Abstract 660: Engineering strategies to control stoichiometry, site of conjugation, serum stability and effector functions of antibody-drug conjugates

Abstract

Abstract A promising approach to enhance the antitumor activity of antibodies and reduce the systemic toxicity of small molecule anti-cancer drugs is to covalently attach the small molecule to the antibody thus forming antibody drug conjugates (ADCs). Conventionally, ADCs are produced by chemical conjugation of drugs to antibodies through either lysine side chain amines or native cysteine sulfhydryl groups generated by reduction of interchain disulfide bonds. Both of these methods yield heterogeneous conjugates with complex biophysical properties. To limit these liabilities, we have designed, characterized, and validated antibody variants, which allow precise control of the site of conjugation and the drug load; such as two and/or four drugs per antibody can be site-specific conjugated. These engineered antibody variants can be efficiently and site-specifically conjugated with drug payloads at milligram and gram scales to yield homogenous ADC products. Engineered antibody variants described here retain antigen-binding affinities, FcRn binding, and have biochemical, biophysical and manufacturability properties similar to their non-engineered parent antibodies. Upon conjugation to highly cytotoxic drugs with anti-mitotic and/or DNA alkylating activities, the antibody variants have potent in vitro and in vivo anti-tumor activity. Furthermore, we describe ADCs vehicles that provide efficient scaffolds for site-specific conjugation of drugs while offering the opportunity to minimize off-target toxicities often observed with ADCs as a result of their binding to cells expressing Fc-gamma receptors. Finally, we show the impact of the identified sites for drug conjugation on the in vivo pharmacokinetic and safety profile of ADCs in rats. Our strategies for engineering ADCs with defined sites for conjugation, controlled drug loads, potentially decreased off-target toxicity, and optimal serum stability are broadly applicable to any full-length IgG or Fc-containing therapeutics as they involve the Fc constant domain of the antibody. Citation Format: Nazzareno Dimasi, Ryan Fleming. Engineering strategies to control stoichiometry, site of conjugation, serum stability and effector functions of antibody-drug conjugates. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 660. doi:10.1158/1538-7445.AM2014-660