Actin and myosin are key proteins for muscle contraction/relaxation, while tropomyosin regulates actin-myosin interactions in the presence or absence of calcium. Mutations or dysregulation of any of these proteins results… Click to show full abstract
Actin and myosin are key proteins for muscle contraction/relaxation, while tropomyosin regulates actin-myosin interactions in the presence or absence of calcium. Mutations or dysregulation of any of these proteins results in cardiomyopathy. We previously showed that skeletal muscle alpha actin (ACTA1) was significantly deacetylated on lysine residues, K52, K317, and K328 in remodeled left ventricular tissue of obese mice. Computational modeling suggests that the positively charged lysine residues K328 and K317 of ACTA1 can interact electrostatically with the negatively charged glutamic acid residue E181 of tropomyosin and E286 of myosin. As acetylation is predicted to neutralize the positively charged lysine, ACTA1 acetylation would be postulated to decrease actin-myosin or actin-tropomyosin electrostatic interactions. To test this hypothesis, we used an in vitro actin motility assay to determine myosin sliding velocity, calcium sensitivity, and attachment/detachment kinetics of acetylated/deacetylated ACTA1. In addition, an actin binding protein spin-down assay was used to determine actin-myosin binding affinity using skeletal and cardiac myosin. In these assays, ACTA1 was chemically acetylated with acetic anhydride. In vitro actin motility analysis showed a significant decrease in sliding velocity with acetylated ACTA1 and skeletal myosin (1.709±0.210 μm/s) compared with deacetylated ACTA1 (4.427±0.275 μm/s). A similar significant decrease was also noted with cardiac myosin. Further analysis showed a significant increase in calcium sensitivity with ACTA1 acetylation (3.197x10-7 Kd compared to deacetylated ACTA1 1.191x10-6 Kd) and a loss of tropomyosin regulation with increasing ACTA1 acetylation. Lastly, ACTA1 acetylation enhanced actin binding affinity to cardiac and skeletal myosin. Investigation of attachment/detachment kinetics are currently underway. These data suggest that ACTA1 acetylation disrupts tropomyosin’s ability to inhibit myosin binding in the absence of calcium and further regulates actin-myosin interactions. Lastly, these data highlight acetylation as an additional post-translational modification outside of phosphorylation in the regulation of muscle contraction.
               
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