Endothelin-1 Alters the Contractile Phenotype of Cultured Embryonic Smooth Muscle Cells

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Circulation Research. 1997;80:885-893

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(Circulation Research. 1997;80:885-893.)
© 1997 American Heart Association, Inc.

Articles

Endothelin-1 Alters the Contractile Phenotype of Cultured Embryonic Smooth Muscle Cells

Steven A. Fisher, Mitsuo Ikebe, , Frank Brozovich

From the Department of Medicine (S.A.F., F.B.), Division of Cardiology and Molecular Cardiovascular Research Center, and the Department of Physiology and Biophysics (S.A.F., M.I., F.B.), Case Western Reserve University School of Medicine, Cleveland, Ohio.

Correspondence to Steven A. Fisher, Division of Cardiology, University Hospitals, 11100 Euclid Ave, Cleveland, OH 44106-5038. E-mail saf9{at}po.cwru.edu

Abstract Smooth muscle tissues may be classified into phasic (fast)or tonic (slow) contractile phenotypes. This study was initiatedto examine the specification of these phenotypes during developmentand the role of growth factors in this process. We used myosinlight chain 17 (MLC₁₇) and myosin heavy chain transcript splicevariants as markers of the tonic (aortic) and phasic (intestinal)smooth muscle phenotypes in chick embryos. By reverse transcription–polymerasechain reaction, we determined embryonic days 6 to 16 to be acritical period for the establishment of these phenotypes. Duringthis period, endothelin-1 is present at 40-fold-higher levelsin aortic compared with intestinal tissues. To test the hypothesisthat endothelin-1 may be involved in establishing the aortic(tonic) phenotype, we developed a system in which embryonicsmooth muscle cells exhibit phasic and tonic contractile propertiesin vitro. Single-cell force measurements showed that culturedembryonic gizzard (phasic) cells developed force more rapidly(8±2 seconds) and achieved greater force (3.0±0.7µN) than did cultured embryonic aortic (tonic) cells (20±0.7seconds, 0.76±0.01 µN; P<.05) in response todepolarization. Chronic exposure of the phasic (gizzard) cellsto endothelin-1 prolonged the time to peak force (24±3seconds) and reduced the peak force (1.0±0.1 µN),so that the contraction resembled the tonic type. This effect,mediated by the endothelin-A receptor, was associated with ashift in MLC₁₇ splicing to the tonic pattern. These resultsdemonstrate that endothelin-1 is highly enriched in developingaortic compared with intestinal tissues and can convert phasicsmooth muscle cells to the tonic type in vitro, suggesting a rolefor this growth factor during development in determining the contractilephenotype of smooth muscle cells.

Key Words: smooth muscle phenotype • phasic and tonic contraction • endothelin-1 • myosin isoform • development

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				S. Shukla, W. P. Dirksen, K. M. Joyce, C. Le Guiner-Blanvillain, R. Breathnach, and S. A. Fisher TIA Proteins Are Necessary but Not Sufficient for the Tissue-specific Splicing of the Myosin Phosphatase Targeting Subunit 1 J. Biol. Chem., April 2, 2004; 279(14): 13668 - 13676. [Abstract] [Full Text] [PDF]

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				Q.-Q. Huang, S. A. Fisher, and F. V. Brozovich Forced Expression of Essential Myosin Light Chain Isoforms Demonstrates Their Role in Smooth Muscle Force Production J. Biol. Chem., December 3, 1999; 274(49): 35095 - 35098. [Abstract] [Full Text] [PDF]

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