Skeletal muscle alpha actin acetylation enhances myosin binding and increases calcium sensitivity.

Abstract

Skeletal muscle alpha actin (ACTA1) is important for muscle contraction and relaxation, with historical studies focused on ACTA1 mutations in muscle dysfunction. Proteomics reports have consistently observed that actin, including ACTA1, is acetylated at multiple lysine sites. However, few reports have studied the effects of actin acetylation on cellular function, and fewer have examined ACTA1 acetylation on skeletal muscle function. Here, we aimed to examine how ACTA1 acetylation affected actomyosin interactions by determining actin sliding velocity, myosin binding, and calcium sensitivity. In this study, ACTA1 was chemically acetylated via acetic anhydride (AA) to increasing levels of acetylation: low-level acetylation (using 0.1 mM AA), mid-level acetylation (0.3 mM AA), and high-level acetylation (1 mM AA). We report that ACTA1 acetylation significantly decreased actin sliding velocity and actin filament length. Further analysis showed that ACTA1 acetylation significantly increased calcium sensitivity, with a loss of tropomyosin regulation noted with high-level ACTA1 acetylation. Lastly, ACTA1 acetylation enhanced skeletal myosin half maximal binding to actin. These data highlight acetylation as an additional posttranslational modification, outside of phosphorylation, in the regulation of muscle contraction and skeletal muscle alpha actin function.