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: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:One of the key aspects of the specialized podocyte morphology is the segregation and organization of distinct cytoskeletal filaments into different subcellular components, for which the exact mechanisms remain poorly understood. By screening the time-dependent proteomic changes within the rat puromycin aminonucleoside-induced nephropathy model, we identify the actin-binding protein nebulette as a unique component of the podocyte cytoskeleton that correlates strongly with glomerular function.

Project description:Indoxyl sulfate (IS) is a uremic toxin and ligand of the aryl-hydrocarbon receptor (Ahr), a transcriptional regulator. Elevated serum IS may contribute to the progression of kidney disease. Therefore, we assessed mouse podocyte damage mediated by IS. Ahr was predominantly localized to the podocyte nucleus in vivo and in vitro. In isolated glomeruli, IS-exposure for 2 – 24 h induced Cyp1a1 expression, the most sensitive biomarker of Ahr activation. Mice exposed to IS for 4–8 weeks exhibited microalbuminuria, and mild glomerular injury characterized by ischemic changes, partial podocyte foot process effacement, as well as vascular and tubulointerstitial damage. Chronically IS-exposed kidneys exhibited decreased mRNA, decreased protein levels, and altered staining patterns for podocin, synaptopodin, and non-muscle myosin IIA (Myh9). Immortalized podocytes, upon differentiation, exhibited Ahr nuclear translocation beginning 30 min after 1 mM IS-exposure. At 2 h, there was a dose-dependent decrease in podocyte mRNA expression of WT1, Podxl, Snypo, Myh9, Actn4, and Cd2ap. After 24 h of exposure to IS, podocytes were smaller, had fewer actin/Myh9 fibers, and decreased viability. Ahr-RNAi decreased mRNA expression of podocyte-specific proteins and inhibited Cyp1a1 induction by IS-exposure. Combinations of Ahr-RNAi and IS-exposure further decreased Myh9 expression. In immortalized human podocytes, IS treatment caused cell injury, decreased mRNA expression of podocyte-specific proteins, integrins, collagens, cytoskeletal proteins, and bone morphogenetic proteins, and increased cytokine and chemokine expression. Thus, chronic IS-exposure causes glomerular damage by activating Ahr, altering podocyte function, differentiation, and morphology, and inducing a pro-inflammatory phenotype. Podocyte cells treated with Indoxyl sulfate, a uremic toxin and aryl-hydrocarbon receptor ligand, mediates progressive glomerular disease by damaging podocytes Human podocyte cell line treated with or without 3-Indoxyl sulfate (1mM/0.1%DMSO) in three replications

Project description:Calcimimetics such as R568 are renoprotective and the underlying mechanism is not yet fully clarified. We consider the importance of podocytes in mediating the beneficial effect of calcimimetics on kidney. Affymetrix array type Moe430_2 was used to study the effect of R-568. Analysis of differential gene expression indicates that R-568 acts antioxidative, stabilizes cytoskeleton, enhances cell cycle control and suppresses apoptosis in podocytes. This suggests that calcimimetics limit podocyte damage by antiapoptotic and cytoskeleton stabilizing effects and may thus constitute a new pharmacological approach in the prevention and treatment of glomerular disease. Podocytes treated with and without R568 were used for RNA extraction and hybridization on Affymetrix microarrays.

Project description:Podocytes are an integral part of the glomerular infiltration barrier. At present, many genes are known essential for podocyte survival and structural and functional homeostasis; however, there are more such genes to be uncovered. By single-cell RNA-seq of mouse podocytes, we detected the expression of gene encoding MCC regulator of WNT signaling pathway (MCC) in majority of the single podocytes and speculated that MCC may be essential for podocytes. We confirmed MCC expression in mouse podocytes and further showed its expression in human podocytes. To experimentally prove the essentiality of MCC for podocytes, we knocked down MCC in cultured podocytes, resulting in marked morphological change of cell shape, cytoskeletal stress fiber disruption, increased apoptosis, and downregulation of podocyte essential genes, CD2AP and WT1, demonstrating that MCC is essential for podocytes. To investigate the mechanism underlying the role of MCC in podocytes, we performed RNA-seq analysis of the podocytes in culture 24 hours after transfection of siRNA against MCC, followed by bioinformatics analysis of the genes with altered expression, and found some mechanistic clues. Lastly, we found that MCC is downregulated in podocytes treated with puromycin aminonucleosides and in glomeruli of diabetic mice and FSGS patients, implicating MCC in the development of podocytopathy and proteinuria. In conclusion, MCC is essential for podocytes and its deficiency may be involved in podocytopathy.

Project description:Obesity can initiate and accelerate the progression of kidney diseases. However, it remains unclear how obesity affects renal dysfunction. Here, we show that a newly generated podocyte-specific tubular sclerosis complex 2 (Tsc2) knockout mouse model (Tsc2∆podocyte) develops proteinuria and dies due to end-stage renal dysfunction by 10 weeks of age. Tsc2∆podocyte mice exhibit an increased glomerular size and focal segmental glomerulosclerosis, including podocyte foot process effacement, mesangial sclerosis and proteinaceous casts. Podocytes isolated from Tsc2∆podocyte mice show nuclear factor, erythroid derived 2, like 2-mediated increased oxidative stress response on microarray analysis and their autophagic activity is lowered through the mammalian target of rapamycin (mTOR)—unc-51-like kinase 1 pathway. Rapamycin attenuated podocyte dysfunction and extends survival in Tsc2∆podocyte mice. Additionally, mTOR complex 1 (mTORC1) activity is increased in podocytes of renal biopsy specimens obtained from obese patients with chronic kidney disease. Our work shows that mTORC1 hyperactivation in podocytes leads to severe renal dysfunction and that inhibition of mTORC1 activity in podocytes could be a key therapeutic target for obesity-related kidney diseases.

Project description:The specialized glomerular epithelial cell (podocyte) of the kidney is a complex cell that is often damaged in glomerular diseases. Study of this cell type is facilitated by an in vitro system of propagation of conditionally immortalized podocytes. Here, genes that are differentially expressed in this in vitro model of podocyte differentiation are evaluated. Conditionally immortalized undifferentiated mouse podocytes were cultured under permissive conditions at 33*C. Podocytes that were differentiated at the non-permissive conditions at 37*C were used for comparison.

Project description:Overexpression of glomerular JAK2 mRNA specifically in glomerular podocytes of 129S6 mice led to significant increases in albuminuria, mesangial expansion, glomerulosclerosis, glomerular fibronectin accumulation, and glomerular basement membrane thickening as well as a significant reduction in podocyte density in diabetic mice. Treatment with a specific JAK1/2 inhibitor partly reversed the major phenotypic changes of DKD

Project description:Calcimimetics such as R568 are renoprotective and the underlying mechanism is not yet fully clarified. We consider the importance of podocytes in mediating the beneficial effect of calcimimetics on kidney. Affymetrix array type Moe430_2 was used to study the effect of R-568. Analysis of differential gene expression indicates that R-568 acts antioxidative, stabilizes cytoskeleton, enhances cell cycle control and suppresses apoptosis in podocytes. This suggests that calcimimetics limit podocyte damage by antiapoptotic and cytoskeleton stabilizing effects and may thus constitute a new pharmacological approach in the prevention and treatment of glomerular disease.