eLife (Dec 2020)

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

DOI
https://doi.org/10.7554/eLife.64107
Journal volume & issue
Vol. 9

Abstract

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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.

Keywords