Regulation of the double-stranded RNA response through ADAR1 licenses metaplastic reprogramming in gastric epithelium
José B. Sáenz, Nancy Vargas, Charles J. Cho, Jason C. Mills
José B. Sáenz, Nancy Vargas, Charles J. Cho, Jason C. Mills
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Research Article Cell biology Gastroenterology

Regulation of the double-stranded RNA response through ADAR1 licenses metaplastic reprogramming in gastric epithelium

Abstract

Cells recognize both foreign and host-derived double-stranded RNA (dsRNA) via a signaling pathway that is usually studied in the context of viral infection. It has become increasingly clear that the sensing and handling of endogenous dsRNA is also critical for cellular differentiation and development. The adenosine RNA deaminase, ADAR1, has been implicated as a central regulator of the dsRNA response, but how regulation of the dsRNA response might mediate cell fate during injury and whether such signaling is cell intrinsic remain unclear. Here, we show that the ADAR1-mediated response to dsRNA was dramatically induced in 2 distinct injury models of gastric metaplasia. Mouse organoid and in vivo genetic models showed that ADAR1 coordinated a cell-intrinsic, epithelium-autonomous, and interferon signaling–independent dsRNA response. In addition, dsRNA accumulated within a differentiated epithelial population (chief cells) in mouse and human stomachs as these cells reprogrammed to a proliferative, reparative (metaplastic) state. Finally, chief cells required ADAR1 to reenter the cell cycle during metaplasia. Thus, cell-intrinsic ADAR1 signaling is critical for the induction of metaplasia. Because metaplasia increases cancer risk, these findings support roles for ADAR1 and the response to dsRNA in oncogenesis.

Authors

José B. Sáenz, Nancy Vargas, Charles J. Cho, Jason C. Mills

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Figure 5

Deletion of Adar1 from gastric chief cells results in the accumulation of dsRNA and activation of the dsRNA response at homeostasis.

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Deletion of Adar1 from gastric chief cells results in the accumulation o...
(A) A representative thick section of gastric tissue from an Adar1fl/fl Mist1Cre-ERT/+ ROSA26LSLTdTomato mouse, 4 days after Cre induction, shows Cre recombination (red; endogenous TdTomato signal) occurring specifically within chief cells (green; gastric intrinsic factor, GIF) of the gastric corpus. (B) An isolated corpus gland base is shown, illustrating Cre recombination (red) in chief cells (green). Scale bars, 100 μm (A) and 5 μm (B). (C) Conditional deletion of Adar1 from chief cells (bottom) results in the accumulation of dsRNA (red) within gastric epithelium (green). No appreciable dsRNA was detected in Adar1fl/+ Mist1Cre-ERT/+ gastric epithelium following Cre induction (top). Scale bars, 50 μm. (D) Fold expression changes, as determined by qRT-PCR, for various transcripts in Adar1fl/fl Mist1Cre-ERT/+ gastric corpus (pink), relative to Adar1fl/+ Mist1Cre-ERT/+ gastric corpus (blue), are shown. Gastric corpus tissue was collected 4 days after the completion of Cre induction. Each data point represents an individual mouse. The dotted line represents the average fold change in Adar1fl/+ Mist1Cre-ERT/+ mice. P values were determined by 2-tailed Student’s t test: **, P < 0.01; ***, P < 0.001; ****, P < 0.0001. (E) Representative Western blot demonstrates the activation of various components of the dsRNA response following Cre-mediated deletion of Adar1. Each lane represents gastric corpus tissue from an individual Adar1fl/fl Mist1Cre-ERT/+ cage mate/littermate mouse at the indicated time point following the completion of Cre induction. “V” refers to vehicle-treated mice, 4 days after the completion of Cre induction, suggesting that any potential leaky Cre expression does not result in activation of the dsRNA response.