Abstract 9026: Endogenous Ca2+/Calmodulin-Dependent Protein Kinase II Overactivation Exacerbates Cardiac Dysfunction and Beta-Adrenergic Desensitization in a Mouse Model With Type 2 Diabetes

Abstract

Background: Emergent evidence indicates that CaMKII overactivity in diabetes (DM) plays a crucial role in the pathophysiology of diabetic cardiomyopathy (DCM) by targeting a diverse array of proteins involved in cardiac electrical, structural and functional remodeling. CaMKII has been proposed to be a therapeutic target for DCM. However, although chronic inhibition of CaMKII has been associated with cardioprotection in several cardiovascular diseases, the direct cardiac effects of CaMKII activation in type 2 (T2) DM are unclear. Moreover, whether and how DCM alters cardiac responses to CaMKII are undefined. We tested the hypothesis that in DCM, CaMKII is upregulated, which alters cardiac contractile behavior. Endogenous CaMKII activation may produce direct depressions in LV myocyte basal function and β-adrenergic reserve. Acute inactivation of CaMKII with KN93 would have a beneficial impact in DCM. Methods: LV myocyte CaMKIIδ expression and activity and myocyte functional responses were compared in 2 groups (n=9/group) of wild-type female mice: Vehicle Control (C) , animals fed chow for 14 weeks (W); T2DM, i nduced with a high-fat diet (HFD) intake for 14 W, but after fed HFD for 4 W receiving streptozotocin (STZ, 40 mg/kg/day, i.p. for 5 days). In T2DM, we further assessed myocyte contractile and [Ca 2+ ] i transient ([Ca 2+ ] iT ) responses with and without acute treatment of myocytes with KN93 (10 -6 M, 30 min). Results: Versus C, in T2DM myocytes, the CaMKIIδ protein levels (28%, 0.51 vs 0.40) and CaMKIIδ phosphorylation (79%, 0.52 vs 0.29) were significantly increased. These changes were followed by significantly reduced cell contraction (dL/dt max , 76.0 vs 137.3 μm/s), relaxation (dR/dt max , 61.7 vs 116.0 μm/s) and [Ca 2+ ] iT (0.16 vs 0.21). ISO-stimulated increases dL/dt max (39% vs 58%), dR/dt max (35% vs 54%) and [Ca 2+ ] iT (20% vs 30%) were also significantly reduced. Moreover, in T2DM myocytes, superfusion with KN93 significantly improved myocyte basal contraction (104.2 μm/s), relaxation (79.3 μm/s) and [Ca 2+ ] iT (0.21). Conclusions: In T2 diabetes-induced DCM, upregulation of CaMKIIδ has adverse functional effects. Acute endogenous CaMKII activation exacerbates LV myocyte dysfunction. The inhibition of CaMKII has a significant beneficial impact.