Underlying mechanism of the contractile dysfunction in atrophied ventricular myocytes from a murine model of hypothyroidism

[Display omitted] •Within 3 weeks, hypothyroidism induced cardiac atrophy and contractile dysfunction.•Blunted contractility was accompanied by slow SERCA due to reduced SERCA/PLB ratio.•Staggered and blunted calcium transients and diminished diastolic calcium leak.•Ventricular T-tubules, mitochondrial density and ATP availability were unchanged.•Diminished calcium-dependent RyR2 sensitivity desynchronizes systolic SR release. Hypothyroidism (Hypo) is a risk factor for cardiovascular diseases, including heart failure. Hypo rapidly induces Ca2+ mishandling and contractile dysfunction (CD), as well as atrophy and ventricular myocytes (VM) remodeling. Hypo decreases SERCA-to-phospholamban ratio (SERCA/PLB), and thereby contributes to CD. Nevertheless, detailed spatial and temporal Ca2+ cycling characterization in VM is missing, and contribution of other structural and functional changes to the mechanism underlying Ca2+ mishandling and CD, as transverse tubules (T-T) remodeling, mitochondrial density (Dmit) and energy availability, is unclear. Therefore, in a rat model of Hypo, we aimed to characterize systolic and diastolic Ca2+ signaling, T-T remodeling, Dmit, citrate synthase (CS) activity and high-energy phosphate metabolites (ATP and phosphocreatine). We confirmed a decrease in SERCA/PLB (59%), which slowed SERCA activity (48%), reduced SR Ca2+ (19%) and blunted Ca2+ transient amplitude (41%). Moreover, assessing the rate of SR Ca2+ release (dRel/dt), we found that early and maximum dRel/dt decreased, and this correlated with staggered Ca2+ transients. However, dRel/dt persisted during Ca2+ transient relaxation due to abundant late Ca2+ sparks. Isoproterenol significantly up-regulated systolic Ca2+ cycling. T-T were unchanged, hence, cannot explain staggered Ca2+ transients and altered dRel/dt. Therefore, we suggest that these might be caused by RyR2 clusters desynchronization, due to diminished Ca2+-dependent sensitivity of RyR2, which also caused a decrease in diastolic SR Ca2+ leak. Furthermore, Dmit was unchanged and CS activity slightly decreased (14%), however, the ratio phosphocreatine/ATP did not change, therefore, energy deficiency cannot account for Ca2+ and contractility dysregulation. We conclude that decreased SR Ca2+, due to slower SERCA, disrupts systolic RyR2 synchronization, and this underlies CD.