Development of Novel Quaternary Ammonium Linkers for Antibody-Drug Conjugates.

A quaternary ammonium-based drug-linker has been developed to expand the scope of antibody-drug conjugate (ADC) payloads to include tertiary amines, a functional group commonly present in biologically active compounds. The linker strategy was exemplified with a ß-glucuronidase-cleavable auristatin E construct. The drug-linker was found to efficiently release free auristatin E (AE) in the presence of ß-glucuronidase and provide ADCs that were highly stable in plasma. Anti-CD30 conjugates comprised of the glucuronide-AE linker were potent and immunologically specific in vitro and in vivo, displaying pharmacologic properties comparable with a carbamate-linked glucuronide-monomethylauristatin E control. The quaternary ammonium linker was then applied to a tubulysin antimitotic drug that contained an N-terminal tertiary amine that was important for activity. A glucuronide-tubulysin quaternary ammonium linker was synthesized and evaluated as an ADC payload, in which the resulting conjugates were found to be potent and immunologically specific in vitro, and displayed a high level of activity in a Hodgkin lymphoma xenograft. Furthermore, the results were superior to those obtained with a related tubulysin derivative containing a secondary amine N-terminus for conjugation using previously known linker technology. The quaternary ammonium linker represents a significant advance in linker technology, enabling stable conjugation of payloads with tertiary amine residues. Mol Cancer Ther; 15(5); 938-45. ©2016 AACR.

Intracellular Released Payload Influences Potency and Bystander-Killing Effects of Antibody-Drug Conjugates in Preclinical Models.

Antibody-drug conjugates (ADC) comprise targeting antibodies armed with potent small-molecule payloads. ADCs demonstrate specific cell killing in clinic, but the basis of their antitumor activity is not fully understood. In this study, we investigated the degree to which payload release predicts ADC activity in vitro and in vivo ADCs were generated to target different receptors on the anaplastic large cell lymphoma line L-82, but delivered the same cytotoxic payload (monomethyl auristatin E, MMAE), and we found that the intracellular concentration of released MMAE correlated with in vitro ADC-mediated cytotoxicity independent of target expression or drug:antibody ratios. Intratumoral MMAE concentrations consistently correlated with the extent of tumor growth inhibition in tumor xenograft models. In addition, we developed a robust admixed tumor model consisting of CD30(+) and CD30(-) cancer cells to study how heterogeneity of target antigen expression, a phenomenon often observed in cancer specimens, affects the treatment response. CD30-targeting ADC delivering membrane permeable MMAE or pyrrolobenzodiazepine dimers demonstrated potent bystander killing of neighboring CD30(-) cells. In contrast, a less membrane permeable payload, MMAF, failed to mediate bystander killing in vivo, suggesting local diffusion and distribution of released payloads represents a potential mechanism of ADC-mediated bystander killing. Collectively, our findings establish that the biophysical properties and amount of released payloads are chief factors determining the overall ADC potency and bystander killing. Cancer Res; 76(9); 2710-9. ©2016 AACR.

Reducing hydrophobicity of homogeneous antibody-drug conjugates improves pharmacokinetics and therapeutic index.

The in vitro potency of antibody-drug conjugates (ADCs) increases with the drug-to-antibody ratio (DAR); however, ADC plasma clearance also increases with DAR, reducing exposure and in vivo efficacy. Here we show that accelerated clearance arises from ADC hydrophobicity, which can be modulated through drug-linker design. We exemplify this using hydrophilic auristatin drug linkers and PEGylated ADCs that yield uniform, high-DAR ADCs with superior in vivo performance.

Self-hydrolyzing maleimides improve the stability and pharmacological properties of antibody-drug conjugates.

Many antibody-drug conjugates (ADCs) are unstable in vivo because they are formed from maleimide-containing components conjugated to reactive thiols. These thiosuccinimide linkages undergo two competing reactions in plasma: elimination of the maleimide through a retro-Michael reaction, which results in loss of drug-linker from the ADC, and hydrolysis of the thiosuccinimide ring, which results in a derivative that is resistant to the elimination reaction. In an effort to create linker technologies with improved stability characteristics, we used diaminopropionic acid (DPR) to prepare a drug-linker incorporating a basic amino group adjacent to the maleimide, positioned to provide intramolecular catalysis of thiosuccinimide ring hydrolysis. This basic group induces the thiosuccinimide to undergo rapid hydrolysis at neutral pH and room temperature. Once hydrolyzed, the drug-linker is no longer subject to maleimide elimination reactions, preventing nonspecific deconjugation. In vivo studies demonstrate that the increased stability characteristics can lead to improved ADC antitumor activity and reduced neutropenia.

Conjugation of anticancer drugs through endogenous monoclonal antibody cysteine residues.

Many methods have been described for the conjugation of drugs to monoclonal antibodies. The presence of a discrete number of readily reducible disulfides in the common IgG subtypes presents a convenient opportunity for conjugation to cysteine residues with thiol-reactive drug-linkers. Such conjugates can be prepared by a straightforward two-step reaction scheme involving the reduction of the antibody disulfides to the desired number of average thiols per antibody, followed by addition of the drug-linker, ideally with a maleimido functionality for rapid, selective reaction. In a discovery setting, this basic method can be scaled down to produce microgram quantities of conjugate for early screening, and in a manufacturing setting can be scaled up to produce grams or kilograms of conjugate for clinical trials and commercialization. The resulting conjugates are readily characterized using common HPLC methods.