Quercetin Inhibits β-catenin Transcriptional Activity During Kidney Development and Reduces the Severity of Renal Dysplasia

Cunanan, Joanna

January 2019

M.Sc. Thesis Dissertation, August 2019, McMaster University / Renal dysplasia, defined as the abnormal development of kidney tissue, is the leading cause of kidney disease in children. While there are numerous causes of renal dysplasia (i.e. genetic, environmental and epigenetic factors), there is no cure to this abnormal defect. Kidney development occurs by two main processes: branching morphogenesis, which forms the collecting duct system, and nephrogenesis, which generates the nephrons, the functional units of the kidney. Our previous studies have demonstrated that β-catenin, a dual-function protein involved in cell adhesion and gene transcription, regulates branching morphogenesis and nephrogenesis. Furthermore, we discovered that nuclear β-catenin levels are increased in kidneys from patients with renal dysplasia, suggesting β-catenin can be a potential therapeutic target to modulate kidney development and renal dysplasia. Quercetin is a flavonoid that reduces β-catenin levels and inhibits its transcriptional activity, leading to improved outcomes in cancer and in kidney fibrosis. The role of quercetin in kidney development and in abnormal defects that arise during kidney development is yet to be examined. Using embryonic mouse kidney organ culture, I found that quercetin treatment resulted in a dose-dependent disruption in branching morphogenesis and nephrogenesis. In addition, quantitative reverse-transcriptase PCR revealed a decreased expression of β-catenin target genes essential for kidney development (i.e. Pax2, Six2 and GDNF). Immunohistochemistry for β-catenin demonstrated that quercetin reduced nuclear β-catenin expression and increased cytoplasmic and membrane-bound expression in a dose-dependent manner. These results were confirmed by Western blot analysis. These novel findings demonstrate that quercetin treatment resulted in decreased levels of nuclear β-catenin, resulting in a decrease in its transcriptional activity which manifested in alterations in kidney developmental processes, suggesting quercetin is effective at reducing nuclear β-catenin in wild-type embryonic kidneys. Next, to determine whether quercetin has any effects on renal dysplasia, I utilized transgenic mice models that overexpress β-catenin in select cells of the embryonic kidney. These models recapitulate the defects observed in human renal dysplasia, including disorganized branching morphogenesis and disrupted nephrogenesis. Quercetin treatment of embryonic dysplastic kidneys resulted in a partial rescue of renal dysplasia which was evident in marked improvements in branching morphogenesis and nephrogenesis, as well as an increase in the number of properly-developing nephrons in the kidney tissue. Analysis of β-catenin expression in quercetin-treated dysplastic kidneys revealed a decrease in nuclear levels and an increase in cytoplasmic and membrane-bound levels, resulting in a reduced expression of target genes (Pax2, Six2, and GDNF). Finally, this partial rescue of renal dysplasia was associated with an improved and organized E-cadherin expression in quercetin-treated dysplastic kidneys, suggesting a possible molecular mechanism of quercetin action in resolving abnormal kidney development. Overall, my findings demonstrate, for the first time, that quercetin reduces β-catenin transcriptional activity in normal and dysplastic kidneys and reduces the severity of defects in renal dysplasia. / Thesis / Master of Science in Medical Sciences (MSMS)

kidney development

beta-catenin

renal dysplasia

quercetin