Combined Pharmacologic and Nutritional Modulation of High-Fat Diet-Associated Tumor-Supportive Features in Prostate Cancer Models
Ke Wu, Qiongyu Hao, Joshua Yang, Yahya Elshimali, Clara E. Magyar, Susanne M. Henning, Ali Andalibi, Piwen WangBackground: Obesity is associated with aggressive prostate cancer, but the links between metabolic dysregulation, inflammation, adipocyte-associated signaling, and tumor growth remain incompletely defined. This study examined whether high-fat diet (HFD)-associated systemic changes and adipocyte-derived paracrine interactions are linked to prostate cancer growth in preclinical models. Methods: An HFD xenograft model and adipocyte co-culture systems were used to evaluate systemic and local tumor-supportive features. Pharmacologic/nutritional modulation was tested using green tea or EGCG, arctigenin, and the CCR2 antagonist RS 504393, alone or in combination. Tumor growth, cell proliferation, angiogenesis-related features, circulating metabolic and cytokine levels, and selected tumor-associated signaling proteins were analyzed. Results: HFD feeding was associated with increased circulating free fatty acids, IGF-1, MCP-1, IL-6, and VEGF, together with increased tumor growth, Ki67 staining, and CD31-positive microvessel density. Adipocyte co-culture systems were used to evaluate treatment-associated changes in prostate cancer cell proliferation under adipocyte-associated conditions. Combined modulation with green tea/EGCG, arctigenin, and RS 504393 was associated with greater reductions in adipocyte-associated proliferation, tumor growth, Ki67 staining, and CD31-positive microvessel density than single or dual interventions. Antibody array analysis showed treatment-associated changes in selected stress- and apoptosis-related proteins, including cleaved caspase-7 and phosphorylated Chk1. Conclusions: HFD-associated metabolic and inflammatory alterations, adipocyte-associated interactions, proliferative activity, angiogenesis-related features, and stress/apoptosis-related signaling changes were linked within a tumor-supportive framework in preclinical prostate cancer models. Combined pharmacologic/nutritional modulation was associated with reduced tumor-supportive features under HFD conditions. Further mechanistic and translational validation is needed.