Beatrice Malacrida

Navitoclax, a Bcl-2/xL Inhibitor, and YM155, a Survivin Inhibitor, in Combination with Carboplatin, Effectively Inhibit Ovarian Cancer Tumor Growth

Abstract High-grade serous ovarian cancer is generally treated with upfront chemotherapy, including carboplatin. The persistence of platinum-resistant cells drives recurrent disease. A high-throughput screen using a 3D organotypic culture assembled with extracellular matrix, primary human fibroblasts, and mesothelial cells was established and validated. Using a library of FDA-approved drugs, the 3D high-throughput screen was performed with the goal of identifying a combination of drugs that synergistically target two populations of ovarian cancer: aldehyde dehydrogenase (ALDH) high (ALDHhi) and ALDH low (ALDHlo) enzyme activity cells, which are less sensitive to carboplatin treatment than the bulk ovarian cancer cells. Initial results showed that omipalisib, verteporfin, CA3, mitoxantrone, navitoclax, venetoclax, and YM155 had significant single-drug activity in either the ALDHlo or both the ALDHlo/ALDHhi cell populations. Synergistic drug activity was identified with three drug combinations: navitoclax/omipalisib, navitoclax/YM155, and YM155/omipalisib. In vitro, the combination of navitoclax/YM155 was most efficient at blocking primary human ovarian cancer sphere formation and the proliferation of four different ovarian cancer cell lines in the 3D organotypic culture. In vivo, the combination of navitoclax/YM155/carboplatin decreased ovarian cancer metastasis, decreased the percentage of ALDHhi ovarian cancer cells in tumors, and increased survival when compared with carboplatin treatment alone in xenograft models. Our results suggest that the combination of navitoclax/YM155/carboplatin has promise as a therapy for treating ovarian cancer.

Human 3D Ovarian Cancer Models Reveal Malignant Cell–Intrinsic and –Extrinsic Factors That Influence CAR T-cell Activity

Abstract In vitro preclinical testing of chimeric antigen receptor (CAR) T cells is mostly carried out in monolayer cell cultures. However, alternative strategies are needed to take into account the complexity and the effects of the tumor microenvironment. Here, we describe the modulation of CAR T-cell activity by malignant cells and fibroblasts in human three-dimensional (3D) in vitro cell models of increasing complexity. In models combining mucin-1 (MUC1) and TnMUC1 CAR T cells with human high-grade serous ovarian cancer cell spheroids, malignant cell–intrinsic resistance to CAR T-cell killing was due to defective death receptor signaling involving TNFα. Adding primary human fibroblasts to spheroids unexpectedly increased the ability of CAR T cells to kill resistant malignant cells as CCL2 produced by fibroblasts activated CCR2/4+ CAR T cells. However, culturing malignant cells and fibroblasts in collagen gels engendered production of a dense extracellular matrix that impeded CAR T-cell activity in a TGFβ-dependent manner. A vascularized microfluidic device was developed that allowed CAR T cells to flow through the vessels and penetrate the gels in a more physiological way, killing malignant cells in a TNFα-dependent manner. Complex 3D human cell models may provide an efficient way of screening multiple cytotoxic human immune cell constructs while also enabling evaluation of mechanisms of resistance involving cell–cell and cell–matrix interactions, thus accelerating preclinical research on cytotoxic immune cell therapies in solid tumors. Significance: Three-dimensional in vitro models of increasing complexity uncover mechanisms of resistance to CAR T cells in solid tumors, which could help accelerate development of improved CAR T-cell constructs.