par Suarez-Carmona, Meggy 
;Hampel, Mareike;Zhang, Xin-Wen;Pöchmann, Alexandra;Grauling-Halama, Silke;Valous, Nektarios;Charoentong, Pornpimol;Ferber, Dyke;Wissfeld, Jannis;Höflich, Alicia;Goriely, Stanislas ;Detavernier, Aurélie ;Azouz, Abdulkader ;Rongvaux, Anthony ;Zukunft, Sven;Fleming, Ingrid;Okun, Jürgen G.;Baracos, Vickie;Heikenwalder, Mathias;Zitvogel, Laurence;Xu, Xinyi;Xu, Chenqi;Volkmar, Michael ;Schraivogel, Daniel;Steinmetz, Lars L.M.;Hamanishi, Junzo;Mandai, Masaki;Gaida, Matthias;Mokry, Theresa;Nattenmüller, Johanna;Sedlaczek, Oliver;Monje, Nanna;Schwab, Roxana;Hasenburg, Annette;Mavratzas, Athanasios;Boger, Regina Johanna;Marmé, Frederik;Schott, Sarah;Halama, Niels
Référence Signal Transduction and Targeted Therapy, 11, 1
Publication Publié, 2026-03-04
;Hampel, Mareike;Zhang, Xin-Wen;Pöchmann, Alexandra;Grauling-Halama, Silke;Valous, Nektarios;Charoentong, Pornpimol;Ferber, Dyke;Wissfeld, Jannis;Höflich, Alicia;Goriely, Stanislas ;Detavernier, Aurélie ;Azouz, Abdulkader ;Rongvaux, Anthony ;Zukunft, Sven;Fleming, Ingrid;Okun, Jürgen G.;Baracos, Vickie;Heikenwalder, Mathias;Zitvogel, Laurence;Xu, Xinyi;Xu, Chenqi;Volkmar, Michael ;Schraivogel, Daniel;Steinmetz, Lars L.M.;Hamanishi, Junzo;Mandai, Masaki;Gaida, Matthias;Mokry, Theresa;Nattenmüller, Johanna;Sedlaczek, Oliver;Monje, Nanna;Schwab, Roxana;Hasenburg, Annette;Mavratzas, Athanasios;Boger, Regina Johanna;Marmé, Frederik;Schott, Sarah;Halama, NielsRéférence Signal Transduction and Targeted Therapy, 11, 1
Publication Publié, 2026-03-04
Article révisé par les pairs
| Résumé : | Abstract Immunotherapy with immune checkpoint blockade (ICB) in epithelial ovarian carcinoma (EOC) shows limited clinical benefit only for a small subset of patients. Overall response rates are low, so that overcoming immunotherapy resistance and improved stratification are key. In this study, we investigated the immunometabolic landscape of EOC with a focus on omental metastases, identifying lipid-laden macrophages as central elements for actionable therapeutic vulnerabilities and giving rise to biomarkers for improved patient stratification. Using patient-derived explants, we demonstrated a functional dichotomy inside the typically lipid-rich microenvironment of omental metastases: augmented maintenance of effector T cell function, while lipid uptake and processing by tumor-associated macrophages (TAMs) induces oxidative stress–dependent signaling programs, which drive macrophage dysfunction and immune suppression. Pharmacological modulation of lipid-driven signaling pathways through CCR5 inhibition (inflammation modulation through maraviroc) or blockade of the lipid scavenger receptor CD36 reprograms TAMs, restores T cell activity, and enhances antitumor immune responses within lipid-rich tumor niches. Mechanistically, studies in humanized mouse models reveal that maraviroc-mediated CCR5 inhibition induces transcriptional programs associated with immune activation in stressed, lipid-laden human TAMs. Consistent with these mechanistic insights, we demonstrated that the specific immunometabolic niche in omental metastases is clinically associated with responsiveness to ICB. We propose a non-invasive radiomics and machine-learning–based analysis of imaging data to assess omental involvement for patient stratification. |
