Project description:The frequency of delayed function of kidney transplants varies greatly and is associated with the quality of graft, donor age, and the duration of cold ischemia time. Body weight differences between donor and recipient can affect primary graft function. The underlying mechanism is poorly understood. Here, we have transplanted kidney grafts from commensurate body weight (L-WD) or reduced body weight (H-WD) donor rats into syngeneic or allogeneic recipients. 24 hours post-transplantation, serum creatinine level in H-WD recipients was significantly higher compared to that of L-WD recipients indicating impaired primary graft function. We detected a 10 fold higher transcription of IL-6 and dramatically increased tubular destruction in grafts from H-WD recipients. This was accompanied by decreased expression of genes associated with kidney function and an up-regulation of other genes such as cytochrome P450 isoforms, FosL and Trib3 as revealed by DNA microarray analysis. A single application of IL-6 into L-WD recipients is sufficient to impair primary graft function and to cause tubular damage. Whereas, immediate neutralization of IL-6 receptor signaling rescued primary graft function resulting in low serum creatinine levels, well-preserved kidney graft architecture and a normalized gene expression profile. These findings have strong clinical implication as anti-IL6R treatment of patients receiving grafts from lower-weight donors could be used to improve primary graft function. The dataset comprises eight samples divided into four sample groups. Each group represents rat kidneys collected after allogeneic transplantation under a certain condition and includes two biological replicates. The first group is characterized by a high body weight difference between donor and recipient, rats in the second group exhibit a low weight difference. Group three and four are similar to group one, but underwent an additional treatment with anti-IL6R mAb or prednisolone immediately after transplantation.

Project description:Transplanting renal allografts represents the major curative treatment of chronic renal failure. Despite recent advances in immunosuppressive therapy, long-term survival of allografts remains a major clinical problem. Kidney function depends in part on transport proteins such as MRP2 (ABCC2) which facilitates renal secretion of amphiphilic exogenous and endogenous compounds. Inherited variants of genes not related to the immune system have been shown to modify the outcome after renal transplantation. We investigated whether ABCC2 gene variants in the donor kidney affect renal graft function. A congenic rat model was established carrying a single nucleotide deletion in the ABCC2 gene. Renal cross transplantations were performed with wild type rats. Renal excretion of the MRP2 substrates bilirubin glucuronide and p-aminohippuric acid, but not morphine-6-glucuronide, was affected by the donor genotype. Moreover, proteomic analyses and transcriptional profiling revealed modified expression patterns indicative of increased oxidative stress in renal grafts carrying the mutated gene. In the clinical part our study, we assessed ABCC2 haplotypes in renal transplant patients and evaluated graft function. The 3563T>A gene polymorphism was significantly associated with delayed graft function. Together, both experimental and clinical data show that the ABCC2 genotype of the donor kidney affects renal graft function. Experiment Overall Design: Performed analyses of (6) wild-type and (6) MRP2 deficient kidneys that had been transplanted in wild-type recipients.

Project description:Donor organ shortage, growing waiting lists and organ discard rates are key problems in kidney transplantation. Donor organ quality is a critical factor determining post-transplant graft outcomes. However, organ quality is difficult to predict. Balancing the use of marginal donors without affecting outcomes is a main issue in the transplant field. The decision of acceptance of a kidney organ for transplantation is mainly based on donor organ biopsy findings, even though there are recognized limitations. The lack of better measures of organ quality at the time of transplantation as a predictor of performance graft outcome is a serious clinical challenge. Herein, we propose the use of a limited set of genes that captures intrinsic biology of kidney donor organs to improve available scoring systems. We studied gene expression in 192 deceased donor kidney biopsies and evaluated short-term outcomes which included delayed graft function and eGFR (high versus low) at 24 months for 168 kidney transplant recipients.

Project description:In deceased donor kidney transplantation, acute kidney injury (AKI) prioir to surgery is a major determinant of delayed graft function (DGF), but AKI is histologically silent and difficult to assess. We hypothesized that a molecular measurement of AKI would add power to conventional risk assessments to predict the early poor allograft function at first week post transplantation. We performed microarrays on implantation biopsies taken during reperfusion in 70 deceased donor kidneys from 53 donors. Early poor function was classified by two definitions on day 7 post-transplantation: serum creatinine greater than 265 umol/L (3 mg/dL) or the requirement for dialysis. Donor age and related risk scores (Irish, Schold, KDRI) associated with worse early function, as expected, but histologic features (glomerulosclerosis; pathology risk scores (Remuzzi, MAPI)) correlated with donor age but not with poor function. However, molecular AKI signal, previously defined in kidneys with early injury, was the best single predictor of poor allograft function. The combination of donor age and the AKI signal improved the prediction of poor function. In addition, asssessments of tissue quality particularly donor age, Banff ct, Irish and KDRI scores, showed negative correlative trend with late graft function, whereas the AKI signal did not. Thus donor age and the molecular AKI signal are the main predictors of early impaired function, but have little impact on survival.

Project description:Transplanting renal allografts represents the major curative treatment of chronic renal failure. Despite recent advances in immunosuppressive therapy, long-term survival of allografts remains a major clinical problem. Kidney function depends in part on transport proteins such as MRP2 (ABCC2) which facilitates renal secretion of amphiphilic exogenous and endogenous compounds. Inherited variants of genes not related to the immune system have been shown to modify the outcome after renal transplantation. We investigated whether ABCC2 gene variants in the donor kidney affect renal graft function. A congenic rat model was established carrying a single nucleotide deletion in the ABCC2 gene. Renal cross transplantations were performed with wild type rats. Renal excretion of the MRP2 substrates bilirubin glucuronide and p-aminohippuric acid, but not morphine-6-glucuronide, was affected by the donor genotype. Moreover, proteomic analyses and transcriptional profiling revealed modified expression patterns indicative of increased oxidative stress in renal grafts carrying the mutated gene. In the clinical part our study, we assessed ABCC2 haplotypes in renal transplant patients and evaluated graft function. The 3563T>A gene polymorphism was significantly associated with delayed graft function. Together, both experimental and clinical data show that the ABCC2 genotype of the donor kidney affects renal graft function. Keywords: dysfunction of organic anion transporter MRP2 (ABCC2)

Project description:Approximately 70% of kidney grafts are obtained from deceased donors, and these grafts must be preserved in hypothermic conditions to prolong their viability until transplantation. However, prolonged cold storage (CS) of kidneys results in poor long-term outcomes after transplantation. We reported previously that CS of rat kidneys for 18 h prior to transplant impaired proteasome function, disrupted protein homeostasis, and reduced graft function. The goal of the present study was to identify the renal proteins that are dysregulated by this CS-induced injury. Isolated donor Lewis rat kidneys were subject to 18-h CS and transplanted into recipient Lewis rats (CS+Tx). Autotransplantation (ATx: transplant with 0-h CS) or Sham (right nephrectomy) surgeries served as controls. The proteome of kidney homogenates was analyzed with tandem mass-tag mass spectrometry to identify CS-induced abnormalities in kidney grafts. CS injury disrupted the renal phosphoproteome in kidney grafts and dysregulated numerous signaling pathways. Integrated analysis of global proteomes and phosphoproteomes identified 15 proteins that were significantly regulated in a CS-specific manner. In particular, proteins and pathways such as complement and coagulation cascades were upregulated, while antioxidant pathways, such as glutathione, were suppressed in CS+Tx groups compared to ATx and Sham controls. This study, for the first time, provides deeper insight into the disruption of the renal graft proteome caused by CS injury and provides a novel set of pathways and molecules that can be investigated to delineate their specific role in renal transplant outcomes, ultimately improving outcomes for patients with end-stage kidney disease.

Project description:Delayed graft function (DGF) is associated with a reduced graft survival. Donors' features have been always considered as key pathogenic factors in this setting. The aim of our study was to evaluate the role of recipients' characteristics in the development of DGF. We prospectively enrolled 932 kidney graft recipients from 466 donors. A total of 226 recipients experienced DGF. Among the 466 donors, in 290 both recipients presented with early graft function (EGF, group A), in 50 both recipients experienced DGF (group B) and in 126 one recipient presented with DGF and the other with EGF (group C). In group C we randomly selected 7 couples of DGF/EGF recipients. In these patients, circulating mononuclear cells were harvested before transplantation and their transcriptomic profile was investigated by a microarray approach. Results were validated by qPCR in an independent group of EGF/DGF couples.

Project description:Complications associated with immunosuppression, specifically nephrotoxicity and infection risk, significantly affect graft and patient survival after kidney transplantation. We previously showed that tolerance could be induced and full donor chimerism, as well as immunosuppression withdrawal, was obtained in highly mismatched allograft recipients using a bioengineered stem cell product (FCRx). Gene expression profiles in renal biopsy samples from tolerance-induced FCRx recipients, paired donor organs before implant, and subjects under standard immunosuppression (SIS) without rejection and with acute rejection were compared. This dataset is part of the TransQST collection.

Project description:To ensure safety tolerance induction protocols are accompanied by conventional immunosuppressive drugs IS. But IS such as calcineurin inhibitors CNI can interfere with tolerance induction. We investigated the effect of an additional CNI treatment on anti-CD4 mAb-induced tolerance induction upon rat kidney transplantation. Additional CNI treatment induced deteriorated graft function and chronic rejection characterised by alloantibody production, intragraft plasma cells and C3d deposition. Microarray analysis revealed enhanced intragraft expression of the B cell chemokine CXCL13 upon additional CNI treatment. In contrast PNOC, a B cell-related gene highly expressed in operational tolerant kidney transplant recipients, was decreased in grafts of anti-CD4 mAb+CsA-treated recipients suggesting an altered balance of B regulatory genes. Transient B cell depletion or transfer of Tregs three weeks after transplantation could inhibit intragraft B cell accumulation, alloantibody production and ameliorate chronic rejection. These data represent unexpected findings and should be taken into consideration when designing new clinical trials. To safe the benefit of CNI in controlling memory T cell responses we need strategies for a therapeutic optimization. We show here that early B cell depletion or transfer of Tregs may be one approach to arrest B cell accumulation, activation and graft destruction. comparative analysis of different immunosuppressive regimens on renal allograft gene expression versus untreated allografts

Project description:Complications associated with immunosuppression, specifically nephrotoxicity and infection risk, significantly affect graft and patient survival after kidney transplantation. We previously showed that tolerance could be induced and full donor chimerism, as well as immunosuppression withdrawal, was obtained in highly mismatched allograft recipients using a bioengineered stem cell product (FCRx).