Notch controls urothelial integrity in the mouse bladder
Varvara Paraskevopoulou, … , Ioannis S. Pateras, Apostolos Klinakis
Varvara Paraskevopoulou, … , Ioannis S. Pateras, Apostolos Klinakis
Published February 13, 2020
Citation Information: JCI Insight. 2020;5(3):e133232. https://doi.org/10.1172/jci.insight.133232.
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Research Article Cell biology

Notch controls urothelial integrity in the mouse bladder

Abstract

The Notch signaling pathway mediates cell-cell communication regulating cell differentiation and proliferation and cell fate decisions in various tissues. In the urinary bladder, Notch acts as a tumor suppressor in mice, while mutations in Notch pathway components have been identified in human bladder cancer as well. Here we report that the genetic inactivation of Notch in mice leads to downregulation of cell-cell and cell-ECM interaction components, including proteins previously implicated in interstitial cystitis/bladder pain syndrome (IC/BPS), structural defects and mucosal sloughing, inflammation, and leaky urine-blood barrier. Molecular profiling of ailing mouse bladders showed similarities with IC/BPS patient tissue, which also presented low Notch pathway activity as indicated by reduced expression of canonical Notch targets. Urothelial integrity was reconstituted upon exogenous reactivation of the Notch pathway, implying a direct involvement of Notch. Despite damage and inflammation, urothelial cells failed to proliferate, uncovering a possible role for α4 integrin in urothelial homeostasis. Our data uncover a broad role for Notch in bladder homeostasis involving urothelial cell crosstalk with the microenvironment.

Authors

Varvara Paraskevopoulou, Vangelis Bonis, Vasilis S. Dionellis, Nikolaos Paschalidis, Pelagia Melissa, Evangelia Chavdoula, Eleni Vasilaki, Ioannis S. Pateras, Apostolos Klinakis

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Figure 3

Molecular analysis of Notch-deficient mouse bladders.

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Molecular analysis of Notch-deficient mouse bladders. (A) GO network ana...
(A) GO network analysis of differentially expressed genes between WT (n = 2) and Krt5CreERT2 Ncstnfl/fl (n = 3) mice. Data were obtained from RNA-Seq. Only the top 20 (20/62) networks are shown. (B) Venn diagram showing common and independent networks affected in mouse bladders from Krt5CreERT2 Ncstnfl/fl mice (RNA-Seq data) and human bladder biopsies from patients with IC corresponding to nonulcerative (ni) and ulcerative (ulcus) regions (Affymetrix expression data, GSE11783). A complete list of all processes as well as the common processes among mouse and human data can be found in Supplemental Table 1. (C) Heatmap depicting expression of canonical Notch pathway targets in the same data sets. (D) Heatmap indicating differential expression levels between WT and Krt5CreERT2 Ncstnfl/fl mouse bladders of genes implicated in cell adhesion and cell-ECM interaction. Data were obtained from RNA-Seq. (E and F) Quantitative PCR analysis of indicated genes from urothelial cell RNA of Notch-deficient bladders. Expression is presented as ratio over WT mice. In all cases n = 4 mice were analyzed. For Krt8CreERT2 RBPJfl/fl n = 6 mice were analyzed. *P < 0.05, **P < 0.01, ***P < 0.001, and ****P < 0.0001. (G) Scatter dot plot indicating urea concentration (ng/dL) in serum from WT (n = 13) and Krt8CreERT2 Ncstnfl/fl (n = 6) mice. *P < 0.05. For E, F, and G, data presented are mean ± SEM and Student’s t test was used.