Game of Zones: how actin-binding proteins organize muscle contraction

Locomotion of C. elegans requires coordinated, efficient transmission of forces generated on the molecular scale by myosin and actin filaments in myocytes to dense bodies and the hypodermis and cuticle enveloping body wall muscles. The complex organization of the acto-myosin scaffold with its access...

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Bibliographic Details
Published in:Worm (Austin, TX) TX), 2016-04, Vol.5 (2), p.e1161880-e1161880
Main Authors: Butkevich, Eugenia, Klopfenstein, Dieter R., Schmidt, Christoph F.
Format: Article
Language:English
Subjects:
actin bundling
actin organization
actin-binding proteins
Drebrin-like proteins
muscle
myosin
sarcomere organization
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Summary:Locomotion of C. elegans requires coordinated, efficient transmission of forces generated on the molecular scale by myosin and actin filaments in myocytes to dense bodies and the hypodermis and cuticle enveloping body wall muscles. The complex organization of the acto-myosin scaffold with its accessory proteins provides a fine-tuned machinery regulated by effectors that guarantees that sarcomere units undergo controlled, reversible cycles of contraction and relaxation. Actin filaments in sarcomeres dynamically undergo polymerization and depolymerization. In a recent study, the actin-binding protein DBN-1, the C. elegans ortholog of human drebrin and drebrin-like proteins, was discovered to stabilize actin in muscle cells. DBN-1 reversibly changes location between actin filaments and myosin-rich regions during muscle contraction. Mutations in DBN-1 result in mislocalization of other actin-binding proteins. Here we discuss implications of this finding for the regulation of sarcomere actin stability and the organization of other actin-binding proteins.
ISSN:2162-4046
2162-4054
2162-4054
DOI:10.1080/21624054.2016.1161880