PROJECT SUMMARY / ABSTRACT Deregulated protein interactions contribute to the development, maintenance, and chemoresistance of human cancer. The critical contact points of cancer-causing proteins are often mediated by so-called “helix-in-groove” interactions, whereby an alpha-helical subcomponent of one protein inserts into the surface groove of another to drive oncogenic signaling. For example, BCL-2 family proteins regulate the critical balance between cellular life and death and cancer cells overexpress the anti-apoptotic members, which contain a surface groove that effectively traps the “killer” helix of pro-apoptotic members, to enforce cellular immortality. We have inserted all- hydrocarbon struts into natural alpha-helices to restore their shape, stability, and bioactivity so that they can be used as both powerful chemical tools to dissect oncogenic protein interactions and as prototype therapeutics to drug them. Over the last 15 years, I have developed special expertise in the design of stapled peptides for diverse applications in cancer research and treatment. I have generated spin-labeled analogs for NMR structural analyses, photoreactive constructs for rapid binding-site analysis by mass spectrometry, cysteine-reactive variants for covalent targeting of oncogenic proteins, fluorescent derivatives for binding affinity quantitation and cellular imaging, radiolabeled constructs for in vivo imaging, and iteratively-optimized analogs for preclinical testing and translation. The remarkable impact of stapled peptides is best reflected by their capacity to identify new cancer targets, mechanisms, and druggable binding sites and their advancement to clinical trials in adults and children with relapsed cancers. The goal of this competitive renewal application is to continue to expand the breadth and depth of stapled peptide innovation in support of critical cancer research programs that harness these reagents in proteomic discovery, structural determination, mechanism-of-action studies, and therapeutic development. Specifically, I aim to robustly support the NCI-funded R35 research program of my Unit Director, Dr. Loren Walensky, who as a chemical biologist and pediatric oncologist, focuses on characterizing the BCL-2 family interaction mechanisms that drive human cancer by neutralizing the mitochondrial apoptosis pathway. Reactivating apoptosis in cancer is essential to overcoming chemoresistance and the pathologic alpha-helical interactions of the BCL-2 family are ideally suited for interrogation by stapled peptides. In running the Stapled Peptide Design Group of the Walensky lab and Dana-Farber’s Program in Cancer Chemical Biology, I am personally responsible for developing and optimizing the chemistry that drives stapled peptide innovations, and creating a high-throughput consultation, production, purification, quantitation, and characterization workflow that is also relied upon by dozens of our internal and external collaborators. As a Res...