Project description:<p>Renal fibrosis, a hallmark of chronic kidney diseases, is driven by the activation of renal fibroblasts. Recent studies have highlighted the role of glycolysis in this process. Nevertheless, one critical glycolytic activator, 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase 3 (PFKFB3), remains unexplored in renal fibrosis. Upon reanalyzing the single-cell sequencing data from Dr. Humphreys' lab, we noticed an upregulation of glycolysis, gluconeogenesis, and TGFβ signaling pathway in myofibroblasts from fibrotic kidneys after unilateral ureter obstruction (UUO) or kidney ischemia/reperfusion. Furthermore, our experiments showed significant induction of PFKFB3 in mouse kidneys following UUO or kidney ischemia/reperfusion. To delve deeper into the role of PFKFB3, we generated mice with Pfkfb3 deficiency specifically in myofibroblasts (Pfkfb3f/fPostnMCM). Following UUO or kidney ischemia/reperfusion, a substantial decrease of fibrosis in injured kidneys of Pfkfb3f/fPostnMCM mice was identified compared to their wild-type littermates. Additionally, in cultured renal fibroblast NRK-49F cells, PFKFB3 was elevated upon exposure to TGFβ1, accompanied by the increase of α-SMA and fibronectin. Notably, this upregulation was significantly diminished with PFKFB3 knockdown, correlated with a glycolysis suppression. Mechanistically, the glycolytic metabolite lactate promoted the fibrotic activation of NRK-49F. In conclusion, our study demonstrates the critical role of PFKFB3 in driving fibroblast activation and subsequent renal fibrosis.</p>

Project description:Kidney fibrosis is characterized by expansion and activation of platelet-derived growth factor receptor-β (PDGFR-β) positive mesenchymal cells. To study the consequences of PDGFR-ß activation, we developed a model of primary renal fibrosis using transgenic mice with PDGFR-β activation specifically in renal mesenchymal cells, driving their pathological proliferation and phenotypic switch towards myofibroblasts. This resulted in progressive mesangioproliferative glomerulonephritis, mesangial sclerosis and interstitial fibrosis with progressive anemia due to loss of erythropoietin production by fibroblasts. We used microarrays to compare wildtype animals (Foxd1_wt Pdgfrb_wt) to animals with constitutive mesenchymal PDGFR-β activation (Foxd1_mt Pdgfrb V536A) in the kidney to identify target genes of PDGFR-β signaling.

Project description:Kidney fibrosis is the hallmark of chronic kidney disease progression, however currently no antifibrotic therapies exist. This is largely because the origin, functional heterogeneity and regulation of scar-forming cells during human kidney fibrosis remains poorly understood. Here, using single cell RNA-seq, we profiled the transcriptomes of proximal tubule and non-proximal tubule cells in healthy and fibrotic human kidneys to map the entire human kidney in an unbiased approach. This enabled mapping of all matrix-producing cells at high resolution, revealing distinct subpopulations of pericytes and fibroblasts as the major cellular sources of scar forming myofibroblasts during human kidney fibrosis. We used genetic fate-tracing, time-course single cell RNA-seq and ATAC-seq experiments in mice, and spatial transcriptomics in human kidney fibrosis to functionally interrogate these findings, shedding new light on the origin, heterogeneity and differentiation of human kidney myofibroblasts and their fibroblast and pericyte precursors at unprecedented resolution. Finally, we used this strategy to facilitate target discovery, identifying Nkd2 as a myofibroblast-specific target in human kidney fibrosis.

Project description:Kidney fibrosis is the hallmark of chronic kidney disease progression, however currently no antifibrotic therapies exist. This is largely because the origin, functional heterogeneity and regulation of scar-forming cells during human kidney fibrosis remains poorly understood. Here, using single cell RNA-seq, we profiled the transcriptomes of proximal tubule and non-proximal tubule cells in healthy and fibrotic human kidneys to map the entire human kidney in an unbiased approach. This enabled mapping of all matrix-producing cells at high resolution, revealing distinct subpopulations of pericytes and fibroblasts as the major cellular sources of scar forming myofibroblasts during human kidney fibrosis. We used genetic fate-tracing, time-course single cell RNA-seq and ATAC-seq experiments in mice, and spatial transcriptomics in human kidney fibrosis to functionally interrogate these findings, shedding new light on the origin, heterogeneity and differentiation of human kidney myofibroblasts and their fibroblast and pericyte precursors at unprecedented resolution. Finally, we used this strategy to facilitate target discovery, identifying Nkd2 as a myofibroblast-specific target in human kidney fibrosis.

Project description:Dissecting the molecular and cellular nature of advanced renal fibrosis is principal for mechanistic understanding of chronic kidney disease (CKD) and developing targeted strategies against its progression. Aberrant renal fibroblast activation and unresolved tubular epithelial injury are key contributors to excessive extracellular matrix (ECM) production and kidney function loss. However, the transcriptional and cellular identities of activated renal fibroblasts remain poorly characterized. Moreover, historically used markers compromise specificity of activated renal fibroblasts tracing and targeting. Here, we created comprehensive single cell transcriptional profiles of two clinically relevant long-term renal fibrosis models and revealed three distinctive “secretory”, “contractile” and “migratory” fibroblast clusters. We identified a novel specific renal activated fibroblast marker expressed in all three populations. Advanced kidney fibrotic remodeling elicited sustaining developmental signature and pronounced epithelial-to-stromal crosstalk. Furthermore, we mechanistically validated AHNAK as a putative novel target of kidney injury in a primary human in vitro model of epithelial-to-mesenchymal transition.

Project description:Telomere dysfunction in type II AECs, mediated by deletion of the telomere shelterin protein TRF1, leads to spontaneous development of pulmonary fibrosis in mice (SPC-creTRF1flox/flox mice). We sought to identify gene signature in these lungs in an effort to understand molecular mechanisms of the disease.

Project description:The kidney has large regenerative capacity that is impeded when injured renal tubular epithelial cells (TECs) undergo SNAI1-driven partial epithelial mesenchymal transition (pEMT). Here we investigate the role of IL11 in TEC pEMT and kidney repair. Wild-type mice with acute kidney injury (AKI) upregulate IL11 in TECs triggering an ERK/P90RSK/GSK3β axis of SNAI1 expression leading to impaired renal function, which is abrogated in Il11 null mice. In mouse models of AKI, a neutralizing IL11 antibody promotes kidney regeneration, while attenuating pEMT, fibrosis and kidney dysfunction. In TECs, TGFβ1 induces autocrine IL11/ERK-dependent pEMT leading to paracrine, IL11-mediated fibroblast activation. Mice with TEC-specific deletion of Il11ra1 are protected from pEMT, inflammation, fibrosis and renal failure. In a mouse model of chronic kidney disease, administration of anti-IL11 reverses fibrosis, regenerates kidney parenchyma and restores renal function. Therapeutic inhibition of IL11 signaling appears permissive for promoting kidney regeneration and improving kidney function.

Project description:Renal fibrosis is the final common pathway for chronic kidney disease. However, the detailed mechanisms and therapeutic strategies for renal fibrosis have not been established. MicroRNAs (miRNAs) are small, non coding RNAs that regulate various pathological conditions and diseases. Previous studies reported that miRNAs play a pivotal role in renal fibrosis. However, the role of miRNAs in renal fibrosis has not been completely elucidated. Therefore, in this study, miRNAs on renal fibrosis was investigated in a renal fibrosis mouse model generated by unilateral ureteral obstruction. MiRNA microarray analysis revealed 109 miRNAs that were upregulated more than 2 fold and 113 miRNAs that were downregulated less than 0.5 fold in the kidney of UUO mice compared with control mice.

Project description:The mRNA transcriptome and m6A methylation microarray profiling of mouse kidney tissues. Kidney tissues from the sham-operated group and unilateral ureteral ligation/obstruction (UUO) kidney tissues were compared. The latter were mainly fibrotic kidney tissues. The goal was to identify the effect of the renal fibrosis on gene expression and corresponding m6A modifications during kidney fibrosis.

Project description:Excessive renal fibrosis is a common pathology in progressive chronic kidney diseases. Inflammatory injury and aberrant repair processes contribute to the development of kidney fibrosis. Myeloid cells, particularly monocytes/macrophages, play a crucial role in kidney fibrosis by releasing their proinflammatory cytokines and extracellular matrix components such as collagen and fibronectin into the microenvironment of the injured kidney. Numerous signaling pathways have been identified in relation to these activities. However, the involvement of metabolic pathways in myeloid cell functions during the development of renal fibrosis remains understudied. In our study, we initially reanalyzed single-cell RNA sequencing data of renal myeloid cells from Dr. Denby’s group and observed an increased glycolytic pathway in myeloid cells that are critical for renal inflammation and fibrosis. To investigate the role of myeloid glycolysis in renal fibrosis, we utilized a model of unilateral ureteral obstruction in mice deficient of Pfkfb3, an activator of glycolysis, in myeloid cells (Pfkfb3ΔMϕ) and their wild type littermates (Pfkfb3WT). We observed a significant reduction in fibrosis in the obstructive kidneys of Pfkfb3ΔMϕ mice compared to Pfkfb3WT mice. This was accompanied by a substantial decrease in myeloid cell infiltration, as well as a decrease in the numbers of M1 and M2 macrophages and suppression of macrophage to obtain myofibroblast phenotype in the obstructive kidneys of Pfkfb3ΔMϕ mice. Mechanistic studies indicate that glycolytic metabolites stabilize HIF1α, leading to alterations in macrophage phenotypes that contribute to renal fibrosis. In conclusion, our study implicates that targeting myeloid glycolysis represents a novel approach to inhibit renal fibrosis.