WIPI1 is a conserved mediator of right ventricular failure
Christos Tzimas, Christoph D. Rau, Petra E. Buergisser, Gaston Jean-Louis Jr., Katherine Lee, Jeffrey Chukwuneke, Wen Dun, Yibin Wang, Emily J. Tsai
Christos Tzimas, Christoph D. Rau, Petra E. Buergisser, Gaston Jean-Louis Jr., Katherine Lee, Jeffrey Chukwuneke, Wen Dun, Yibin Wang, Emily J. Tsai
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Research Article Cardiology

WIPI1 is a conserved mediator of right ventricular failure

Abstract

Right ventricular (RV) dysfunction is highly prevalent across cardiopulmonary diseases and independently predicts death in both heart failure (HF) and pulmonary hypertension (PH). Progression towards RV failure (RVF) can occur in spite of optimal medical treatment of HF or PH, highlighting current insufficient understanding of RVF molecular pathophysiology. To identify molecular mechanisms that may distinctly underlie RVF, we investigated the cardiac ventricular transcriptome of advanced-HF patients, with and without RVF. Using an integrated systems genomic and functional biology approach, we identified an RVF-specific gene module, for which WIPI1 served as a hub and HSPB6 and MAP4 as drivers, and confirmed the ventricular specificity of Wipi1, Hspb6, and Map4 transcriptional changes in adult murine models of pressure overload–induced RV versus left ventricular failure. We uncovered a shift towards noncanonical autophagy in the failing RV that correlated with RV-specific Wipi1 upregulation. In vitro siRNA silencing of Wipi1 in neonatal rat ventricular myocytes limited noncanonical autophagy and blunted aldosterone-induced mitochondrial superoxide levels. Our findings suggest that Wipi1 regulates mitochondrial oxidative signaling and noncanonical autophagy in cardiac myocytes. Together with our human transcriptomic analysis and corroborating studies in an RVF mouse model, these data render Wipi1 a potential target for RV-directed HF therapy.

Authors

Christos Tzimas, Christoph D. Rau, Petra E. Buergisser, Gaston Jean-Louis Jr., Katherine Lee, Jeffrey Chukwuneke, Wen Dun, Yibin Wang, Emily J. Tsai

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Figure 6

Silencing Wipi1 blunts aldosterone induction of noncanonical autophagy.

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Silencing Wipi1 blunts aldosterone induction of noncanonical autophagy. ...
Neonatal rat ventricular myocytes (NRVMs) were transfected with scramble or Wipi1-specific siRNAs and then stimulated with aldosterone (Aldo, 1 μM, 48 hours), bafilomycin A (BafA, 100 nM, 1 hour), or chloroquine (CQ, 100 μM, 1 hour). (A) Representative Western blots of autophagy proteins (n = 9–18 per group from 3–6 independent experiments). (B) Summary Western analysis of LC3 lipidation (LC3II/LC3I) and canonical autophagy (pS16-/total HSPB6). (C) Representative Western blots of LC3 and WIPI1 in si-Scramble– versus si-Wipi–transfected NRVMs treated with BafA or CQ to differentiate, respectively, canonical versus noncanonical autophagy. BafA blocks LCII lysosomal degradation during canonical autophagy, whereas CQ inhibits the fusion between the autophagosome and lysosome. Hence, CQ reveals total autophagic flux and the difference between the effects of CQ and BafA on LC3II/I ratios is attributable to noncanonical autophagy (32, 33). (D) Quantification of LC3II/I ratio shows that silencing Wipi1 selectively inhibits noncanonical autophagy (CQ) without affecting canonical autophagy (BafA) (n = 11 per group from 4 independent experiments for LC3II/I). *P < 0.0001, P < 0.01, P < 0.05 versus basal, unless otherwise indicated by comparison bar, by Tukey’s multiple-comparison test following 2-way ANOVA. Scatter dot plots with bars show individual values and mean ± SEM.