Immune checkpoint CD47 molecule engineered islets mitigate instant blood‐mediated inflammatory reaction and show improved engraftment following intraportal transplantation

Instant blood‐mediated inflammatory reaction (IBMIR) causes significant destruction of islets transplanted intraportally. Myeloid cells are a major culprit of IBMIR. Given the critical role of CD47 as a negative checkpoint for myeloid cells, we hypothesized that the presence of CD47 on islets will minimize graft loss by mitigating IBMIR. We herein report the generation of a chimeric construct, SA‐CD47, encompassing the extracellular domain of CD47 modified to include core streptavidin (SA). SA‐CD47 protein was expressed in insect cells and efficiently displayed on biotin‐modified mouse islet surface without a negative impact on their viability and function. Rat cells engineered with SA‐CD47 were refractory to phagocytosis by mouse macrophages. SA‐CD47‐engineered islets showed intact structure and minimal infiltration by CD11b⁺ granulocytes/macrophages as compared with SA‐engineered controls in an in vitro loop assay mitigating IBMIR. In a syngeneic marginal mass model of intraportal transplantation, SA‐CD47‐engineered islets showed better engraftment and function as compared with the SA‐control group (87.5% vs 14.3%). Engraftment was associated with low levels of intrahepatic inflammatory cells and mediators of islet destruction, including high‐mobility group box‐1, tissue factor, and IL‐1β. These findings support the use of CD47 as an innate immune checkpoint to mitigate IBMIR for enhanced islet engraftment with translational potential.     

Rejection of xenogeneic porcine islets in humanized mice is characterized by graft‐infiltrating Th17 cells and activated B cells

Xenogeneic porcine islet transplantation is a promising potential therapy for type 1 diabetes (T1D). Understanding human immune responses against porcine islets is crucial for the design of optimal immunomodulatory regimens for effective control of xenogeneic rejection of porcine islets in humans. Humanized mice are a valuable tool for studying human immune responses and therefore present an attractive alternative to human subject research. Here, by using a pig‐to‐humanized mouse model of xenogeneic islet transplantation, we described the human immune response to transplanted porcine islets, a process characterized by dense islet xenograft infiltration of human CD45⁺ cells comprising activated human B cells, CD4⁺CD44⁺IL‐17⁺ Th17 cells, and CD68⁺ macrophages. In addition, we tested an experimental immunomodulatory regimen in promoting long‐term islet xenograft survival, a triple therapy consisting of donor splenocytes treated with ethylcarbodiimide (ECDI‐SP), and peri‐transplant rituximab and rapamycin. We observed that the triple therapy effectively inhibited graft infiltration of T and B cells as well as macrophages, promoted transitional B cells both in the periphery and in the islet xenografts, and provided a superior islet xenograft protection. Our study therefore indicates an advantage of donor ECDI‐SP treatment in controlling human immune cells in promoting long‐term islet xenograft survival.     

UVB‐induced depletion of donor‐derived dendritic cells prevents allograft rejection of immune‐privileged hair follicles in humanized mice

Dendritic cells (DCs) are key targets for immunity and tolerance induction; they present donor antigens to recipient T cells by donor‐ and recipient‐derived pathways. Donor‐derived DCs, which are critical during the acute posttransplant period, can be depleted in graft tissue by forced migration via ultraviolet B light (UVB) irradiation. Here, we investigated the tolerogenic potential of donor‐derived DC depletion through in vivo and ex vivo UVB preirradiation (UV) combined with the injection of anti‐CD154 antibody (Ab) into recipients in an MHC‐mismatched hair follicle (HF) allograft model in humanized mice. Surprisingly, human HF allografts achieved long‐term survival with newly growing pigmented hair shafts in both Ab‐treated groups (Ab‐only and UV plus Ab) and in the UV‐only group, whereas the control mice rejected all HF allografts with no hair regrowth. Perifollicular human CD3⁺ T cell and MHC class II⁺ cell infiltration was significantly diminished in the presence of UV and/or Ab treatment. HF allografts in the UV‐only group showed stable maintenance of the immune privilege in the HF epithelium without evidence of antigen‐specific T cell tolerance, which is likely promoted by normal HFs in vivo. This immunomodulatory strategy targeting the donor tissue exhibited novel biological relevance for clinical allogeneic transplantation without generalized immunosuppression.     

Combined Anti‐CD154/CTLA4Ig Costimulation Blockade‐Based Therapy Induces Donor‐Specific Tolerance to Vascularized Osteomyocutaneous Allografts

Tolerance induction by means of costimulation blockade has been successfully applied in solid organ transplantation; however, its efficacy in vascularized composite allotransplantation, containing a vascularized bone marrow component and thus a constant source of donor‐derived stem cells, remains poorly explored. In this study, osteomyocutaneous allografts (alloOMCs) from Balb/c (H2^d) mice were transplanted into C57BL/6 (H2^b) recipients. Immunosuppression consisted of 1 mg anti‐CD154 on day 0, 0.5 mg CTLA4Ig on day 2 and rapamycin (RPM; 3 mg/kg per day from days 0–7, then every other day for 3 weeks). Long‐term allograft survival, donor‐specific tolerance and donor–recipient cell trafficking were evaluated. Treatment with costimulation blockade plus RPM resulted in long‐term graft survival (>120 days) of alloOMC in 12 of 15 recipients compared with untreated controls (median survival time [MST] ≈10.2 ± 0.8 days), RPM alone (MST ≈33 ± 5.5 days) and costimulation blockade alone (MST ≈45.8 ± 7.1 days). Donor‐specific hyporesponsiveness in recipients with viable grafts was demonstrated in vitro. Evidence of donor‐specific tolerance was further assessed in vivo by secondary donor‐specific skin graft survival and third‐party graft rejection. A significant increase of Foxp3⁺ regulatory T cells was evident in tolerant animals. Donor cells populated peripheral blood, thymus, and both donor and recipient bone marrow. Consequently, combined anti‐CD154/CTLA4Ig costimulation blockade‐based therapy induces donor‐specific tolerance in a stringent murine alloOMC transplant model.     

Co‐localized immune protection using dexamethasone‐eluting micelles in a murine islet allograft model

The broad application of ß cell transplantation for type 1 diabetes is hindered by the requisite of lifelong systemic immunosuppression. This study examines the utility of localized islet graft drug delivery to subvert the inflammatory and adaptive immune responses. Herein, we have developed and characterized dexamethasone (Dex) eluting Food and Drug Administration‐approved micro‐Poly(lactic‐co‐glycolic acid) micelles and examined their efficacy in a fully major histocompatibility complex‐mismatch murine islet allograft model. A clinically relevant dose of 46.6 ± 2.8 μg Dex per graft was confirmed when 2 mg of micelles was implemented. Dex‐micelles + CTLA‐4‐Ig (n = 10) resulted in prolonged allograft function with 80% of the recipients demonstrating insulin independence for 60 days posttransplant compared to 40% in empty micelles + CTLA‐4‐Ig recipients (n = 10, P = .06). Recipients of this combination therapy (n = 8) demonstrated superior glucose tolerance profiles, compared to empty micelles + CTLA‐4‐Ig recipients (n = 4, P < .05), and significantly reduced localized intragraft proinflammatory cytokine expression. Histologically, increased insulin positive and FOXP3⁺ T cells were observed in Dex‐micelles + CTLA‐4‐Ig grafts compared to empty micelles + CTLA‐4‐Ig grafts (P < .01 and P < .05, respectively). Localized drug delivery via micelles elution has the potential to alter the inflammatory environment, enhances allograft survival, and may be an important adjuvant approach to improve clinical islet transplantation outcomes.     

Assessment of plasma microvesicles to monitor pancreatic islet graft dysfunction: Beta cell‐ and leukocyte‐derived microvesicles as specific features in a pilot longitudinal study

Markers of early pancreatic islet graft dysfunction and its causes are lacking. We monitored 19 type 1 diabetes islet‐transplanted patients for up to 36 months following last islet injection. Patients were categorized as Partial (PS) or complete (S) Success, or Graft Failure (F), using the β‐score as an indicator of graft function. F was the subset reference of maximum worsened graft outcome. To identify the immune, pancreatic, and liver contribution to the graft dysfunction, the cell origin and concentration of circulating microvesicles (MVs) were assessed, including MVs from insulin‐secreting β‐cells typified by polysialic acid of neural cell adhesion molecule (PSA‐NCAM), and data were compared with values of the β‐score. Similar ranges of PSA‐NCAM⁺‐MVs were found in healthy volunteers and S patients, indicating minimal cell damage. In PS, a 2‐fold elevation in PSA‐NCAM⁺‐MVs preceded each β‐score drop along with a concomitant rise in insulin needs, suggesting β‐cell damage or altered function. Significant elevation of liver asialoglycoprotein receptor (ASGPR)⁺‐MVs, endothelial CD105⁺‐MVs, neutrophil CD66b⁺‐MVs, monocyte CD 14⁺‐MVs, and T4 lymphocyte CD4⁺‐MVs occurred before each β‐score drop, CD8⁺‐MVs increased only in F, and B lymphocyte CD19⁺‐MVs remained undetectable. In conclusion, PSA‐NCAM⁺‐MVs are noninvasive early markers of transplant dysfunction, while ASGPR⁺‐MVs signal host tissue remodeling. Leukocyte MVs could identify the cause of graft dysfunction.     

Loss of end‐differentiated β‐cell phenotype following pancreatic islet transplantation

Replacement of pancreatic β‐cells through deceased donor islet transplantation is a proven therapy for preventing recurrent life‐threatening hypoglycemia in type 1 diabetes. Although near‐normal glucose levels and insulin independence can be maintained for many years following successful islet transplantation, restoration of normal functional β‐cell mass has remained elusive. It has recently been proposed that dedifferentiation/plasticity towards other endocrine phenotypes may play an important role in stress‐induced β‐cell dysfunction in type 2 diabetes. Here we report loss of end‐differentiated β‐cell phenotype in 2 intraportal islet allotransplant recipients. Despite excellent graft function and sustained insulin independence, all examined insulin‐positive cells had lost expression of the end‐differentiation marker, urocortin‐3, or appeared to co‐express the α‐cell marker, glucagon. In contrast, no insulin⁺/urocortin‐3^? cells were seen in nondiabetic deceased donor control pancreatic islets. Loss of end‐differentiated phenotype may facilitate β‐cell survival during the stresses associated with islet isolation and culture, in addition to sustained hypoxia following engraftment. As further refinements in islet isolation and culture are made in parallel with exploration of alternative β‐cell sources, graft sites, and ultimately fully vascularized bioengineered insulin‐secreting microtissues, differentiation status immunostaining provides a novel tool to assess whether fully mature β‐cell phenotype has been maintained.     

CMV‐infected kidney grafts drive the expansion of blood‐borne CMV‐specific T cells restricted by shared class I HLA molecules via presentation on donor cells

We aimed to determine the role of cytomegalovirus (CMV)‐infected donor cells in the development of a CMV‐specific immune response in kidney transplant recipients. We assessed the CMV pp65‐specific immune response by using interferon‐? ELISPOT and dextramers in peripheral blood mononuclear cells from 115 recipients (D+R? 31, D+R + 44, D?R + 40) late after transplantation (mean 59 ± 42 months). Receiving a kidney from a D+ donor resulted in a higher number of IFN‐?‐producing anti‐CMV T cells (P = .004). This effect disappeared with the absence of shared HLA class I specificities between donors and recipients (P = .430). To confirm the role of donor cells in stimulating the expansion of newly developed CMV‐specific CD8⁺ T cells after transplantation, we compared the number of HLA‐A2–restricted CMV‐specific CD8⁺ T cells in primo‐infected recipients who received an HLA‐A2 or non–HLA‐A2 graft. The median of anti‐CMV pp65 T cells restricted by HLA‐A2 was very low for patients who received a non–HLA‐A2 graft vs an HLA‐A2 graft (300 [0‐14638] vs. 17972 [222‐85594] anti‐CMV pp65 CD8⁺ T cells/million CD8⁺ T cells, P = .001). This adds new evidence that CMV‐infected kidney donor cells present CMV peptides and drive an inflation of memory CMV‐specific CD8⁺ T cells, likely because of frequent CMV replications within the graft.     

Fas配体表达对同种胰岛移植的影响

目的探究睾丸细胞FasL表达能否对共移植的胰岛移植物提供免疫豁免作用以及胰岛细胞FasL基因转染对同种胰岛移植的影响.方法将同种大鼠胰岛及睾丸细胞同时移植于糖尿病受体,重组腺病毒AdV-FasL感染胰岛细胞后移植,观察移植物存活情况、胰岛功能,并检测移植物内浸润淋巴细胞以及基因转染胰岛细胞凋亡情况.结果单纯移植胰岛组平均存活期为(6.3±0.56)?d.与胰岛细胞同时移植的睾丸细胞数增加至1×107时,存活期大于50?d(P＜0.05).表达FasL的睾丸细胞在移植物内诱导浸润淋巴细胞凋亡.FasL基因转染组出现排斥加速,存活期缩短至(3.4±0.24)?d.FasL转染的胰岛细胞在移植后24h见FasL表达,48h表达增强,移植后FasL转染胰岛细胞凋亡.结论表达FasL的睾丸细胞与胰岛同时移植可诱导活化的淋巴细胞凋亡,使胰岛移植物获得免疫豁免、存活期延长,但通过FasL基因转染使胰岛细胞直接表达FasL引起胰岛细胞凋亡和粒细胞浸润,导致排斥加速.     

Long‐ and short‐term outcomes in renal allografts with deceased donors: A large recipient and donor genome‐wide association study

Improvements in immunosuppression have modified short‐term survival of deceased‐donor allografts, but not their rate of long‐term failure. Mismatches between donor and recipient HLA play an important role in the acute and chronic allogeneic immune response against the graft. Perfect matching at clinically relevant HLA loci does not obviate the need for immunosuppression, suggesting that additional genetic variation plays a critical role in both short‐ and long‐term graft outcomes. By combining patient data and samples from supranational cohorts across the United Kingdom and European Union, we performed the first large‐scale genome‐wide association study analyzing both donor and recipient DNA in 2094 complete renal transplant‐pairs with replication in 5866 complete pairs. We studied deceased‐donor grafts allocated on the basis of preferential HLA matching, which provided some control for HLA genetic effects. No strong donor or recipient genetic effects contributing to long‐ or short‐term allograft survival were found outside the HLA region. We discuss the implications for future research and clinical application.     

Comparison of exendin‐4 on beta‐cell replication in mouse and human islet grafts

Exendin‐4 can stimulate β‐cell replication in mice. Whether it can stimulate β‐cell replication in human islet grafts remains unknown. Therefore, we compared the effects of exendin‐4 on β‐cell replication in mouse and human islet grafts. Islets, isolated from mouse and human donors at different ages, were transplanted into diabetic mice and/or diabetic nude mice that were given bromodeoxyuridine (BrdU) with or without exendin‐4. At 4 weeks post‐transplantation, islet grafts were removed for insulin and BrdU staining and quantification of insulin⁺/BrdU⁺ cells. Although diabetes was reversed in all mice transplanting syngeneic mouse islets from young or old donors, normoglycemia was achieved significantly faster in exendin‐4 treated mice. Mouse islet grafts in exendin‐4 treated mice had significantly more insulin⁺/BrdU⁺β cells than in untreated mice (P < 0.01). Human islet grafts from ≤22‐year‐old donors had more insulin⁺/BrdU⁺β cells in exendin‐4 treated mice than that in untreated mice (P < 0.01). However, human islet grafts from ≥35‐year‐old donors contained few insulin⁺/BrdU⁺β cells in exendin‐4 treated or untreated mice. Our data demonstrated that the capacity for β‐cell replication in mouse and human islet grafts is different with and without exendin‐4 treatment and indicated that GLP‐1 agonists can stimulate β‐cell replication in human islets from young donors.     

Attenuation of Donor‐Reactive T Cells Allows Effective Control of Allograft Rejection Using Regulatory T Cell Therapy

Regulatory T cells (Tregs) are essential for the establishment and maintenance of immune tolerance, suggesting a potential therapeutic role for Tregs in transplantation. However, Treg administration alone is insufficient in inducing long‐term allograft survival in normal hosts, likely due to the high frequency of alloreactive T cells. We hypothesized that a targeted reduction of alloreactive T effector cells would allow a therapeutic window for Treg efficacy. Here we show that preconditioning recipient mice with donor‐specific transfusion followed by cyclophosphamide treatment deleted 70–80% donor‐reactive T cells, but failed to prolong islet allograft survival. However, infusion of either 5 × 10⁶ Tregs with direct donor reactivity or 25 × 10⁶ polyclonal Tregs led to indefinite survival of BALB/c islets in more than 70% of preconditioned C57BL/6 recipients. Notably, protection of C3H islets in autoimmune nonobese diabetic mice required islet autoantigen‐specific Tregs together with polyclonal Tregs. Treg therapy led to significant reduction of CD8⁺ T cells and concomitant increase in endogenous Tregs among graft‐infiltrating cells early after transplantation. Together, these results demonstrate that reduction of the donor‐reactive T cells will be an important component of Treg‐based therapies in transplantation.     

Synthetic poly(ethylene glycol)‐based microfluidic islet encapsulation reduces graft volume for delivery to highly vascularized and retrievable transplant site

Transplant of hydrogel‐encapsulated allogeneic islets has been explored to reduce or eliminate the need for chronic systemic immunosuppression by creating a physical barrier that prevents direct antigen presentation. Although successful in rodents, translation of alginate microencapsulation to large animals and humans has been hindered by large capsule sizes (≥500 μm diameter) that result in suboptimal nutrient diffusion in the intraperitoneal space. We developed a microfluidic encapsulation system that generates synthetic poly(ethylene glycol)‐based microgels with smaller diameters (310 ± 14 μm) that improve encapsulated islet insulin responsiveness over alginate capsules and allow transplant within vascularized tissue spaces, thereby reducing islet mass requirements and graft volumes. By delivering poly(ethylene glycol)‐encapsulated islets to an isolated, retrievable, and highly vascularized site via a vasculogenic delivery vehicle, we demonstrate that a single pancreatic donor syngeneic islet mass exhibits improved long‐term function over conventional alginate capsules and close integration with transplant site vasculature. In vivo tracking of bioluminescent allogeneic encapsulated islets in an autoimmune type 1 diabetes murine model showed enhanced cell survival over unencapsulated islets in the absence of chronic systemic immunosuppression. This method demonstrates a translatable alternative to intraperitoneal encapsulated islet transplant.     

Prevention of Allograft Rejection by Use of Regulatory T Cells With an MHC‐Specific Chimeric Antigen Receptor

CD4⁺CD25^highFOXP3⁺ regulatory T cells (Tregs) are involved in graft‐specific tolerance after solid organ transplantation. However, adoptive transfer of polyspecific Tregs alone is insufficient to prevent graft rejection even in rodent models, indicating that graft‐specific Tregs are required. We developed a highly specific chimeric antigen receptor that recognizes the HLA molecule A*02 (referred to as A2‐CAR). Transduction into natural regulatory T cells (nTregs) changes the specificity of the nTregs without alteration of their regulatory phenotype and epigenetic stability. Activation of nTregs via the A2‐CAR induced proliferation and enhanced the suppressor function of modified nTregs. Compared with nTregs, A2‐CAR Tregs exhibited superior control of strong allospecific immune responses in vitro and in humanized mouse models. A2‐CAR Tregs completely prevented rejection of allogeneic target cells and tissues in immune reconstituted humanized mice in the absence of any immunosuppression. Therefore, these modified cells have great potential for incorporation into clinical trials of Treg‐supported weaning after allogeneic transplantation.     

Rapamycin‐Conditioned Donor Dendritic Cells Differentiate CD4+CD25+Foxp3+ T Cells In Vitro with TGF‐β1 for Islet Transplantation

Dendritic cells (DCs) conditioned with the mammalian target of rapamycin (mTOR) inhibitor rapamycin have been previously shown to expand naturally existing regulatory T cells (nTregs). This work addresses whether rapamycin‐conditioned donor DCs could effectively induce CD4⁺CD25⁺Foxp3⁺ Tregs (iTregs) in cell cultures with alloantigen specificities, and whether such in vitro‐differentiated CD4⁺CD25⁺Foxp3⁺ iTregs could effectively control acute rejection in allogeneic islet transplantation. We found that donor BALB/c bone marrow‐derived DCs (BMDCs) pharmacologically modified by the mTOR inhibitor rapamycin had significantly enhanced ability to induce CD4⁺CD25⁺Foxp3⁺ iTregs of recipient origin (C57BL/6 (B6)) in vitro under Treg driving conditions compared to unmodified BMDCs. These in vitro‐induced CD4⁺CD25⁺Foxp3⁺ iTregs exerted donor‐specific suppression in vitro, and prolonged allogeneic islet graft survival in vivo in RAG^?/‐ hosts upon coadoptive transfer with T‐effector cells. The CD4⁺CD25⁺Foxp3⁺ iTregs expanded and preferentially maintained Foxp3 expression in the graft draining lymph nodes. Finally, the CD4⁺CD25⁺Foxp3⁺ iTregs were further able to induce endogenous naïve T cells to convert to CD4⁺CD25⁺Foxp3⁺ T cells. We conclude that rapamycin‐conditioned donor BMDCs can be exploited for efficient in vitro differentiation of donor antigen‐specific CD4⁺CD25⁺Foxp3⁺ iTregs. Such in vitro‐generated donor‐specific CD4⁺CD25⁺Foxp3⁺ iTregs are able to effectively control allogeneic islet graft rejection.     

Immunoisolation of murine islet allografts in vascularized sites through conformal coating with polyethylene glycol

Islet encapsulation may allow transplantation without immunosuppression, but thus far islets in large microcapsules transplanted in the peritoneal cavity have failed to reverse diabetes in humans. We showed that islet transplantation in confined well‐vascularized sites like the epididymal fat pad (EFP) improved graft outcomes, but only conformal coated (CC) islets can be implanted in these sites in curative doses. Here, we showed that CC using polyethylene glycol (PEG) and alginate (ALG) was not immunoisolating because of its high permselectivity and strong allogeneic T cell responses. We refined the CC composition and explored PEG and islet‐like extracellular matrix (Matrigel; MG) islet encapsulation (PEG MG) to improve capsule immunoisolation by decreasing its permselectivity and immunogenicity while allowing physiological islet function. Although the efficiency of diabetes reversal of allogeneic but not syngeneic CC islets was lower than that of naked islets, we showed that CC (PEG MG) islets from fully MHC‐mismatched Balb/c mice supported long‐term (>100 days) survival after transplantation into diabetic C57BL/6 recipients in the EFP site (750‐1000 islet equivalents/mouse) in the absence of immunosuppression. Lack of immune cell penetration and T cell allogeneic priming was observed. These studies support the use of CC (PEG MG) for islet encapsulation and transplantation in clinically relevant sites without chronic immunosuppression.     

Anti‐Donor HLA Antibody Response After Pancreatic Islet Grafting: Characteristics,Risk Factors,and Impact on Graft Function

Pancreatic islet grafting restores endogenous insulin production in type 1 diabetic patients, but long‐term outcomes remain disappointing as a result of immunological destruction of allogeneic islets. In solid organ transplantation, donor‐specific anti‐HLA antibodies (DSA) are the first cause of organ failure. This retrospective multicentric study aimed at providing in‐depth characterization of DSA response after pancreatic islet grafting, identifying the risk factor for DSA generation and determining the impact of DSA on graft function. Forty‐two pancreatic islet graft recipients from the Groupe Rhin‐Rhône‐Alpes‐Genève pour la Greffe d'Ilots de Langerhans consortium were enrolled. Pre‐ and postgrafting sera were screened for the presence of DSA and their ability to activate complement. Prevalence of DSA was 25% at 3 years postgrafting. The risk of sensitization increased steeply after immunosuppressive drug withdrawal. DSA repertoire diversity correlated with the number of HLA and eplet mismatches. DSA titer was significantly lower from that observed in solid organ transplantation. No detected DSA bound the complement fraction C3d. Finally, in contrast with solid organ transplantation, DSA did not seem to negatively affect pancreatic islet graft survival. This might be due to the low DSA titers, specific features of IgG limiting their ability to activate the complement and/or the lack of allogenic endothelial targets in pancreatic islet grafts.     

Renal Allograft Survival in Nonhuman Primates Infused With Donor Antigen‐Pulsed Autologous Regulatory Dendritic Cells

Systemic administration of autologous regulatory dendritic cells (DCreg; unpulsed or pulsed with donor antigen [Ag]), prolongs allograft survival and promotes transplant tolerance in rodents. Here, we demonstrate that nonhuman primate (NHP) monocyte‐derived DCreg preloaded with cell membrane vesicles from allogeneic peripheral blood mononuclear cells induce T cell hyporesponsiveness to donor alloantigen (alloAg) in vitro. These donor alloAg‐pulsed autologous DCreg (1.4–3.6 × 10⁶/kg) were administered intravenously, 1 day before MHC‐mismatched renal transplantation to rhesus monkeys treated with costimulation blockade (cytotoxic T lymphocyte Ag 4 immunoglobulin [CTLA4] Ig) and tapered rapamycin. Prolongation of graft median survival time from 39.5 days (no DCreg infusion; n = 6 historical controls) and 29 days with control unpulsed DCreg (n = 2), to 56 days with donor Ag‐pulsed DCreg (n = 5) was associated with evidence of modulated host CD4⁺ and CD8⁺ T cell responses to donor Ag and attenuation of systemic IL‐17 production. Circulating anti‐donor antibody (Ab) was not detected until CTLA4 Ig withdrawal. One monkey treated with donor Ag‐pulsed DCreg rejected its graft in association with progressively elevated anti‐donor Ab, 525 days posttransplant (160 days after withdrawal of immunosuppression). These findings indicate a modest but not statistically significant beneficial effect of donor Ag‐pulsed autologous DCreg infusion on NHP graft survival when administered with a minimal immunosuppressive drug regimen.     

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.     

Endogenous Expansion of Regulatory T Cells Leads to Long‐Term Islet Graft Survival in Diabetic NOD Mice

Donor pancreatic lymph node cells (PLNC) protect islet transplants in Non‐obese diabetic (NOD) mice. We hypothesized that induced FoxP3⁺ regulatory T cells (Tregs) were required for long‐term islet engraftment. NOD or NOD.NON mice were treated with ALS (antilymphocyte serum) and transplanted with NOR islets +/–PLNC (5 × 10⁷). In vivo proliferation and expansion of FoxP3⁺ Tregs was monitored in spleen and PLN from ALS‐ and ALS/PLNC‐treated recipient mice. Anti‐CD25 depletion was used to determine the necessity of Tregs for tolerance. FoxP3⁺ numbers significantly increased in ALS/PLNC‐treated recipients compared to ALS‐treated mice. In ALS/PLNC‐treated mice, recipient‐derived Tregs localized to the transplanted islets, and this was associated with intact, insulin‐producing β cells. Proliferation and expansion of FoxP3⁺ Tregs was markedly increased in PLNC‐treated mice with accepted islet grafts, but not in diabetic mice not receiving PLNC. Deletion of Tregs with anti‐CD25 antibodies prevented islet graft tolerance and resulted in rejection. Adoptive transfer of Tregs to secondary NOD.scid recipients inhibited autoimmunity by cotransferred NOD effector T cells. Treg expansion induced by ALS/PLNC‐treatment promoted long term islet graft survival. Strategies leading to Treg proliferation and localization to the transplant site represent a therapeutic approach to controlling recurrent autoimmunity.