👤 Chelsea M Hutchinson Bunch

Declines in skeletal muscle and cognitive function in older adults have been linked to abnormalities in abdominal subcutaneous adipose tissue (ASAT), yet the underlying molecular mediators remain poorly understood. Here, leveraging ASAT transcriptomics and explant-conditioned media proteomics from participants in the Study of Muscle, Mobility and Aging (SOMMA; age ≥70 years, n = 229), we identified ASAT gene clusters and secreted proteins strongly associated with comprehensive assessments of physical and cognitive function in older adults. ASAT inflammation and secreted immunoglobulins were identified as key signatures of aging-associated physical and cognitive performance limitations. Systems genetics analysis confirmed secreted-SERPINF1 as a negative regulator of skeletal muscle contraction and highlighted its potential role in inducing inflammation in the heart in silico. Additionally, novel ASAT-secreted proteins such as NID2 and APOA4 were implicated in mediating ASAT crosstalk with skeletal muscle and brain in silico. Our framework provides insights into ASAT-driven tissue crosstalk underlying physical and cognitive performance in older adults and offers a valuable resource for understanding the role of ASAT in human aging. Show less

Declines in skeletal muscle and cognitive function in older adults have been linked to abnormalities in abdominal subcutaneous adipose tissue (ASAT), yet the underlying molecular mediators remain poorly understood. Here, leveraging ASAT transcriptomics and explant-conditioned media proteomics from participants in the Study of Muscle, Mobility and Aging (SOMMA; age ≥70 years, n = 229), we identified ASAT gene clusters and secreted proteins strongly associated with comprehensive assessments of physical and cognitive function in older adults. ASAT inflammation and secreted immunoglobulins were identified as key signatures of aging-associated physical and cognitive performance limitations. Systems genetics analysis confirmed secreted-SERPINF1 as a negative regulator of skeletal muscle contraction and highlighted its potential role in inducing inflammation in the heart Show less

Mutations in cardiac myosin-binding protein C (cMyBP-C) are a leading cause of hypertrophic cardiomyopathy (HCM). Although most cMyBP-C mutations produce truncated proteins and cause HCM via haploinsufficiency, the mechanisms by which missense mutations result in disease remain poorly understood. Here, we have evaluated three mutations in immunoglobulin-like domains C1 (P161S, Y237S) and C2 (P371R), predicted to be pathogenic for HCM, assessing their effects on cMyBP-C actin-binding function, protein thermal stability, and residue mobility. Using a fluorescence lifetime-based actin-binding assay, we found that N-terminal mutants P161S, Y237S, and P371R enhanced C0-C2 interactions with actin in both unphosphorylated and phosphorylated states, suggesting that the mutations strengthen actin binding and make the binding resistant to phosphorylation-mediated regulation. Differential scanning calorimetry revealed that mutants exhibit destabilized thermal melting profiles with reduced unfolding temperature, energy, and cooperativity. Molecular dynamics simulations indicated that these mutations induce allosteric effects, increasing fluctuations of unstructured loops in C1 or C2 that contain key actin-binding residues. These alterations in protein stability and residue mobility may promote domains to visit binding-competent conformations more frequently, reduce the energetic cost of complex formation, and/or expose actin-interacting interfaces, thereby enhancing C0-C2 binding and contributing to HCM pathogenesis. Show less