Project description:Molecular regulation of acute kidney injury (mRNA)

Project description:Molecular regulation of acute kidney injury (miRNA)

Project description:Molecular Phenotypes of Acute Kidney Injury in Kidney Transplants

Project description:The goal of this observational study is to compare anesthetic modalities (intravenous propofol anesthesia with sevoflurane gas anesthesia) in patients who underwent colorectal cancer resection surgery regarding the outcome of acute kidney injury. The main questions it aims to answer are: * is there a difference in acute kidney injury incidence in the two anesthetic modalities? * is there a difference in plasma creatinine between the two anesthetic modalities? * are there any patient characteristics or intraoperative factors that effect the incidence of acute kidney injury in either anesthetic modality? The study will analyze data from the CAN clinical trial database. (Cancer and Anesthesia: Survival After Radical Surgery - a Comparison Between Propofol or Sevoflurane Anesthesia, NCT01975064)

Project description:Acetaminophen (APAP) overdose can lead to acute kidney injury (AKI), yet its molecular mechanisms remain unclear and no effective treatments are currently available. In this study, we combined transcriptomic, proteomic, and phosphoproteomic profiling of kidneys from APAP-exposed mice to explore molecular mechanisms and potential therapeutic strategies. Ten-week-old male C57BL/6 mice were fasted overnight for 16 hours prior to APAP treatment. Acute kidney injury was induced by intraperitoneal injection of APAP overdose (300 mg/kg body weight) for 6 hours (n = 4). Control mice received an equivalent volume of PBS via intraperitoneal injection (n = 4). Kidney tissues were subsequently collected from APAP-induced kidney injury mice and PBS-injected controls.

Project description:Transcription profiling of molecular phenotypes of acute kidney injury in kidney transplants

Project description:Acute kidney injury (AKI) remains a leading cause of morbidity and mortality, yet the molecular pathways driving kidney tubule damage in AKI are not fully understood. Here, we report dual-specificity phosphatase 26 (DUSP26) as a critical regulator of kidney tubule injury in AKI. In our study, DUSP26 expression was markedly reduced in kidney biopsies from AKI patients and in murine models of cisplatin nephrotoxic and ischemic AKI. This down-regulation was driven by hypermethylation of the gene promoter of DUSP26 in kidney tubular cells. Loss of DUSP26 exacerbated tubular damage, whereas knock-in of DUSP26 specifically in kidney proximal tubule cells conferred protection. Mechanistically, DUSP26 directly bound to p53 to dephosphorylate it at serine 312, dampening the transcriptional activity of p53 towards cell death genes. Pharmacologic inhibition of DUSP26 sensitized kidneys to AKI, whereas DUSP26 overexpression was protective. Pharmacologic inhibition of DUSP26 also exacerbated ischemia-reperfusion injury in the liver. These findings uncover DUSP26 as a key phosphatase guarding against tissue injury by dephosphorylating p53 at serine 312, and highlight the DUSP26-p53 axis as a promising therapeutic target.

Project description:Fibroblasts are present in every organ. While the role fibroblasts in chronic diseases such as fibrosis or tumor expression has been extensively explored, little is known about their physiological role. The kidney possesses a unique capacity to recover from even severe acute injury. We study molecular mechanisms of this intrinsic repair capacity in the mouse model of ischemia-reperfusion (IR). In this model, the renal artery and vein are clamped for 45 min, leading to acute kidney injury. The kidney spontaneously recovers from such IR injury within 14 days. IR kidney injury is associated with a transient accumulation of fibroblasts in the diseased tissue. We hypothesized that fibroblasts aid the repair of acute IR injury in the kidney. To elucidate how FSP1+ fibroblasts may contribute to the repair of kidney injury, we undertook a global unbiased approach to compare gene expression profiles of fibroblasts isolated from kidneys post-IRI and from control kidneys by FACS sorting. To investigate the role fibroblasts may play in the repair of kidney inhury, we performed ischemia reperfusion injury surgery on transgenic mice in which the FSP-1 promoter drives EGFP expression. Kidney injury peaks at day 3 post-IRI, followed by spontaneous regeration that restores nearly perfect kidney architecture and health by day 10. Fibroblasts are thought to possibly play a role in this process, as they are normally rare in the healthy kidney, acute kidney injury is associated with a transient accumulation of interstitial fibroblasts, but whether they may help repair the acute kidney injury or in fact could contribute to the damage is not known. To compare the gene expression profiles of normal fibroblasts and those from post-ischemic kidneys, we sacrificed control FSP1-GFP mice and the FSP1-GFP mice three days post-IRI. We generated single-cell suspensions from both the post-IRI and control kidneys, and then isolated FSP1-GFP+ cells by FACS sorting that, when cultured on plastic, displayed typical fibroblast morphology. Total RNA was immediately extracted from the sorted cells and amplified to produce enough for a array. We biotinylated five of the samples from post-ischemic kidneys and three of the control (non-ischemic) kidneys and used Affymetrix 3' Arrays to examine differences in gene expression profiles between the two groups that may she some light on what role, if any, fibroblasts play in the spontaneous healing of the kidney after acute kidney injury. We performed ischemia reperfusion surgery in FSP1-GFP mice, and at day 3, we sacrificed the mice, isolated FSP1-GFP positive cells from both IR and normal control kidneys by FACS sorting, extracted total RNA from the isolated FSP1-GFP cells and used Affymetrix Mouse Expression Array 430 2.0 microarrays to perform gene expression profiling of the samples. All told, we performed the FACS Sorting, RNA extration, and hybridization with 5 ischemic kidneys and 3 normal kidneys. Fibroblasts, acute kidney injury, repair, comparative gene expression profiling, microarrays, FACS sorting, role in healing

Project description:Acute kidney injury frequently occurs in patients with severe pneumonia and contributes to poor clinical outcomes. In this study, we established a mouse model of severe pneumonia–associated acute kidney injury (SP-AKI) and performed RNA sequencing to investigate transcriptomic alterations in both lung and kidney tissues. Lung and kidney samples were collected from control mice and SP-AKI mice, followed by high-throughput RNA sequencing. Differential gene expression and pathway analyses were performed to identify molecular mechanisms involved in organ injury and inter-organ communication during SP-AKI. This dataset provides a comprehensive transcriptomic resource for understanding the molecular mechanisms underlying SP-AKI.

Project description:Apobec1 and acute kidney injury