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Home Science News Cancer

Gut Microbes Produce Cancer-Fighting Bile Acids That Inhibit Hormone Signals

April 15, 2025
in Cancer
Reading Time: 3 mins read
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The image depicts gut microbes producing secondary bile acids to support the host’s immune defense against cancer. Microbiota-derived bile acids (shown in light green) blocked the androgen receptor (depicted as a door) from binding with androgen (in lig
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A groundbreaking study led by researchers at Weill Cornell Medicine has unveiled a remarkable new dimension in the complex interplay between the gut microbiota and the host immune system, revealing how microbial metabolites derived from bile acids can modulate androgen receptor signaling to potentiate anti-tumor immunity. This discovery, published in the prestigious journal Cell on April 15, 2025, opens promising avenues for novel cancer therapies by harnessing the biochemical transformations orchestrated by intestinal bacteria.

The human gut harbors trillions of microorganisms whose diverse metabolic activities profoundly impact host physiology. One of their critical roles, as this study elucidates, involves chemically modifying primary bile acids synthesized by the liver. Traditionally recognized for their role in lipid digestion and cholesterol metabolism, bile acids have emerged as potent signaling molecules. This research highlights how gut bacteria convert these primary molecules into a broad spectrum of secondary bile acids, many previously unidentified, expanding our understanding of microbiome-driven chemical diversity.

Dr. Chun-Jun Guo, co-senior author and immunologist at Weill Cornell, expresses enthusiasm over these findings, emphasizing the novelty of bile acids’ ability to interfere with the androgen receptor (AR), a nuclear receptor pivotal in regulating gene transcription in response to androgen hormones like testosterone. The study’s revelation that certain microbiota-derived bile acid derivatives act as antagonists to AR demonstrates an unprecedented cross-talk between microbial metabolism and host endocrine pathways.

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The researchers employed sophisticated biochemical frameworks to map out more than fifty novel microbiota-modified bile acid structures, using advanced metabolomic profiling to characterize their unique steroid backbones and functional groups. This endeavor underscores the gut microbiota’s extraordinary synthetic capacity, as structural variants of bile acids mimic endogenous sex steroids closely enough to influence hormone receptor dynamics.

Intriguingly, the androgen receptor is expressed not only in reproductive tissues but also across specific immune cell populations, including cytotoxic CD8+ T lymphocytes, which play a central role in tumor surveillance and eradication. Prior studies hinted that AR suppression could invigorate these immune cells’ anti-tumor potency, yet a biochemically defined mechanism had eluded scientists until now.

Capitalizing on this insight, the investigators screened the identified bile acids for their AR-modulating effects, discovering four metabolites capable of antagonizing AR with high specificity. This interaction effectively blocks androgen binding, disrupting downstream signaling cascades that normally attenuate T cell-mediated immune responses within the tumor microenvironment.

The in vivo implications of this microbial-endocrine axis were validated in murine models bearing bladder cancer, where administration of these bile acid antagonists resulted in a marked enhancement of CD8+ T cell infiltration and cytotoxic function. The increase in T cell survival and effector activity contributed to robust tumor regression, signifying a profound immunotherapeutic potential derived from microbial metabolites rather than conventional pharmacological agents.

Dr. Nicholas Collins, co-senior author and immunology expert, highlights that these results establish a new paradigm in cancer immunology: gut microbiota-generated molecules can recalibrate systemic immune responses through hormonal receptor modulation. This synergy between microbial metabolism and host defense mechanisms showcases an intricate evolutionary partnership with therapeutic implications.

Moreover, collaboration between microbiologists, immunologists, and biochemists was integral to unraveling these complex interactions, illustrating the expanding utility of interdisciplinary approaches in microbiome research. Dr. David Artis, director at the Jill Roberts Institute, notes that such studies deepen our molecular grasp of host–microbe relationships, potentially revolutionizing multiple facets of medicine, from oncology to endocrinology.

Looking forward, the team envisions translating these findings into innovative treatments that either supplement patients with specific gut bacteria engineered to produce beneficial bile acids or directly administer these compounds as adjuvants to existing cancer therapies. This strategy might amplify treatment efficacy while reducing toxicity by targeting immune pathways naturally tuned through microbial-host co-evolution.

Despite these breakthroughs, critical questions remain unresolved. How dietary factors modulate microbial bile acid synthesis, and what systemic effects these androgen receptor-blocking bile acids exert in healthy individuals demand further exploration. The researchers are investing efforts to engineer gut microbes with controllable bile acid production, enabling precise dissection of their physiologic roles beyond oncology.

This study underscores the untapped potential of the microbiome as a source of bioactive metabolites capable of influencing fundamental receptor-mediated signaling pathways in humans. By illuminating bile acids’ dual roles as digestive agents and pivotal immunomodulators, this work paves the way for a renaissance in utilizing microbiota-derived molecules to harness the immune system’s full therapeutic potential against cancer.

In summary, the discovery that microbiota-modified bile acids can antagonize the androgen receptor to invigorate anti-tumor immunity heralds a paradigm shift in our understanding of host-microbe interactions. The prospect of leveraging these natural compounds to synergize with immunotherapies offers a visionary direction for future cancer treatment strategies, highlighting the microbiome’s profound influence on human health and disease.


Subject of Research: Interaction of microbiota-derived bile acids with the host androgen receptor and their role in enhancing anti-tumor immunity

Article Title: Microbiota-derived bile acids antagonize the host androgen receptor and drive anti-tumor immunity

News Publication Date: 15-Apr-2025

Image Credits: Credit: Sondii Image

Keywords: Bile, Androgen signaling, Acids, Discovery research, Immune receptors, Intestines

Tags: androgen receptor signaling and cancer therapybile acids and immune systembiochemical transformations in gut microbiotacancer therapies targeting gut microbiomegut microbiota and cancerimpact of microorganisms on host physiologyintestinal bacteria and bile acid conversionmicrobial metabolites and anti-tumor immunitymicrobiome and hormone signalingnovel cancer treatment strategiessecondary bile acids and healthWeill Cornell Medicine research
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