How certain gut bacteria compromise radiotherapy

A study led by Ludwig Cancer Research Chicago Co-Director Ralph Weichselbaum and Yang-Xin Fu of the University of Texas Southwestern Medical Center has shown how bacteria in the gut can dull the efficacy of radiotherapy, a treatment received by about half of all cancer patients. Their findings appear in the Journal of Experimental Medicine.

A wide variety of commensal bacteria inhabit the human body, particularly the gut, where they participate in important physiological processes ranging from digestion to regulation of the immune system. Studies have shown that gut microbes also have a profound influence on cancer therapies, most notably immunotherapies. Since ionising radiation is known to activate anti-tumour immune responses, Kaiting Yang, a postdoctoral researcher in Weichselbaum’s lab, examined how antibiotics affect the outcomes of tumour radiotherapy.

Her studies showed that vancomycin, an antibiotic against gram-positive bacteria, enhanced responses to tumour irradiation in mice. Gentamycin, which targets gram-negative bacteria, did not have that effect. It turned out that vancomycin’s decimation of two families of gram-positive gut bacteria — Lachnospiraceae and Ruminococcaceae — was most closely associated with the improved response. Further analysis revealed that a decline in levels of butyrate, a metabolite produced by these bacteria, accompanied the effect.

When Lachnospiraceae were introduced into mice completely devoid of bacteria, the effect of radiation on their tumours was notably diminished and the dampened response corresponded to a systemic increase in butyrate levels. The injection of butyrate directly into tumours had a similarly dampening effect on radiotherapy.

Since butyrate did not directly protect the tumours from radiation, the researchers turned their attention to the immune response elicited by radiotherapy. Their experiments revealed that butyrate interferes with the activation of cytotoxic (or killer) T cells, immune cells that target cancer cells and are known to attack tumours following radiotherapy.

Previous studies led by Weichselbaum and Fu have shown that irradiation activates a signalling pathway in another immune cell — the dendritic cell, which can prime killer T cells to attack tumours. This biochemical pathway, controlled by a protein named STING, ramps up the dendritic cells’ production of immune-stimulating factors known as type-1 interferons (IFN-I), which boosts their activation of killer T cells.

The researchers showed that butyrate inhibits a step of the biochemical signalling cascade that links STING activation to the production of IFN-I. Adding an IFN-I to tumours simultaneously injected with butyrate restored the therapeutic effects of radiotherapy in the mice. Their findings confirm those of a study published in the Journal of Clinical Investigation in 2019, which also showed that butyrate compromises the activation of killer T cells by dendritic cells following tumour irradiation.

The current study also has some immediate clinical relevance. The researchers found that levels of other beneficial bacteria (Akkermansia and Lactobacillus) increase in the gut and within tumours of mice following vancomycin treatment. This suggests that butyrate depletion might not be the only mechanism behind the observed improvement in responses to radiotherapy: antibiotic treatment might also affect the microbiome in other ways to support immune responses elicited by radiotherapy.

“Our findings offer clues to the development of new strategies to improve patient responses to radiotherapy,” Weichselbaum said. “This includes the specific targeting of particular types of gut bacteria that produce butyrate — once we have a better understanding of the various ways in which these microbes interact with the immune system and cancer therapies.”

Image credit: ©stock.adobe.com/au/nobeastsofierce

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