CCL2 blockade combined with PD-1/P-selectin immunomodulators impedes breast cancer brain metastasis
Sahar Israeli Dangoor, Rami Khoury, K. Salomon, Sabina Pozzi, Shir Shahar, Anna Miari, Yael Leichtmann-Bardoogo, Neta Bar-Hai, Neta Frommer, Eilam Yeini, Tom Winkler, Nora Balint Lahat, Iris Kamer, Ori Hadad, Kathrin Laue, Henry Brem, Thomas M. Hyde, Jair Bar, Iris Barshack, Uri Ben-David, Dana Ishay-Ronen, Ben M. Maoz, Ronit Satchi‐Fainaro
Abstract
Over the last two decades, the diagnosis and treatment of breast cancer patients have improved considerably. However, brain metastases remain a major clinical challenge and a leading cause of mortality. Thus, a better understanding of the pathways involved in the metastatic cascade is essential. To this end, we have investigated the reciprocal effects of astrocytes and breast cancer cells, employing traditional 2D cell culture and our unique 3D multicellular tumouroid models. Our findings revealed that astrocytes enhance the proliferation, migration and invasion of breast cancer cells, suggesting a supportive role for astrocytes in breast cancer outgrowth to the brain. Elucidating the key players in astrocyte-breast cancer cells crosstalk, we found that CCL2 is highly expressed in breast cancer brain metastases tissue sections from both patients and mice. Our in vitro and in vivo models further confirmed that CCL2 has a functional role in brain metastasis. Given their aggressive nature, we sought additional immune checkpoints for rationale combination therapy. Among the promising candidates were the adhesion molecule P-selectin, which we have recently shown to play a key role in the crosstalk with microglia cells and the co-inhibitory receptor PD-1, the main target of currently approved immunotherapies. Finally, combining CCL2 inhibition with immunomodulators targeting either PD-1/PD-L1 or P-selectin/P-Selectin Ligand-1 axes in our human 3D tumouroid models and in vivo presented more favourable outcomes than each monotherapy. Taken together, we propose that CCL2-CCR2/CCR4 is a key pathway promoting breast cancer brain metastases and a promising target for an immunotherapeutic combination approach.