐specific CD4⁺ memory T cells with multifunctional production of IFN‐γ, TNF‐α, IL‐2 and MIP‐1β were significantly increased in LMNCs, in contrast to similar intercompartmental CD8⁺ memory function. Moreover, the absolute number of CMV‐specific CD4⁺IFN‐γ⁺ memory cells in BAL was significantly increased in LTRs exhibiting viral control compared to those with CMV early antigen positivity. Collectively, these data demonstrate both preferential distribution and functional quality of CMV‐specific CD4⁺ memory in the lung allograft during chronic infection, and show an important association with CMV mucosal immunity and viral control.     

CMV‐specific T‐cell immunity,viral load,and clinical outcome in seropositive renal transplant recipients: a pilot study

Sund F, Lidehäll A‐K, Claesson K, Foss A, Tötterman TH, Korsgren O, Eriksson B‐M. CMV‐specific T‐cell immunity, viral load, and clinical outcome in seropositive renal transplant recipients: a pilot study.
Clin Transplant 2010: 24: 401–409. © 2009 Wiley Periodicals, Inc. Abstract: Background: Cytomegalovirus (CMV) infection is still the leading opportunistic infection following solid organ transplantation. The aim of this prospective study of renal transplant recipients was to evaluate the dynamics of CMV‐specific T‐cells, viral load, and clinical symptoms of CMV infection. Methods: Levels of tetramer‐selected CD8⁺ T‐cells (TetraCD8), CMV‐specific interferon‐γ producing CD8⁺ T‐cells (IFNγCD8), and CD4⁺ T‐cells (IFNγCD4), measured using major histocompatibility complex‐tetramer and cytokine flow cytometry techniques, and CMV DNA were monitored monthly in 17 CMV‐seropositive patients up to one yr (median 12 months, range 3–12) after transplantation and correlated to clinical outcome. Results: CMV DNAemia was detected in 94% of the patients, but only one patient developed CMV disease. CMV DNAemia >1 million copies/mL was seen in asymptomatic patients. CMV‐specific T‐cells decreased rapidly after transplantation. TetraCD8 and IFNγCD8 regenerated within three months, whereas IFNγCD4 recovery was impaired up to one yr after transplantation. The proportion of IFNγCD4 at two months post‐transplantation as compared with baseline, correlated strongly with the magnitude of the CMV DNAemia. Conclusions: Monitoring the reduction of IFNγCD4 compared with baseline during the first months after transplantation could be considered in predicting risk for high‐grade CMV DNAemia and in deciding strategic approaches for pre‐emptive and prophylactic therapy.     

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.     

Inconsistent Responses of Cytomegalovirus-Specific T Cells to pp65 and IE-1 versus Infected Dendritic Cells in Organ Transplant Recipients

CD4(+) and CD8(+) T cells specific for human cytomegalovirus (HCMV) and two immunodominant HCMV antigens (pp65 and IE-1) were monitored in 20 solid organ transplant recipients undergoing primary (n = 4) or reactivated (n = 16) HCMV infection during the first year after transplantation by using as a stimulator either HCMV-infected autologous dendritic cells (DCs) or pp65- or IE-1 peptide mixtures. Turnaround times for test performance were 7 days for infected DCs and 24 h for peptides. Using infected DCs, HCMV-specific T-cell restoration occurred in all patients for CD8(+) and in 18/20 (90%) for CD4(+) T-cell subpopulations, resulting in virus clearance from blood. Using peptide mixtures, T-cell responses were less frequently detected. In detail, 14 (70%) patients showed pp65-specific CD8(+) T cells and 10 (50%) patients IE-1-specific CD8(+) T cells, whereas pp65-specific CD4(+) T cells were detected in 14 (70%) patients, and IE-1-specific CD4(+) T cells in three (15%) patients only. Protection from HCMV infection was associated with the presence of a HCMV-specific T-cell response directed against multiple viral proteins, but not against pp65 or IE-1 only. In conclusion, the use of pp65 and IE-1 peptide mixtures for rapid monitoring of HCMV-specific T-cell responses in solid organ transplant recipients underestimates the actual T-cell immune response against HCMV.     

Peritransplant VLA‐4 blockade inhibits endogenous memory CD8 T cell infiltration into high‐risk cardiac allografts and CTLA‐4Ig resistant rejection

Recipient endogenous memory CD8 T cells expressing reactivity to donor class I MHC infiltrate MHC‐mismatched cardiac allografts within 24 hours after reperfusion and express effector functions mediating graft injury. The current study tested the efficacy of Very Late Antigen‐4 (VLA‐4) blockade to inhibit endogenous memory CD8 T cell infiltration into cardiac allografts and attenuate early posttransplant inflammation. Peritransplant anti‐VLA‐4 mAb given to C57BL6 (H‐2^b) recipients of AJ (H‐2^a) heart allografts completely inhibited endogenous memory CD4 and CD8 T cell infiltration with significant decrease in macrophage, but not neutrophil, infiltration into allografts subjected to either minimal or prolonged cold ischemic storage (CIS) prior to transplant, reduced intra‐allograft IFN‐γ‐induced gene expression and prolonged survival of allografts subjected to prolonged CIS in CTLA‐4Ig treated recipients. Anti‐VLA‐4 mAb also inhibited priming of donor‐specific T cells producing IFN‐γ until at least day 7 posttransplant. Peritransplant anti‐VLA plus anti‐CD154 mAb treatment similarly prolonged survival of allografts subjected to minimal or increased CIS prior to transplant. Overall, these data indicate that peritransplant anti‐VLA‐4 mAb inhibits early infiltration memory CD8 T cell infiltration into allografts with a marked reduction in early graft inflammation suggesting an effective strategy to attenuate negative effects of heterologous alloimmunity in recipients of higher risk grafts.     

The immunobiology of pig‐to‐nonhuman primate islet xenotransplantation: insights,innovation, and impact

Previous studies of pig‐to‐non‐human primate (NHP) islet xenotransplantation have provided important insights into the immune recognition and effector pathways operative in this relevant preclinical model. The specifics of the xenograft product, microenvironment at the implantation site, and the immunosuppressive regimen significantly influence the mechanisms underlying the rejection of xenogeneic islets. Our current understanding of the immunological barriers to survival of pig islets in NHPs is largely based on studies on intraportal islet xenografts and on comparisons with islet allografts. The demonstration of cell‐mediated rejection of intraportal porcine islet xenografts at about 1 month posttransplant in monkeys immunosuppressed with the same protocols that prevent monkey islet allograft rejection indicates that islet xenograft rejection involves cellular mechanisms that are not present in acute islet allograft rejection. While these mechanisms remain poorly defined the demonstration of long‐term diabetes reversal after intraportal islet xenotransplantation in non‐human primates immunosuppressed with anti‐CD40L but not with anti‐CD40 antibody‐based protocols suggests that the therapeutic efficacy of anti‐CD40L in this transplantation setting likely involves the depletion of donor‐reactive, activated T cells besides CD40:CD40L costimulation blockade. Rejection of intraportal islet xenografts in NHPs immunosuppressed with CTLA4‐Ig and rapamycin was mediated largely by IL‐15‐primed, CXCR3+CD8+ memory T cells recruited by IP‐10 (CXCL10) positive pig islets and macrophages that showed staining for IL‐12 and iNOS. Adding basiliximab induction and tacrolimus maintenance therapy to this protocol prevented rejection in 24 of 26 recipients followed for up to 275 days. Comparison of both groups suggests, though by no means conclusive, that prolongation of graft survival in this large cohort was associated with reduced direct T cell responses to xenoantigens, reduced proportion of intrahepatic (intragraft) B cells and IFN‐γ+ and IL‐17+ CD4 and CD8 T cells, and increased local production of immunoregulatory molecules linked with Tregs, including TGF‐β, Foxp3, HO‐1, and IL‐10. Anti‐pig non‐Gal IgG antibody elicitation was suppressed in both groups. We are currently exploring the concept of negative vaccination to markedly minimize the need for immunosuppression in islet xenotransplantation. Peritransplant administration of donor apoptotic cells extended pig‐to‐mouse islet xenograft survival to >250 days when combined with peritransplant B cell‐depletion and rapamycin. This costimulation blockade‐sparing, antigen‐specific immunotherapy is expected to cause rapid pretransplant clonal deletion of indirect and anergy of direct xenospecific T cells while inducing regulatory T cells. As anti‐CD40L antibodies, B cell depleting antibodies are expected to interfere with indirect antigen presentation, costimulation, and cytokine production required for optimal T cell proliferation, memory formation, and intragraft CD8+ effector function. It is conceivable that additional strategies must be employed in NHPs and eventually in diabetic patients to achieve – as previously with anti‐CD40L antibodies – more complete, yet selective depletion of donor‐reactive, activated T‐cells for the purpose of stable xenograft acceptance.     

Endogenous Memory CD8 T Cells Are Activated Within Cardiac Allografts Without Mediating Rejection

Endogenous memory CD8 T cells infiltrate MHC‐mismatched cardiac allografts within 12–24 h posttransplant in mice and are activated to proliferate and produce IFN‐γ. To more accurately assess the graft injury directly imposed by these endogenous memory CD8 T cells, we took advantage of the ability of anti‐LFA‐1 mAb given to allograft recipients on days 3 and 4 posttransplant to inhibit the generation of primary effector T cells. When compared to grafts from IgG‐treated recipients on day 7 posttransplant, allografts from anti‐LFA‐1 mAb‐treated recipients had increased numbers of CD8 T cells but these grafts had marked decreases in expression levels of mRNA encoding effector mediators associated with graft injury and decreases in donor‐reactive CD8 T cells producing IFN‐γ. Despite this decreased activity within the allograft, CD8 T cells in allografts from recipients treated with anti‐LFA‐1 mAb continued to proliferate up to day 7 posttransplant and did not upregulate expression of the exhaustion marker LAG‐3 but did have decreased expression of ICOS. These results indicate that endogenous memory CD8 T cells infiltrate and proliferate in cardiac allografts in mice but do not express sufficient levels of functions to mediate overt graft injury and acute rejection.     

A Novel Xenogeneic Graft‐Versus‐Host Disease Model for Investigating the Pathological Role of Human CD4+ or CD8+ T Cells Using Immunodeficient NOG Mice

Graft‐versus‐host disease (GVHD) is a major complication of allogenic bone marrow transplantation and involves the infiltration of donor CD4⁺ and/or CD8⁺ T cells into various organs of the recipient. The pathological role of human CD4⁺ and CD8⁺ T cells in GVHD remains controversial. In this study, we established two novel xenogeneic (xeno)‐GVHD models. Human CD4⁺ or CD8⁺ T cells were purified from peripheral blood and were transplanted into immunodeficient NOD/Shi‐scid IL2rg^null (NOG) mice. Human CD8⁺ T cells did not induce major GVHD symptoms in conventional NOG mice. However, CD8⁺ T cells immediately proliferated and induced severe GVHD when transferred into NOG mice together with at least 0.5 × 10⁶ CD4⁺ T cells or into NOG human interleukin (IL)‐2 transgenic mice. Human CD4⁺ T cell–transplanted NOG mice developed skin inflammations including alopecia, epidermal hyperplasia, and neutrophilia. Pathogenic T helper (Th)17 cells accumulated in the skin of CD4⁺ T cell–transplanted NOG mice. Further, an anti‐human IL‐17 antibody (secukinumab) significantly suppressed these skin pathologies. These results indicate that pathogenic human Th17 cells induce cutaneous GVHD via IL‐17–dependent pathways. This study provides fundamental insights into the pathogenesis of xeno‐GVHD, and these humanized mouse models may be useful as preclinical tools for the prevention of GVHD.     

The Allo‐ and Viral‐Specific Immunosuppressive Effect of Belatacept,but Not Tacrolimus,Attenuates With Progressive T Cell Maturation

Tacrolimus impairs allo‐ and viral‐specific T cell responses. Belatacept, a costimulation‐based alternative to tacrolimus, has emerged with a paradoxical picture of less complete control of alloimmunity with concomitant impaired viral immunity limited to viral‐naïve patients. To reconcile these signatures, bulk population and purified memory and naïve lymphocytes from cytomegalovirus (CMV)‐seropositive (n = 10) and CMV‐seronegative (n = 10) volunteers were studied using flow cytometry, interrogating proliferation (carboxyfluorescein succinimidyl ester dilution) and function (intracellular cytokine staining) in response to alloantigens or CMV‐pp‐65 peptides. As anticipated, T cells from CMV‐experienced, but not naïve, individuals responded to pp‐65 with a small percentage of their repertoire (<2.5%) consisting predominantly of mature, polyfunctional (expressing interferon gamma, tumor necrosis factor alpha and IL‐2) T effector memory cells. Both CMV naïve and experienced individuals responded similarly to alloantigen with a substantially larger percentage of the repertoire (up to 48.2%) containing proportionately fewer polyfunctional cells. Tacrolimus completely inhibited responses of CMV‐ and allo‐specific T cells regardless of their maturation. However, belatacept's effects were decreasingly evident in increasingly matured cells, with minimal effect on viral‐specific triple cytokine producers and CD28‐negative allo‐specific cells. These data indicate that belatacept's immunosuppressive effect, unlike tacrolimus's, wanes on progressively developed effector responses, and may explain the observed clinical effects of belatacept.     

Rapamycin ameliorates the CTLA4‐Ig–mediated defect in CD8+ T cell immunity during gammaherpesvirus infection

Latent viral infections are a major concern among immunosuppressed transplant patients. During clinical trials with belatacept, a CTLA4‐Ig fusion protein, patients showed an increased risk of Epstein–Barr virus‐associated posttransplant lymphoproliferative disorder, thought to be due to a deficient primary CD8⁺ T cell response to the virus. Using a murine model of latent viral infection, we observed that rapamycin treatment alone led to a significant increase in virus‐specific CD8⁺ T cells, as well as increased functionality of these cells, including the ability to make multiple cytokines, while CTLA4‐Ig treatment alone significantly dampened the response and inhibited the generation of polyfunctional antigen‐specific CD8⁺ T cells. However, the addition of rapamycin to the CTLA4‐Ig regimen was able to quantitatively and qualitatively restore the antigen‐specific CD8⁺ T cell response to the virus. This improvement was physiologically relevant, in that CTLA4‐Ig treated animals exhibited a greater viral burden following infection that was reduced to levels observed in untreated immunocompetent animals by the addition of rapamycin. These results reveal that modulation of T cell differentiation though inhibition of mTOR signaling can restore virus‐specific immune competence even in the absence of CD28 costimulation, and have implications for improving protective immunity in transplant recipients.     

Pretransplant Interferon‐γ Secretion by CMV‐Specific CD8+ T Cells Informs the Risk of CMV Replication After Transplantation

In this prospective study we analyzed pretransplant interferon‐γ secretion by cytomegalovirus (CMV)‐specific CD8+ T cells to assess its possible utility in determining the risk of CMV replication after solid organ transplantation. A total of 113 lung and kidney transplant patients were enrolled in the study but only 55 were evaluable. All CMV‐seronegative recipients were pretransplant “nonreactive” (IFNγ <0.2 IU/mL) (11/11), whereas 30/44 (68.2%) CMV‐seropositive (R+) recipients were “reactive” (IFNγ ≥0.2 IU/mL) and 14/44 (31.8%) were “nonreactive”. In the R(+) “nonreactive” group, 7/14 (50%) developed posttransplant CMV replication, whereas the virus replicated only in 4/30 (13.3%) of the R(+) “reactive” patients (p = 0.021). According to the best multivariate model, pretransplant “nonreactive” recipients receiving an organ from a CMV‐seropositive donor had a 10‐fold increased risk of CMV replication compared to pretransplant “reactive” recipients (adjusted OR 10.49, 95% CI 1.88–58.46). This model displayed good discrimination ability (AUC 0.80) and calibration (Hosmer–Lemeshow test, p = 0.92). Negative and positive predictive values were 83.7% and 75%, respectively. The accuracy of the model was 82%. Therefore, assessment of interferon‐γ secretion by cytomegalovirus (CMV)‐specific CD8+ T cells prior to transplantation is useful in informing the risk of posttransplant CMV replication in solid organ transplant patients.     

Cyclosporine A Drives a Th17‐ and Th2‐Mediated Posttransplant Obliterative Airway Disease

Calcineurin‐inhibitor refractory bronchiolitis obliterans (BO) represents the leading cause of late graft failure after lung transplantation. T helper (Th)2 and Th17 lymphocytes have been associated with BO development. Taking advantage of a fully allogeneic trachea transplantation model in mice, we addressed the pathogenicity of Th cells in obliterative airway disease (OAD) occurring in cyclosporine A (CsA)‐treated recipients. We found that CsA prevented CD8⁺ T cell infiltration into the graft and downregulated the Th1 response but affected neither Th2 nor Th17 responses in vivo. In secondary mixed lymphocyte cultures, CsA dramatically decreased donor‐specific IFN‐γ production, enhanced IL‐17 production and did not affect IL‐13. As CD4⁺ depletion efficiently prevented OAD in CsA‐treated recipients, we further explored the role of Th2 and Th17 immunity in vivo. Although IL‐4 and IL‐17 deficient untreated mice developed an OAD comparable to wild‐type recipients, a single cytokine deficiency afforded significant protection in CsA‐treated recipients. In conclusion, CsA treatment unbalances T helper alloreactivity and favors Th2 and Th17 as coexisting pathways mediating chronic rejection of heterotopic tracheal allografts.     

Immune Responses to Collagen‐IV and Fibronectin in Renal Transplant Recipients With Transplant Glomerulopathy

Antibodies (Abs) to donor HLA (donor‐specific antibodies [DSA]) have been associated with transplant glomerulopathy (TG) following kidney transplantation (KTx). Immune responses to tissue‐restricted self‐antigens (self‐Ags) have been proposed to play a role in chronic rejection. We determined whether KTx with TG have immune responses to self‐Ags, Collagen‐IV (Col‐IV) and fibronectin (FN). DSA were determined by solid phase assay, Abs against Col‐IV and FN by enzyme‐linked immunosorbent assay and CD4+ T cells secreting interferon gamma (IFN‐γ), IL‐17 or IL‐10 by ELISPOT. Development of Abs to self‐Ags following KTx increased the risk for TG with an odds ratio of 22 (p‐value = 0.001). Abs to self‐Ags were IgG and IgM isotypes. Pretransplant Abs to self‐Ags increased the risk of TG (22% vs. 10%, p < 0.05). Abs to self‐Ags were identified frequently in KTx with DSA. TG patients demonstrated increased Col‐IV and FN specific CD4+ T cells secreting IFN‐γ and IL‐17 with reduction in IL‐10. We conclude that development of Abs to self‐Ags is a risk factor and having both DSA and Abs to self‐Ags increases the risk for TG. The increased frequency of self‐Ag‐specific IFN‐γ and IL‐17 cells with reduction in IL‐10 demonstrate tolerance breakdown to self‐Ags which we propose play a role in the pathogenesis of TG.     

Cytomegalovirus-specific regulatory and effector T cells share TCR clonality--possible relation to repetitive CMV infections

Cytomegalovirus (CMV) infections have a major impact on morbidity and mortality of transplant patients. Among the complex antiviral T‐cell response, CMV‐IE‐1 antigen‐specific CD8+ cells are crucial for preventing CMV disease but do not protect from recurring/lasting CMV reactivation. Recently, we confirmed that adoptive transfer of autologous IE‐1/pp65‐specific T‐cell lines was able to combat severe CMV disease; however, the control of CMV infection was only temporary. We hypothesized that CMV‐induced regulatory T cells (iTreg) might be related to recurring/lasting CMV infection. In fact, kidney transplant patients with recurring CMV infections expressed enhanced suppression on CMV response. Analysis of in vitro expanded CD4+ epitope‐specific cells revealed that CMV‐specific CD4+CD25^high Treg cells functionally suppress CD25^low effector T cells (Teff) upon epitope‐specific reactivation. Their phenotype is similar to iTreg – CD39^high/Helios‐/IL‐2^low/IFNγ^high/IL‐10±/TGFß‐LAP±/FOXP3+ and methylated foxp3 locus. Remarkably, in vitro expanded CD4+CD25^high iTreg share the same dominant TCR‐Vβ‐CDR3 clones with functionally distinct CD4+CD25^low Teff. Moreover, the same clones were present in freshly isolated CD4+CD25^high and CD4+CD25^low T cells suggesting their in vivo generation. These findings directly demonstrate that Teff and iTreg can differentiate from one “mother” clone with specificity to the same viral epitope and indicate that peripheral iTreg generation is related to frequent antigen appearance.     

Disengaging the IL‐2 Receptor with Daclizumab Enhances IL‐7–Mediated Proliferation of CD4+ and CD8+ T Cells

Allograft rejection is mainly driven by the production of IL‐2, which expands T cells by linking the IL‐2 receptor (IL‐2R) composed of three subunits: CD25, CD122 and CD132. Daclizumab, widely used in immunosuppression, is a humanized anti‐CD25 antibody that disrupts IL‐2 signaling by binding to CD25 and preventing the assembly of the high‐affinity IL‐2R. Here we show that Daclizumab, while blocking the T‐cell response to IL‐2, increases CD4⁺ and CD8⁺ T‐cell proliferative response to the homeostatic cytokine IL‐7. The IL‐7R shares CD132 with the IL‐2R and blocking of CD25 by Daclizumab results in the enhanced formation of the IL‐7R that in turn allows IL‐7 to bind more efficiently on the cell surface. The consequently increased IL‐7R signaling boosts intracellular phosphorylated STAT5 and T‐cell proliferation. In addition, treatment with Daclizumab delays the internalization of CD127 upon IL‐7 treatment, retaining T‐cell sensitivity to IL‐7 for a prolonged time. This effect of Daclizumab highlights the redundancy of the cytokine system, which may influence T‐cell proliferation in transplanted patients, and provides information to improve future immunosuppressive strategies.