The senescence-associated secretome of Hedgehog-deficient hepatocytes drives MASLD progression
Ji Hye Jun, … , Steven S. Pullen, Anna Mae Diehl
Ji Hye Jun, … , Steven S. Pullen, Anna Mae Diehl
Published August 27, 2024
Citation Information: J Clin Invest. 2024;134(19):e180310. https://doi.org/10.1172/JCI180310.
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Research Article Hepatology Metabolism

The senescence-associated secretome of Hedgehog-deficient hepatocytes drives MASLD progression

Abstract

The burden of senescent hepatocytes correlates with the severity of metabolic dysfunction–associated steatotic liver disease (MASLD), but the mechanisms driving senescence and how it exacerbates MASLD are poorly understood. Hepatocytes experience lipotoxicity and become senescent when Smoothened (Smo) is deleted to disrupt Hedgehog signaling. We aimed to determine whether the secretomes of Smo-deficient hepatocytes perpetuate senescence to drive MASLD progression. RNA-Seq analysis of liver samples from human and murine cohorts with MASLD confirmed that hepatocyte populations in MASLD livers were depleted of Smo+ cells and enriched with senescent cells. When fed a choline-deficient, amino acid–restricted high-fat diet (CDA-HFD) to induce MASLD, Smo– mice had lower antioxidant markers and developed worse DNA damage, senescence, steatohepatitis, and fibrosis than did Smo+ mice. Sera and hepatocyte-conditioned medium from Smo– mice were depleted of thymidine phosphorylase (TP), a protein that maintains mitochondrial fitness. Treating Smo– hepatocytes with TP reduced senescence and lipotoxicity, whereas inhibiting TP in Smo+ hepatocytes had the opposite effect and exacerbated hepatocyte senescence, steatohepatitis, and fibrosis in CDA-HFD–fed mice. We conclude that inhibition of Hedgehog signaling in hepatocytes promoted MASLD by suppressing hepatocyte production of proteins that prevent lipotoxicity and senescence.

Authors

Ji Hye Jun, Kuo Du, Rajesh Kumar Dutta, Raquel Maeso-Diaz, Seh Hoon Oh, Liuyang Wang, Guannan Gao, Ana Ferreira, Jon Hill, Steven S. Pullen, Anna Mae Diehl

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Figure 3

Hepatocyte Smo-KO induces mitochondrial dysfunction.

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Hepatocyte Smo-KO induces mitochondrial dysfunction. (A) Representative ...
(A) Representative images of staining for Nrf2 and quantification of the positively stained areas in liver tissues from Smo-KO versus control mice (n = 5 mice per group). Scale bars: 250 μm. Original magnification, ×100 (enlarged insets). (B) HO1 protein expression in total liver from Smo-KO versus control mice, as determined by immunoblotting (n = 7 mice per group). (C) Interaction between TP, Smo, Nrf2, and HO1 in mouse primary hepatocytes by immunoprecipitation. WB, Western blot. (D) Protein expression of TP, HO1, OXPHOS complexes, SDHA, PDH, PHB1, HSP 60, VDAC, SOD, and cytochrome C by immunoblotting of isolated mitochondria in total liver from Smo-KO mice (n = 7 mice per group). (E) Representative images of staining for PGC1a and quantification of the positively stained areas in liver tissues from Smo-KO versus control mice (n = 9 control mice; n = 10 Smo-KO mice). Scale bars: 60 μm. (F) Immunoblots showing AIF and Smac protein expression in mitochondria or cytoplasm in total liver from Smo-KO and control mice (n = 7 mice per group). *P < 0.05, by 1-way ANOVA. Data are graphed as the mean ± SEM. (G) Hypothetical design.