Abstract
Mutations in titin are responsible for many cardiac and muscle diseases, yet the underlying mechanisms remain largely unexplained. Numerous studies have established roles for titin in muscle function, and Ca2+-dependent interactions between titin and actin have been suggested to play a role in muscle contraction. The present study used co-sedimentation assays, dynamic force spectroscopy (DFS), and in vitro motility (IVM) assays to determine whether the N2A region of titin, overlooked in previous studies, interacts with actin in the presence of Ca2+. Co-sedimentation demonstrated that N2A – F-actin binding increases with increasing protein and Ca2+ concentration, DFS demonstrated increased rupture forces and decreased koff in the presence of Ca2+, and IVM demonstrated a Ca2+-dependent reduction in motility of F-actin and reconstituted thin filaments in the presence of N2A. These results indicate that Ca2+ increases the strength and stability of N2A – actin interactions, supporting the hypothesis that titin plays a regulatory role in muscle contraction. The results further support a model in which N2A – actin binding in active muscle increases titin stiffness, and that impairment of this mechanism contributes to the phenotype in muscular dystrophy with myositis. Future studies are required to determine whether titin – actin binding occurs in skeletal muscle sarcomeres in vivo.
Highlights
Titinopathies, inherited diseases caused by mutations in the titin (TTN) gene, are responsible for diverse cardiac and muscle diseases[1]
Titin constructs based on skeletal muscle titin (GenBank X90569, residues 5618–7791) exhibited only Ca2+-independent interactions with actin[17,18,19,20], and constructs based on cardiac titin (GenBank X90568) were inhibited by S100A1 when Ca2+ was present[20]
We used in vitro motility (IVM) assays to measure the effect of titin constructs on velocity of actin filaments and reconstituted thin filaments in the presence of myosin
Summary
Titinopathies, inherited diseases caused by mutations in the titin (TTN) gene, are responsible for diverse cardiac and muscle diseases[1]. Using in vitro motility and binding assays, Kellermayer and Granzier[11] found that a T2 fragment of titin (comprising the N2-line to M-line) from rabbit longissimus dorsi interacts with actin filaments and reconstituted thin filaments at pCa < 6.0. Such interactions have been suggested to increase titin stiffness in active skeletal muscle[12,13,14], this model has been slow to gain wide-spread acceptance[15]. The terminal Ig83 domain was not included in this construct[21]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
