Mechanical Tension and Spontaneous Muscle Twitching Precede the Formation of Cross-striated Muscle

Overview

Journal Development

Specialty Biology

Date 2017 Feb 9

PMID 28174246

Citations 26

Authors

Manuela Weitkunat

Martina Brasse

Andreas R Bausch

Frank Schnorrer

Affiliations

Soon will be listed here.

Abstract

Muscle forces are produced by repeated stereotypical actomyosin units called sarcomeres. Sarcomeres are chained into linear myofibrils spanning the entire muscle fiber. In mammalian body muscles, myofibrils are aligned laterally, resulting in their typical cross-striated morphology. Despite this detailed textbook knowledge about the adult muscle structure, it is still unclear how cross-striated myofibrils are built Here, we investigate the morphogenesis of abdominal muscles and establish them as an model for cross-striated muscle development. By performing live imaging, we find that long immature myofibrils lacking a periodic actomyosin pattern are built simultaneously in the entire muscle fiber and then align laterally to give mature cross-striated myofibrils. Interestingly, laser micro-lesion experiments demonstrate that mechanical tension precedes the formation of the immature myofibrils. Moreover, these immature myofibrils do generate spontaneous Ca-dependent contractions , which, when chemically blocked, result in cross-striation defects. Taken together, these results suggest a myofibrillogenesis model in which mechanical tension and spontaneous muscle twitching synchronize the simultaneous self-organization of different sarcomeric protein complexes to build highly regular cross-striated myofibrils spanning the length of large muscle fibers.

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