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Graded titin cleavage progressively reduces tension and uncovers the source of A-band stability in contracting muscle

Yong Li, Anthony L. Hessel, Andreas Unger, David Ing, Jannik Recker, Franziska Koser, Johanna K. Freundt, Wolfgang A. Linke

2020eLife52 citationsDOIOpen Access PDF

Abstract

The giant muscle protein titin is a major contributor to passive force; however, its role in active force generation is unresolved. Here, we use a novel titin-cleavage (TC) mouse model that allows specific and rapid cutting of elastic titin to quantify how titin-based forces define myocyte ultrastructure and mechanics. We show that under mechanical strain, as TC doubles from heterozygous to homozygous TC muscles, Z-disks become increasingly out of register while passive and active forces are reduced. Interactions of elastic titin with sarcomeric actin filaments are revealed. Strikingly, when titin-cleaved muscles contract, myosin-containing A-bands become split and adjacent myosin filaments move in opposite directions while also shedding myosins. This establishes intact titin filaments as critical force-transmission networks, buffering the forces observed by myosin filaments during contraction. To perform this function, elastic titin must change stiffness or extensible length, unveiling its fundamental role as an activation-dependent spring in contracting muscle.

Topics & Concepts

TitinMyosinSarcomereBiophysicsActinMuscle contractionChemistryMyosin light-chain kinaseProtein filamentMyofibrilObscurinCleavage (geology)MyocyteAnatomyCell biologyMaterials scienceBiologyBiochemistryComposite materialFracture (geology)Cardiomyopathy and Myosin StudiesForce Microscopy Techniques and ApplicationsMuscle Physiology and Disorders
Graded titin cleavage progressively reduces tension and uncovers the source of A-band stability in contracting muscle | Litcius