Molecular Assessment of Microcirculation Injury in Formalin‐Fixed Human Cardiac Allograft Biopsies With Antibody‐Mediated Rejection

Precise diagnosis of antibody‐mediated rejection (AMR) in cardiac allograft endomyocardial biopsies (EMBs) remains challenging. This study assessed molecular diagnostics in human EMBs with AMR. A set of 34 endothelial, natural killer cell and inflammatory genes was quantified in 106 formalin‐fixed, paraffin‐embedded EMBs classified according to 2013 International Society for Heart and Lung Transplantation (ISHLT) criteria. The gene set expression was compared between ISHLT diagnoses and correlated with donor‐specific antibody (DSA), endothelial injury by electron microscopy (EM) and prognosis. Findings were validated in an independent set of 57 EMBs. In the training set (n = 106), AMR cases (n = 70) showed higher gene set expression than acute cellular rejection (ACR; n = 21, p < 0.001) and controls (n = 15, p < 0.0001). Anti‐HLA DSA positivity was associated with higher gene set expression (p = 0.01). Endothelial injury by electron microscopy strongly correlated with gene set expression, specifically in AMR cases (r = 0.62, p = 0.002). Receiver operating characteristic curve analysis for diagnosing AMR showed greater accuracy with gene set expression (area under the curve [AUC] = 79.88) than with DSA (AUC = 70.47) and C4d (AUC = 70.71). In AMR patients (n = 17) with sequential biopsies, increasing gene set expression was associated with inferior prognosis (p = 0.034). These findings were confirmed in the validation set. In conclusion, biopsy‐based molecular assessment of antibody‐mediated microcirculation injury has the potential to improve diagnosis of AMR in human cardiac transplants.     

Th‐17 Alloimmune Responses in Renal Allograft Biopsies From Recipients of Kidney Transplants Using Extended Criteria Donors During Acute T Cell–Mediated Rejection

Although renal transplantation using expanded criteria donors has become a common practice, immune responses related to immunosenescence in those kidney allografts have not been studied yet in humans. We performed a retrospective molecular analysis of the T cell immune response in 43 kidney biopsies from patients with acute T cell–mediated rejection including 25 from recipients engrafted with a kidney from expanded criteria donor and 18 from recipients grafted with optimal kidney allograft. The clinical, transplant and acute T cell–mediated rejection characteristics of both groups were similar at baseline. The expression of RORγt, Il‐17 and T‐bet mRNA was significantly higher in the elderly than in the optimal group (p = 0.02, p = 0.036, and p = 0.01, respectively). Foxp3 mRNA levels were significantly higher in elderly patients experiencing successful acute T cell–mediated rejection reversal (p = 0.03). The presence of IL‐17 mRNA was strongly associated with nonsuccessful reversal in elderly patients (p = 0.008). Patients with mRNA IL17 expression detection and low mRNA Foxp3 expression experienced significantly more treatment failure (87.5%) than patients with no mRNA IL17 expression and/or high mRNA Foxp3 expression (26.7%; p = 0.017). Our study suggests that the Th17 pathway is involved in pathogenesis and prognosis of acute T cell–mediated rejection in recipients of expanded criteria allograft.     

Dominant regulation of long‐term allograft survival is mediated by microRNA‐142

Organ transplantation is often lifesaving, but the long‐term deleterious effects of combinatorial immunosuppression regimens and allograft failure cause significant morbidity and mortality. Long‐term graft survival in the absence of continuing immunosuppression, defined as operational tolerance, has never been described in the context of multiple major histocompatibility complex (MHC) mismatches. Here, we show that miR‐142 deficiency leads to indefinite allograft survival in a fully MHC mismatched murine cardiac transplant model in the absence of exogenous immunosuppression. We demonstrate that the cause of indefinite allograft survival in the absence of miR‐142 maps specifically to the T cell compartment. Of therapeutic relevance, temporal deletion of miR‐142 in adult mice prior to transplantation of a fully MHC mismatched skin allograft resulted in prolonged allograft survival. Mechanistically, miR‐142 directly targets Tgfbr1 for repression in regulatory T cells (T_REG). This leads to increased T_REG sensitivity to transforming growth factor – beta and promotes transplant tolerance via an augmented peripheral T_REG response in the absence of miR‐142. These data identify manipulation of miR‐142 as a promising approach for the induction of tolerance in human transplantation.     

Basophils Trigger Fibroblast Activation in Cardiac Allograft Fibrosis Development

Fibrosis is a major component of chronic cardiac allograft rejection. Although several cell types are able to produce collagen, resident (donor‐derived) fibroblasts are mainly responsible for excessive production of extracellular matrix proteins. It is currently unclear which cells regulate production of connective tissue elements in allograft fibrosis and how basophils, as potential producers of profibrotic cytokines, are involved this process. We studied this question in a fully MHC‐mismatched model of heart transplantation with transient depletion of CD4⁺ T cells to largely prevent acute rejection. The model is characterized by myocardial infiltration of leukocytes and development of interstitial fibrosis and allograft vasculopathy. Using depletion of basophils, IL‐4–deficient recipients and IL‐4 receptor–deficient grafts, we showed that basophils and IL‐4 play crucial roles in activation of fibroblasts and development of fibrotic organ remodeling. In the absence of CD4⁺ T cells, basophils are the predominant source of IL‐4 in the graft and contribute to expansion of myofibroblasts, interstitial deposition of collagen and development of allograft vasculopathy. Our results indicated that basophils trigger the production of various connective tissue elements by myofibroblasts. Basophil‐derived IL‐4 may be an attractive target for treatment of chronic allograft rejection.     

Paneth and intestinal stem cells preserve their functional integrity during worsening of acute cellular rejection in small bowel transplantation

Graft survival after small bowel transplantation remains impaired due to acute cellular rejection (ACR), the leading cause of graft loss. Although it was shown that the number of enteroendocrine progenitor cells in intestinal crypts was reduced during mild ACR, no results of Paneth and intestinal stem cells localized at the crypt bottom have been shown so far. Therefore, we wanted to elucidate integrity and functionality of the Paneth and stem cells during different degrees of ACR, and to assess whether these cells are the primary targets of the rejection process. We compared biopsies from ITx patients with no, mild, or moderate ACR by immunohistochemistry and quantitative PCR. Our results show that numbers of Paneth and stem cells remain constant in all study groups, whereas the transit‐amplifying zone is the most impaired zone during ACR. We detected an unchanged level of antimicrobial peptides in Paneth cells and similar numbers of Ki‐67⁺ IL‐22R⁺ stem cells revealing cell functionality in moderate ACR samples. We conclude that Paneth and stem cells are not primary target cells during ACR. IL‐22R⁺ Ki‐67⁺ stem cells might be an interesting target cell population for protection and regeneration of the epithelial monolayer during/after a severe ACR in ITx patients.     

miR-21 antagonism reprograms macrophage metabolism and abrogates chronic allograft vasculopathy

Despite much progress in improving graft outcome during cardiac transplantation, chronic allograft vasculopathy (CAV) remains an impediment to long-term graft survival. MicroRNAs (miRNAs) emerged as regulators of the immune response. Here, we aimed to examine the miRNA network involved in CAV. miRNA profiling of heart samples obtained from a murine model of CAV and from cardiac-transplanted patients with CAV demonstrated that miR-21 was most significantly expressed and was primarily localized to macrophages. Interestingly, macrophage depletion with clodronate did not significantly prolong allograft survival in mice, while conditional deletion of miR-21 in macrophages or the use of a specific miR-21 antagomir resulted in indefinite cardiac allograft survival and abrogated CAV. The immunophenotype, secretome, ability to phagocytose, migration, and antigen presentation of macrophages were unaffected by miR-21 targeting, while macrophage metabolism was reprogrammed, with a shift toward oxidative phosphorylation in naïve macrophages and with an inhibition of glycolysis in pro-inflammatory macrophages. The aforementioned effects resulted in an increase in M2-like macrophages, which could be reverted by the addition of L-arginine. RNA-seq analysis confirmed alterations in arginase-associated pathways associated with miR-21 antagonism. In conclusion, miR-21 is overexpressed in murine and human CAV, and its targeting delays CAV onset by reprogramming macrophages metabolism.     

IL‐17 Deficiency Attenuates Allograft Injury and Prolongs Survival in a Murine Model of Fully MHC‐Mismatched Renal Allograft Transplantation

IL‐17 is a pro‐inflammatory cytokine implicated in the pathogenesis of inflammatory and autoimmune diseases. However the role of IL‐17 in renal allograft rejection has not been fully explored. Here, we investigate the impact of IL‐17 in a fully MHC‐mismatched, life‐sustaining, murine model of kidney allograft rejection using IL‐17 deficient donors and recipients (IL‐17^?/? allografts). IL‐17^?/? allografts exhibited prolonged survival which was associated with reduced expression of the Th1 cytokine IFN‐γ and histological attenuation of acute and chronic allograft rejection, as compared to wild‐type allograft recipients. Results were confirmed in WT allograft recipients treated with an IL‐17 blocking antibody. Subsequent experiments using either donors or recipients deficient in IL‐17 showed a trend towards prolongation of survival only when recipients were IL‐17^?/?. Administration of a depleting anti‐CD25 antibody to IL‐17^?/? recipients abrogated the survival advantage conferred by IL‐17 deficiency, suggesting the involvement of a CD4⁺CD25⁺ T cell regulatory mechanism. Therefore, IL‐17 deficiency or neutralization was protective against the development of kidney allograft rejection, which may be mediated by impairment of Th1 responses and/or enhanced protection by Tregs.

     

Identification and Characterization of microRNAs Associated With Human β‐Cell Loss in a Mouse Model

Currently there is no effective approach for monitoring early β‐cell loss during islet graft rejection following human islet transplantation (HIT). Due to ethical and technical constraints, it is difficult to directly study biomarkers of islet destruction in humans. Here, we established a humanized mouse model with induced human β‐cell death using adoptive lymphocyte transfer (ALT). Human islet grafts of ALT‐treated mice had perigraft lymphocyte infiltration, fewer insulin⁺ β cells, and increased β‐cell apoptosis. Islet‐specific miR‐375 was used to validate our model, and expression of miR‐375 was significantly decreased in the grafts and increased in the circulation of ALT‐treated mice before hyperglycemia. A NanoString expression assay was further used to profile 800 human miRNAs in the human islet grafts, and the results were validated using quantitative real‐time polymerase chain reaction. We found that miR‐4454 and miR‐199a‐5p were decreased in the human islet grafts following ALT and increased in the circulation prior to hyperglycemia. These data demonstrate that our in vivo model of induced human β‐cell destruction is a robust method for identifying and characterizing circulating biomarkers, and suggest that miR‐4454 and miR‐199a‐5p can serve as novel biomarkers associated with early human β‐cell loss following HIT.     

MicroRNA Profiles in Allograft Tissues and Paired Urines Associate With Chronic Allograft Dysfunction With IF/TA

Despite the advances in immunosuppression, renal allograft attrition over time remains unabated due to chronic allograft dysfunction (CAD) with interstitial fibrosis (IF) and tubular atrophy (TA). We aimed to evaluate microRNA (miRNA) signatures in CAD with IF/TA and appraise correlation with paired urine samples and potential utility in prospective evaluation of graft function. MiRNA signatures were established between CAD with IF/TA versus normal allografts by microarray. Validation of the microarray results and prospective evaluation of urine samples was performed using real‐time quantitative‐PCR (RT‐qPCR). Fifty‐six miRNAs were identified in samples with CAD‐IF/TA. Five miRNAs were selected for further validation based on array fold change, p‐value and in silico predicted mRNA targets. We confirmed the differential expression of these five miRNAs by RT‐qPCR using an independent set of samples. Differential expression was detected for miR‐142‐3p, miR‐204, miR‐107 and miR‐211 (p < 0.001) and miR‐32 (p < 0.05). Furthermore, differential expression of miR‐142‐3p (p < 0.01), miR‐204 (p < 0.01) and miR‐211 (p < 0.05) was also observed between patient groups in urine samples. A characteristic miRNA signature for IF/TA that correlates with paired urine samples was identified. These results support the potential use of miRNAs as noninvasive markers of IF/TA and for monitoring graft function.     

Late Failing Heart Allografts: Pathology of Cardiac Allograft Vasculopathy and Association With Antibody‐Mediated Rejection

In heart transplantation, there is a lack of robust evidence of the specific causes of late allograft failure. We hypothesized that a substantial fraction of failing heart allografts may be associated with antibody‐mediated injury and immune‐mediated coronary arteriosclerosis. We included all patients undergoing a retransplantation for late terminal heart allograft failure in three referral centers. We performed an integrative strategy of heart allograft phenotyping by assessing the heart vascular tree including histopathology and immunohistochemistry together with circulating donor‐specific antibodies. The main analysis included 40 explanted heart allografts patients and 402 endomyocardial biopsies performed before allograft loss. Overall, antibody‐mediated rejection was observed in 19 (47.5%) failing heart allografts including 16 patients (40%) in whom unrecognized previous episodes of subclinical antibody‐mediated rejection occurred 4.5 ± 3.5 years before allograft loss. Explanted allografts with evidence of antibody‐mediated rejection demonstrated higher endothelitis and microvascular inflammation scores (0.89 ± 0.26 and 2.25 ± 0.28, respectively) compared with explanted allografts without antibody‐mediated rejection (0.42 ± 0.11 and 0.36 ± 0.09, p = 0.046 and p < 0.0001, respectively). Antibody‐mediated injury was observed in 62.1% of failing allografts with pure coronary arteriosclerosis and mixed (arteriosclerosis and atherosclerosis) pattern, while it was not observed in patients with pure coronary atherosclerosis (p = 0.0076). We demonstrate that antibody‐mediated rejection is operating in a substantial fraction of failing heart allografts and is associated with severe coronary arteriosclerosis. Unrecognized subclinical antibody‐mediated rejection episodes may be observed years before allograft failure.     

A Novel,Blocking, Fc‐Silent Anti‐CD40 Monoclonal Antibody Prolongs Nonhuman Primate Renal Allograft Survival in the Absence of B Cell Depletion

CD40–CD154 pathway blockade prolongs renal allograft survival in nonhuman primates (NHPs). However, antibodies targeting CD154 were associated with an increased incidence of thromboembolic complications. Antibodies targeting CD40 prolong renal allograft survival in NHPs without thromboembolic events but with accompanying B cell depletion, raising the question of the relative contribution of B cell depletion to the efficacy of anti‐CD40 blockade. Here, we investigated whether fully silencing Fc effector functions of an anti‐CD40 antibody can still promote graft survival. The parent anti‐CD40 monoclonal antibody HCD122 prolonged allograft survival in MHC‐mismatched cynomolgus monkey renal allograft transplantation (52, 22, and 24 days) with accompanying B cell depletion. Fc‐silencing yielded CFZ533, an antibody incapable of B cell depletion but still able to potently inhibit CD40 pathway activation. CFZ533 prolonged allograft survival and function up to a defined protocol endpoint of 98–100 days (100, 100, 100, 98, and 76 days) in the absence of B cell depletion and preservation of good histological graft morphology. CFZ533 was well‐tolerated, with no evidence of thromboembolic events or CD40 pathway activation and suppressed a gene signature associated with acute rejection. Thus, use of the Fc‐silent anti‐CD40 antibody CFZ533 appears to be an attractive approach for preventing solid organ transplant rejection.     

Back signaling of HLA class I molecules and T/NK cell receptor ligands in epithelial cells reflects the rejection‐specific microenvironment in renal allograft biopsies

The role of endothelial cells in the pathophysiology of antibody‐mediated rejection after renal transplantation has been widely investigated. We expand this scenario to the impact of epithelial cells on the microenvironment during rejection. Primary proximal tubular epithelial cells were stimulated via HLA class I, CD155 and CD166 based on their potential signal‐transducing capacity to mediate back signaling after encounter with either T/NK cells or donor‐specific antibodies. Upon crosslinking of these ligands with mAbs, PTEC secreted IL‐6, CXCL1,8,10, CCL2, and sICAM‐1. These proteins were also released by PTEC as consequence of a direct interaction with T/NK cells. Downmodulation of the receptor CD226 on effector cells confirmed the involvement of this receptor/ligand pair in back signaling. In vivo, CD155 and CD166 expression was detectable in proximal and distal tubuli of renal transplant biopsies, respectively. The composition of the protein microenvironment in these biopsies showed a substantial overlap with the PTEC response. Cluster and principal component analyses of the microenvironment separated unsuspicious from rejection biopsies and, furthermore, ABMR, TCMR, and borderline rejection. In conclusion, our results provide evidence that epithelial cells may contribute to the rejection process and pave the way to a better understanding of the pathomechanisms of kidney allograft rejection.     

Control of Immune Response to Allogeneic Embryonic Stem Cells by CD3 Antibody–Mediated Operational Tolerance Induction

Implantation of embryonic stem cells (ESCs) and their differentiated derivatives into allogeneic hosts triggers an immune response that represents a hurdle to clinical application. We established in autoimmunity and in transplantation that CD3 antibody therapy induces a state of immune tolerance. Promising results have been obtained with CD3 antibodies in the clinic. In this study, we tested whether this strategy can prolong the survival of undifferentiated ESCs and their differentiated derivatives in histoincompatible hosts. Recipients of either mouse ESC–derived embryoid bodies (EBs) or cardiac progenitors received a single short tolerogenic regimen of CD3 antibody. In immunocompetent mice, allogeneic EBs and cardiac progenitors were rejected within 20–25 days. Recipients treated with CD3 antibody showed long‐term survival of implanted cardiac progenitors or EBs. In due course, EBs became teratomas, the growth of which was self‐limited. Regulatory CD4⁺FoxP3⁺ T cells and signaling through the PD1/PDL1 pathway played key roles in the CD3 antibody therapeutic effect. Gene profiling emphasized the importance of TGF‐β and the inhibitory T cell coreceptor Tim3 to the observed effect. These results demonstrate that CD3 antibody administered alone promotes prolonged survival of allogeneic ESC derivatives and thus could prove useful for enhancing cell engraftment in the absence of chronic immunosuppression.     

Myeloid‐derived suppressor cells increase and inhibit donor‐reactive T cell responses to graft intestinal epithelium in intestinal transplant patients

Recent advances in immunosuppressive regimens have decreased acute cellular rejection (ACR) rates and improved intestinal and multivisceral transplant (ITx) recipient survival. We investigated the role of myeloid‐derived suppressor cells (MDSCs) in ITx. We identified MDSCs as CD33⁺CD11b⁺ lineage(CD3/CD56/CD19)^?HLA‐DR^?/low cells with 3 subsets, CD14^?CD15^? (e‐MDSCs), CD14⁺CD15^? (M‐MDSCs), and CD14^?CD15⁺ (PMN‐MDSCs), in peripheral blood mononuclear cells (PBMCs) and mononuclear cells in the grafted intestinal mucosa. Total MDSC numbers increased in PBMCs after ITx; among MDSC subsets, M‐MDSC numbers were maintained at a high level after 2 months post ITx. The MDSC numbers decreased in ITx recipients with ACR. MDSC numbers were positively correlated with serum interleukin (IL)‐6 levels and the glucocorticoid administration index. IL‐6 and methylprednisolone enhanced the differentiation of bone marrow cells to MDSCs in vitro. M‐MDSCs and e‐MDSCs expressed CCR1, ‐2, and ‐3; e‐MDSCs and PMN‐MDSCs expressed CXCR2; and intestinal grafts expressed the corresponding chemokine ligands after ITx. Of note, the percentage of MDSCs among intestinal mucosal CD45⁺ cells increased after ITx. A novel in vitro assay demonstrated that MDSCs suppressed donor‐reactive T cell–mediated destruction of donor intestinal epithelial organoids. Taken together, our results suggest that MDSCs accumulate in the recipient PBMCs and the grafted intestinal mucosa in ITx, and may regulate ACR.