Overexpression of tropomodulin in neonatal rat cardiomyocytes shortened actin filaments and caused myofibril degeneration, while decreased content formed abnormally long actin filament bundles.
Regulated tropomodulin expression is essential for maintaining stabilized actin filament structures and sarcomeric organization in cardiomyocytes.
Tropomodulin is a tropomyosin-binding protein that terminates "pointed-end" actin filament polymerization. To test the hypothesis that regulation of tropomodulin:actin filament stoichiometry is critical for maintenance of actin filament length, tropomodulin levels were altered in cells by infection with recombinant adenoviral expression vectors, which produce either sense or antisense tropomodulin mRNA. Neonatal rat cardiomyocytes were infected, and sarcomeric actin filament organization was examined. Confocal microscopy indicated that overexpression of tropomodulin protein shortened actin filaments and caused myofibril degeneration. In contrast, decreased tropomodulin content resulted in the formation of abnormally long actin filament bundles. Despite changes in myofibril structure caused by altered tropomodulin expression, total protein turnover of the cardiomyocytes was unaffected. Biochemical analyses of infected cardiomyocytes indicated that changes in actin distribution, rather than altered actin content, accounted for myofibril reorganization. Ultrastructural analysis showed thin-filament disarray and revealed the presence of leptomeres after tropomodulin overexpression. Tropomodulin-mediated effects constitute a novel mechanism to control actin filaments, and our findings demonstrate that regulated tropomodulin expression is necessary to maintain stabilized actin filament structures in cardiac muscle cells.
Sussman et al. (Fri,) conducted a other in Sarcomeric structure of myofibrils. Altered tropomodulin expression via recombinant adenoviral expression vectors was evaluated on Sarcomeric actin filament organization and myofibril structure. Overexpression of tropomodulin in neonatal rat cardiomyocytes shortened actin filaments and caused myofibril degeneration, while decreased content formed abnormally long actin filament bundles.