Inhibition by calponin of isometric force in demembranated vascular smooth muscle strips: the critical role of serine-175.

Abstract

alpha-Calponin is a thin-filament-associated protein which has been implicated in the regulation of smooth muscle contraction. Quantification of the tissue content of rat tail arterial smooth muscle revealed approximately half the amount of alpha-calponin relative to actin compared with chicken gizzard and other smooth muscles, suggesting that this tissue would be particularly suitable for investigation of the effects of exogenous alpha-calponin on the contractile properties of permeabilized muscle strips. Rat tail arterial strips demembranated with Triton X-100 retained approximately 90% of their complement of alpha-calponin, and exogenous chicken gizzard alpha-calponin (which conveniently has a slightly lower molecular mass than the rat arterial protein) bound to the permeabilized muscle, presumably through its high affinity for actin. Exogenous alpha-calponin inhibited force in demembranated muscle strips in a concentration-dependent manner when added at the peak of a submaximal Ca(2+)-induced contraction, with a half-maximal effect at approximately 3 microM alpha-calponin. Pretreatment of demembranated muscle strips with alpha-calponin inhibited subsequent force development at all concentrations of Ca2+ examined over the activation range. The inhibitory effect of alpha-calponin was shown to be Ca(2+)-independent, since exogenous alpha-calponin also inhibited force in the absence of Ca2+ in demembranated muscle strips containing thiophosphorylated myosin. Phosphorylation of alpha-calponin on Ser-175 by protein kinase C has been suggested to alleviate the inhibitory effect of alpha-calponin on smooth muscle contraction. To test this hypothesis, the effects on Ca(2+)-induced and Ca(2+)-independent contractions of demembranated muscle strips of phosphorylated alpha-calponin and three site-specific mutants of alpha-calponin (in which Ser-175 was replaced by Ala, Asp or Thr) were compared with the effects of unphosphorylated tissue-purified and recombinant wild-type alpha-calponins. The recombinant wild-type protein behaved identically to the unphosphorylated tissue-purified protein, as did the S175T mutant, which is known to bind actin with high affinity and to inhibit the actin-activated myosin MgATPase in vitro. On the other hand, phosphorylated alpha-calponin and the S175A and S175D mutants, which bind weakly to actin and have little effect on the actin-activated myosin MgATPase in vitro, failed to cause significant inhibition of force induced by Ca2+ or myosin thiophosphorylation. These results support a role for alpha-calponin in the regulation of smooth muscle contraction and indicate the functional importance of Ser-175 of alpha-calponin as a regulatory site of phosphorylation.