Abstract
Estrogen receptor (ER) positive breast cancer is the most prevalent subtype, commonly responsive to endocrine therapies. Immune checkpoint inhibitors (ICIs) have limited efficacy in ER-positive disease, highlighting the need for the development of combination immunotherapies for these patients. We previously established that nitroso-N-methylurea-induced mammary tumors in outbred Sprague-Dawley rats mimic immune evasive mechanisms and the heterogeneity of ICI response observed in patients. We identified a "luminal growing" gene signature in ER-positive tumors, which correlated with tumor growth and immune-related differences. Here, we evaluated targeting candidates from this signature KMT5B/C and IKBKE using inhibitors A-196 and IKBKEi respectively, alongside anti-estrogen (fulvestrant) and a TGFβ blocking antibody (NIS793), both individually and in combination with αPD-L1, within this rat model. Fulvestrant emerged as the most effective treatment, inducing regression of most existing tumors and reducing on-treatment tumor burden when combined with αPD-L1. A-196, while ineffective as a monotherapy, demonstrated enhanced response when combined with αPD-L1. Comprehensive tumor profiling through polychromatic flow cytometry and single-cell RNA sequencing revealed that A-196 induced a luminal-to-basal shift in tumor epithelial cells, enhancing antigen presentation, whereas epithelial-to-mesenchymal transition was linked to fulvestrant resistance. Our findings underscore the value of the rat mammary tumor model for preclinical studies in ER-positive breast cancer and advocate for the further validation and potential clinical development of KMT5B/C inhibitors to enhance the efficacy and broaden the applicability of ICI therapy in cancer patients.