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), are missing or incompletely described, and a systematic comparison between mouse and human kidney is lacking. To this end, we use Smart-seq2 to profile 4332 individual glomerulus-associated cells isolated from human living donor renal biopsies and mouse kidney. The analysis reveals genetic programs for all four glomerular cell types (podocytes, glomerular endothelial cells, MCs and PECs) as well as rare glomerulus-associated macula densa cells. Importantly, we detect 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 observe 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.
Cisplatin is a cytostatic drug used for treatment of solid organ tumors. The main adverse effect is organic cation transporter 2 (OCT2)-mediated nephrotoxicity, observed in 30% of patients. The contribution of other renal drug transporters is elusive. Here, cisplatin-induced toxicity was evaluated in human-derived conditionally immortalized proximal tubule epithelial cells (ciPTEC) expressing renal drug transporters, including OCT2 and organic anion transporters 1 (OAT1) or 3 (OAT3). Parent ciPTEC demonstrated OCT2-dependent cisplatin toxicity (TC 50 34 6 1 mM after 24-hour exposure), as determined by cell viability. Overexpression of OAT1 and OAT3 resulted in reduced sensitivity to cisplatin (TC 50 45 6 6 and 64 6 11 mM after 24-hour exposure, respectively). This effect was independent of OAT-mediated transport, as the OAT substrates probenecid and diclofenac did not influence cytotoxicity. Decreased cisplatin sensitivity in OAT-expressing cells was associated directly with a trend toward reduced intracellular cisplatin accumulation, explained by reduced OCT2 gene expression and activity. This was evaluated by V max of the OCT2-model substrate ASP + (23.5 6 0.1, 13.1 6 0.3, and 21.6 6 0.6 minutes 21 in ciPTEC-parent, ciPTEC-OAT1, and ciPTEC-OAT3, respectively). Although gene expression of cisplatin efflux transporter multidrug and toxin extrusion 1 (MATE1) was 16.2 6 0.3-fold upregulated in ciPTEC-OAT1 and 6.1 6 0.7-fold in ciPTEC-OAT3, toxicity was unaffected by the MATE substrate pyrimethamine, suggesting that MATE1 does not play a role in the current experimental set-up. In conclusion, OAT expression results in reduced cisplatin sensitivity in renal proximal tubule cells, explained by reduced OCT2-mediated uptake capacity. In vitro drug-induced toxicity studies should consider models that express both OCT and OAT drug transporters.
Inflammatory pathways are activated in most glomerular diseases but molecular mechanisms driving them in kidney tissue are poorly known. We identified retinoic acid receptor responder 1 (Rarres1) as a highly podocyteenriched protein in healthy kidneys. Studies in podocytespecific knockout animals indicated that Rarres1 was not needed for the normal development or maintenance of the glomerulus filtration barrier and did not modulate the outcome of kidney disease in a model of glomerulonephritis. Interestingly, we detected an induction of Rarres1 expression in glomerular and peritubular capillary endothelial cells in IgA and diabetic kidney disease, as well as in ANCA-associated vasculitis. Analysis of publicly available RNA data sets showed that the induction of Rarres1 expression was a common molecular mechanism in chronic kidney diseases. A conditional knock-in mouse line, overexpressing Rarres1 specifically in endothelial cells, did not show any obvious kidney phenotype. However, the overexpression promoted the progression of kidney damage in a model of glomerulonephritis. In line with this, conditional knock-out mice, lacking Rarres1 in endothelial cells, were partially protected in the disease model. Mechanistically, Rarres1 promoted inflammation and fibrosis via transcription factor Nuclear Factor-kB signaling pathway by activating receptor tyrosine kinase Axl. Thus, induction of Rarres1 expression in endothelial cells is a prevalent molecular mechanism in human glomerulopathies and this seems to have a pathogenic role in driving inflammation and fibrosis via the Nuclear Factor-kB signaling pathway.
AbstractαKlotho (Klotho) has well established renoprotective effects; however, the molecular pathways mediating its glomerular protection remain incompletely understood. Recent studies have reported that Klotho is expressed in podocytes and protects glomeruli through auto- and paracrine effects. Here, we examined renal expression of Klotho in detail and explored its protective effects in podocyte-specific Klotho knockout mice, and by overexpressing human Klotho in podocytes and hepatocytes. We demonstrate that Klotho is not significantly expressed in podocytes, and transgenic mice with either a targeted deletion or overexpression of Klotho in podocytes lack a glomerular phenotype and have no altered susceptibility to glomerular injury. In contrast, mice with hepatocyte-specific overexpression of Klotho have high circulating levels of soluble Klotho, and when challenged with nephrotoxic serum have less albuminuria and less severe kidney injury compared to wildtype mice. RNA-seq analysis suggests an adaptive response to increased endoplasmic reticulum stress as a putative mechanism of action. To evaluate the clinical relevance of our findings, the results were validated in patients with diabetic nephropathy, and in precision cut kidney slices from human nephrectomies. Together, our data reveal that the glomeruloprotective effects of Klotho is mediated via endocrine actions, which increases its therapeutic potential for patients with glomerular diseases.
Background and Aims Podocyte integrity is crucial for the maintenance of glomerular function in health and disease. Numerous studies have reported that Klotho overexpression, or treatment with recombinant Klotho, reduces glomerular and tubular damage in mouse models of renal disease. However, the mechanism(s) of action are not fully understood. Several recent studies have also reported that Klotho is expressed in podocytes, where it protects against various types of injury. These findings conflict with previous studies, which have shown that renal Klotho expression is exclusively confined to proximal and distal tubular cells. Method To address this discrepancy and enhance our understanding of the putative glomeruloprotective effects mediated by Klotho, we examined the expression pattern of Klotho in human and mouse kidney by several different methods, and explored its protective effects by overexpressing full-length human Klotho directly in podocytes or in a distant organ (i.e. liver). Results Data at the mRNA and protein levels all converged towards an absence or very low expression of Klotho in podocytes. The generation of a podocyte-specific Klotho knockout mouse further demonstrated that its deletion did not affect glomerular structure or function. Moreover, Klotho deficiency did not worsen glomerular injury in an experimental model of glomerulonephritis (anti-GBM). However, when Klotho was overexpressed in hepatocytes (Alb-cre;hKlothofl/+ - Alb-hKL), serum Klotho increased drastically with no changes in Fgf23 or phosphate metabolism. In mice challenged with anti-GBM, renal histology and ultrastructure of the filtration barrier was less severely affected in Alb-hKL compared to WT mice. There were also significantly less albuminuria, podocyte loss and interstitial fibrosis in Alb-hKL mice compared to their WT littermates. In contrast, mice which overexpressed Klotho in podocytes (Pod-hKL) were not protected from renal injury. Conclusion Taken together, these results strongly suggest that Klotho is not expressed in any substantial amounts in human or mouse podocytes, and that membrane-bound Klotho does not play a role in podocyte biology. Importantly, our results confirm a beneficial role for soluble Klotho in protecting podocytes against injury, and in maintaining glomerular integrity and function.
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