Project description:Human kidneys which were accepted for transplantation and subsequently not used were subjected to ex vivo normothermic machine perfusion. During perfusion it was found the tubular epithelia synthesized fibrinogen which led to red blood cell aggregation and pathologic plugging of renal microvasculature. Sequential ex vivo delivery of plasminogen and tissue plasminogen activator (tPA) during normothermic machine perfusion effectively lyses these fibrinogen-mediated plugs.

Project description:This study aimed to investigate impact of myeloid ferritin heavy chain (FtH) deletion on iron trafficking in kidney health and disease. Myeloid FtH deletion (FtHΔ/Δ) led to upregulation of synuclein-α (Snca) as the only iron-binding protein. When exposed to kidney injury, FtHΔ/Δ mice exhibited significantly worse kidney function. Transcriptome analysis identified ferroptosis as a key pathway triggered by FtH deletion. This was confirmed by elevated expression of ferroptosis-related genes, oxidative stress markers, and increased iron deposition in the kidneys. The latter was mediated via reprogramming of macrophages to an iron-recycling phenotype by inducing Spic. Mechanistically, we demonstrate ferrireductase activity of monomeric Snca acts as a catalyst triggering oxidative stress and ferroptosis. Moreover, kidney accumulation of Snca is promoted in kidney diseases marked by heavy leukocyte infiltration in both mice and humans. These findings emphasize role of FtH in regulating iron metabolism and promoting kidney repair by suppressing Snca and Spic.

Project description:Hemolysis drives susceptibility to lung injury and predicts poor outcomes in diseases, such as malaria and sickle cell disease (SCD). However, the underlying pathological mechanism remains unknown. Here, we report that major facilitator superfamily domain containing 7C (MFSD7C) protects the lung from hemolytic-induced damage by preventing ferroptosis. Mechanistically, MFSD7C deficiency leads to mitochondrial dysfunction and lipid remodeling caused by increased fatty acid uptake and decreased consumption, the excess accumulation of lipids sensitizes cells to peroxidation and ferroptosis. Moreover, systematic delivery of MFSD7C mRNA-loaded nanoparticles to the lungs effectively prevented lung injury in mice with hemolysis. These findings present the detailed link between hemolytic complications and ferroptosis, providing potential therapeutic targets for patients with hemolytic disorders.

Project description:Backgroud: among strategies to limit ischemia/reperfusion (IR) injuries in transplantation, cell therapy using stem cells to condition/repair transplanted organ appears promising. We hypothesized that using a cell therapy based on exosomes derived from Urine Progenitor Cells (UPCs) during hypothermic and normothermic machine perfusion can prevent IR-related kidney damages. Methods: we isolated and characterized porcine UPCs and their exosomes (Exo). Then these were used in an ex vivo preclinical porcine kidney preservation model. Kidneys were subjected to warm ischemia (32min) then preserved by Hypothermic Machine Perfusion (HMP) for 24h before 5h of Normothermic Machine Perfusion (NMP). Three groups were performed (n=5-6): Group 1 (G1): HMP/vehicle + NMP/vehicle, Group 2 (G2): HMP/Exo + NMP/vehicle, Group 3 (G3): HMP/Exo + NMP/Exo. Results: porcine UPCs were successfully isolated from urine and fully characterized as well as their exosomes which were found of expected size/phenotype. RNA-seq performed on kidney biopsies showed different profiles between G1 and G3 with regulation of potential IR targets of Exo therapy. Conclusions: we showed the feasibility/efficacy of UPC-exosomes for hypothermic/normothermic kidney conditioning prior to transplantation, paving the way of combining machine perfusion with exosome-based cell therapy for organ conditioning.

Project description:Nanostring nCounter Organ Transplant Panel data on 4 cortex biopsies from discarded human kidneys analysing the differential expressed genes after one hour of normothermic perfusion

Project description:We compared the gene expression analysis of 2 different glomerular isolation techniques (laser capture microdissection with 2 rounds of RNA amplification and unamplified glomerular RNA after iron perfusion with glomerular sieving) and obtained different results depending on the glomerular isolation technique that was used Experiment Overall Design: Paired kidneys from Lewis-Hsd rat kidneys were collected. The glomeruli of one kidney was obtained by LCM with 2 rounds of RNA amplification while the unamplified glomerular RNA of the contralateral kidney was obtained after perfusion with iron oxide and isolated by magnetic purification and a glomerular sieving technique. The RNA was analyzed using the Affymetrix Rat 230A microarrays.

Project description:Normothermic human kidney preservation drives iron accumulation and ferroptosis

Project description:As an iron-dependent programmed cell death model, ferroptosis has been reported to be involved in the pathogenesis of acute kidney injury. Methyltransferase-like 3 (METTL3) -mediated m6A modification has recently been associated with various renal diseases. However, the relationship between METTL3 and ferroptosis is unclear. In order to further study the molecules involved in that, we first performed m6A sequencing on the kidneys of the control mice and the mice injected with folic acid(FA).

Project description:We describe a proteomics analysis to determine the molecular differences between normothermically perfused (normothermic machine perfusion, NMP) human kidneys with urine recirculation (URC) and urine replacement (UR). Proteins were extracted from 16 kidney biopsies with URC (n=8 donors after brain death (DBD), n=8 donors after circulatory death (DCD)) and three with UR (n=2 DBD, n=1 DCD), followed by quantitative analysis by mass spectrometry. Damage-associated molecular patterns (DAMPs) were decreased in kidney tissue after six hours NMP with URC, suggesting reduced inflammation. Vasoconstriction was also attenuated in kidneys with URC as angiotensinogen levels were reduced. Strikingly, kidneys became metabolically active during NMP, which could be enhanced and prolonged by URC. For instance, mitochondrial succinate dehydrogenase enzyme levels as well as carbonic anhydrase were enhanced with URC, contributing to pH stabilisation. Levels of cytosolic and the mitochondrial phosphoenolpyruvate carboxykinase were elevated after 24 hours of NMP, more prevalent in DCD than DBD tissue. Key enzymes involved in glucose metabolism were also increased after twelve and 24 hours of NMP with URC, including mitochondrial malate dehydrogenase and glutamic-oxaloacetic transaminase, predominantly in DCD tissue. We conclude that NMP with URC permits prolonged preservation and revitalises metabolism to possibly minimize better cope with ischemia reperfusion injury in discarded kidneys.

Project description:Normothermic ex-vivo kidney perfusion (NEVKP) has demonstrated superior outcomes for donation-after-cardiovascular death (DCD) grafts compared to static cold storage (SCS). To determine the mechanisms responsible for this, we performed an unbiased genome-wide microarray analysis. Kidneys from 30kg-Yorkshire pigs were subjected to 30min of warm ischemia followed by 8hrs of NEVKP or SCS, or no storage (NS), prior to auto-transplantation. mRNA expression was analyzed on POD3 renal biopsies.