<p>Hepatocellular carcinoma (HCC) is the fastest growing cause of cancer-related mortality and there are limited therapies<sup><CitationRef CitationID="CR1">1</CitationRef></sup>. Although endoplasmic reticulum (ER) stress and the unfolded protein response (UPR) are implicated in HCC, the involvement of the UPR&#xa0;transducer ATF6α remains unclear<sup><CitationRef CitationID="CR2">2</CitationRef></sup>. Here&#xa0;we demonstrate the&#xa0;function of&#xa0;ATF6α as an ER-stress-inducing tumour driver and metabolic master regulator restricting cancer immunosurveillance for HCC, in contrast to its well-characterized role as an adaptive response to ER stress<sup><CitationRef CitationID="CR3">3</CitationRef></sup>. ATF6α activation in human HCC is significantly correlated with an aggressive tumour phenotype, characterized by reduced patient survival, enhanced tumour progression and local immunosuppression. Hepatocyte-specific ATF6α activation in mice induced progressive hepatitis with ER stress, immunosuppression and hepatocyte proliferation. Concomitantly, activated ATF6α increased glycolysis and directly repressed the gluconeogenic enzyme FBP1 by binding to gene regulatory elements. Restoring FBP1 expression limited ATF6α-activation-related pathologies. Prolonged ATF6α activation in hepatocytes triggered hepatocarcinogenesis, intratumoural T cell infiltration and nutrient-deprived immune exhaustion. Immune checkpoint blockade (ICB)<sup><CitationRef CitationID="CR4">4</CitationRef></sup> restored immunosurveillance and reduced HCC. Consistently, patients with HCC who achieved a complete response to immunotherapy displayed significantly increased ATF6α activation compared with those with a weaker response. Targeting <i>Atf6</i> through germline ablation, hepatocyte-specific ablation or therapeutic hepatocyte delivery of antisense oligonucleotides dampened HCC in preclinical liver cancer models. Thus, prolonged ATF6α activation drives ER stress, leading to glycolysis-dependent immunosuppression in liver cancer and sensitizing to ICB. Our findings suggest that persistently activated ATF6α is a tumour driver, a potential stratification marker for ICB response and a therapeutic target for HCC.</p>

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Activated ATF6α is a hepatic tumour driver restricting immunosurveillance

  • Xin Li,
  • Cynthia Lebeaupin,
  • Aikaterini Kadianaki,
  • Clementine Druelle-Cedano,
  • Niklas Vesper,
  • Charlotte Rennert,
  • Júlia Huguet-Pradell,
  • Borja Gomez Ramos,
  • Chaofan Fan,
  • Robert Stefan Piecyk,
  • Laimdota Zizmare,
  • Pierluigi Ramadori,
  • Luqing Li,
  • Lukas Frick,
  • Menjie Qiu,
  • Cangang Zhang,
  • Luiza Martins Nascentes Melo,
  • Vikas Prakash Ranvir,
  • Peng Shen,
  • Johannes Hanselmann,
  • Jan Kosla,
  • Mirian Fernández-Vaquero,
  • Mihael Vucur,
  • Praveen Baskaran,
  • Xuanwen Bao,
  • Olivia I. Coleman,
  • Yingyue Tang,
  • Miray Cetin,
  • Zhouji Chen,
  • Insook Jang,
  • Stefania Del Prete,
  • Mohammad Rahbari,
  • Peng Zhang,
  • Timothy V. Pham,
  • Yushan Hou,
  • Aihua Sun,
  • Li Gu,
  • Laura C. Kim,
  • Ulrike Rothermel,
  • Danijela Heide,
  • Adnan Ali,
  • Suchira Gallage,
  • Nana Talvard-Balland,
  • Marta Piqué-Gili,
  • Albert Gris-Oliver,
  • Alessio Bevilacqua,
  • Lisa Schlicker,
  • Alec Duffey,
  • Kristian Unger,
  • Marta Szydlowska,
  • Jenny Hetzer,
  • Duncan T. Odom,
  • Tim Machauer,
  • Daniele Bucci,
  • Pooja Sant,
  • Jun-Hoe Lee,
  • Jonas Rösler,
  • Sven W. Meckelmann,
  • Johannes Schreck,
  • Sue Murray,
  • M. Celeste Simon,
  • Sven Nahnsen,
  • Almut Schulze,
  • Ping-Chih Ho,
  • Manfred Jugold,
  • Kai Breuhahn,
  • Jan-Philipp Mallm,
  • Peter Schirmacher,
  • Susanne Roth,
  • Nuh Rahbari,
  • Darjus F. Tschaharganeh,
  • Stephanie Roessler,
  • Benjamin Goeppert,
  • Bertram Bengsch,
  • Geoffroy Andrieux,
  • Melanie Boerries,
  • Nisar P. Malek,
  • Marco Prinz,
  • Achim Weber,
  • Robert Zeiser,
  • Pablo Tamayo,
  • Peter Bronsert,
  • Konrad Kurowski,
  • Robert Thimme,
  • Detian Yuan,
  • Rafael Carretero,
  • Tom Luedde,
  • Roser Pinyol,
  • Felix J. Hartmann,
  • Michael Karin,
  • Alpaslan Tasdogan,
  • Christoph Trautwein,
  • Moritz Mall,
  • Maike Hofmann,
  • Josep M. Llovet,
  • Dirk Haller,
  • Randal J. Kaufman,
  • Mathias Heikenwälder

摘要

Hepatocellular carcinoma (HCC) is the fastest growing cause of cancer-related mortality and there are limited therapies1. Although endoplasmic reticulum (ER) stress and the unfolded protein response (UPR) are implicated in HCC, the involvement of the UPR transducer ATF6α remains unclear2. Here we demonstrate the function of ATF6α as an ER-stress-inducing tumour driver and metabolic master regulator restricting cancer immunosurveillance for HCC, in contrast to its well-characterized role as an adaptive response to ER stress3. ATF6α activation in human HCC is significantly correlated with an aggressive tumour phenotype, characterized by reduced patient survival, enhanced tumour progression and local immunosuppression. Hepatocyte-specific ATF6α activation in mice induced progressive hepatitis with ER stress, immunosuppression and hepatocyte proliferation. Concomitantly, activated ATF6α increased glycolysis and directly repressed the gluconeogenic enzyme FBP1 by binding to gene regulatory elements. Restoring FBP1 expression limited ATF6α-activation-related pathologies. Prolonged ATF6α activation in hepatocytes triggered hepatocarcinogenesis, intratumoural T cell infiltration and nutrient-deprived immune exhaustion. Immune checkpoint blockade (ICB)4 restored immunosurveillance and reduced HCC. Consistently, patients with HCC who achieved a complete response to immunotherapy displayed significantly increased ATF6α activation compared with those with a weaker response. Targeting Atf6 through germline ablation, hepatocyte-specific ablation or therapeutic hepatocyte delivery of antisense oligonucleotides dampened HCC in preclinical liver cancer models. Thus, prolonged ATF6α activation drives ER stress, leading to glycolysis-dependent immunosuppression in liver cancer and sensitizing to ICB. Our findings suggest that persistently activated ATF6α is a tumour driver, a potential stratification marker for ICB response and a therapeutic target for HCC.