Prostate Cancer at the Microbial Crossroads: Illuminating a New Frontier in Precision Medicine.

The human body harbors a complex, dynamic community of trillions of microbes, collectively termed the microbiota, which profoundly affects homeostasis and disease processes, including cancer. Prostate cancer remains a major cause of morbidity and mortality among men worldwide; however, critical questions remain regarding its etiology, progression, and resistance to therapy. Multiple epidemiological studies have found associations between certain urinary and intestinal microorganisms and an increased prostate cancer risk, although the causal mechanisms remain incompletely understood. Recent studies suggest that dysregulated microbial communities, or dysbiosis, are hypothesized to drive chronic inflammation, induce genotoxic insults, and modulate steroid metabolism, thereby influencing tumor initiation and progression. Conflicting findings across different investigations often stem from heterogeneous sampling methods, population differences, and disparate bioinformat ics pipelines, underscoring the critical need for standardized protocols and reproducible data analytics. For example, diet induced alterations in the gut microbiota can shift systemic inflammatory and hormonal pathways in ways that predispose individuals to malignant transformation. Simultaneously, prostatic and urinary microbes are hypothesized to fuel local inflam mation and promote precursor lesions, although whether this microbial activity is causative or merely reflective of the exist ing tumor biology remains a key unresolved question. Microbiota-driven mechanisms also shape responses to radiotherapy, chemotherapy, and emerging immunotherapies, highlighting the potential of interventions such as probiotics, prebiotics, and fecal microbiota transplantation to enhance treatment efficacy and mitigate side effects. Innovative approaches, including ar tificial intelligence-assisted predictive modeling, CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats)-based microbial gene editing, and immunomodulatory strategies (e.g., chimeric antigen receptor-T cells), offer new avenues for exploiting microbiota for therapeutic benefits. Nevertheless, unresolved questions regarding the long-term safety, ecological balance, and individual patient factors require caution. By integrating rigorous methodologies with these novel technologies, prostate cancer research may ultimately harness microbial insights to refine diagnostic tools, personalize therapies, and im prove patient outcomes.