Parietal Epithelial Cell Activation Research Articles

Investigating FSGS-like Injury in Zebrafish Larvae by Nifurpirinol: Efficacy and Molecular Insight.

Identifying effective drugs for focal segmental glomerulosclerosis (FSGS) treatment holds significant importance. Our high-content drug screening on zebrafish larvae relies on nitroreductase/metronidazole (NTR/MTZ)-induced podocyte ablation to generate FSGS-like injury. A crucial factor for successful drug screenings is minimizing variability in injury induction. For this, we introduce Nifurpirinol (NFP) as a more reliable prodrug for targeted podocyte depletion. NFP showed a 2.3-fold increase in efficiency at concentrations 1600-fold lower compared to MTZ-mediated injury induction. Integration into the screening workflow validated its suitability for the high-content drug screening. The presence of crucial FSGS hallmarks such as podocyte foot process effacement, proteinuria, and activation of parietal epithelial cells, were found. After the isolation of the glomeruli from the larvae, we identified essential pathways by proteomic analysis. This study shows that NFP serves as a highly effective prodrug to induce the FSGS-like disease in zebrafish larvae and is well-suited for a high-content drug screening to identify new candidates for the treatment of FSGS.

#417 Targeting parietal epithelial cell activation with mineralocorticoid receptor antagonism controls FSGS and crescentic glomerulonephritis

Abstract Background and Aims We have recently demonstrated that targeting specific pathways in parietal epithelial cells (PEC) can markedly alleviate experimental extracapillary glomerular injury [1]. Accumulating evidence has indicated the potential contributions of the mineralocorticoid receptor (MR) to the pathophysiology of chronic kidney disease. MR is expressed in endothelial cells, glomerular mesangial cells, podocytes, and distal tubular cells. Previous studies have shown that administering mineralocorticoid receptor antagonists has beneficial effects in various renal injury animal models, the role of the MR in extracapillary glomerulopathies is still elusive and mechanistically unclear. Methods To investigate the cell-specific role of the MR in PEC in the course of focal segmental glomerulosclerosis (FSGS) and crescentic glomerulonephritis (GN), we generated chimeric mice specifically lacking MR (Pec Cre Nr3c2lox/lox) in PECs using an inducible Cre recombinase system. Maladaptive FSGS was induced by combining a high-salt diet and deoxycorticosterone acetate (DOCA) with unilateral nephrectomy (DOCA-UniN). Crescentic glomerulonephritis (GN) was induced using the anti-glomerular basement membrane nephrotoxic serum (NTS) model. Results At baseline, Pec Cre Nr3c2wt/wt and Pec Cre Nr3c2lox/lox mice displayed no kidney morphology and function differences. When challenged by DOCA-UniN, PEC-selective Nr3c2 targeting significantly inhibited the expression of PEC activation markers Ki67, CD44, and FSGS lesions. Importantly, Pec Cre Nr3c2lox/lox mice showed less albuminuria and preserved renal function compared to Pec Cre Nr3c2 wt/wt counterparts. Likewise, Pec Cre Nr3c2lox/lox mice showed less albuminuria and preserved renal function in the NTS-induced CGN model. Crescents were also more numerous and organised in Pec Cre Nr3c2wt/wt mice than in Pec Cre Nr3c2lox/lox animals. Next, we examined whether pharmacological MR inhibition could alleviate the severity of crescentic GN. When Pec Cre Nr3c2wt/wt mice were orally given eplerenone for 14 days after the onset of the crescentic GN, they were significantly protected from renal injury and failure (decreased proteinuria, normal BUN and reduced number of crescent). Such global action was associated with less expression of the CD44 activation marker on PECs. Thus, genetic disruption of MR in PEC and pharmacological inhibition using eplerenone reduced glomerular expression of CD44 and crescent formation. Furthermore, kidney biopsies of individuals diagnosed with crescentic glomerulonephritis displayed increased expression of MR in PEC within FSGS and crescents. We next evaluated PEC migration under various conditions (DMSO, HB-EGF, Eplerenone, or HB-EGF+Eplerenone) for 24 hours. Eplerenone fully abrogated HB-EGF-induced PEC migration and Pcna, Snai1, and Vim mRNA expressions. Conclusion Altogether, these results indicate the critical role of MR in PEC activation during crescentic glomerulonephritis, along with the recently discovered CD9/EGFR/PDGFR [1] and CLDN1 pathways. This further supports the idea that the PEC phenotype switch is not a bystander event but plays a targetable critical active pathogenic role in FGSS and, more surprisingly, in crescentic GN. MR modulation using eplerenone may be a new therapeutic option for the management of such severe disease.

Renin-Angiotensin System Signaling in Parietal Epithelial Cells

INTRODUCTION. Bowman's capsule surrounds the kidney glomerular tuft and consists of a monolayer of parietal epithelial cells (PECs) creating a physiologically functioning barrier between the urinary space and the renal interstitium. Pathophysiological PEC activation describes the phenotypic switch from their normal quiescent state to one of proliferation and migration to the glomerular tuft, leading to glomerular injury. The development of several proteinuric kidney diseases is closely associated with PEC activation, however, the mechanisms of functional receptor signaling in these cells are not well described. This study investigates the functional presence of renin-angiotensin system (RAS) components and corresponding intracellular mechanisms in PECs. Methods. The vibrodissociation method was utilized to obtain freshly isolated Bowman’s capsules from discarded adult male human transplant tissues and 12-week old Wistar male and female rats. Confocal fluorescent microscopy of freshly isolated Bowman’s capsule PECs was performed using Fluo-8 or DAF-FM fluorescent dyes to detect changes in intracellular Ca2+ concentrations and nitric oxide (NO) response to the variety of RAS peptides. RESULTS. In separate experiments on freshly isolated rodent and human Bowman’s capsule PECs, we demonstrate the changes in redox response to the stimulation of RAS components. In particular, the acute application of Ang II peptide caused a rapid increase in NO production. Interestingly, we did not indicate significant changes in intracellular Ca2+ influx. To find out which receptor is responsible for the NO release we preincubated PECs with AT1R and AT2R blockers (Losartan and PD123319 respectively). Our data indicate that RAS mediates NO production through the AT2R activation. There is no sex difference was observed in these experiments. Further experiments with the variety of nitric oxide synthase (NOS) pharmacology reveal the functional distribution of NOS in rodent PECs. CONCLUSION. Our study provides an overview of the RAS signaling within PECs. For the first time, we present evidence demonstrating a direct connection between Ang II and redox homeostasis in PECs. Further investigation using the developed approach will be essential for understanding the role of Bowman's capsule cells in the glomerulus and the development of potential treatment against the hyperplasia of activated PECs and corresponding chronic kidney pathologies. Funding Sources: R01 DK129227, R01 DK126720, VA CDA-2 1IK2BX005605-01. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Colony stimulating factor-1 receptor drives glomerular parietal epithelial cell activation in focal segmental glomerulosclerosis

Parietal epithelial cells (PECs) are kidney progenitor cells with similarities to a bone marrow stem cell niche. In focal segmental glomerulosclerosis (FSGS) PECs become activated and contribute to extracellular matrix deposition. Colony stimulating factor-1 (CSF-1), a hematopoietic growth factor, acts via its specific receptor, CSF-1R, and has been implicated in several glomerular diseases, although its role on PEC activation is unknown. Here, we found that CSF-1R was upregulated in PECs and podocytes in biopsies from patients with FSGS. Through invitro studies, PECs were found to constitutively express CSF-1R. Incubation with CSF-1 induced CSF-1R upregulation and significant transcriptional regulation of genes involved in pathways associated with PEC activation. Specifically, CSF-1/CSF-1R activated the ERK1/2 signaling pathway and upregulated CD44 in PECs, while both ERK and CSF-1R inhibitors reduced CD44 expression. Functional studies showed that CSF-1 induced PEC proliferation and migration, while reducing the differentiation of PECs into podocytes. These results were validated in the Adriamycin-induced FSGS experimental mouse model. Importantly, treatment with either the CSF-1R-specific inhibitor GW2580 or Ki20227 provided a robust therapeutic effect. Thus, we provide evidence of the role of the CSF-1/CSF-1R pathway in PEC activation in FSGS, paving the way for future clinical studies investigating the therapeutic effect of CSF-1R inhibitors on patients with FSGS.

Role of Colony-Stimulating Factor-1 Receptor in Driving Parietal Epithelial Cell Activation in Focal Segmental Glomerulosclerosis

Role of Colony-Stimulating Factor-1 Receptor in Driving Parietal Epithelial Cell Activation in Focal Segmental Glomerulosclerosis

The Role of Platelet-Derived Growth Factor in Focal Segmental Glomerulosclerosis.

FSGS is the final common pathway to nephron loss in most forms of severe or progressive glomerular injury. Although podocyte injury initiates FSGS, parietal epithelial cells (PECs) are the main effectors. Because PDGF takes part in fibrotic processes, we hypothesized that the ligand PDGF-B and its receptor PDGFR- β participate in the origin and progression of FSGS. We challenged Thy1.1 transgenic mice, which express Thy1.1 in the podocytes, with anti-Thy1.1 antibody to study the progression of FSGS. We investigated the role of PDGF in FSGS using challenged Thy1.1 mice, 5/6 nephrectomized mice, Col4 -/- (Alport) mice, patient kidney biopsies, and primary murine PECs, and challenged Thy1.1 mice treated with neutralizing anti-PDGF-B antibody therapy. The unchallenged Thy1.1 mice developed only mild spontaneous FSGS, whereas challenged mice developed progressive FSGS accompanied by a decline in kidney function. PEC activation, proliferation, and profibrotic phenotypic switch drove the FSGS. During disease, PDGF-B was upregulated in podocytes, whereas PDGFR- β was upregulated in PECs from both mice and patients with FSGS. Short- and long-term treatment with PDGF-B neutralizing antibody improved kidney function and reduced FSGS, PEC proliferation, and profibrotic activation. In vitro , stimulation of primary murine PECs with PDGF-B recapitulated in vivo findings with PEC activation and proliferation, which was inhibited by PDGF-B antibody or imatinib. PDGF-B-PDGFR- β molecular crosstalk between podocytes and PECs drives glomerulosclerosis and the progression of FSGS. This article contains a podcast at.

FC074: Mineralocorticoid Receptor Drives Parietal Epithelial Cell Activation and Glomerular Injury During Crescentic Glomerulonephritis

Abstract BACKGROUND AND AIMS We have recently demonstrated that targeting specific pathways in parietal epithelial cells (PEC) can markedly alleviate experimental extracapillary glomerular injury (1). Accumulating evidence has indicated the potential contributions of aldosterone and mineralocorticoid receptor (MR) to the pathophysiology of chronic kidney disease. MR is strongly expressed in endothelial cells, glomerular mesangial cells, podocytes and distal tubular cells. Previous studies have shown that administration of mineralocorticoid receptor antagonists, including spironolactone and eplerenone, has beneficial effects in various renal injury animal models, such as unilateral ureteral obstruction, ischemia-reperfusion, cyclosporine-induced nephrotoxicity and hypertensive renal injury. The role of the MR in extra capillary glomerulopathies is still elusive and mechanistically unclear. METHOD To investigate the cell-specific role of the MR in PEC in the course of crescentic glomerulonephritis, we generated chimeric mice specifically lacking MR (Pec Cre Nr3c2lox/lox) in PECs using an inducible Cre recombinase system. Crescentic glomerulonephritis (GN) was induced using the antiglomerular basement membrane nephrotoxic serum (NTS) model. In vivo, biological parameters (albuminuria, blood urea nitrogen—BUN), glomerular injury, as well as PEC activation (CD44, CD9 and fibronectin staining) were assessed. RESULTS At baseline, Pec Cre Nr3c2wt/wt and Pec Cre Nr3c2lox/lox mice displayed no kidney morphology and function differences. When challenged using the NTS model, Pec Cre Nr3c2lox/lox mice showed less albuminuria and preserved renal function as compared to Pec Cre Nr3c2 wt/wt counterparts. Crescents were also more numerous and organized in Pec Cre Nr3c2wt/wt mice. Next, we examined whether pharmacological MR inhibition could alleviate the severity of crescentic GN. When Pec Cre Nr3c2wt/wt mice were orally given eplerenone for 14 days after the onset of the crescentic GN, they were significantly protected from renal injury and failure (decreased proteinuria, normal BUN and reduced number of crescent). Such global action was associated with less activation molecule CD44 on PECs. Thus, genetic disruption of MR in PEC as well as pharmacological inhibition using eplerenone reduced glomerular expression of CD44 and crescent formation. Furthermore, kidney biopsies of individuals diagnosed with crescentic glomerulonephritis displayed increased expression of MR in PEC and crescents. CONCLUSION Altogether, these results indicate the critical role of MR in PEC activation during crescentic glomerulonephritis along with the recently discovered CD9/EGFR/PDGFR pathway. This further supports the idea that the PEC phenotype switch is not a bystander event but plays a targetable critical active pathogenic role in crescentic GN. MR modulation using eplerenone may be a new therapeutic option for the management of such severe disease.

FC019: Parietal Epithelial Cells Activation During Gemcitabine-Induced Nephrotoxicity: Communication With Endothelial Cells?

Abstract BACKGROUND AND AIMS Gemcitabine (GEM) is an anticancer drug, indicated in the treatment of several types of solid cancers such as pancreatic, breast, bladder cancer, etc. This molecule is effective in tumor processes but causes adverse effects on other organs, including the haematopoietic system and the kidney. The renal toxicity of gemcitabine is illustrated by thrombotic microangiopathy (TMA), whose onset is dramatic and associated in more than 97% of cases with acute renal failure. This adverse effect induces discontinuation of treatment with negative consequences on tumor control. It is, therefore, essential to understand the pathophysiological mechanisms of gemcitabine nephrotoxicity. TMA at the glomerular level reflects damage to the endothelial cell (ECs). However, previously, data of our team show that other glomerular cells, parietal epithelial cells (PECs), could be involved in these lesions. Thus, in this project, we want: i) to describe the modifications of the PEC and EC proteome exposed to gemcitabine and ii) to analyse PEC and EC secretome exposed to gemcitabine and to study the cell communication between PECs and ECs. METHOD In our in vitro experiments, we used a murine PEC cell line and a murine EC cell line. The PECs are exposed to 100 μM GEM for 24-h and the culture supernatants are recovered. These PEC supernatants are used in conditioned media experiments to expose ECs for 24-h. On the other hand, ECs were directly exposed to 1 μM GEM for 24-h and culture supernatants were also recovered. Analyses of protein expression are carried out by western blot and immunofluorescence staining. RESULTS When PECs are exposed to GEM (100 µM, 24-h), we observe an increase in apoptosis (caspase 3 cleavage) as well as DNA damage (γH2AX). However, PECs specific markers, such as PAX2 and Claudin-1, do not appear to be affected. Our results also show an increase in the expression of the transcription factor CHOP and the chaperone protein BIP, suggesting the presence of endoplasmic reticulum (ER) stress in PECs exposed to gemcitabine. In order to study cell communication between PECs and ECs, we set up conditioned media experiments. We first studied the expression of different endothelial markers on ECs exposed to PEC supernatants. The expression of the endothelial markers such as E-cadherin, CD31 and PDGFRβ decreases compared with control cells when ECs are exposed to PEC supernatants. Actin cytoskeleton reorganization is also observed with an increase in cortical actin. Moreover, the microtubule network seems to be also affected with a tendency to decrease tubulin expression. Finally, there is an increase in γH2AX suggesting the presence of DNA damage in ECs exposed to PEC supernatant. The next experiments aim at identifying the factors responsible for this cell communication (proteins, lipid mediators, non-coding RNA, extracellular vesicles). CONCLUSION Our results show GEM has a direct effect on PECs (apoptosis, DNA damage, ER stress). In addition, we show the effect of PEC supernatants exposed to GEM on ECs (decrease in endothelial markers, cytoskeleton modifications, DNA damage).

FC071: An HDAC Inhibitor Attenuates Crescentic Glomerulonephritis and Avoid Chronic Kidney Disease Enhancing Podocyte Progenitor Differentiation

Abstract BACKGROUND AND AIMS Crescentic glomerulonephritis (crescentic GN) encompasses a group of diverse disorders characterized by the presence of massive hyperplasia of parietal epithelial cells (PEC) as the main histopathological lesion at kidney biopsy. It is associated with a rapid decline in kidney function. Typically, crescent formation is the consequence of diverse upstream pathomechanisms involving the specific activation of PEC. PEC normally reside peacefully along Bowman capsule and represent in part renal progenitor cells (RPC). Previous studies observed RPC markers in crescents from patients with different types of glomerulonephritis. Similarities between stem cell niches of bone marrow and kidney, prompted us to hypothesized that crescents result from monoclonal expansion of a single RPC clone conceptually similar to monoclonal diseases originating from hematopoietic stem cells. According to this analogy, we further hypothesized that drugs known to cure monoclonal disease of the hematopoietic stem cells by enforcing their terminal differentiation could also attenuate crescentic glomerulonephritis. METHOD To address this hypothesis, we established a crescentic GN disease model in a conditional transgenic mouse based on the mT/mG and the Confetti reporter that allows lineage tracing and clonal analysis of RPCs. Animals were treated with known pharmacological inhibitors of clonal stem cell proliferation in myeloproliferative disorders. Crescentic lesions were characterized by super-resolution STED microscopy. Finally, we employed single cell RNA sequencing of human renal progenitor cultures to identify the immature progenitor subset-generating crescent in human to identify putative new biomarkers of crescentic GN to validate in biopsy of patients. RESULTS We observed that the crescentic lesions originated from the clonal expansion of single RPC, thus suggesting a clonal stem cell disorder. Therefore, we administrated a series of drugs known to ameliorates myeloproliferative neoplasms to our crescentic GN mouse model as potential therapeutic agents. Treatment with one of the compounds induced a reduction in both proteinuria and crescent formation. STED super-resolution imaging of glomeruli showed that this compound turned the uncontrolled hyperplasia of a specific immature PEC subset into a controlled differentiation into podocytes thereby restoring the injured glomerular filtration barrier. Moreover, delayed drug administration still induced proteinuria remission and avoided long-term development of chronic kidney disease (CKD), an effect associated to a continued generation of new podocytes and crescent regression over time. Single cell RNA sequencing of human RPC identified a new marker of the crescent-generating progenitor cells. Expression of this marker in biopsies of patients with crescentic GN associated with progression toward end stage kidney disease. Treatment of human PEC with the drug that in in vivo experiments showed a therapeutic effect on crescentic GN reduced proliferation of the immature progenitor subset promoting their differentiation into podocytes. CONCLUSION These results demonstrate that glomerular hyperplastic lesions derive from clonal amplification of a RPC subset and that shifting proliferation to podocyte differentiation reverses improves clinical outcome and avoid CKD.

MO066: The Role of Platelet-Derived Growth Factor in Focal Segmental Glomerulosclerosis

Abstract BACKGROUND AND AIMS Focal segmental glomerulosclerosis (FSGS) describes a primary disease of podocytes (podocytopathy) and a secondary consequence of severe or progressive glomerular damage. No specific treatment options exist for FSGS, with many patients progressing to end-stage kidney disease. While podocyte injury is considered to initiate FSGS, parietal epithelial cells (PECs) were shown to be one of the main effector cells forming FSGS. Given the involvement of platelet-derived growth factor (PDGF) in fibrotic processes, we hypothesized that PDGF signaling is involved in the formation and progression of FSGS. METHOD We analyzed the role of PDGF in FSGS development and progression using a murine Thy1.1 trangenic FSGS model, patient kidney biopsies and primary murine PECs. In a second step, we therapeutically treated mice with FSGS with a neutralizing anti-PDGF-B antibody. RESULTS The podocyte-specific Thy1.1 transgenic mice 3 weeks after anti-Thy1.1 antibody injection showed reduced kidney function due to FSGS development. In this model, compared with control mice, PECs were progressively activated (63.3-fold increase in CD44 expression), showed a significantly increased proliferation (14-fold increase in Ki67 expression), followed by glomerular extracellular matrix deposition (2.6-fold increase in collagen 4) and FSGS development. Fluorescence in situ hybridization showed that mRNA of Pdgfb and Pdgfd was elevated in podocytes and Pdgfrb was upregulated in PECs during the time course of the disease. Similarly, in human FSGS biopsies, gene expression of both ligands, PDGFB and PDGFD, was elevated in podocytes and PDGFRB was increased in PECs compared with healthy glomeruli. Stimulation of primary mouse PECs with PDGF-B and PDGF-D in vitro led to significant activation (1.37- and 1.44-fold increase in CD44 expression, respectively), proliferation (1.46- and 1.36-fold increase, respectively), migration and extracellular matrix production (1.40-fold increase in fibronectin after PDGF-D stimulation) which could be inhibited by imatinib or a neutralizing PDGF-B antibody. In mice with FSGS, both a short- and long-term treatment with PDGF-B neutralizing antibody improved kidney function and reduced FSGS, PEC proliferation and profibrotic activation. CONCLUSION PDGFR-β and its ligands PDGF-B and PDGF-D were upregulated in experimental and clinical samples with FSGS in PECs and podocytes, respectively, and the inhibition of PDGF-B reduced PEC proliferation and FSGS development. This suggests paracrine cross-talk between injured podocytes and PECs, leading to PECs activation toward a profibrotic (pro-FSGS) phenotype and FSGS development. Thus, PDGF represents a novel molecular pathway in FSGS pathogenesis and potential target for therapy.

Molecular Mechanisms of Kidney Injury and Repair.

Chronic kidney disease (CKD) will become the fifth global cause of death by 2040, thus emphasizing the need to better understand the molecular mechanisms of damage and regeneration in the kidney. CKD predisposes to acute kidney injury (AKI) which, in turn, promotes CKD progression. This implies that CKD or the AKI-to-CKD transition are associated with dysfunctional kidney repair mechanisms. Current therapeutic options slow CKD progression but fail to treat or accelerate recovery from AKI and are unable to promote kidney regeneration. Unraveling the cellular and molecular mechanisms involved in kidney injury and repair, including the failure of this process, may provide novel biomarkers and therapeutic tools. We now review the contribution of different molecular and cellular events to the AKI-to-CKD transition, focusing on the role of macrophages in kidney injury, the different forms of regulated cell death and necroinflammation, cellular senescence and the senescence-associated secretory phenotype (SAPS), polyploidization, and podocyte injury and activation of parietal epithelial cells. Next, we discuss key contributors to repair of kidney injury and opportunities for their therapeutic manipulation, with a focus on resident renal progenitor cells, stem cells and their reparative secretome, certain macrophage subphenotypes within the M2 phenotype and senescent cell clearance.

Regression of diabetic nephropathy by treatment with empagliflozin in BTBR ob/ob mice.

The sodium-glucose cotransporter-2 (SGLT2) inhibitor empagliflozin lowers blood glucose via reduced tubular reabsorption of filtered glucose and is an important new therapy for diabetic nephropathy (DN). This study tested whether treatment with empagliflozin would ameliorate proteinuria and the pathologic alterations of DN including podocyte number and integrity in the leptin-deficient BTBR ob/ob mouse model of DN. Study cohorts included wild-type (WT) BTBR mice, untreated diabetic BTBR ob/ob mice and mice treated with empagliflozin for 6 weeks after development of established DN at 18 weeks of age. Hyperglycemia, proteinuria, serum creatinine, accumulation of mesangial matrix and the extent of mesangiolysis were reversed with empagliflozin treatment. Treatment with empagliflozin resulted in an increased podocyte number and podocyte density, improvement in the degree of podocyte foot process effacement and parietal epithelial cell activation. SGLT2 inhibition reduced renal oxidative stress, measured by urinary excretion of markers of RNA/DNA damage and in situ demonstration of decreased carbonyl oxidation. There was no discernable difference in accumulations of advanced glycation end-products by immunohistochemistry. The structural improvements seen in BTBR ob/ob mice treated with empagliflozin provide insights into potential long-term benefits for humans with DN, for whom there is no comparable biopsy information to identify structural changes effected by SGLT2 inhibition. The findings suggest SGLT2 inhibition may ameliorate DN through glucose lowering-dependent and -independent mechanisms that lead to podocyte restoration and delay or reversal of disease progress.

Podocyte-specific KLF4 is required to maintain parietal epithelial cell quiescence in the kidney.

Podocyte loss triggering aberrant activation and proliferation of parietal epithelial cells (PECs) is a central pathogenic event in proliferative glomerulopathies. Podocyte-specific Krüppel-like factor 4 (KLF4), a zinc-finger transcription factor, is essential for maintaining podocyte homeostasis and PEC quiescence. Using mice with podocyte-specific knockdown of Klf4, we conducted glomerular RNA-sequencing, tandem mass spectrometry, and single-nucleus RNA-sequencing to identify cell-specific transcriptional changes that trigger PEC activation due to podocyte loss. Integration with in silico chromatin immunoprecipitation identified key ligand-receptor interactions, such as fibronectin 1 (FN1)–αVβ6, between podocytes and PECs dependent on KLF4 and downstream signal transducer and activator of transcription 3 (STAT3) signaling. Knockdown of Itgb6 in PECs attenuated PEC activation. Additionally, podocyte-specific induction of human KLF4 or pharmacological inhibition of downstream STAT3 activation reduced FN1 and integrin β 6 (ITGB6) expression and mitigated podocyte loss and PEC activation in mice. Targeting podocyte-PEC crosstalk might be a critical therapeutic strategy in proliferative glomerulopathies.

Establishment and characterization of a novel conditionally immortalized human parietal epithelial cell line

Parietal epithelial cells (PECs) are epithelial cells in the kidney, surrounding Bowman's space. When activated, PECs increase in cell volume, proliferate, migrate to the glomerular tuft and excrete extracellular matrix. Activated PECs are crucially involved in the formation of sclerotic lesions, seen in focal segmental glomerulosclerosis (FSGS). In FSGS, a number of glomeruli show segmental sclerotic lesions. Further disease progression will lead to increasing number of involved glomeruli and gradual destruction of the affected glomeruli. Although the involvement of PECs in FSGS has been acknowledged, little is known about the molecular processes driving PEC activation. To get more insights in this process, accurate in vivo and in vitro models are needed. Here, we describe the development and characterization of a novel conditionally immortalized human PEC (ciPEC) line. We demonstrated that ciPECs are differentiated when grown under growth-restrictive conditions and express important PEC-specific markers, while lacking podocyte and endothelial markers. In addition, ciPECs showed PEC-like morphology and responded to IL-1β treatment. We therefore conclude that we have successfully generated a novel PEC line, which can be used for future studies on the role of PECs in FSGS.

FC 038CRESCENTS DERIVE FROM SINGLE PODOCYTE PROGENITORS AND A DRUG ENHANCING THEIR DIFFERENTIATION ATTENUATES RAPIDLY PROGRESSIVE GLOMERULONEPHRITIS

Abstract Background and Aims Rapidly progressive glomerulonephritis (RPGN) encompasses a group of diverse disorders characterized by the presence of massive hyperplasia of parietal epithelial cells (PEC) as the main histopathological lesion at kidney biopsy. It is associated with a rapid decline in kidney function referred to altogether as rapidly progressive glomerulonephritis. Typically, crescent formation is the consequence of diverse upstream pathomechanisms involving the specific activation of PEC. PEC normally reside peacefully along Bowman capsule and represent in part renal progenitor cells (RPC). Previous studies observed RPC markers in crescents from patients with different types of glomerulonephritis. Similarities between stem cell niches of bone marrow and kidney, prompted us to hypothesized that crescents result from monoclonal expansion of a single RPC clone conceptually similar to monoclonal diseases originating from hematopoietic stem cells. According to this analogy, we further hypothesized that drugs known to cure monoclonal disease of the hematopoietic stem cells by enforcing their terminal differentiation could also attenuate crescentic glomerulonephritis. Method To address this hypothesis, we established a RPGN disease model in a conditional transgenic mouse based on the mT/mG and the Confetti reporter that allows lineage tracing and clonal analysis of RPCs. Animals were treated with known pharmacological inhibitors of clonal stem cell proliferation in myeloproliferative disorders. Crescentic lesions were characterized by super-resolution STED microscopy. Finally, we employed single cell RNA sequencing of human renal progenitor cultures to identify the immature progenitor subset-generating crescent in human to identify putative new biomarker(s) of RPNG to validate in biopsy of patients. Results We observed that the crescentic lesions originated from the clonal expansion of single RPC, thus suggesting a clonal stem cell disorder. Therefore, we administrated a series of drugs known to ameliorates myeloproliferative neoplasms to our RPGN mouse model as potential therapeutic agents. In particular, treatment with one of the compounds induced a reduction in both proteinuria and crescent formation. 3D confocal microscopy and STED super-resolution imaging of glomeruli showed that this compound turned the uncontrolled hyperplasia of a specific immature PEC subset into a controlled differentiation into new podocytes thereby restoring the injured glomerular filtration barrier. Single cell RNA sequencing of human renal progenitor cultures identified a new marker of the crescent-generating progenitor cells. Expression of this marker in biopsies of patients with rapidly progressive glomerulonephritis associated with progression toward end stage kidney disease. Treatment of human PEC with the drug that in in vivo experiments showed a therapeutic effect on RPGN reduced proliferation of the immature progenitor subset promoting their differentiation into podocytes. Conclusion These results demonstrate that glomerular hyperplastic lesions derive from clonal amplification of a RPC subset and that shifting proliferation to podocyte differentiation reverses crescent formation and improves clinical outcome.

Castrated autoimmune glomerulonephritis mouse model shows attenuated glomerular sclerosis with altered parietal epithelial cell phenotype.

Sex hormones help in maintaining proper immunity as well as renal homeostasis in mammals, and these multi-functional properties characterize the onset of sex-dependent diseases. To clarify the contribution of sex hormones to autoimmune disease-related renal pathogenesis, BXSB/MpJ-Yaa was investigated as a murine autoimmune glomerulonephritis model. BXSB/MpJ-Yaa and its wild-type, BXSB/MpJ-Yaa+ were castrated or sham-operated at three weeks and examined until six months of age. Both castrated strains showed significantly lower serum testosterone levels and body weights than sham-operated mice. Castration did not change the disease phenotypes in BXSB/MpJ-Yaa+. At three months, both sham-operated and castrated BXSB/MpJ-Yaa manifested splenomegaly, autoantibody production, and glomerulonephritis, and castrated BXSB/MpJ-Yaa tended to show heavier spleen weights than the sham-operated group. At six months, both the treated BXSB/MpJ-Yaa showed equivalent autoimmune disease conditions; however, castrated mice clearly showed milder glomerular sclerotic lesions than the sham-operated groups. Urinary albumin excretion in castrated BXSB/MpJ-Yaa was significantly milder than in sham-operated mice at four months, but those of both the treated BXSB/MpJ-Yaa were comparable at six months. The examined renal histopathological indices in parietal epithelial cells were remarkably altered by castration. Briefly, castration decreased the height of parietal epithelial cells and total parietal epithelial cell number in BXSB/MpJ-Yaa at six months. For immunostaining, parietal epithelial cells facing the injured glomeruli of BXSB/MpJ-Yaa expressed CD44, an activated parietal epithelial cell marker, and CD44-positive parietal epithelial cells showed nuclear localization of the androgen receptor and proliferation marker Ki67. CD44- or Ki67-positive parietal epithelial cells were significantly fewer in castrated group than in sham-operated BXSB/MpJ-Yaa at six months. Further, quantitative indices for CD44-positive parietal epithelial cell number and frequency in renal corpuscles positively correlated with glomerular sclerotic severity in BXSB/MpJ-Yaa. In conclusion, androgen seemed to have an effect on both systemic immunity and renal morpho-function; however, the effect on the latter could be more clearly observed in BXSB/MpJ-Yaa, as parietal epithelial cell activation resulted in glomerular sclerosis.

Transplantation of mesenchymal stem cells preserves podocyte homeostasis through modulation of parietal epithelial cell activation in adriamycin-induced mouse kidney injury model.

To determine the role of the transplantation of bone marrow-derived mesenchymal stem cells (MSCs) in podocyte renewal, we studied BALB/C mice with or without adriamycin-induced acute kidney injury. MSCs were transplanted ectopically under the capsule of the left kidney or into the peritoneal cavity after the onset of kidney injury to test testing their local or systemic paracrine effects, respectively. Adriamycin produced increases in urine protein: creatinine ratios, blood urea nitrogen, and blood pressure, which improved after both renal subcapsular and intraperitoneal MSCs transplants. The histological changes of adriamycin kidney changes regressed in both kidneys and in only the ipsilateral kidney after intraperitoneal or renal subcapsular transplants indicating that the benefits of transplanted MSCs were related to the extent of paracrine factor distribution. Analysis of kidney tissues for p57-positive parietal epithelial cells (PECs) showed that MSC transplants restored adriamycin-induced decreases in the abundance of these cells to normal levels, although after renal subcapsular transplants these changes did not extend to contralateral kidneys. Moreover, adriamycin caused inflammatory activation of PECs with coexpression of CD44 and phospho-ERK, which was normalized in both or only ipsilateral kidneys depending on whether MSCs were transplanted in the peritoneal cavity or subcapsular space, respectively.

Parietal epithelial cell differentiation to a podocyte fate in the aged mouse kidney.

Healthy aging is typified by a progressive and absolute loss of podocytes over the lifespan of animals and humans. To test the hypothesis that a subset of glomerular parietal epithelial cell (PEC) progenitors transition to a podocyte fate with aging, dual reporter PEC-rtTA|LC1|tdTomato|Nphs1-FLPo|FRT-EGFP mice were generated. PECs were inducibly labeled with a tdTomato reporter, and podocytes were constitutively labeled with an EGFP reporter. With advancing age (14 and 24 months) glomeruli in the juxta-medullary cortex (JMC) were more severely injured than those in the outer cortex (OC). In aged mice (24m), injured glomeruli with lower podocyte number (41% decrease), showed more PEC migration and differentiation to a podocyte fate than mildly injured or healthy glomeruli. PECs differentiated to a podocyte fate had ultrastructural features of podocytes and co-expressed the podocyte markers podocin, nephrin, p57 and VEGF164, but not markers of mesangial (Perlecan) or endothelial (ERG) cells. PECs differentiated to a podocyte fate did not express CD44, a marker of PEC activation. Taken together, we demonstrate that a subpopulation of PECs differentiate to a podocyte fate predominantly in injured glomeruli in mice of advanced age.

MAD2B contributes to parietal epithelial cell activation and crescentic glomerulonephritis via Skp2.

Mitotic spindle assembly checkpoint protein 2 (MAD2B), a well-known anaphase-promoting complex/cyclosome (APC/C) inhibitor and a small subunit of DNA polymerase-ζ, is critical for mitotic control and DNA repair. Previously, we detected a strong increase of MAD2B in the glomeruli from patients with crescentic glomerulonephritis and anti-glomerular basement membrane (anti-GBM) rats, which predominantly originated from activated parietal epithelial cells (PECs). Consistently, in vitro MAD2B was increased in TNF-α-treated PECs, along with cell activation and proliferation, as well as extracellular matrix accumulation, which could be reversed by MAD2B genetic depletion. Furthermore, we found that expression of S phase kinase-associated protein 2 (Skp2), an APC/CCDH1 substrate, was increased in the glomeruli of anti-GBM rats, and TNF-α-stimulated PECs and could be suppressed by MAD2B depletion. Additionally, genetic deletion of Skp2 inhibited TNF-α-induced PEC activation and dysfunction. Finally, TNF-α blockade or glucocorticoid therapy administered to anti-GBM rats could ameliorate MAD2B and Skp2 accumulation as well as weaken PEC activation. Collectively, our data suggest that MAD2B has a pivotal role in the pathogenesis of glomerular PEC activation and crescent formation through induction of Skp2 expression.

Glomerular Outgrowth as an Ex Vivo Assay to Analyze Pathways Involved in Parietal Epithelial Cell Activation.

Parietal epithelial cell (PEC) activation is one of the key factors involved in the development and progression of glomerulosclerosis. Inhibition of pathways involved in parietal epithelial cell activation could therefore be a tool to attenuate the progression of glomerular diseases. This article describes a method to culture and analyze parietal epithelial cell outgrowth of encapsulated glomeruli isolated from mouse kidney. After dissecting isolated mouse kidneys, the tissue is minced, and glomeruli are isolated by sieving. Encapsulated glomeruli are collected, and single glomeruli are cultured for 6 days to obtain glomerular outgrowth of parietal epithelial cells. During this period, parietal epithelial cell proliferation and migration can be analyzed by determining the cell number or the surface area of outgrowing cells. This assay can therefore be used as a tool to study the effects of an altered gene expression in transgenic- or knockout-mice or the effects of culture conditions on parietal epithelial cell growth characteristics and signaling. Using this method, important pathways involved in the process of parietal epithelial cell activation and consequently in glomerulosclerosis can be studied.