Project description:Podocyte detachment due to mechanical stress is a common issue in hypertension-induced kidney disease. The present study investigated the role of zyxin in mechanically stretched podocytes, a model for glomerular hypertension. Conditionally immortalized differentiated podocytes were seeded on flexible silicon membranes of a six well plate, which was mounted on a manifold connected to a custom-built stretch apparatus (NIPOKA GmbH, Greifswald, Germany), which induced cyclic pressure variations resulting in upward and downward motion of the silicone membranes. We found that zyxin is essential for the adhesion of the postmitotic cell type, the podocytes, in vitro during mechanical stretch as well as in vivo for the maintenance of the kidney filtration.

Project description:Background and Objective: Hypertensive nephropathy (HN) requires a kidney biopsy as gold-standard for its diagnosis but histological findings are not entirely specific and lack specific prognostic markers. We aimed at defining prognostic candidate markers based on glomerular protein signatures. Method: We included adult patients (n=17) with an eGFR >30 ml/min/1.73m2 and proteinuria <3g/d from the Norwegian Kidney Biopsy Registry: stable patients (n=9) and subjects with HN progression (n=8) leading to end-stage renal disease (ESRD) within 20 years of follow-up. Glomerular cross-sections were microdissected from archival kidney biopsy sections and processed for protein extraction. Proteomic analyses were performed using Q-exactive HF mass spectrometer and relative glomerular protein abundance were compared between progressive vs non-progressive patients. Results: Amongst 1870 quality filtered proteins, we identified 58 proteins with an absolute fold change (FC)>1.5, p<0.05, including 17 proteins with absolute FC >2, indicative of HN progression (highest FC: Cadherin 16 and UDP-glucuronosyl-transferase 2B7). Hierarchical cluster and principal component analysis (PCA) with the 17 proteins showed clear separation of samples into HN progressors and non-progressors. Supervised classifier analysis (K nearest neighbour) identified a set of five proteins which classified 16/17 samples correctly. Applying Geneset Enrichment Analysis (GSEA), in general metabolic pathways were enriched in progressors, and structural cell pathways enriched in non-progressors. Pathway analysis identified Epithelial Adherens Junction Signaling as the most affected canonical pathway. The signature of HN progression is different from the respective signature of IgA progression. Conclusion: Glomerular proteomic profiling can be used to discriminate progressors from non-progressors in HN.

Project description:RATIONALE: Hypertension can lead to podocyte damage and subsequent apoptosis, eventually resulting in glomerulosclerosis. Although alleviating podocyte apoptosis has clinical significance for the treatment of hypertensive nephropathy, an effective therapeutic target has not yet been identified. The function of Septin4, a pro-apoptotic protein and an important marker of organ damage, is regulated by post-translational modification (PTM). However, the exact role of Septin4 in regulating podocyte apoptosis and its connection to hypertensive renal damage remains unclear. OBJECTIVE: We investigated the function and underlying mechanism of Septin4 in AngII-induced hypertensive nephropathy to discover a theoretical basis for targeted treatment. METHODS AND RESULTS: Using transgenic Septin4-K174Q mutant mice treated with the antioxidant Tempol, we found that hyperacetylation of the K174 site of Septin4 exacerbates AngII induced hypertensive renal injury resulting from oxidative stress. Proteomics and western blotting assays indicated that Septin4-K174Q activates the cleaved-PARP1-cleaved-Caspase3 pathway. In Septin4-knockdown human renal podocytes, Septin4-K174R, which mimics deacetylation at K174, rescues podocyte apoptosis induced by AngII. We conclude that Septin4, when activated through acetylation of K174 (K174Q), promotes hypertensive renal injury. Immunoprecipitation and mass spectrometry analyses identified SIRT2 as a deacetylase that interacts with the Septin4 GTPase domain and deacetylates Septin4-K174. In Sirt2-deficient mice and SIRT2-knockdown renal podocytes, Septin4-K174 remains hyperacetylated and exacerbates hypertensive renal injury. By contrast, in Rosa26-Sirt2-Flag (SIRT2-TG) mice and SIRT2-knockdown renal podocytes re-expressing wild-type SIRT2, Septin4-K174 is hypoacetylated and mitigates hypertensive renal injury. CONCLUSION: Septin4-K174R, which mimics deacetylation by SIRT2, inhibits the cleaved-PARP1-cleaved-Caspase3 pathway. Septin4-K174R acts as a renal protective factor, mitigating AngII-induced hypertensive renal injury. These findings indicate that Septin4-K174 is a potential therapeutic target for the treatment of hypertensive renal injury.

Project description:This RNA-sequencing study investigates the role of SHROOM3 in podocyte function and its contribution to renal pathophysiology. Podocytes are highly specialized epithelial cells critical for glomerular filtration barrier integrity. The study explores how SHROOM3 deficiency affects podocyte cytoskeletal architecture and focal adhesion dynamics in the context of Adriamycin-induced nephropathy, a widely used experimental model of podocyte injury and proteinuric kidney disease. We performed transcriptome analysis using RNA-sequencing on human podocyte cell lines, comparing Control (n=4) and SHROOM3 knockdown (KD) podocytes (n=4). Our objective was to identify the molecular mechanisms and signaling pathways through which SHROOM3 regulates podocyte cytoskeletal organization, with particular focus on stress fiber formation and focal adhesion assembly/disassembly. The dataset provides comprehensive gene expression profiles revealing how SHROOM3 deficiency exacerbates podocyte injury, disrupts actin cytoskeleton dynamics, and impairs focal adhesion stability during nephropathy progression.

Project description:Cyclic circumferential stretch (CCS) induced by pulsatile blood pressure affects endothelial cell (EC) gene expression and regulates vascular mechanical properties. Although alterations in EC gene expression in response to increased CCS as observed in hypertensive patients is widely studied, the EC response to low or lack of CCS as observed in intracranial aneurysm (IA) disease has been poorly investigated. In this project we explored how exposure of ECs to low CCS may contribute to IA disease.

Project description:Several different mechanical signals have been proposed to control the extent and pattern of myocardial growth and remodeling, though this has largely been studied using in vitro model systems that are not representative of intact myocardium or in vivo models in which isolating the effects of individual candidate stimuli is exceedigly difficult. We used a unique tissue culture system that allows the simultaneous control of multiple mechanical inputs and other potentially confounding stimuli (e.g., hormonal). Following a 12 hour culture period under prescribed mechanics, we used microarrays to identify genes that are up- or down-regulated in response to different amounts of mean stretch and cyclic shortening. Muscles were dissected (one from each of 12 different male LBN-F1 rats) and cultured for 12 hours in a pseudo-sterile muscle culture system under one of four mechanical input schemes (i.e., three biological replicates per mechanical input group). We prescribed low or high values of both time averaged stretch and cyclic shortening. Specifically, we targeted 4% or 16% mean stretch (from slack length) and 4% of 16% cylic shortening (% of slack length) over the 12 hour culture period to give the following four groups: high mean stretch x high shortening (group A); high mean stretch x low shortening (group B); low mean stretch x low shortening (group C); low mean stretch x high shortening (group D). This 2 x 2 factorial design allowed us to identify individual genes and/or molecular pathways that might be regulated by one or both of these mechanical inputs indpendent from other candidate mechanical or hormonal stimuli.

Project description:Transcriptomes of differentiated cells of the conditionally immortalized mouse podocyte cell line SVI (Schiwek et al., Kidney Int. 66: 91-101, 2004) were determined as described in Warsow et al. (Kidney Int. 84: 104-115, 2013) after application of mechanical stress (Endlich et al., J. Am. Soc. Nephrol. 12: 413-422, 2001) as compared to control conditions. Elevated glomerular pressure represents a high risk for the development of severe kidney diseases and causes an increase of mechanical load to podocytes. In this study we investigated whether mechanical stress alters gene expression in cultured podocytes using gene arrays. We found that tetraspanin CD9 is significantly upregulated in cultured podocytes after mechanical stress. The differential expression of CD9 was confirmed by RT-PCR and Western blot under stretched and unstretched conditions. Furthermore, mechanical stress resulted in a relocalization of CD9. To get an insight into the functional role of CD9, podocytes were transfected with pEGFP-CD9. The expression of CD9 induced the formation of substratum-attached thin arborized protrusions (TAPs). Ca2+ depletion revealed that podocytes over-expressing CD9 possess altered adhesive properties in contrast to the control transfected cells. Finally, elevated CD9 expression increased migration of podocytes in a wound assay. In summary, our results suggest that upregulation of CD9 may play an important role in podocyte morphology, adhesion and migration. Three independent batches were used.

Project description:Expression data from human with IgA nephropathy (IgAN) and hypertensive nephropathy (HT) We used microarrays to analyze the transcriptome of microdissected renal biopsies from patients with IgAN and HT

Project description:We used scRNA-seq to confirm the rich cellular interactions between podocytes and glomerular parietal epithelial cells in early diabetic nephropathy and to construct a global view of early diabetic nephropathy.

Project description:Alveolar epithelial type II (AEII) cells are the first line host in response to mechanical ventilation. We tested the hypothesis that the modulation of microRNA on AEII cells in response to mechanical stretch may participate in the ventilator-induced lung injury. This experiment is designed to screen miRNAs that are deregulated during mechanical stretch of AEII cells.