Dyad content is reduced in cardiac myocytes of mice with impaired calmodulin regulation of RyR2.

In cardiac muscle, calmodulin (CaM) regulates the activity of several membrane proteins involved in Ca(2+) homeostasis (CaV1.2; RyR2, SERCA2, PMCA). Three engineered amino acid substitutions in the CaM binding site of the cardiac ryanodine receptor (RyR2) in mice (Ryr2 (ADA/ADA) ) strongly affect cardiac function, with impaired CaM inhibition of RyR2, reduced SR Ca(2+) sequestration, and early cardiac hypertrophy and death (Yamaguchi et al., J Clin Invest 117:1344-1353, 2007). We have examined the ultrastructure and RyR2 immunolocalization in WT and Ryr2 (ADA/ADA) hearts at ~10 days after birth. The myocytes show only minor evidence of structural damage: some increase in intermyofibrillar space, with occasional areas of irregular SR disposition and an increase in frequency of smaller myofibrils, despite an increase of about 15 % in average myocyte cross sectional area. Z line streaming, a sign of myofibrillar stress, is limited and fairly rare. Immunolabeling with an anti-RyR2 antibody shows that RyR-positive foci located at the level of the Z lines are less frequent in mutant hearts. A dramatic decrease in the frequency and size of dyads, accompanied by a decrease in occupancy of the gap by RyR2, but without obvious alterations in location and general structure is a notable ultrastructural feature. The data suggest that the uneven distribution of dyads or calcium release sites within the cells resulting from an overall reduction in RyR2 content may contribute to the poor cardiac performance and early death of Ryr2 (ADA/ADA) mice. An unusual fragmentation of mitochondria, perhaps related to imbalances in free cytoplasmic calcium levels, accompanies these changes.

Overexpression of junctophilin-2 does not enhance baseline function but attenuates heart failure development after cardiac stress.

Heart failure is accompanied by a loss of the orderly disposition of transverse (T)-tubules and a decrease of their associations with the junctional sarcoplasmic reticulum (jSR). Junctophilin-2 (JP2) is a structural protein responsible for jSR/T-tubule docking. Animal models of cardiac stresses demonstrate that down-regulation of JP2 contributes to T-tubule disorganization, loss of excitation-contraction coupling, and heart failure development. Our objective was to determine whether JP2 overexpression attenuates stress-induced T-tubule disorganization and protects against heart failure progression. We therefore generated transgenic mice with cardiac-specific JP2 overexpression (JP2-OE). Baseline cardiac function and Ca(2+) handling properties were similar between JP2-OE and control mice. However, JP2-OE mice displayed a significant increase in the junctional coupling area between T-tubules and the SR and an elevated expression of the Na(+)/Ca(2+) exchanger, although other excitation-contraction coupling protein levels were not significantly changed. Despite similar cardiac function at baseline, overexpression of JP2 provided significantly protective benefits after pressure overload. This was accompanied by a decreased percentage of surviving mice that developed heart failure, as well as preservation of T-tubule network integrity in both the left and right ventricles. Taken together, these data suggest that strategies to maintain JP2 levels can prevent the progression from hypertrophy to heart failure.