Titin activates myosin filaments in skeletal muscle by switching from an extensible spring to a mechanical rectifier.
Caterina SquarciPasquale BiancoMassimo ReconditiIrene PerticiMarco CaremaniTheyencheri NarayananÁdám I HorváthAndrás Málnási-CsizmadiaMarco LinariVincenzo LombardiGabriella PiazzesiPublished in: Proceedings of the National Academy of Sciences of the United States of America (2023)
Titin is a molecular spring in parallel with myosin motors in each muscle half-sarcomere, responsible for passive force development at sarcomere length (SL) above the physiological range (>2.7 μm). The role of titin at physiological SL is unclear and is investigated here in single intact muscle cells of the frog ( Rana esculenta ), by combining half-sarcomere mechanics and synchrotron X-ray diffraction in the presence of 20 μM para-nitro-blebbistatin, which abolishes the activity of myosin motors and maintains them in the resting state even during activation of the cell by electrical stimulation. We show that, during cell activation at physiological SL, titin in the I-band switches from an SL-dependent extensible spring (OFF-state) to an SL-independent rectifier (ON-state) that allows free shortening while resisting stretch with an effective stiffness of ~3 pN nm -1 per half-thick filament. In this way, I-band titin efficiently transmits any load increase to the myosin filament in the A-band. Small-angle X-ray diffraction signals reveal that, with I-band titin ON, the periodic interactions of A-band titin with myosin motors alter their resting disposition in a load-dependent manner, biasing the azimuthal orientation of the motors toward actin. This work sets the stage for future investigations on scaffold and mechanosensing-based signaling functions of titin in health and disease.
Keyphrases
- skeletal muscle
- binding protein
- resting state
- functional connectivity
- single cell
- high resolution
- public health
- cell therapy
- induced apoptosis
- single molecule
- spinal cord injury
- heart rate
- insulin resistance
- stem cells
- mental health
- blood pressure
- metabolic syndrome
- risk assessment
- heart rate variability
- magnetic resonance
- adipose tissue
- gene expression
- dna methylation
- climate change
- signaling pathway
- contrast enhanced