Resistance to the Antibody-Drug Conjugate T-DM1 Is Based in a Reduction in Lysosomal Proteolytic Activity.

Trastuzumab-emtansine (T-DM1) is an antibody-drug conjugate (ADC) that was approved recently to treat HER2 breast cancers. Despite its impressive clinical efficacy in many patients, intrinsic and acquired resistance to T-DM1 has emerged as a challenge. To identify mechanisms of T-DM1 resistance, we isolated several resistant HER2 clones exhibiting stable drug refractoriness and Genomic comparisons showed substantial differences among three of the isolated clones, indicating several potential mechanisms of resistance to T-DM1. However, we observed no differences in HER2 levels and signaling among the resistant models and parental HER2 cells. Bioinformatics studies suggested that intracellular trafficking of T-DM1 could underlie resistance to T-DM1, and systematic analysis of the path followed by T-DM1 showed that the early steps in the internalization of the drug were unaltered. However, in some of the resistant clones, T-DM1 accumulated in lysosomes. In these clones, lysosomal pH was increased and the proteolytic activity of these organelles was deranged. These results were confirmed in T-DM1-resistant cells from patient-derived HER2 samples. We postulate that resistance to T-DM1 occurs through multiple mechanisms, one of which is impaired lysosomal proteolytic activity. Because other ADC may use the same internalization-degradation pathway to deliver active payloads, strategies aimed at restoring lysosomal functionality might overcome resistance to ADC-based therapies and improve their effectiveness. .