Project description:The kidney governs many physiological factors of the body, and the glomerulus is its core filtration unit. Glomeruli comprise of less than 1.5% of the kidney’s volume and thus are underrepresented in many analyses of the kidney, and require particular isolation methods. Aging is a major risk factor for kidney disease, yet despite the importance of proper glomerular function, we have limited knowledge of the changes that glomerular cells undergo during aging. Here we interrogate the aged mouse kidney, glomerulus and glomerular cells using various approaches, including single cell RNA sequencing (scRNA-Seq), to identify age and senescence associated changes at the tissue and cellular level. We show that the aged kidney and glomerulus undergo structural changes, including increased fibrosis, glomerulonephritis and expression of injury and senescence-associated markers. Lastly, we utilized our method for high-throughput analysis of mouse glomeruli to characterize cell-specific and age-related changes in glomerular cells. This analysis revealed a senescence-associated phenotype in aged mesangial cells, and emphasized the potential importance of mesangial cells and macrophages in this niche. Our study provides insights into the molecular and cellular changes of the aging glomerulus that suggest therapeutic targets for age-related renal dysfunction.

Project description:Kidney aging and its contribution to disease and its underlying mechanisms are not well understood. Yet with an aging population, kidney health becomes an important medical and socioeconomic factor. We previously showed that podocytes isolated from aged mice exhibit increased expression of Programed Cell Death Protein 1 (PD-1) surface receptor and its two ligands (PD-L1, PD-L2). We now extend this observation to aged human kidneys. In vitro studies in cultured podocytes demonstrate a critical role of PD-1 signaling in cell survival and the induction of a Senescence-Associated Secretory Phenotype (SASP). To prove that the PD-1 signaling is critical to podocyte aging, aged mice were injected with an anti-PD-1 antibody (aPD-1ab). This treatment significantly improved the aging phenotype of the kidney and liver. In the glomerulus, it increased the lifespan of podocytes, but not parietal epithelial, mesangial or endothelial cells. Moreover, transcriptomic and immunohistochemistry studies demonstrate that anti-PD-1 treatment also improved the health-span of podocytes. It restored the expression of canonical podocyte genes, transcription factors and gene regulatory networks, increased the cellular metabolism signatures and lessened the SASP of aged podocytes. Increased PD-1 transcripts in human glomeruli significantly correlated with reduced eGFR.Together, these results suggest a critical contribution of increased PD-1 signaling towards both kidney and liver aging.

Project description:Molecular characterization of the individual cell types in human kidney as well as model organisms are critical in defining organ function and understanding translational aspects of biomedical research. Previous studies have uncovered gene expression profiles of several kidney glomerular cell types, however, important cells, including mesangial (MCs) and glomerular parietal epithelial cells (PECs), were missing or incompletely described, and a systematic comparison between mouse and human kidney is lacking. To this end, we used Smart-seq2 to profile 4332 individual glomerulus-associated cells isolated from human living donor renal biopsies and mouse kidney. The analysis revealed genetic programs for all four glomerular cell types (podocytes, glomerular endothelial cells, MCs and PECs) as well as rare glomerulus-associated macula densa cells (MDCs). Importantly, we detected heterogeneity in glomerulus-associated Pdgfrb-expressing cells, including bona fide intraglomerular MCs with the functionally active phagocytic molecular machinery, as well as a unique mural cell type located in the central stalk region of the glomerulus tuft. Furthermore, we observed remarkable species differences in the individual gene expression profiles of defined glomerular cell types that highlight translational challenges in the field and provide a guide to design translational studies.

Project description:The Wilms tumor-suppressor gene WT1, a key player in renal development, also has a crucial role in maintenance of the glomerulus in the mature kidney. However, molecular pathways orchestrated by WT1 in podocytes, where it is highly expressed, remain unknown. Their defects are thought to modify the cross-talk between podocytes and other glomerular cells and ultimately lead to glomerular sclerosis, as observed in diffuse mesangial sclerosis (DMS) a nephropathy associated with WT1 mutations. To identify podocyte WT1 targets, we generated a novel DMS mouse line, performed gene expression profiling in isolated glomeruli, and identified excellent candidates that may modify podocyte differentiation and growth factor signalling in glomeruli. Scel, encoding sciellin, a protein of the cornified envelope in the skin, and sulf1, encoding a 6-O endosulfatase, are shown to be expressed in wild type podocytes and to be strongly down-regulated in mutants. Co-expression of Wt1, Scel and Sulf1 was also found in a mesonephric cell line, and siRNA-mediated knockdown of WT1 decreased Scel and Sulf1 mRNAs and proteins. By ChIP we show that Scel and Sulf1 are direct WT1 targets. Cyp26a1, encoding an enzyme involved in the degradation of retinoic acid, is shown to be up-regulated in mutant podocytes. Cyp26a1 may play a role in the development of glomerular lesions but does not seem to be regulated by WT1. These results provide novel clues in our understanding of normal glomerular function and early events involved in glomerulosclerosis. Experiment Overall Design: Isolation of glomeruli from mutant (FVB-N4 Wt1+/R394W) and wild-type (FVB-N4 Wt1+/+) was performed after cardiac Dynabead perfusion. GeneChip analysis of glomeruli from 5 Wt1+/R394W mice and 5 Wt1+/+ littermates (N4-FVB) were performed independently. Animals were unweaned 27-day-old males. The Wt1+/R394W mice used were showing little albuminuria (<3 ug/ul on Coomassie blue stained SDS-PAGE gel) and no evidence of mesangial lesions by light microscopy.

Project description:Background: Recent single-cell RNA sequencing (scRNA-seq) analyses have offered much insight into cell-specific gene expression profiles in normal kidneys. However, in diseased kidneys, understanding of changes in specific cells, particularly glomerular cells, remains limited. Methods: To elucidate the glomerular cell–specific gene expression changes in diabetic kidney disease, we performed scRNA-seq analysis of isolated glomerular cells from streptozotocin-induced diabetic endothelial nitric oxide synthase (eNOS)–deficient (eNOS-/-) mice and control eNOS-/- mice. Results: We identified five distinct cell populations, including glomerular endothelial cells, mesangial cells, podocytes, immune cells, and tubular cells. Using scRNA-seq analysis, we confirmed the expression of glomerular cell–specific markers and also identified several new potential markers of glomerular cells. The number of immune cells was significantly higher in diabetic glomeruli compared with control glomeruli, and further cluster analysis showed that these immune cells were predominantly macrophages. Analysis of differential gene expression in endothelial and mesangial cells of diabetic and control mice showed dynamic changes in the pattern of expressed genes, many of which are known to be involved in diabetic kidney disease. Moreover, gene expression analysis showed variable responses of individual cells to diabetic injury. Conclusion: Our findings demonstrate the ability of scRNA-seq analysis in isolated glomerular cells from diabetic and control mice to reveal dynamic changes in gene expression in diabetic kidneys, with variable responses of individual cells. Such changes, which might not be apparent in bulk transcriptomic analysis of glomerular cells, may help identify important pathophysiologic factors contributing to the progression of diabetic kidney disease.

Project description:Alteration of fetal kidney morphogenesis in diabetic pregnancies is poorly described, especially changes in the extracellular matrix (ECM) and glomerular basement membrane (GBM) during glomerulogenesis. Addressing the ECM proteome, or matrisome, in mouse fetal glomeruli in a healthy and diabetic environment will improve understanding about the association between ECM and GBM changes in the glomerulus as potential reprogramming mechanisms for glomerular dysfunction in infants of mothers with diabetes. This project aimed to define the matrisome and BM composition in the maturing murine fetal glomeruli collected from normal and diabetic mothers. For this, we used laser microdissection microscopy to isolate maturing glomeruli from cryosections, and analyse by label-free tandem mass spectrometry to test the hypothesis that maternal diabetes influences ECM and GBM composition, assembly and function.

Project description:Glomerular diseases account for the majority of cases with chronic renal failure. Several genes have been identified with key relevance for glomerular function. Quite a few of these genes show a specific or preferential mRNA expression in the renal glomerulus. To identify additional candidate genes involved in glomerular function in humans we generated a human renal glomerulus-specific transcript dataset (GTD) by comparing gene expression profiles from human glomeruli and tubulointerstitium obtained from six transplant living donors using Affymetrix HG-U133A arrays. This analysis resulted in 677 genes with prominent overrepresentation in the glomerulus. Genes with ‘a prior’i established known prominent glomerular expression served for validation and were all found in the novel expression library (e.g. CDKN1, DAG1, DDN, EHD3, MYH9, NES, NPHS1, NPHS2, PDPN, PLA2R1, PLCE1, PODXL, PTPRO, SYNPO, TCF21, TJP1, WT1). The mRNA expression for several novel glomerulus-enriched genes identified in REGGEL was validated by qRT-PCR. Gene ontology and pathway analysis identified biological processes previously not reported to be of relevance in glomeruli including among others axon guidance. This finding was further validated by assessing the expression of the axon guidance molecules neuritin (NRN1) and roundabout receptor ROBO1 and -2. Glomerular disease associated differential mRNA regulation of ROBO2 was found in diabetic nephropathy. In summary, using a comparative strategy on microdissected nephrons novel transcripts with predominant expression in the human glomerulus could be identified. A systematic analysis of this glomerulus-specifc gene expression library allows the detection of target molecules and biological processes involved in glomerular biology and renal disease. Sample from kidney biopsies of 6 transplant Living Donors (LD) were microdissected into tubular and glomerular compartment and separately hybridized an Affymetrix HG-U133A microarrays. Background correction and quantile normalization was ferformed using RMAexpress Version 0.3 as part of a dataset of 88 samples for glomeruli and 84 samples for tubuli. All data are reported in log2 scale. A background filter cut-off was defined to lower the count of false positive calls using the highest signal value obtained from non-human Affymetrix control oligonucleotides multiplied by a factor of 1.2, following previous studies: Schmid H, Boucherot A, Yasuda Y, et al.: Modular activation of nuclear factor-kappaB transcriptional programs in human diabetic nephropathy. Diabetes 55:2993-3003, 2006 A linear model was fit to compensate differences in expression due to separate sample processing of the compartments. Subsequently, genes were selected based on foldchange.

Project description:The decrease in the podocyte’s lifespan and health-span that typify healthy kidney aging cause a decrease in their normal structure, physiology and function. The ability to halt and even reverse these changes becomes clinically relevant when disease is superimposed on an aged kidney. RNA-sequencing of podocytes from middle-aged mice showed an inflammatory phenotype with increases in the NLRP3 inflammasome, signaling for IL2/Stat5, IL6 and TNF, interferon gamma response, allograft rejection and complement, consistent with inflammaging. Furthermore, injury-induced NLRP3 signaling in podocytes was further augmented in aged mice compared to young ones. The NLRP3 inflammasome (NLRP3, Caspase-1, IL1ß IL-18) was also increased in podocytes of middle-aged humans. Higher transcript expression for NLRP3 in human glomerular was accompanied by reduced podocyte density and increased global glomerulosclerosis and glomerular volume. Pharmacological inhibition of NLRP3 with MCC950, or gene deletion, reduced podocyte senescence and the genes typifying aging in middle-aged mice, which was accompanied by an improved podocyte lifespan and health-span. Moreover, modeling the injury-dependent increase in NLRP3 signaling in human kidney organoids confirmed the anti-senescence effect of MC9950. Finally, the impact of NLRP3 also impacted liver aging. Together, these results suggest a critical role for the NLRP3 inflammasome in podocyte and liver aging.

Project description:Aging and senescence-associated signatures of aged kidney glomerular cells

Project description:There are 3 cell types in a glomerulus: podocytes, mesangial cells and endothelial cells. These cell types play distinct roles in the structure and functions of glomeruli. In order to profile the gene expression of single glomerular cells, we isolated mouse glomeruli by Dynabead/magnetic concentration method and digested them with enzymes to dissociate them into single cells. We loaded the single cell suspension to a Fluidigm C1 Single-Cell Auto Prep System for single cell cDNA preparation. We performed qPCR analyses of marker genes of podocytes (Npsh2, Synaptopodin, WT1), mesangial cells (Gata3, IGFbp5) and endothelial cells (CD31, Tie2) to determine the identity of each cDNA sample. To identify podocyte-specific genes, we mixed 15 mesangial cell cDNA samples and 15 endothelial cell cDNA samples and further divided into 3 aliquots as replicates for sequencing using Illumina HiSeq 2000 system. The resulting data are used to compare with that of podocytes in order to identify podocyte-specific genes.