Background: The rising incidence of obesity and metabolic syndrome in the US has profound implications for the pathology of heart disease in coming years. Excessive fat and sugar intake is linked to elevated acetyl-CoA, which in turn is linked to protein acetylation. Although an increasing body of work has determined that non-nuclear lysine acetylation can alter the activity and stability of key proteins involved in cardiac health, the impact of acetylation on calcium handling sarcoplasmic reticulum (SR) proteins, particularly the SERCA2a regulator phospholamban, remains poorly understood. Hypothesis: Metabolic dysregulation and obesity lead to the acetylation of phospholamban, relieving its inhibition on SERCA2a and increasing calcium uptake into the SR. APPROACH: C57BL/6J Mice were subjected to high fat diet-induced obesity (DIO). Left ventricle (LV) tissue was collected and analyzed using immunoblotting and acetylation was quantified by immunoprecipitation with acetyl-lysine antibodies. Human LV tissue from control and diabetic patients was similarly processed and evaluated. Adult ventricular cardiomyocytes were isolated from DIO and control mice, and DIO cells were incubated in media containing excess lipid substrates (1% Lipid Mix 1, Millipore Sigma) and acutely administered HDAC activator ITSA-1 to promote deacetylation. Changes in stimulated calcium dynamics were assessed using Fura-2AM and Fluo-4AM imaging. Results: Phospholamban acetylation significantly increased in LV tissue from both DIO mice (p=0.003) and human diabetic patients (p=0.034) compared to their respective controls. Primary cardiomyocytes isolated from DIO mice and incubated for 24hrs in a high-fat environment exhibited increased calcium transient amplitude and reuptake time (tau) into the SR, while incubation with pan HDAC activators significantly reduced these parameters (p=0.0004, and p=0.003 respectively). Conclusions: Obesity increases the acetylation of phospholamban and enhances the reuptake of calcium into the SR, while deacetylation reverses these effects. These data directly tie nutritive status to a novel phospholamban post-translational modification that may directly impact myocardial calcium handling and contractile function.