Project description:Podocyte injury that compromises the glomerular filtration barrier is an initiating feature of chronic kidney disease. Podocytes extend major cytoplasmic projections that ultimately subdivide into interdigitating foot processes to form a scaffold that supports the glomerular filtration barrier. We investigated whether podocytes, like other cell types that elaborate complex cytoplasmic projections, utilize RNA transport and local translation in order to synthesize proteins at sites distal from the cell body. Here we show that mice deficient in the RNA binding proteins Staufen1 and 2 are significantly more sensitive to podocyte injury. Furthermore, Staufen2 associates with the podocyte cytoskeleton and is present in foot processes. After injury, Staufen2 and translating ribosomes increase markedly in areas of effacement adjacent to the glomerular basement membrane. Lastly, we found that Staufen2-bound RNAs are enriched in those encoding proteins mediating cytoskeletal assembly and cell-matrix adhesion. RNA transport and localized translation is identified as a crucial process for maintaining the glomerular filtration barrier.

Project description:The glomerular filtration barrier prevents large serum proteins from being lost into the urine. It is not known, however, why the filter does not routinely clog with large proteins that enter the glomerular basement membrane (GBM). Here we provide evidence that an active transport mechanism exists to remove immunoglobulins that accumulate at the filtration barrier. We found that FcRn, an IgG and albumin transport receptor, is expressed in podocytes and functions to internalize IgG from the GBM. Mice lacking FcRn accumulated IgG in the GBM as they aged and tracer studies showed delayed clearance of IgG from the kidneys of FcRn deficient mice. Supporting a role for this pathway in disease, saturating the clearance mechanism potentiated the pathogenicity of nephrotoxic sera. These studies support the idea that podocytes play an active role in removing proteins from the GBM and suggest that genetic or acquired impairment of the clearance machinery is likely to be a common mechanism promoting glomerular diseases. Experiment Overall Design: Total RNA for genechip analysis was derived from two sources: Experiment Overall Design: 1) Primary mouse podocytes isolated by FACS sorting of collagenase digested glomeruli Experiment Overall Design: 2) In vitro differentiated conditionally immortalized mouse podocyte cell line. Experiment Overall Design: After obtaining genechip data, the expression of various IgG and albumin receptors was queried in the genechip data and then confirmed by RT-PCR.

Project description:Podocyte histone deacetylases (HDAC) are essential in maintaining a normal glomerular filtration barrier by modulating podocyte quiescence. Podocyte-specific loss Hdac1 and 2 in mice results in severe proteinuria and sustained DNA damage, likely caused by epigenetic alterations and deficient DNA repair, that result in podocyte senescence. Through glomeruli isolation and RNA-seq profiling from the mutant mice, we demonstrated that senescent podocytes develop a senescence-associated secretory phenotype (SASP) that contribute to the loss of podocytes. The role of HDACs in senescence may provide important clues in our understanding of how podocytes are lost following injury.

Project description:Glomerular podocytes are highly differentiated cells that are key components of the kidney filtration units. The podocyte cytoskeleton builds the basis for the dynamic podocyte cytoarchitecture and plays a central role for proper podocyte function. Recent studies implicate that immunosuppressive agents including the mTOR-inhibitor everolimus have a protective role directly on the stability of the podocyte cytoskeleton. To elucidate mechanisms underlying mTOR-inhibitor mediated cytoskeletal rearrangements, we carried out microarray gene expression studies to identify target genes and corresponding pathways in response to everolimus. We analyzed the effect of everolimus in a puromycin aminonucleoside experimental in vitro model of podocyte injury. Upon treatment with puromycin aminonucleoside, microarray analysis revealed gene clusters involving cytoskeletal-associated pathways, adhesion, migration and extracellular matrix composition to be affected. Everolimus is capable of protecting podocytes from injury, both on the transcriptome and protein level. Rescued genes included TUBB2B and DCDC2, both involved in microtubule structure formation in neuronal cells but not identified in podocytes so far. Confirming gene expression data, Western-blot analysis in cultured podocytes showed an increase of TUBB2B and DCDC2 protein after everolimus treatment, and immunohistochemistry in healthy control kidneys confirmed a podocyte-specific expression. Microtubule-inhibitor experiments led to a maldistribution of TUBB2B and DCDC2 as well as an aberrant reorganization of the actin cytoskeleton. Tubb2bbrdp/brdp mice showed a delay in glomerular podocyte and capillary development. Taken together, our study suggests that off-target, non-immune mediated effects of the mTOR-inhibitor everolimus on the podocyte cytoskeleton might involve regulation of microtubules, revealing a potential novel role of TUBB2B and DCDC2 in glomerular podocyte development We analyzed the effect of everolimus on gene expression in a puromycin aminonucleoside experimental in vitro model of podocyte injury using microarrays

Project description:Podocytes form filtration barrier through foot process around glomerualar basement membrane and selectively permit permeability of molecular smaller than albumin. Diabetes can cause podocyte pathological changes leading to high urine albumin level. Diabetic mouse model OVE26 has extremly high urine albumin and previously studies indicated its podocyte damaged. Here we try to find the key genes change in OVE26 diabetic mouse model podocyte by microarray assay while normal FVB mouse podocyte set as control. Podocyte eGFP transgenic mice were made on FVB background and crossbred to OVE26 diabetic model. Glomeruli isolated from OVE-GFP mice were digested by trypsin into signal cell. Podocytes with GFP were sorting out by FACS.

Project description:The integrity of the kidney filtration barrier essentially relies on the balanced interplay of podocytes, endothelial cells and the glomerular basement membrane. Dysfunction in any of these components results in proteinuria and can progress to chronic kidney disease. While the relevance of cell-matrix interactions for podocytes is well established, it is only incompletely understood whether and how adhesion receptors reciprocally influence the basement membrane and maintain glomerular function. Here, we show by analysis of in vitro and in vivo models that a loss of the podocyte specific FERM-domain protein EPB41L5 results in impaired extracellular matrix integrity and stability. Employing quantitative proteomics analysis of the secretome, matrisome and integrin adhesome revealed that EPB41L5 promotes mechanosensitive properties of podocyte integrin complexes by recruitment of PDLIM5/ACTN4. Consecutively, EPB41L5 knockout podocytes showed insufficient reinforcement of integrin adhesion sites, which translated into impaired ECM assembly. These observations build the framework for a model where EPB41L5 as a cell type specific regulator of the podocyte adhesome controls a localized adaptive module in order to prevent podocyte detachment and ensures GBM integrity.

Project description:The integrity of the kidney filtration barrier essentially relies on the balanced interplay of podocytes, endothelial cells and the glomerular basement membrane. Dysfunction in any of these components results in proteinuria and can progress to chronic kidney disease. While the relevance of cell-matrix interactions for podocytes is well established, it is only incompletely understood whether and how adhesion receptors reciprocally influence the basement membrane and maintain glomerular function. Here, we show by analysis of in vitro and in vivo models that a loss of the podocyte specific FERM-domain protein EPB41L5 results in impaired extracellular matrix integrity and stability. Employing quantitative proteomics analysis of the secretome, matrisome and integrin adhesome revealed that EPB41L5 promotes mechanosensitive properties of podocyte integrin complexes by recruitment of PDLIM5/ACTN4. Consecutively, EPB41L5 knockout podocytes showed insufficient reinforcement of integrin adhesion sites, which translated into impaired ECM assembly. These observations build the framework for a model where EPB41L5 as a cell type specific regulator of the podocyte adhesome controls a localized adaptive module in order to prevent podocyte detachment and ensures GBM integrity.

Project description:Podocytes, highly differentiated glomerular epithelial cells, are essential for the maintenance of glomerular filtration barrier. Podocyte dysfunction in podocytes is a major determinant of proteinuric kidney disease. By RNA sequencing analysis in ADR-treated podocytes with or without MYDGF overexpression, we observed the significant changes of genes important in regulating cell cycle in podocytes with ADR treatment.

Project description:Glomerular podocytes are highly differentiated cells that are key components of the kidney filtration units. The podocyte cytoskeleton builds the basis for the dynamic podocyte cytoarchitecture and plays a central role for proper podocyte function. Recent studies implicate that immunosuppressive agents including the mTOR-inhibitor everolimus have a protective role directly on the stability of the podocyte cytoskeleton. To elucidate mechanisms underlying mTOR-inhibitor mediated cytoskeletal rearrangements, we carried out microarray gene expression studies to identify target genes and corresponding pathways in response to everolimus. We analyzed the effect of everolimus in a puromycin aminonucleoside experimental in vitro model of podocyte injury. Upon treatment with puromycin aminonucleoside, microarray analysis revealed gene clusters involving cytoskeletal-associated pathways, adhesion, migration and extracellular matrix composition to be affected. Everolimus is capable of protecting podocytes from injury, both on the transcriptome and protein level. Rescued genes included TUBB2B and DCDC2, both involved in microtubule structure formation in neuronal cells but not identified in podocytes so far. Confirming gene expression data, Western-blot analysis in cultured podocytes showed an increase of TUBB2B and DCDC2 protein after everolimus treatment, and immunohistochemistry in healthy control kidneys confirmed a podocyte-specific expression. Microtubule-inhibitor experiments led to a maldistribution of TUBB2B and DCDC2 as well as an aberrant reorganization of the actin cytoskeleton. Tubb2bbrdp/brdp mice showed a delay in glomerular podocyte and capillary development. Taken together, our study suggests that off-target, non-immune mediated effects of the mTOR-inhibitor everolimus on the podocyte cytoskeleton might involve regulation of microtubules, revealing a potential novel role of TUBB2B and DCDC2 in glomerular podocyte development

Project description:The glomerular filtration barrier prevents large serum proteins from being lost into the urine. It is not known, however, why the filter does not routinely clog with large proteins that enter the glomerular basement membrane (GBM). Here we provide evidence that an active transport mechanism exists to remove immunoglobulins that accumulate at the filtration barrier. We found that FcRn, an IgG and albumin transport receptor, is expressed in podocytes and functions to internalize IgG from the GBM. Mice lacking FcRn accumulated IgG in the GBM as they aged and tracer studies showed delayed clearance of IgG from the kidneys of FcRn deficient mice. Supporting a role for this pathway in disease, saturating the clearance mechanism potentiated the pathogenicity of nephrotoxic sera. These studies support the idea that podocytes play an active role in removing proteins from the GBM and suggest that genetic or acquired impairment of the clearance machinery is likely to be a common mechanism promoting glomerular diseases. Keywords: Unique cell type expression analysis