Glu-rich N-terminal variable region of troponin T functions as a myofilament Ca2+-reservoir to reduce SR Ca2+-cycling.

Abstract

The long Glu-rich N-terminal segment of avian pectoral muscle troponin T (TnT) and C-terminal extension of insect TnT are multi-valent Ca2+-binding sites with physiologically relevant affinities. Genetic deletion of the Glu-rich C-terminal extension of insect TnT decreases muscle and heart functions but increases the tolerance of cardiomyocytes to Ca2+ overloading, indicating decreased [Ca2+]i. In contrast, cardiomyocytes from gene-edited mice expressing modified cardiac TnT with N-terminal variable region replaced by a C-terminal segment of insect TnT (51E-cTnT) show higher shortening amplitude and contraction and relaxation velocities than that of wild type (WT) control. Isolated 51E-cTnT cardiomyocytes exhibited shorter resting sarcomeres, which can be corrected by inhibiting myosin ATPase, indicating increased resting [Ca2+]i. A similar gain-of-function model,fast skeletal muscle TnTgene-edited mice with the N-terminal variable region replaced by the N-terminal segment of adult turkey pectoral muscle TnT (Tx9-fsTnT), shows normal baseline muscle functions but slower and less rising of contractile force during caffeine-induced Ca2+ release from sarcoplasmic reticulum (SR) than that of WT control, indicating a decreased SR Ca2+ store. Consistently, 51E-cTnT mouse hearts respond to beta-adrenergic stimulation or Ca2+ agonist with higher than WT ventricular peak pressure and diastolic velocity. The data support a hypothesis that the Glu-rich segments of insect and avian flight muscle TnT function as myofilament Ca2+ reservoirs to tune muscle kinetics and reduce the amount of Ca2+ cycled during contraction and relaxation. The functional effects are prominent in heterozygotes of the genetically modified flies and mice whereas the loss-of-function in Drosophila TnT and gain-of-function in 51E-cTnT and Tx9-fsTnT mice both produced homozygote lethality, indicating sensitive dose effects of the myofilament Ca2+ reservoir for use as a potent mechanism to improve energetic efficiency of cardiac and skeletal muscles.