Chang et al. developed novel, conditionally active biologic (CAB) anti-CTLA-4 mAbs by selecting variants with reversible, pH-dependent binding to CTLA-4 at pH 6.0 (acidic TME) but not at pH 7.4 (healthy tissue). CAB selectivity was characterized as responsive to physiological levels of bicarbonate and hydrogen sulfide as non-covalent protein-associated chemical switches (PaCS). CAB antitumor efficacy was similar to an ipilimumab analog (IpA), but (in combination with anti-PD-1) resulted in dramatically less GI toxicity and peripheral T cell activation compared to IpA in an NHP toxicology study. PaCS can be applied to many Ab formats to improve the therapeutic index.
Contributed by Katherine Turner
ABSTRACT: Anticytotoxic T lymphocyte-associated protein 4 (CTLA4) antibodies have shown potent antitumor activity, but systemic immune activation leads to severe immune-related adverse events, limiting clinical usage. We developed novel, conditionally active biologic (CAB) anti-CTLA4 antibodies that are active only in the acidic tumor microenvironment. In healthy tissue, this binding is reversibly inhibited by a novel mechanism using physiological chemicals as protein-associated chemical switches (PaCS). No enzymes or potentially immunogenic covalent modifications to the antibody are required for activation in the tumor. The novel anti-CTLA4 antibodies show similar efficacy in animal models compared to an analog of a marketed anti-CTLA4 biologic, but have markedly reduced toxicity in nonhuman primates (in combination with an anti-PD1 checkpoint inhibitor), indicating a widened therapeutic index (TI). The PaCS encompass mechanisms that are applicable to a wide array of antibody formats (e.g., ADC, bispecifics) and antigens. Examples shown here include antibodies to EpCAM, Her2, Nectin4, CD73, and CD3. Existing antibodies can be engineered readily to be made sensitive to PaCS, and the inhibitory activity can be optimized for each antigen's varying expression level and tissue distribution. PaCS can modulate diverse physiological molecular interactions and are applicable to various pathologic conditions, enabling differential CAB antibody activities in normal versus disease microenvironments.