Non-histone post-translational modifications (PTMs) are an increasingly important area of study that contribute to our understanding for protein function in the control of health and disease. Protein PTMs, such as acetylation, are emerging as key regulators of striated muscle function, yet our understanding of how non-histone protein acetylation affects muscle physiology remains fragmentary. Previous reports from our lab identified lysine (K) 52 of skeletal muscle alpha actin (ACTA1) to be acetylated, yet no reports have shown a role for ACTA1 acetylation in muscle function. Act88F is 93% homologous to ACTA1 and K50 is identical to K52 of ACTA1. Thus, for these studies, we mutated K50 with a glutamine (Q) on the Act88F gene in the indirect flight muscle (IFM) of Drosophila to mimic acetylation. We examined physiological function (i.e. flight and climbing) as well as biophysical changes between acetylated Act88F and the associated myofibrillar proteins involved in contraction and relaxation (myosin, tropomyosin, and troponin). We report that Act88F K50Q pseudo-acetylation resulted in a flightless phenotype and decreased climbing ability. In addition, we report that Act88F K50Q flies had increased IFM damage as examined via fluorescent imaging. Interestingly, Act88F K50Q did not change actin-myosin binding, actin sliding velocity, or Ca2+ sensitivity in actin-motility assays. However, Act88F pseudo-acetylation did decrease actin filament length, but only after interacting with myosin, implying that Act88F acetylation increases actin filament breaking. These data suggest that Act88F acetylation at K50 worsens muscle function by destabilizing filamentous actin, resulting in muscle tearing and damage to the IFM, which results in loss of flight. This work suggests that actin acetylation, at least on lysine 50, in response to environmental stressors or diet could greatly change muscle function and sarcomere integrity.