Bile acid synthesis impedes tumor-specific T cell responses during liver cancer

Siva Karthik Varanasi(Salk Institute for Biological Studies), Dan Chen(Salk Institute for Biological Studies), Yingluo Liu(University of California San Diego), Melissa Johnson(Salk Institute for Biological Studies), Cayla M. Miller(University of California San Diego), S Ganguly(Sanford Burnham Prebys Medical Discovery Institute), Kathryn Lande(Salk Institute for Biological Studies), Michael A. LaPorta(Salk Institute for Biological Studies), Filipe Araujo Hoffmann(Salk Institute for Biological Studies), Thomas H. Mann(Salk Institute for Biological Studies), Marcos G. Teneche(Sanford Burnham Prebys Medical Discovery Institute), Eduardo Casillas(Salk Institute for Biological Studies), Kailash Chandra Mangalhara(Salk Institute for Biological Studies), Varsha Mathew(Salk Institute for Biological Studies), Ming Sun(Salk Institute for Biological Studies), Isaac J. Jensen(Columbia University Irving Medical Center), Yagmur Farsakoglu(Salk Institute for Biological Studies), T.-S. Chen(Salk Institute for Biological Studies), Bianca Parisi(Salk Institute for Biological Studies), Shaunak Deota(Salk Institute for Biological Studies), Aaron Havas(Sanford Burnham Prebys Medical Discovery Institute), Jin Lee(University of California San Diego), H. Kay Chung(Salk Institute for Biological Studies), Andrea Schietinger(Memorial Sloan Kettering Cancer Center), Satchidananda Panda(Salk Institute for Biological Studies), April E. Williams(Salk Institute for Biological Studies), Donna L. Färber(Columbia University Irving Medical Center), Debanjan Dhar(Sanford Burnham Prebys Medical Discovery Institute), Peter D. Adams(Sanford Burnham Prebys Medical Discovery Institute), Gen‐Sheng Feng(University of California San Diego), Gerald S. Shadel(Salk Institute for Biological Studies), Mark S. Sundrud(Dartmouth College), Susan M. Kaech(Salk Institute for Biological Studies)
Science
January 9, 2025
10.1126/science.adl4100
Cited by 127Open Access
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Abstract

The metabolic landscape of cancer greatly influences antitumor immunity, yet it remains unclear how organ-specific metabolites in the tumor microenvironment influence immunosurveillance. We found that accumulation of primary conjugated and secondary bile acids (BAs) are metabolic features of human hepatocellular carcinoma and experimental liver cancer models. Inhibiting conjugated BA synthesis in hepatocytes through deletion of the BA-conjugating enzyme bile acid–CoA:amino acid N -acyltransferase (BAAT) enhanced tumor-specific T cell responses, reduced tumor growth, and sensitized tumors to anti–programmed cell death protein 1 (anti–PD-1) immunotherapy. Furthermore, different BAs regulated CD8 + T cells differently; primary BAs induced oxidative stress, whereas the secondary BA lithocholic acid inhibited T cell function through endoplasmic reticulum stress, which was countered by ursodeoxycholic acid. We demonstrate that modifying BA synthesis or dietary intake of ursodeoxycholic acid could improve tumor immunotherapy in liver cancer model systems.

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