A CRISPR Screen Reveals Resistance Mechanisms to CD3-Bispecific Antibody Therapy

CD3-bispecific antibodies represent an important therapeutic strategy in oncology. These molecules work by redirecting cytotoxic T cells to antigen-bearing tumor cells. Although CD3-bispecific antibodies have been developed for several clinical indications, cases of cancer-derived resistance are an emerging limitation to the more generalized application of these molecules. Here, we devised whole-genome CRISPR screens to identify cancer resistance mechanisms to CD3-bispecific antibodies across multiple targets and cancer types. By validating the screen hits, we found that deficiency in IFNγ signaling has a prominent role in cancer resistance. Interestingly, IFNγ functions by stimulating the expression of T cell killing-related molecules in a cell type-specific manner. Additionally, by assessing resistance to the clinical CD3-bispecific antibody flotetuzumab, we identified core fucosylation as a novel and critical pathway to regulate flotetuzumab binding to the CD123 antigen. Disruption of this pathway resulted in significant resistance to flotetuzumab treatment. Moreover, proper fucosylation of CD123 is required for its normal biological functions. In order to treat the resistance associated with fucosylation loss, flotetuzumab in combination with an alternative targeting CD3-bispecific antibody demonstrated superior efficacy. Together, our study reveals multiple mechanisms that can be targeted to enhance the clinical potential of current and future T cell engaging CD3-bispecific antibody therapies. Using RNA-seq to analyze the effects of interferon-gamma (IFNg) treatment on three cancer cell lines (MOLM13, SEM, HCC827) at three time points (0, 6, and 24 hours of IFN-g) in biological triplicates.