GATA4 induces liver fibrosis regression by deactivating hepatic stellate cells
Noelia Arroyo, … , David A. Cano, Anabel Rojas
Noelia Arroyo, … , David A. Cano, Anabel Rojas
Published October 26, 2021
Citation Information: JCI Insight. 2021;6(23):e150059. https://doi.org/10.1172/jci.insight.150059.
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Research Article Cell biology Gastroenterology

GATA4 induces liver fibrosis regression by deactivating hepatic stellate cells

Abstract

In response to liver injury, hepatic stellate cells activate and acquire proliferative and contractile features. The regression of liver fibrosis appears to involve the clearance of activated hepatic stellate cells, either by apoptosis or by reversion toward a quiescent-like state, a process called deactivation. Thus, deactivation of active hepatic stellate cells has emerged as a novel and promising therapeutic approach for liver fibrosis. However, our knowledge of the master regulators involved in the deactivation and/or activation of fibrotic hepatic stellate cells is still limited. The transcription factor GATA4 has been previously shown to play an important role in embryonic hepatic stellate cell quiescence. In this work, we show that lack of GATA4 in adult mice caused hepatic stellate cell activation and, consequently, liver fibrosis. During regression of liver fibrosis, Gata4 was reexpressed in deactivated hepatic stellate cells. Overexpression of Gata4 in hepatic stellate cells promoted liver fibrosis regression in CCl4-treated mice. GATA4 induced changes in the expression of fibrogenic and antifibrogenic genes, promoting hepatic stellate cell deactivation. Finally, we show that GATA4 directly repressed EPAS1 transcription in hepatic stellate cells and that stabilization of the HIF2α protein in hepatic stellate cells leads to liver fibrosis.

Authors

Noelia Arroyo, Laura Villamayor, Irene Díaz, Rita Carmona, Mireia Ramos-Rodríguez, Ramón Muñoz-Chápuli, Lorenzo Pasquali, Miguel G. Toscano, Franz Martín, David A. Cano, Anabel Rojas

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Figure 6

Stabilization of HIF2α protein in HSCs causes liver fibrosis.

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Stabilization of HIF2α protein in HSCs causes liver fibrosis. Immunofluo...
Immunofluorescence analysis in liver sections of E13.5 (B) G2-Cre;HIF2dPA embryos demonstrating efficient accumulation of HIF2α compared with (A) control embryonic livers. Reduced size of E13.5 (D) G2-Cre;HIF2dPA embryonic livers compared with (C) control livers. (E and F) H&E-stained sections of E13.5 G2-Cre;HIF2dPA and control embryonic livers. (G and H) Polarized light microscopy images of Sirius red–stained liver sections from E13.5 G2-Cre;HIF2dPA and control embryos. Immunofluorescence analysis of (I and J) laminin, (K and L) collagen IV, and (M and N) α-SMA accumulation in liver sections of E13.5 (J, L, and N) G2-Cre;HIF2dPA and (I, K, and M) control embryos. Quantification of proliferating liver cells, (O) marked by phosphohistone H3 immunoreactivity (n = 4 each group), and (P) apoptotic liver cells marked by cleaved caspase-3 accumulation (E13.5 n = 3–4; E15.5 n = 5–6). (Q) Quantification of Sirius red–stained area of liver of E13.5 G2-Cre;HIF2dPA and control embryos (n = 3 each group). (R) Quantitative RT-PCR analysis of α-Sma, Lama1, Cola1a, and VEGF expression (n = 5–8). Scale bars: 100 μm (A and B); 500 μm (C and D); 25 μm (EN). Statistical analyses was performed using 2-tailed Student’s test. Error bars represent mean ± SEM. *P < 0.05.