Anti-tumor immunity varies due to interactions between innate and adaptive immune cells, microbial community diversity, host and microbially derived metabolites, and other local factors that shape tumoricidal responses. While most of the recent microbiome research focuses on the gut microbiome and cancer outcomes, extra-intestinal microbial communities are detected in the tumor microenvironment (TME). We recently reported that specific microbes identified in patient breast tumors compared to pathologically normal breast samples associated with tumor stage, tumor subtype, and for the first time, race. Triple Negative Breast Cancer (TNBC), an aggressive subtype that has generally eluded personalized medicine approaches, contained unique microbes that may mediate immunosuppression and impact standard chemotherapy or immune checkpoint inhibitor (ICI) efficacies. Yet to date, mechanisms underpinning these observations are unresolved as to how the gut and/or extra-intestinal microbiome influence BC onset, progression, and response to therapies, which is a major knowledge gap in this field. One cogent mechanism that may link microbes to anti-tumor immunity are microbially modified metabolites, namely bile acids. Certain microbes rich in 7-alpha-hydroxylase convert primary to secondary bile acids which regulate bile acid composition. Bile acids have been shown to limit progression and metastasis in other cancers through reversing immunosuppression, but minimal work has explored the role of bile acids in BC. Bile acids signal through several bile acid receptors including farnesoid X receptor (FXR). We posit that specific gut or local resident microbes that impact bile acid pools and composition will interact with cells expressing FXR to regulate the TME immune milieu. We report for the first time that patients with high FXR expression have greater relapse-free survival uniquely in TNBC subtype, but not in less aggressive luminal BC subtype, suggesting potential for targeted approaches. The overall objective of this proposal is to test mechanisms linking Microbes?Bile Acids?TNBC which poses an opportunity to generate novel therapeutics and precision medicine informed by microbial compositions. Our innovative approach interrogates targetable microbial pathways that we demonstrate change the microbiome, bile acids, and tumor progression. Our central hypothesis is microbial composition and microbially-modified metabolic products, such as bile acids, increase immunotherapeutic efficacy through reprogramming the TME leading to enhanced anti-tumor immunity. We will test our hypothesis by performing the following aims: 1) Determine if commensal microbes play a physiological role in TNBC anti-tumor immunity; 2) Determine if the microbiome alters immunosurveillance of early tumor onset and progression; 3) Determine if pharmacologic bile acid receptor agonism improves TNBC immunotherapy. Findings generated will have high impact because the lack of targeted therapies for TNBC presents a great unmet clinical need and could be transformative to improve patient outcomes.
Microbes influence immunosurveillance as well as the efficacy of chemotherapy and immunotherapy that shape cancer outcomes, but underlying mechanisms remain unclear. Microbes themselves or metabolites derived by bacterial metabolism may be the mediating factors that alter the tumor microenvironment to impact anti-tumor immunity. Upon conclusion, this study will determine whether microbial-modification of bile acid pools and activation of bile acid receptor signaling act as novel mechanisms that can be leveraged to enhance anti-tumor immunity to improve patient outcomes in triple negative breast cancer.
