Project description:Nature efficiently self-organizes cells and tissues into complex fractal forms. Whether fractal patterning contributes functionally to maturation, and how cells sense and interpret such shape cues, is not well understood. Using kidney podocytes as a model system, bioinspired templating of glomerular histology was leveraged to design controlled fractal 2½ -D surfaces for cell culture. Microcurvature was associated with charge density gradients in space, found to direct extracellular matrix protein organization resulting in hierarchical assembly of cell structures and fractally-branching podocyte morphology in vitro, outlined with a novel fluorescent assaying technique. Shape simulation was uniquely associated with mature-like foot processes on an organized ECM. In applications of drug testing, coronavirus infection, and a cells-as-sensors approach to patient serum diagnostics, fractally stimulated cells were more responsive than flat cultures. Fractal frameworks may thus provide a functional role in podocyte maturation and could serve to advance other bioengineered systems.

Project description:Although injury in glomerular disease might only damage a subset of podocytes in any given glomerulus, the response of the healthy neighboring podocytes to the injured podocytes oftentimes determines the course of the disease. To investigate this relationship, we designed a dual chamber open microfluidic co-culture device to specifically examine paracrine signaling to healthy podocytes from podocytes targeted injured by either Adriamycin, Puromycin Aminonucleoside or a cytopathic anti-podocyte antibody. Global transcriptomic analysis measured by RNA-sequencing revealed shared and unique pathways between the three forms of targeted injury, with temporal differences in the transcriptomic responses to each form of injury. Paracrine-induced injury to neighboring podocytes was similar to the targeted primary injured podocytes and was specific for each podocyte injury model. Ligand-receptor analysis of ligands secreted by the insult targeted podocytes and receptors expressed by the responsive, paracrine injured counterparts identified 23 candidate mediator pairs. These findings critically define a new concept for future studies to understand the pathways involved in secondary cellular injury fields in animal models and ultimately human studies.

Project description:We analyzed the proteome of mouse FACS-sorted podocytes. We compared podocytes ("green cells") with non-podocyte ("red cells") cells of the glomerulus.

Project description:The thorough characterization of the transcriptome of endogenous podocytes has been hampered by low yields of cell isolation procedures. Here we introduce a double fluorescent reporter mouse model combined with an optimized bead perfusion protocol and efficient single cell dissociation yielding more than 500,000 podocytes per mouse allowing for global, unbiased downstream applications. Combining mRNA transcriptional profiling revealed programs of highly specific gene regulation tightly controlling cytoskeleton, cell differentiation, endosomal transport and peroxisome function in podocytes. Strikingly, the analyses further predict that these podocyte-specific gene regulatory networks are accompanied by alternative splicing of respective genes. In summary, the presented M-bM-^@M-^XomicsM-bM-^@M-^Y approach will facilitate the discovery and integration of novel gene, protein and organelle regulatory networks that deepen our systematic understanding of podocyte biology. To compare gene expression of glomerulus podocytes versus non-podocytes 5 replicates of 4 pooled mice were used. Data were normalized by robust multi-chip analysis. Exon expression values were summarised to the core meta probesets, as defined by Affymetrix, using the oligo library from R.

Project description:Mutations in several genes expressed in podocytes, including Cd2ap, have been associated with focal segmental glomerulosclerosis in humans. Mutant mouse models provide an opportunity to better understand the molecular pathology that drives these diseases. In this report we use a battery of transgenic-GFP mice to facilitate the purification of all three major cell types of the glomerulus from Cd2ap mutant mice. Both microarrays and RNA-seq were used to characterize the gene expression profiles of the podocytes, mesangial cells and endothelial cells, providing a global dual platform cross-validating dataset. The mesangial cells showed increased expression of profibrotic factors, including thrombospondin, Tgfb2 and Tgfb3, as well as the angiogenesis factor Vegf. They also showed upregulation of protective genes, including Aldh1a2, involved in retinoic acid synthesis, and Decorin, a Tgfb antagonist. Of interest, the mesangial cells also showed significant expression of Wt1, which has generally been considered podocyte specific. The Cd2ap mutant podocytes showed upregulation of proteases as well as genes involved in muscle and vasculature development, and showed a very strong gene expression signature indicating programmed cell death. Endothelial cells showed increased expression of the leukocyte adhesion associated factors Vcam1 and Sele, as well as Midkine (promoting angiogenesis), endothelin, and many genes responsive to cytokines and interferons. This study provides a comprehensive analysis of the changing properties of the three cell types of the glomerulus in Cd2ap mutants, identifying activated and repressed pathways and responsible genes, thereby delivering a deeper molecular understanding of this genetic disease. All three major cell types of the glomerulus were FACS purified from CD2AP-/- mutant mice and normal controls and gene expression profiled with Affymetrix Mouse Exon 1.0 ST arrays. Data was analyzed with GeneBASE software. Biological triplicates were performed.

Project description:Transcriptome analysis of growth hormone dependant genes in glomerular podocytes Differentiated human glomerular podocytes in culture exposed to growth hormone for 0 min, 2 min, 5 min, 15 min, and 30 min. Total RNA is extracted and subjected to microarray analysis.

Project description:Podocyte effacement and loss characterizes glomerulopathies such as diabetic nephropathy, lupus, and glomerular toxicity. Human primary podocyte-like epithelial cells cultured from urine (ECU) were characterized as a window to understand podocyte regeneration in these glomerulopathies. Cytokines TNF, and VEGF stimulated regrowth, whereas FGF-1 and IL1 inhibited growth, consistent with other podocyte or parietal epithelial cell models. Review of published micrographs indicated that podocyte foot processes in rodent kidneys interdigitated exclusively with foot processes from other cells, suggesting podocytes practice self-avoidance. In culture, ECU avoided close interactions with other cells arising from the same clone, until enough cells grew for the culture to become confluent. In contrast, ECU derived from multiple clones associated actively to form contiguous monolayers. Gene expression profiling of eight clonal ECU colonies using RNA sequencing revealed that each colony expressed a highly variable profile of the 53 Protocadherin genes. Variable combinations of the 53 Protocadherin PCDHA-, PCDHB-, and PCDHG- gene products are known to act homophilically to direct self-avoidance interactions in human neurons, so PCDH- genes are postulated to govern self-avoidance similarly in podocytes. Such protocadherin profiles could be considered cell names. Transcriptional profiles of ECUs suggest they may represent intermediate stages of Parietal Epithelial Cells (PECs) differentiating into podocytes. They further suggest that each podocyte practices self-avoidance, interdigitating selectively with other cells in the glomerulus. To enable further investigation of multi-clonal podocyte interactions, five podocyte clones were immortalized using temperature-sensitive SV40 Large T antigen. These results suggest that non-self interdigitation of new podocytes with remnant podocytes may facilitate replacement of dying podocytes and re-establishment of a functional filtration barrier.

Project description:Background: The kidney glomerulus is a specialized capillary bed that is involved in urine production and blood pressure control. Glomerular injury is a major cause of chronic kidney disease, a widespread epidemic without therapeutic options. Single-cell transcriptomics have radically improved our ability to characterize complex organs, such as the kidney. Cells of the glomerulus, however, have been largely underrepresented in previous single cell kidney studies due to their paucity and intractability. Methods: We used single-cell RNA sequencing to comprehensively characterize the different types of cells in the glomerulus from healthy mice and from four different disease models (nephrotoxic serum nephritis, diabetes, doxorubicin toxicity, CD2AP deficiency). Results: All cell types in the glomerulus were identified using unsupervised clustering analysis. We identified novel marker genes and gene signatures of mesangial cells, vascular smooth muscle cells of the afferent and efferent arteriole, parietal epithelial cells, and three different types of endothelial cells. Analysis of the disease models revealed cell type-specific and injury type-specific responses in the glomerulus, including acute activation of the Hippo pathway in podocytes after nephrotoxic immune injury. Conclusions: We have generated a comprehensive high-resolution single-cell transcriptomic profile of the kidney glomerulus from healthy and injured mice. The dataset provides a useful resource for identifying novel disease-related genes and pathways.

Project description:Glomerular podocytes are highly differentiated kidney cells that constitute one of the key components responsible for removing toxins and metabolic waste while preserving nutrients in the bloodstream in the renal glomerulus. In addition, podocytes contribute significantly to the formation of the glomerular basement membrane and the integrity of the vascular endothelium. Thus, podocyte injury and/or loss of podocytes results in impaired blood filtration and causes many common renal diseases characterized by severe proteinuria (protein in the urine) and hypoalbuminemia (low levels of blood albumin). Small lipopholic molecules such as steroids, fatty acids, prostaglandins and vitamin metabolites control many aspects of animal development, cell proliferation and differentiation, and homeostasis through binding to their intracellular receptors. Upon binding to their cognate ligands, these nuclear receptors (NRs) are capable of turning on or off of an array of gene networks. By doing so, they regulate a whole spectrum of cellular activities. The ability of small molecule hormones to regulate NR activity makes them excellent pharmaceutical targets. Clinical evidence and animal studies have implicated several NRs in contributing to podocyte development and disease. Recent studies from animals and cultured human or mouse podocytes indicate that synthetic hormones including estradiol, glucocorticoid, retinoid, pioglitazone, vitamin D3 and WY-14643 protect or rescue podocytes from experimental injury. Post treatment of injured podocytes with ligands for the above-mentioned NRs restores cytoskeletal architecture of the podocytes. Nonetheless, the mechanisms underlying the ability of these hormones in protecting podocytes remain largely unexplored. This is partly due to our limited knowledge of the target genes controlled by these hormones. In order to elucidate the mechanisms by which Dex, VD3 and ATRA elicit their renoprotective activity, we initiate a gene expression profiling study to identify the target genes of these hormones in cultured human podocytes. The temperature-sensitive cultured human podocytes (HPCs) were maintained in culture media of RPMI supplemented with 10% FBS, 1% antibiotics and the Insulin-Transferrin-Selenium at the permissive (undifferentiated) temperature of 33 Celsius degree. The 70%~80% confluent HPCs were induced to in vitro differentiate by culturing at 37 Celsius degree for 2 days then with incubation of vehicle (equal volume of DMSO), 100 nM all-trans retinoic acid (ATRA), 100 nM dexamethasone (Dex), or 100 nM vitamin D3 (VD3) treatment for 3 more days. The undifferentiated HPCs with vehicle (equal volume of DMSO) treatment was included as a control. The total RNAs of these cells were isolated using USB prepEase RNA spin kit following the manufacturer's instructions. Total 1 microgram RNA at 100 nanogram per microliter for each sample were sent for a single-channel gene expression microarray studies using HumanRef-8 chip (V3_0_R3_11282963) on Illumina BeadStation platform. The RNA were converted to aRNA and appropriately labelled using MessageAmp Biotin aRNA Amplification Kit (Ambion) following the manufacturer's instructions. The raw data were collected by scanning the chip on Illumina BeadStation. Background subtracted raw data were exported and the following analysis was done in R/Bioconductor environment. Thus, we were able to compare the gene expression profiles between differentiated and undifferentiated HPCs with or without hormone treatment.

Project description:Differentiated mouse podocytes (SVI)