Mice with a Pax2 missense variant display impaired glomerular repair.

PAX2 regulates kidney development, and its expression persists in parietal epithelial cells (PECs), potentially serving as a podocyte reserve. We hypothesized that mice with a Pax2 pathogenic missense variant (Pax2A220G/+) have impaired PEC-mediated podocyte regeneration. Embryonic wild-type mouse kidneys showed overlapping expression of PAX2/Wilms' tumor-1 (WT-1) until PEC and podocyte differentiation, reflecting a close lineage relationship. Embryonic and adult Pax2A220G/+ mice have reduced nephron number but demonstrated no glomerular disease under baseline conditions. Pax2A220G/+ mice compared with wild-type mice were more susceptible to glomerular disease after adriamycin (ADR)-induced podocyte injury, as demonstrated by worsened glomerular scarring, increased podocyte foot process effacement, and podocyte loss. There was a decrease in PAX2-expressing PECs in wild-type mice after adriamycin injury accompanied by the occurrence of PAX2/WT-1-coexpressing glomerular tuft cells. In contrast, Pax2A220G/+ mice showed no changes in the numbers of PAX2-expressing PECs after adriamycin injury, associated with fewer PAX2/WT-1-coexpressing glomerular tuft cells compared with injured wild-type mice. A subset of PAX2-expressing glomerular tuft cells after adriamycin injury was increased in Pax2A220G/+ mice, suggesting a pathological process given the worse outcomes observed in this group. Finally, Pax2A220G/+ mice have increased numbers of glomerular tuft cells expressing Ki-67 and cleaved caspase-3 compared with wild-type mice after adriamycin injury, consistent with maladaptive responses to podocyte loss. Collectively, our results suggest that decreased glomerular numbers in Pax2A220G/+ mice are likely compounded with the inability of their mutated PECs to regenerate podocyte loss, and together these two mechanisms drive the worsened focal segmental glomerular sclerosis phenotype in these mice.NEW & NOTEWORTHY Congenital anomalies of the kidney and urinary tract comprise some of the leading causes of kidney failure in children, but our previous study showed that one of its genetic causes, PAX2, is also associated with adult-onset focal segmental glomerular sclerosis. Using a clinically relevant model, our present study demonstrated that after podocyte injury, parietal epithelial cells expressing PAX2 are deployed into the glomerular tuft to assist in repair in wild-type mice, but this mechanism is impaired in Pax2A220G/+ mice.

Minimal Kidney Disease Phenotype in Shroom3 Heterozygous Null Mice.

Background: Shroom family member 3 (SHROOM3) encodes an actin-associated protein that regulates epithelial morphology during development. Several genome-wide association studies (GWAS) have identified genetic variances primarily in the 5' region of SHROOM3, associated with chronic kidney disease (CKD) and poor transplant outcomes. These genetic variants are associated with alterations in Shroom3 expression. Objective: Characterize the phenotypic abnormalities associated with reduced Shroom3 expression in postnatal day 3-, 1-month and 3-month-old mice. Methods: The Shroom3 protein expression pattern was determined by immunofluorescence. We generated Shroom3 heterozygous null mice (Shroom3Gt/+) and performed comparative analyses with wild type littermates based on somatic and kidney growth, gross renal anatomy, renal histology, renal function at postnatal day 3, 1 month, and 3 months. Results: The Shroom3 protein expression localized to the apical regions of medullary and cortical tubular epithelium in postnatal wild type kidneys. Co-immunofluorescence studies confirmed protein expression localized to the apical side of the tubular epithelium in proximal convoluted tubules, distal convoluted tubules, and collecting ducts. While Shroom3 heterozygous null mice exhibited reduced Shroom3 protein expression, no differences in somatic and kidney growth were observed when compared to wild type mice. Although, rare cases of unilateral hypoplasia of the right kidney were observed at postnatal 1 month in Shroom3 heterozygotes. Yet renal histological analysis did not reveal any overt abnormalities in overall kidney structure or in glomerular and tubular organization in Shroom3 heterozygous null mice when compared to wild type mice. Analysis of the apical-basolateral orientation of the tubule epithelium demonstrated alterations in the proximal convoluted tubules and modest disorganization in the distal convoluted tubules at 3 months in Shroom3 heterozygotes. Additionally, these modest abnormalities were not accompanied by tubular injury or physiological defects in renal and cardiovascular function. Conclusion: Taken together, our results describe a mild kidney disease phenotype in adult Shroom3 heterozygous null mice, suggesting that Shroom3 expression and function may be required for proper structure and maintenance of the various tubular epithelial parenchyma of the kidney.

Contexte: Le gène SHROOM3 (membre 3 de la famille Shroom) code pour une protéine associée à l'actine qui régule la morphologie épithéliale pendant le développement. Plusieurs études d'association à l'échelle du génome (GWAS ­ Genome-wide association studies) ont identifié des variations génétiques, principalement dans la région 5' du gène SHROOM3, associées à l'insuffisance rénale chronique (IRC) et à de mauvais résultats de transplantation. Ces variations génétiques sont associées à des altérations dans l'expression de (Shroom3). Objectif: Caractériser les anomalies phénotypiques associées à une diminution de l'expression de Shroom3 chez des souris à l'âge postnatal de 3 jours, 1 mois et 3 mois. Méthodologie: Le profil d'expression des protéines Shroom3 a été déterminé par immunofluorescence. Nous avons généré des souris hétérozygotes Shroom3 (Shroom3Gt/+) et procédé à des analyses comparatives avec des congénères de type sauvage en ce qui concerne la croissance somatique et rénale, l'anatomie rénale, l'histologie rénale et la fonction rénale à l'âge postnatal de 3 jours, 1 mois et 3 mois. Résultats: L'expression de la protéine Shroom3 est localisée dans les régions apicales de l'épithélium tubulaire médullaire et cortical des reins des souris de type sauvage après la naissance. Des études de co-immunofluorescence ont confirmé l'expression des protéines localisée sur le côté apical de l'épithélium tubulaire dans les tubules contournés proximaux, les tubules contournés distaux et les tubes collecteurs. Les souris hétérozygotes Shroom3 ont présenté une expression réduite de la protéine Shroom3, mais aucune différence dans la croissance somatique et rénale n'a été observée par rapport aux souris de type sauvage. Cependant, de rares cas d'hypoplasie unilatérale du rein droit ont été observés à l'âge postnatal de 1 mois chez les souris hétérozygotes Shroom3. L'analyze histologique rénale n'a révélé aucune anomalie manifeste dans la structure globale des reins ou dans l'organization des glomérules et des tubules chez les souris hétérozygotes Shroom3 par rapport aux souris de type sauvage. L'analyze de l'orientation apicale-basolatérale de l'épithélium tubulaire a montré des altérations dans les tubules contournés proximaux et une légère désorganisation dans les tubules contournés distaux à l'âge de 3 mois chez les souris hétérozygotes Shroom3. En outre, ces légères anomalies n'étaient pas accompagnées d'une lésion tubulaire ou d'anomalies physiologiques dans la fonction rénale et cardiovasculaire. Conclusion: Pris dans leur ensemble, nos résultats décrivent un phénotype d'insuffisance rénale légère chez les souris hétérozygotes Shroom3 adultes, ce qui suggère que l'expression et la fonction de la protéine Shroom3 peuvent être nécessaires pour la structure et le maintien appropriés des différents parenchymes épithéliaux tubulaires du rein.

ß-Catenin in the kidney stroma modulates pathways and genes to regulate kidney development.

BACKGROUND: Kidney development is regulated by cellular interactions between the ureteric epithelium, mesenchyme, and stroma. Previous studies demonstrate essential roles for stromal ß-catenin in kidney development. However, how stromal ß-catenin regulates kidney development is not known. We hypothesize that stromal ß-catenin modulates pathways and genes that facilitate communications with neighboring cell populations to regulate kidney development. RESULTS: We isolated purified stromal cells with wild type, deficient, and overexpressed ß-catenin by fluorescence-activated cell sorting and conducted RNA Sequencing. A Gene Ontology network analysis demonstrated that stromal ß-catenin modulates key kidney developmental processes, including branching morphogenesis, nephrogenesis and vascular formation. Specific stromal ß-catenin candidate target genes that may mediate these effects included secreted, cell-surface and transcriptional factors that regulate branching morphogenesis and nephrogenesis (Wnts, Bmp, Fgfr, Tcf/Lef) and secreted vascular guidance cues (Angpt1, VEGF, Sema3a). We validated established ß-catenin targets including Lef1 and novel candidate ß-catenin targets including Sema3e which have unknown roles in kidney development. CONCLUSIONS: These studies advance our understanding of gene and biological pathway dysregulation in the context of stromal ß-catenin misexpression during kidney development. Our findings suggest that during normal kidney development, stromal ß-catenin may regulate secreted and cell-surface proteins to communicate with adjacent cell populations.

Advancing Discovery Research in Nephrology in Canada: A Conference Report From the 2021 Molecules and Mechanisms Mediating Kidney Health and Disease (M3K) Scientific Meeting and Investigator Summit.

Purpose of conference: New discoveries arising from investigations into fundamental aspects of kidney development and function in health and disease are critical to advancing kidney care. Scientific meetings focused specifically on fundamental biology of the kidney can facilitate interactions, support the development of collaborative groups, and accelerate translation of key findings. The Canadian fundamental kidney researcher community has lacked such a forum. On December 3 to 4, 2021, the first Molecules and Mechanisms Mediating Kidney Health and Disease (M3K) Scientific Meeting and Investigator Summit was held to address this gap with the goal of advancing fundamental kidney research nationally. The meeting was held virtually and was supported by a planning and dissemination grant from the Canadian Institutes of Health Research. Attendees included PhD scientists, nephrology clinician scientists, engineers, industry representatives, graduate students, medical residents, and fellows. Sources of information: This report was prepared from the scientific program, registration numbers, and details obtained from the online platform WHOVA, and summaries written by organizers and participants of the 2021 meeting. Methods: A 21-person team, consisting of the organizing committee members and participants from the meeting, was assembled. Key highlights of the meeting and future directions were identified and the team jointly assembled this report. Key findings: Participation in the meeting was strong, with more than 140 attendees across a range of disciplines. The program featured state-of-the-art presentations on diabetic nephropathy, the immune system, kidney development, and fibrosis, and was heavily focused on trainee presentations. The moderated "Investigator Summit" identified key barriers to research advancement and discussed strategies for overcoming them. These included establishment of a pan-Canadian fundamental kidney research network, development of key resources, cross-pollination with clinical nephrology, better reintegration into the Canadian Society of Nephrology, and further establishment of identity and knowledge translation. Limitations and implications: The 2021 M3K meeting represented a key first step in uniting fundamental kidney researchers in Canada. However, it was universally agreed that regular meetings were necessary to sustain this momentum. The proceedings of this meeting and future actions to sustain the M3K Scientific Meeting and Investigator Summit are presented in this article.

Objectif de la conférence: De nouvelles découvertes découlant des enquêtes sur les aspects fondamentaux du développement et de la fonction des reins en santé ou malades sont essentielles pour faire progresser les soins rénaux. Les réunions scientifiques axées spécifiquement sur la biologie fondamentale du rein peuvent faciliter les interactions, appuyer le développement de groupes de collaboration et accélérer l'application des principaux résultats. La communauté canadienne des chercheurs fondamentaux en néphrologie a manqué d'un tel forum. Les 3 et 4 décembre 2021, le premier Sommet des chercheurs et la réunion scientifique M3K (Molecules and Mechanisms Mediating Kidney Health and Disease) sur les molécules et les médiateurs de la santé et des maladies rénales ont eu lieu pour combler cette lacune; l'objectif était de faire progresser la recherche fondamentale en néphrologie à l'échelle nationale. La réunion s'est tenue virtuellement et était financée par une subvention de planification et de diffusion des Instituts de recherche en santé du Canada. Des doctorants, cliniciens-chercheurs en néphrologie, ingénieurs, représentants de l'industrie, étudiants diplômés, résidents en médecine et en surspécialisation figuraient parmi les participants. Sources: Ce rapport a été préparé à partir du program scientifique, des informations et des numéros d'inscription tirés de la plateforme en ligne WHOVA, et des résumés rédigés par les organisateurs et les participants à la réunion de 2021. Méthodologie: Une équipe de 20 personnes composée de membres du comité organisateur et de participants à la réunion a été formée. Les principaux points saillants de la réunion et les orientations futures ont été déterminés, puis l'équipe a rédigé conjointement le présent rapport. Principaux résultats: La réunion s'est avérée un succès; plus de 140 personnes provenant d'un large éventail de disciplines y ont participé. Le program comprenait des présentations de pointe sur la néphropathie diabétique, le système immunitaire, le développement des reins et la fibrose, et était fortement axé sur des présentations par des stagiaires. Le « Sommet des chercheurs ¼, animé par un modérateur, a permis de déterminer les principaux obstacles à l'avancement de la recherche et de discuter des stratégies pour les surmonter. Ces dernières incluent notamment la création d'un réseau pancanadien de recherche fondamentale en néphrologie, le développement de ressources clés, la pollinisation croisée avec la néphrologie clinique, une « meilleure réintégration dans la Société canadienne de néphrologie ¼ et la poursuite de l'établissement de l'identité et de l'application des connaissances. Limites et implications: La réunion M3K de 2021 a constitué une première étape clé dans l'unification des chercheurs fondamentaux en néphrologie au Canada. On a cependant universellement convenu que des réunions régulières étaient nécessaires pour maintenir cet élan. Le compte rendu de cette réunion ainsi que les actions futures pour soutenir la réunion scientifique M3K et le Sommet des chercheurs sont présentés dans le présent article.

Shroom3, a Gene Associated with CKD, Modulates Epithelial Recovery after AKI.

Background: Ischemia-induced AKI resulting in tubular damage can often progress to CKD and is a common cause of nephrology consultation. After renal tubular epithelial damage, molecular and cellular mechanisms are activated to repair and regenerate the damaged epithelium. If these mechanisms are impaired, AKI can progress to CKD. Even in patients whose kidney function returns to normal baseline are more likely to develop CKD. Genome-wide association studies have provided robust evidence that genetic variants in Shroom3, which encodes an actin-associated protein, are associated with CKD and poor outcomes in transplanted kidneys. Here, we sought to further understand the associations of Shroom3 in CKD. Methods: Kidney ischemia was induced in wild-type (WT) and Shroom3 heterozygous null mice (Shroom3Gt/+ ) and the mechanisms of cellular recovery and repair were examined. Results: A 28-minute bilateral ischemia in Shroom3Gt/+ mice resulted in 100% mortality within 24 hours. After 22-minute ischemic injury, Shroom3Gt/+ mice had a 16% increased mortality, worsened kidney function, and significantly worse histopathology, apoptosis, proliferation, inflammation, and fibrosis after injury. The cortical tubular damage in Shroom3Gt/+ was associated with disrupted epithelial redifferentiation, disrupted Rho-kinase/myosin signaling, and disorganized apical F-actin. Analysis of MDCK cells showed the levels of Shroom3 are directly correlated to apical organization of actin and actomyosin regulators. Conclusion: These findings establish that Shroom3 is required for epithelial repair and redifferentiation through the organization of actomyosin regulators, and could explain why genetic variants in Shroom3 are associated with CKD and allograft rejection.

Clinically and biologically relevant subgroups of Wilms tumour defined by genomic and epigenomic analyses.

BACKGROUND: Although cure rates for Wilms tumours (WT) are high, many patients receive therapy with attendant long-term complications. Our goal was to stratify WT using genome-wide analyses to identify candidate molecular features for patients who would benefit from a reduction in therapy. METHODS: We generated DNA methylation and exome sequencing data on WT-kidney pairs (n = 57) and unpaired tumours (n = 27) collected either at our centre or by the Children's Oncology Group. Samples were divided into a discovery set (n = 32) and validation set (n = 52). RESULTS: Analysis of DNA methylation revealed two subgroups of WT with distinct features. Subgroup A has a similar DNA methylation profile to mature kidney, while Subgroup B has genome-wide dysregulation of DNA methylation. The rate of non-synonymous missense mutations and segmental chromosomal aberrations was higher in Subgroup B tumours, suggesting that this group has genome instability related to its epigenetic state. Subgroup A had a higher proportion of cases of bilateral disease. Tumours with high-risk histology or from patients who relapsed were only found in Subgroup B. CONCLUSION: We have identified subgroup-specific molecular events that could inform future work supporting more targeted therapeutic approaches and patient stratification. We propose a novel developmental tumour model based on these findings.

Quercetin treatment reduces the severity of renal dysplasia in a beta-catenin dependent manner.

Renal dysplasia, the major cause of childhood renal failure, is characterized by defective branching morphogenesis and nephrogenesis. Beta-catenin, a transcription factor and cell adhesion molecule, is markedly increased in the nucleus of kidney cells in human renal dysplasia and contributes to its pathogenesis by altering target genes that are essential for kidney development. Quercetin, a naturally occurring flavonoid, reduces nuclear beta-catenin levels and reduces beta-catenin transcriptional activity. In this study, we utilized wild type and dysplastic mouse kidney organ explants to determine if quercetin reduces beta-catenin activity during kidney development and whether it improves the severity of renal dysplasia. In wild type kidney explants, quercetin treatment resulted in abnormal branching morphogenesis and nephrogenesis in a dose dependent manner. In wild type embryonic kidneys, quercetin reduced nuclear beta-catenin expression and decreased expression of beta-catenin target genes Pax2, Six2, and Gdnf, which are essential for kidney development. Our RDB mouse model of renal dysplasia recapitulates the overexpression of beta-catenin and histopathological changes observed in human renal dysplasia. RDB kidneys treated with quercetin resulted in improvements in the overall histopathology, tissue organization, ureteric branching morphogenesis, and nephrogenesis. Quercetin treatment also resulted in reduced nuclear beta-catenin and reduced Pax2 expression. These improvements were associated with the proper organization of vimentin, NCAM, and E-cadherin, and a 45% increase in the number of developing and maturing nephrons. Further, our results show that in human renal dysplasia, beta-catenin, vimentin, and e-cadherin also have abnormal expression patterns. Taken together, these data demonstrate that quercetin treatment reduces nuclear beta-catenin and this is associated with improved epithelial organization of developing nephrons, resulting in increased developing nephrons and a partial rescue of renal dysplasia.