BACKGROUND: Titin contains a molecular spring segment that underlies passive myocardial stiffness. Myocardium coexpresses titin isoforms with molecular spring length variants and, consequently, distinct stiffness characteristics: the stiff N2B isoform (short spring) and more compliant N2BA isoform (long spring). We tested whether changes in titin isoform expression occur in the diastolic dysfunction that accompanies heart failure. METHODS AND RESULTS: We used the tachycardia-induced dilated cardiomyopathy canine model (4-week pacing) and found that control myocardium coexpresses the N2B and N2BA isoforms at similar levels, whereas in dilated cardiomyopathy the expression ratio had shifted, without affecting the amount of total titin, toward more prominent N2B expression. This shift was accompanied by elevated titin-based passive muscle stiffness. Pacing also resulted in significant upregulation of obscurin, an approximately 800-kDa elastic protein with several signaling domains. CONCLUSIONS: Coexpression of titin isoforms with distinct mechanical properties allows modulation of passive stiffness via adjustment of the isoform expression ratio. The canine pacing-induced heart failure model uses this mechanism to increase myocardial stiffness. Thus, changes in titin isoform expression may play a role in diastolic dysfunction in heart failure.
BACKGROUND:Titin contains a molecular spring segment that underlies passive myocardial stiffness. Myocardium coexpresses titin isoforms with molecular spring length variants and, consequently, distinct stiffness characteristics: the stiff N2B isoform (short spring) and more compliant N2BA isoform (long spring). We tested whether changes in titin isoform expression occur in the diastolic dysfunction that accompanies heart failure. METHODS AND RESULTS: We used the tachycardia-induced dilated cardiomyopathycanine model (4-week pacing) and found that control myocardium coexpresses the N2B and N2BA isoforms at similar levels, whereas in dilated cardiomyopathy the expression ratio had shifted, without affecting the amount of total titin, toward more prominent N2B expression. This shift was accompanied by elevated titin-based passive muscle stiffness. Pacing also resulted in significant upregulation of obscurin, an approximately 800-kDa elastic protein with several signaling domains. CONCLUSIONS: Coexpression of titin isoforms with distinct mechanical properties allows modulation of passive stiffness via adjustment of the isoform expression ratio. The canine pacing-induced heart failure model uses this mechanism to increase myocardial stiffness. Thus, changes in titin isoform expression may play a role in diastolic dysfunction in heart failure.
Authors: Felipe S Leite; Fábio C Minozzo; Albert Kalganov; Anabelle S Cornachione; Yu-Shu Cheng; Nicolae A Leu; Xuemei Han; Chandra Saripalli; John R Yates; Henk Granzier; Anna S Kashina; Dilson E Rassier Journal: Am J Physiol Cell Physiol Date: 2015-10-28 Impact factor: 4.249
Authors: Leta S Steffen; Jeffrey R Guyon; Emily D Vogel; Melanie H Howell; Yi Zhou; Gerhard J Weber; Leonard I Zon; Louis M Kunkel Journal: Dev Biol Date: 2007-06-23 Impact factor: 3.582
Authors: Marion L Greaser; Chad M Warren; Karla Esbona; Wei Guo; Yingli Duan; Amanda M Parrish; Paul R Krzesinski; Holly S Norman; Sandra Dunning; Daniel P Fitzsimons; Richard L Moss Journal: J Mol Cell Cardiol Date: 2008-02-23 Impact factor: 5.000