Safe targeting of T cell acute lymphoblastic leukemia by pathology-specific NOTCH inhibition.

Given the high frequency of activating NOTCH1 mutations in T cell acute lymphoblastic leukemia (T-ALL), inhibition of the γ-secretase complex remains an attractive target to prevent ligand-independent release of the cytoplasmic tail and oncogenic NOTCH1 signaling. However, four different γ-secretase complexes exist, and available inhibitors block all complexes equally. As a result, these cause severe "on-target" gastrointestinal tract, skin, and thymus toxicity, limiting their therapeutic application. Here, we demonstrate that genetic deletion or pharmacologic inhibition of the presenilin-1 (PSEN1) subclass of γ-secretase complexes is highly effective in decreasing leukemia while avoiding dose-limiting toxicities. Clinically, T-ALL samples were found to selectively express only PSEN1-containing γ-secretase complexes. The conditional knockout of Psen1 in developing T cells attenuated the development of a mutant NOTCH1-driven leukemia in mice in vivo but did not abrogate normal T cell development. Treatment of T-ALL cell lines with the selective PSEN1 inhibitor MRK-560 effectively decreased mutant NOTCH1 processing and led to cell cycle arrest. These observations were extended to T-ALL patient-derived xenografts in vivo, demonstrating that MRK-560 treatment decreases leukemia burden and increased overall survival without any associated gut toxicity. Therefore, PSEN1-selective compounds provide a potential therapeutic strategy for safe and effective targeting of T-ALL and possibly also for other diseases in which NOTCH signaling plays a role.

Human NOTCH2 Is Resistant to Ligand-independent Activation by Metalloprotease Adam17.

Cell surface receptors of the NOTCH family of proteins are activated by ligand induced intramembrane proteolysis. Unfolding of the extracellular negative regulatory region (NRR), enabling successive proteolysis by the enzymes Adam10 and γ-secretase, is rate-limiting in NOTCH activation. Mutations in the NOTCH1 NRR are associated with ligand-independent activation and frequently found in human T-cell malignancies. In mammals four NOTCH receptors and five Delta/Jagged ligands exist, but mutations in the NRR are only rarely reported for receptors other than NOTCH1. Using biochemical and functional assays, we compared the molecular mechanisms of ligand-independent signaling in NOTCH1 and the highly related NOTCH2 receptor. Both murine Notch1 and Notch2 require the metalloprotease protease Adam17, but not Adam10 during ligand-independent activation. Interestingly, the human NOTCH2 receptor is resistant to ligand-independent activation compared with its human homologs or murine orthologs. Taken together, our data reveal subtle but functionally important differences for the NRR among NOTCH paralogs and homologs.