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.

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.

Developmental Origins for Kidney Disease Due to Shroom3 Deficiency.

CKD is a significant health concern with an underlying genetic component. Multiple genome-wide association studies (GWASs) strongly associated CKD with the shroom family member 3 (SHROOM3) gene, which encodes an actin-associated protein important in epithelial morphogenesis. However, the role of SHROOM3 in kidney development and function is virtually unknown. Studies in zebrafish and rat showed that alterations in Shroom3 can result in glomerular dysfunction. Furthermore, human SHROOM3 variants can induce impaired kidney function in animal models. Here, we examined the temporal and spatial expression of Shroom3 in the mammalian kidney. We detected Shroom3 expression in the condensing mesenchyme, Bowman's capsule, and developing and mature podocytes in mice. Shroom3 null (Shroom3Gt/Gt) mice showed marked glomerular abnormalities, including cystic and collapsing/degenerating glomeruli, and marked disruptions in podocyte arrangement and morphology. These podocyte-specific abnormalities are associated with altered Rho-kinase/myosin II signaling and loss of apically distributed actin. Additionally, Shroom3 heterozygous (Shroom3Gt/+) mice showed developmental irregularities that manifested as adult-onset glomerulosclerosis and proteinuria. Taken together, our results establish the significance of Shroom3 in mammalian kidney development and progression of kidney disease. Specifically, Shroom3 maintains normal podocyte architecture in mice via modulation of the actomyosin network, which is essential for podocyte function. Furthermore, our findings strongly support the GWASs that suggest a role for SHROOM3 in human kidney disease.

Stromally expressed ß-catenin modulates Wnt9b signaling in the ureteric epithelium.

The mammalian kidney undergoes cell interactions between the epithelium and mesenchyme to form the essential filtration unit of the kidney, termed the nephron. A third cell type, the kidney stroma, is a population of fibroblasts located in the kidney capsule, cortex and medulla and is ideally located to affect kidney formation. We found ß-catenin, a transcriptional co-activator, is strongly expressed in distinctive intracellular patterns in the capsular, cortical, and medullary renal stroma. We investigated ß-catenin function in the renal stroma using a conditional knockout strategy that genetically deleted ß-catenin specifically in the renal stroma cell lineage (ß-cats-/-). ß-cats-/- mutant mice demonstrate marked kidney abnormalities, and surprisingly we show ß-catenin in the renal stroma is essential for regulating the condensing mesenchyme cell population. We show that the population of induced mesenchyme cells is significantly reduced in ß-cats-/- mutants and exhibited decreased cell proliferation and a specific loss of Cited 1, while maintaining the expression of other essential nephron progenitor proteins. Wnt9b, the key signal for the induction of nephron progenitors, was markedly reduced in adjacent ureteric epithelial cells in ß-cats-/-. Analysis of Wnt9b-dependent genes in the neighboring nephron progenitors was significantly reduced while Wnt9b-independent genes remained unchanged. In contrast mice overexpressing ß-catenin exclusively in the renal stroma demonstrated massive increases in the condensing mesenchyme population and Wnt9b was markedly elevated. We propose that ß-catenin in the renal stroma modulates a genetic program in ureteric epithelium that is required for the induction of nephron progenitors.