Abstract Objectives To understand the early stages if Alport nephropathy, we characterize the structural, functional, and biophysical properties of glomerular capillaries and podocytes in Col4α3 -/- mice, analyze kidney cortex transcriptional profiles at three time points, and investigate the effects of the ER stress mitigation by TUDCA on these parameters. We use human FSGS associated genes to identify molecular pathways rescued by TUDCA. Findings We define a disease progression timeline in Col4α3 -/- mice. Podocyte injury is evident by 3 months, with glomeruli reaching maximum deformability at 4 months, associated with 40% podocytes loss, followed by progressive capillary stiffening, increasing proteinuria, reduced renal function, inflammatory infiltrates, and fibrosis from months 4 to 7. RNA sequencing at 2, 4, and 7 months reveals increased cytokine and chemokine signaling, matrix and cell injury, and activation of the TNF pathway genes by 7 months, similar to NEPTUNE FSGS cohorts. These features are suppressed by TUDCA. Conclusions We define two phases of Col4α3 -/- nephropathy. The first is characterized by podocytopathy, increased glomerular capillary deformability and accelerated podocyte loss, and the second by increased capillary wall stiffening and renal inflammatory and profibrotic pathway activation. Disease suppression by TUDCA treatment identifies potential therapeutic targets for treating Alport and related nephropathies.
Focal segmental glomerulosclerosis (FSGS) accounts for about 40% of all nephrotic syndrome cases in adults. The presence of several potential circulating factors has been suggested in patients with primary FSGS and particularly in patients with recurrent disease after transplant. Irrespectively of the nature of the circulating factors, this study was aimed at identifying early glomerular/podocyte-specific pathways that are activated by the sera of patients affected by FSGS. Kidney biopsies were obtained from patients undergoing kidney transplantation due to primary FSGS. Donor kidneys were biopsied pre-reperfusion (PreR) and a subset 1–2 hours after reperfusion of the kidney (PostR). Thirty-one post reperfusion (PostR) and 36 PreR biopsy samples were analyzed by microarray and gene enrichment KEGG pathway analysis. Data were compared to those obtained from patients with incident primary FSGS enrolled in other cohorts as well as with another cohort to correct for pathways activated by ischemia reperfusion. Using an ex-vivo cell-based assay in which human podocytes were cultured in the presence of sera from patients with recurrent and non recurrent FSGS, the molecular signature of podocytes exposed to sera from patients with REC was compared to the one established from patients with NON REC. We demonstrate that inflammatory pathways, including the TNF pathway, are primarily activated immediately after exposure to the sera of patients with primary FSGS, while phagocytotic pathways are activated when proteinuria becomes clinically evident. The TNF pathway activation by one or more circulating factors present in the sera of patients with FSGS supports prior experimental findings from our group demonstrating a causative role of local TNF in podocyte injury in FSGS. Correlation analysis with clinical and histological parameters of disease was performed and further supported a possible role for TNF pathway activation in FSGS. Additionally, we identified a unique set of genes that is specifically activated in podocytes when cultured in the presence of serum of patients with REC FSGS. This clinical translational study supports our prior experimental findings describing a potential role of the TNF pathway in the pathogenesis of FSGS. Validation of these findings in larger cohorts may lay the ground for the implementation of integrated system biology approaches to risk stratify patients affected by FSGS and to identify novel pathways relevant to podocyte injury.
Limiting progressive fibrosis in chronic kidney disease (CKD) is an ongoing therapeutic challenge that requires effective and safe inhibition of a broad inflammatory cell milieu that leads to irreversible organ damage. Asengeprast, an anti-fibrotic and anti-inflammatory small molecule, has shown promising efficacy in animal models of kidney disease, however its target and mechanism of action was unknown. Using in vitro assays, we showed that asengeprast modulates inflammatory and fibrotic responses through selective inhibition of G protein-coupled receptor 68 (GPR68), a proton sensor, expressed in tissue-resident and immune-infiltrating cells of the kidney. Transcriptomic analysis of kidney tissue from animal models of diabetic kidney disease (DKD) and CKD demonstrated that fibrotic and inflammatory pathways dysregulated in disease were reversed by asengeprast treatment. Differential expression analysis of upstream regulators showed that the major, distinct signaling networks reversed were centered on a key driver of fibroblast activation, transforming growth factor β1, and associated signaling molecules. An asengeprast response gene signature derived from the CKD animal model when mapped onto gene expression profiles obtained from human kidney biopsies confirmed that the molecular pathways modulated by asengeprast were also dysregulated in human DKD and CKD. Further, this asengeprast response signature correlated with clinical markers of disease progression and tissue pathology. Overall, these findings provide evidence for targeted inhibition of GPR68 by asengeprast as a promising therapeutic strategy for treatment of CKD and potentially other fibrotic and inflammatory conditions.
The molecular mechanisms of sodium-glucose cotransporter-2 (SGLT2) inhibitors (SGLT2i) remain incompletely understood. Single-cell RNA sequencing and morphometric data were collected from research kidney biopsies donated by young persons with type 2 diabetes (T2D), aged 12 to 21 years, and healthy controls (HCs). Participants with T2D were obese and had higher estimated glomerular filtration rates and mesangial and glomerular volumes than HCs. Ten T2D participants had been prescribed SGLT2i (T2Di[+]) and 6 not (T2Di[-]). Transcriptional profiles showed SGLT2 expression exclusively in the proximal tubular (PT) cluster with highest expression in T2Di(-) patients. However, transcriptional alterations with SGLT2i treatment were seen across nephron segments, particularly in the distal nephron. SGLT2i treatment was associated with suppression of transcripts in the glycolysis, gluconeogenesis, and tricarboxylic acid cycle pathways in PT, but had the opposite effect in thick ascending limb. Transcripts in the energy-sensitive mTORC1-signaling pathway returned toward HC levels in all tubular segments in T2Di(+), consistent with a diabetes mouse model treated with SGLT2i. Decreased levels of phosphorylated S6 protein in proximal and distal tubules in T2Di(+) patients confirmed changes in mTORC1 pathway activity. We propose that SGLT2i treatment benefits the kidneys by mitigating diabetes-induced metabolic perturbations via suppression of mTORC1 signaling in kidney tubules.
