Myotactin, A Novel Hypodermal Protein Involved in Muscle–Cell Adhesion in Caenorhabditis elegans

doi:10.1083/jcb.146.3.659

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J. Cell Biol., Volume 146, Number 3, August 9, 1999 659-672
Copyright © 1999 by The Rockefeller University Press.

Myotactin, A Novel Hypodermal Protein Involved in Muscle–Cell Adhesion in Caenorhabditis elegans

Michelle Coutu Hresko^a, Lawrence A. Schriefer^a, Paresh Shrimankar^a, and Robert H. Waterston^a
^a Department of Genetics, Washington University School of Medicine, St. Louis, Missouri 63110

Correspondence to: Michelle Coutu Hresko, Washington University School of Medicine, Department of Genetics, Box 8232, 4566 Scott Ave., St. Louis, MO 63110. Tel:(314) 362-2766 Fax:(314) 362-2985 E-mail:coutu{at}genetics.wustl.edu.

In C. elegans, assembly of hypodermal hemidesmosome-like structurescalled fibrous organelles is temporally and spatially coordinatedwith the assembly of the muscle contractile apparatus, suggestingthat signals are exchanged between these cell types to positionfibrous organelles correctly. Myotactin, a protein recognizedby monoclonal antibody MH46, is a candidate for such a signalingmolecule. The antigen, although expressed by hypodermis, firstreflects the pattern of muscle elements and only later reflectsthe pattern of fibrous organelles. Confocal microscopy showsthat in adult worms myotactin and fibrous organelles show coincidentlocalization. Further, cell ablation studies show the bodywallmuscle cells are necessary for normal myotactin distribution.To investigate myotactin's role in muscle-hypodermal signaling,we characterized the myotactin locus molecularly and genetically.Myotactin is a novel transmembrane protein of ~500 kd. The extracellulardomain contains at least 32 fibronectin type III repeats andthe cytoplasmic domain contains unique sequence. In mutantslacking myotactin, muscle cells detach when embryonic musclecontraction begins. Later in development, fibrous organellesbecome delocalized and are not restricted to regions of thehypodermis previously contacted by muscle. These results suggestmyotactin helps maintain the association between the musclecontractile apparatus and hypodermal fibrous organelles.

Key Words: Caenorhabditis elegans, cell adhesion, cell ablations, muscle,hemidesmosome-like structures

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