Title of project: DIVERSITY SUPPLEMENT TO SKELETAL MYOSIN-BINDING PROTEIN C REGULATION & STRUCTURAL DYNAMICS. Summary of the diversity supplement to the parent project. Skeletal myosin-binding protein C (MyBP-C) plays a major role in the modulation of cardiac function by its phosphorylation and causes deficits in contractile function due to MyBP-C mutations in distal arthrogryposis (DA) and the role of phosphorylation and DA mutations is not known. Our goal is to understand the molecular biophysics of muscle and to train the next generation of muscle biophysicists, inclusive of diverse trainees. The parent research project and diversity supplement ask fundamental questions about the role of protein interactions and structural dynamics that regulate function in skeletal muscle. To gain insight into the correlation of structure- function involved in MyBP-C mechanisms in physiological and pathological settings, we will probe the actin- myosin-MyBP-C complex of these proteins in solution with varied binding, phosphorylation, DA mutations, and MyBP-C drugs. Our core technology is site-directed spectroscopy, applied to purified MyBP-C and actin/myosin filaments. We will apply innovative complementary methods in site-directed labeling and spectroscopy to correlate protein binding, structural dynamics and function. We will test the central hypothesis that phosphorylation and DA mutations influence N-terminal and central domain skeletal MyBP-C binding with actin and/or myosin in a dynamic equilibrium to modulate contraction. Related to the parent grant, the first period of the diversity supplement focuses on using spectroscopic approaches to accurately measure the structural dynamics within, and adjacent to, the Pro/Ala-rich linker (P/A) of purified skeletal MyBP-C fragment C1-C7, primarily by measuring nanometer distances and molecular disorder. Major emphasis is placed on detection of conformational changes (structure) within and nearby MyBP-C’s P/A due to phosphorylation, DA mutation, actin or myosin binding (function), and drugs. By including the location of probes in P/A and in adjacent C1 and C2 domains, the Candidate will measure structural changes. Fluorescently-labeled MyBP-C will be prepared to acquire fluorescence lifetime using time-resolved methods. Human splice variants containing and missing the phosphorylation site in long and short forms in P/A will be evaluated. In the second period, the Candidate will learn new skills in spectroscopic data fitting analysis to determine probe-to-probe distances and disorder in N- terminal and central domain MyBP-C. The third period will provide molecular details of the structural dynamics upon phosphorylation of P/A in long form sMyBP-C and actin- or myosin- MyBP-C complexes. The Candidate will systematically build in model system complexity, from unbound to actin/myosin-bound MyBP-C, upon phosphorylation. Spectroscopic study of sMyBP-C regulation will determine protein interactions and structural dynami...