Mechanical responses of the mechanosensitive unstructured domains in cardiac titin.

BACKGROUND INFORMATION: Titin is one of the three main filaments in cardiac sarcomere. Besides a chain of Ig domains, cardiac titin also contains a proline (P), glutamate (E), valine (V), lysine (K) (PEVK) domain and a cardiac-specific N2B domain, both are largely unstructured. While they are believed to be involved in the elastic (PEVK and N2B) and the trophic (N2B) functions of the heart, their mechanical responses in physiological level of forces remains poorly understood. RESULTS: In order to gain understanding on their mechanical responses, we used magnetic tweezers to investigate their force responses from 1 to 30 pN. We confirmed that in vitro the PEVK domain is intrinsically disordered within the force range. Surprisingly, we discovered a mechanosensitive folded element in the disordered region of N2B, ∼84 amino acids in length, which has a large folding energy of approximately -10 kB T. Based on the force responses of PEVK and N2B domains, as well as an approximated force-dependent unfolding and refolding rates of titin Ig domains, we show that the tension in cardiac titin fluctuates within 5 pN during cardiac contraction and extension cycle using Gillespie simulation algorithm. Exceptionally, the simulation shows that deletion of N2B domain results in 10-fold increase in peak force. CONCLUSION: Our results highlight a critical role that N2B may potentially play in regulating tension on cardiac titin. SIGNIFICANCE: The study provides new insights into the tension regulatory role of unstructured domains in the elastic function of the heart, which has broad implication in diastolic dysfunction and cardiac trophic mechanisms. In addition, the method can be applied to probing other unstructured mechanosensitive proteins/domains.

Mechanical stability of αT-catenin and its activation by force for vinculin binding.

αT (Testes)-catenin, a critical factor regulating cell-cell adhesion in the heart, directly couples the cadherin-catenin complex to the actin cytoskeleton at the intercalated disk (ICD), a unique cell-cell junction that couples cardiomyocytes. Loss of αT-catenin in mice reduces plakophilin2 and connexin 43 recruitment to the ICD. Since αT-catenin is subjected to mechanical stretch during actomyosin contraction in cardiomyocytes, its activity could be regulated by mechanical force. To provide insight in how force regulates αT-catenin function, we investigated the mechanical stability of the putative, force-sensing middle (M) domain of αT-catenin and determined how force impacts vinculin binding to αT-catenin. We show that 1) physiological levels of force, <15 pN, are sufficient to unfold the three M domains; 2) the M1 domain that harbors the vinculin-binding site is unfolded at ∼6 pN; and 3) unfolding of the M1 domain is necessary for high-affinity vinculin binding. In addition, we quantified the binding kinetics and affinity of vinculin to the mechanically exposed binding site in M1 and observed that αT-catenin binds vinculin with low nanomolar affinity. These results provide important new insights into the mechanosensing properties of αT-catenin and how αT-catenin regulates cell-cell adhesion at the cardiomyocyte ICD.