Chris J. Novotny scite author profile

Precision medicines exert selective pressure on tumor cells that leads to the preferential growth of resistant subpopulations, necessitating the development of next generation therapies to treat the evolving cancer. The PIK3CA/AKT/mTOR pathway is one of the most commonly activated pathways in human cancers1, which has led to the development of small molecule inhibitors that target various nodes in the pathway. Among these agents, first generation mTOR inhibitors (rapalogs) have caused responses in so-called “N-of-1” cases and second generation mTOR kinase inhibitors (TORKi) are currently in clinical trials2–4. We sought to delineate the likely resistance mechanisms to existing mTOR inhibitors as a guide for next generation therapies. The mechanism of resistance to the TORKi was unusual in that intrinsic kinase activity of mTOR was increased, rather than a direct active site mutation interfering with drug binding. Indeed, the identical drug resistant mutations have been also identified in drug-naïve patients4, suggesting that tumors with activating mTOR mutations will be intrinsically resistant to second generation mTOR inhibitors. Here, we report the development of a new class of mTOR inhibitors which overcomes resistance to existing first and second generation inhibitors. The third generation mTOR inhibitor exploits the unique juxtaposition of two drug binding pockets to create a bivalent interaction that allows inhibition of these resistant mutants.

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Structure of the Human Autophagy Initiating Kinase ULK1 in Complex with Potent Inhibitors

Lazarus

2015

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Autophagy is a conserved cellular process that involves the degradation of cellular components for energy maintenance and cytoplasmic quality control that has recently gained interest as a novel target for a variety of human diseases, including cancer. A prime candidate to determine the potential therapeutic benefit of targeting autophagy is the kinase ULK1, whose activation initiates autophagy. Here, we report the first structures of ULK1, in complex with multiple potent inhibitors. These structures show features unique to the enzyme and will provide a path for the rational design of selective compounds as cellular probes and potential therapeutics.

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Procaspase-3 Activation as an Anti-Cancer Strategy: Structure−Activity Relationship of Procaspase-Activating Compound 1 (PAC-1) and Its Cellular Co-Localization with Caspase-3

et al. 2009

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A goal of personalized medicine as applied to oncology is to identify compounds that exploit a defined molecular defect in a cancerous cell. A compound called procaspase-activating compound 1 (PAC-1) was reported that enhances the activity of procaspase-3 in vitro and induces apoptotic death in cancer cells in culture and in mouse xenograft models. Experimental evidence indicates that PAC-1 activates procaspase-3 in vitro through chelation of inhibitory zinc ions. Described herein is the synthesis and biological activity of a family of PAC-1 derivatives where key functional groups have been systematically altered. Analysis of these compounds reveals a strong correlation between the in vitro procaspase-3 activating effect and their ability to induce death in cancer cells in culture. Importantly, we also show that a fluorescently-labeled version of PAC-1 co-localizes with sites of caspase-3 activity in cancer cells. The data presented herein further bolster the hypothesis that PAC-1 induces apoptosis in cancer cells through the direct activation of procaspase-3, has implications for the design and discovery of next-generation procaspase-3 activating compounds, and sheds light on the anti-apoptotic role of cellular zinc.

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Chris J. Novotny

Overcoming mTOR resistance mutations with a new-generation mTOR inhibitor

Structure of the Human Autophagy Initiating Kinase ULK1 in Complex with Potent Inhibitors

Procaspase-3 Activation as an Anti-Cancer Strategy: Structure−Activity Relationship of Procaspase-Activating Compound 1 (PAC-1) and Its Cellular Co-Localization with Caspase-3

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