Barbara A. Leece

Antibody-Drug Conjugates Designed to Eradicate Tumors with Homogeneous and Heterogeneous Expression of the Target Antigen

Conjugates of the anti-CanAg humanized monoclonal antibody huC242 with the microtubule-formation inhibitor DM1 (a maytansinoid), or with the DNA alkylator DC1 (a CC1065 analogue), have been evaluated for their ability to eradicate mixed cell populations formed from CanAg-positive and CanAg-negative cells in culture and in xenograft tumors in mice. We found that in culture, conjugates of either drug killed not only the target antigen-positive cells but also the neighboring antigen-negative cells. Furthermore, we showed that, in vivo, these conjugates were effective in eradicating tumors containing both antigen-positive and antigen-negative cells. The presence of antigen-positive cells was required for this killing of bystander cells. This target cell-activated killing of bystander cells was dependent on the nature of the linker between the antibody and the drug. Conjugates linked via a reducible disulfide bond were capable of exerting the bystander effect whereas equally potent conjugates linked via a nonreducible thioether bond were not. Our data offer a rationale for developing optimally constructed antibody-drug conjugates for treating tumors that express the target antigen either in a homogeneous or heterogeneous manner.

Disulfide-Linked Antibody−Maytansinoid Conjugates: Optimization of In Vivo Activity by Varying the Steric Hindrance at Carbon Atoms Adjacent to the Disulfide Linkage

In this report, we describe the synthesis of a panel of disulfide-linked huC242 (anti-CanAg) antibody maytansinoid conjugates (AMCs), which have varying levels of steric hindrance around the disulfide bond, in order to investigate the relationship between stability to reduction of the disulfide linker and antitumor activity of the conjugate in vivo. The conjugates were first tested for stability to reduction by dithiothreitol in vitro and for plasma stability in CD1 mice. It was found that the conjugates having the more sterically hindered disulfide linkages were more stable to reductive cleavage of the maytansinoid in both settings. When the panel of conjugates was tested for in vivo efficacy in two human colon cancer xenograft models in SCID mice, it was found that the conjugate with intermediate disulfide bond stability having two methyl groups on the maytansinoid side of the disulfide bond and no methyl groups on the linker side of the disulfide bond (huC242-SPDB-DM4) displayed the best efficacy. The ranking of in vivo efficacies of the conjugates was not predicted by their in vitro potencies, since all conjugates were highly active in vitro, including a huC242-SMCC-DM1 conjugate with a noncleavable linkage which showed only marginal activity in vivo. These data suggest that factors in addition to intrinsic conjugate potency and conjugate half-life in plasma influence the magnitude of antitumor activity observed for an AMC in vivo. We provide evidence that bystander killing of neighboring nontargeted tumor cells by diffusible cytotoxic metabolites produced from target cell processing of disulfide-linked antibody-maytansinoid conjugates may be one additional factor contributing to the activity of these conjugates in vivo.

Synthesis and Evaluation of Hydrophilic Linkers for Antibody–Maytansinoid Conjugates

The synthesis and biological evaluation of hydrophilic heterobifunctional cross-linkers for conjugation of antibodies with highly cytotoxic agents are described. These linkers contain either a negatively charged sulfonate group or a hydrophilic, noncharged PEG group in addition to an amine-reactive N-hydroxysuccinimide (NHS) ester and sulfhydryl reactive termini. These hydrophilic linkers enable conjugation of hydrophobic organic molecule drugs, such as a maytansinoid, at a higher drug/antibody ratio (DAR) than hydrophobic SPDB and SMCC linkers used earlier without triggering aggregation or loss of affinity of the resulting conjugate. Antibody-maytansinoid conjugates (AMCs) bearing these sulfonate- or PEG-containing hydrophilic linkers were, depending on the nature of the targeted cells, equally to more cytotoxic to antigen-positive cells and equally to less cytotoxic to antigen-negative cells than conjugates made with SPDB or SMCC linkers and thus typically displayed a wider selectivity window, particularly against multidrug resistant (MDR) cancer cell lines in vitro and tumor xenograft models in vivo.

Design of Antibody−Maytansinoid Conjugates Allows for Efficient Detoxification via Liver Metabolism

Antibody-maytansinoid conjugates (AMCs) are targeted chemotherapeutic agents consisting of a potent microtubule-depolymerizing maytansinoid (DM1 or DM4) attached to lysine residues of a monoclonal antibody (mAb) using an uncleavable thioether linker or a stable disulfide linker. Most of the administered dose of an antibody-based therapeutic is slowly catabolized by the liver and other tissues of the reticuloendothelial system. Maytansinoids released from an AMC during this catabolic process could potentially be a source of toxicity. To investigate this, we isolated and identified liver metabolites in mice for three different [(3)H]AMCs with structures similar to those currently undergoing evaluation in the clinic. We then synthesized each metabolite to confirm the identification and assessed their cytotoxic potencies when added extracellularly. We found that the uncleavable mAb-SMCC-[(3)H]DM1 conjugate was degraded to a single major maytansinoid metabolite, lysine-SMCC-[(3)H]DM1, that was nearly 50-fold less cytotoxic than maytansine. The two disulfide-linked conjugates, mAb-SPP-[(3)H]DM1 and mAb-SPDB-[(3)H]DM4, were also found to be catabolized to the analogous lysine-linked maytansinoid metabolites. However, subsequent reduction, S-methylation, and NADPH-dependent oxidation steps in the liver yielded the corresponding S-methyl sulfoxide and S-methyl sulfone derivatives. The cytotoxic potencies of the oxidized maytansinoids toward several human carcinoma cell lines were found to be 5- to 50-fold less potent than maytansine. Our results suggest that liver plays an important role in the detoxification of both cleavable and uncleavable AMCs.

Synthesis and Biological Evaluation of Antibody Conjugates of Phosphate Prodrugs of Cytotoxic DNA Alkylators for the Targeted Treatment of Cancer

The synthesis and biological evaluation of phosphate prodrugs of analogues of 1 (CC-1065) and their conjugates with antibodies are described. The phosphate group on the 1,2,9,9a-tetrahydrocyclopropa[c]benz[e]indol-4-one (CBI) portion of the compounds confers enhanced solubility and stability in aqueous solutions. In the presence of phosphatases, these compounds convert into active DNA-alkylating agents. The synthesis of the prodrugs was achieved sequentially through coupling of CBI with a bis-indolyl moiety, followed by attachment of a thiol-containing linker, and conversion of the hydroxyl group of CBI into a phosphate prodrug. The linkers incorporated into the prodrugs enable conjugation to an antibody via either a stable disulfide or thioether bond, in aqueous buffer solutions containing as little as 5% organic cosolvent, resulting in exclusively monomeric and stable antibody-cytotoxic prodrug conjugates. Two disulfide-containing linkers differing in the degree of steric hindrance were used in antibody conjugates to test the effect of different rates of intracellular disulfide cleavage and effector release on biological activity. The prodrugs can be converted to the active cytotoxic compounds through the action of endogenous phosphatases. Antibody-prodrug conjugates displayed potent antigen-selective cytotoxic activity in vitro and antitumor activity in vivo.

Abstract B126: Potent antigen‐specific anti‐tumor activity observed with antibody‐drug conjugates (ADCs) made using a new class of DNA‐crosslinking agents

The clinical support for ADC therapeutics has expanded as more highly‐engineered ADCs advance in human clinical testing. Most of the ADCs now in clinical testing contain a tubulin‐acting compound (a maytansine or dolastatin derivative) as the cytotoxic agent. While tubulin‐acting agents can be effective against many different types of cancers, some cancers are more responsive to DNA‐acting agents. To expand the therapeutic potential for ADCs, we sought to develop a new class of cytotoxic agents with a novel, DNA‐acting mechanism of action for use with tumor‐targeting antibodies. Herein, we report the development of our IGN family of cytotoxic agents. These IGN agents comprise indolino‐benzodiazepine dimers that are highly potent by virtue of their ability to alkylate and crosslink DNA. This novel class of compounds demonstrated sequence‐selective DNA adduct formation in vitro and cytotoxicity in the picomolar range towards cultured human cancer cells. The intense potency of these compounds, along with their desired aqueous solubility and stability, make them ideally suited for use in ADCs. A lead compound from this class was conjugated to an EpCAM‐binding antibody, B38.1, and to a CD33‐binding antibody, huMy9‐6, through amide bonds. The B38.1‐IGN conjugate was highly potent against three different EpCAM‐expressing cell lines ‐ COLO 205, LoVo and OVCAR‐3 ‐ with IC50 values of 1 pM, 5 pM and 18 pM, respectively. The addition of excess unconjugated B38.1 antibody abolished this cytotoxic effect, demonstrating that the activity of the conjugate is antigen specific. The B38.1‐IGN conjugate was considerably less potent towards the antigen‐negative Namalwa cell line, with an IC50 value of >1 nM, further demonstrating antigen specificity. Similar potent cytotoxicity was seen with a huMy9‐6‐IGN conjugate targeting the CD33‐positive human promyelocytic leukemia cell line, NB4 (IC50 ∼4pM), in spite of the low antigen expression level (∼10,000 molecules/cell) in this cell line. Of particular interest, the B38.1‐IGN conjugate also was potent towards multidrug resistant cancer cells. B38.1‐IGN had a IC50 value of 14 pM for COLO 205MDR, a COLO 205 clone engineered to overexpress MDR1 transporter, and 7 pM for HCT‐15, an EpCAM‐expressing cell line that naturally expresses MDR1. Antibody‐IGN conjugates demonstrated dose‐dependent activity in multiple human tumor xenograft models in mice, with anti‐tumor activity observed at non‐toxic doses. The unique mechanism of action of the IGN class of compounds, and the high antigen‐specific potency of antibody‐IGN conjugates seen in vitro and in vivo, provides a promising new cytotoxic agent for use in the development of new ADCs. Citation Information: Mol Cancer Ther 2009;8(12 Suppl):B126.

Metabolites of Antibody–Maytansinoid Conjugates: Characteristics and in Vitro Potencies

Several antibody-maytansinoid conjugates (AMCs) are in clinical trials for the treatment of various cancers. Each of these conjugates can be metabolized by tumor cells to give cytotoxic maytansinoid metabolites that can kill targeted cells. In preclinical studies in mice, the cytotoxic metabolites initially formed in vivo are further processed in the mouse liver to give several oxidized metabolic species. In this work, the primary AMC metabolites were synthesized and incubated with human liver microsomes (HLMs) to determine if human liver would likely give the same metabolites as those formed in mouse liver. The results of these HLM metabolism studies as well as the subsequent syntheses of the resulting HLM oxidation products are presented. Syntheses of the minor impurities formed during the conjugation of AMCs were also conducted to determine their cytotoxicities and to establish how these impurities would be metabolized by HLM.