ABSTRACT''Catch'' is a condition of prolonged, highforce maintenance at resting intracellular Ca 2؉ concentration ([Ca 2؉ ]) and very low energy usage, occurring in invertebrate smooth muscles, including the anterior byssus retractor muscle (ABRM) of Mytilus edulis. Relaxation from catch is rapid on serotonergic nerve stimulation in intact muscles and application of cAMP in permeabilized muscles. This release of catch occurs by protein kinase A-mediated phosphorylation of a high (Ϸ600 kDa) molecular mass protein, the regulator of catch. Here, we identify the catch-regulating protein as a homologue of the mini-titin, twitchin, based on (i) a partial cDNA of the purified isolated protein showing 77% amino acid sequence identity to the kinase domain of Aplysia californica twitchin; (ii) a polyclonal antibody to a synthetic peptide in this sequence reacting with the phosphorylated catchregulating protein band from permeabilized ABRM; and (iii) the similarity of the amino acid composition and molecular weight of the protein to twitchin. In permeabilized ABRM, at all but maximum [Ca 2؉ ], phosphorylation of twitchin results in a decreased calcium sensitivity of force production (halfmaximum at 2.5 vs. 1.3 M calcium). At a given submaximal force, with equal numbers of force generators, twitchin phosphorylation increased unloaded shortening velocity Ϸ2-fold. These data suggest that aspects of the catch state exist not only at resting [Ca 2؉ ], but also at higher submaximal [Ca 2؉ ]. The mechanism that gives rise to force maintenance in catch probably operates together, to some extent, with that of cycling myosin crossbridges.Isometric force production in the anterior byssus retractor muscle (ABRM) of Mytilus edulis, initiated by cholinergic nerve stimulation, is maintained for a prolonged period of time after cessation of stimulation. This condition, during which relaxation of force occurs at an extremely slow rate, lasting minutes, or even hours, has been termed ''catch.'' When catch occurs, the intracellular Ca 2ϩ concentration ([Ca 2ϩ ]), which was transiently elevated as a result of the stimulus, has declined to near-resting levels (1, 2). In this invertebrate smooth muscle, calcium activates contraction by direct binding to myosin (3, 4), and its subsequent removal establishes the catch state (5). The catch state is characterized by a marked slowing of crossbridge cycling rate, measured as energy usage (6-8) and mechanical behavior such as force-velocity relations and force redevelopment after a quick release (9-12). Catch exemplifies the high economy of smooth muscle: the ability to maintain force with a low expenditure of energy. In the ABRM, rapid relaxation, or release of catch, occurs on stimulation of serotonergic nerves, a response that is mediated by an increase in cellular cAMP and the activation of protein kinase A (13, 14).We have shown that the catch state is regulated by the cAMP-dependent phosphorylation of a high molecular mass (Ϸ600 kDa) protein in the intact and permeabilized ABRM (15). Seve...
Molluscan smooth muscle can maintain tension over extended periods with little energy expenditure, a process termed catch. Catch is thought to be regulated by phosphorylation of a thick filament protein, twitchin, and involves two phosphorylation sites, D1 and D2, close to the N and C termini, respectively. This study was initiated to investigate the role of the D2 site and its phosphorylation in the catch mechanism. A peptide was constructed containing the D2 site and flanking immunoglobulin (Ig) motifs. It was shown that the dephosphorylated peptide, but not the phosphorylated form, bound to both actin and myosin. The binding site on actin was within the sequence L10 to P29. This region also binds to loop 2 of the myosin head. The dephosphorylated peptide linked myosin and F-actin and formed a trimeric complex. Electron microscopy revealed that twitchin is distributed on the surface of the thick filament with an axial periodicity of 36.25·nm and it is suggested that the D2 site aligns with the myosin heads. It is proposed that the complex formed with the dephosphorylated D2 site of twitchin, F-actin and myosin represents a component of the mechanical linkage in catch.
Catch in certain molluscan muscles is released by an increase in cAMP, and it was suggested that the target of cAMP-dependent protein kinase (PKA) is the high molecular weight protein twitchin [Siegman, M. J., Funabara, J., Kinoshita, S., Watabe, S., Hartshorne, D. J., and Butler, T. M. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 5384-5388]. This study was carried out to investigate the phosphorylation of twitchin by PKA. Twitchin was isolated from Mytilus catch muscles and was phosphorylated by PKA to a stoichiometry of about 3 mol of P/mol of twitchin. There was no evidence of twitchin autophosphorylation. Two phosphorylated peptides were isolated and sequenced, termed D1 and D2. Additional cDNA sequence for twitchin was obtained, and the D2 site was located at the C-terminal side of the putative kinase domain in a linker region between two immunoglobulin C2 repeats. Excess PKA substrates, e.g., D1 and D2, blocked the reduction in force on addition of cAMP, confirming the role for PKA in regulating catch. Papain proteolysis of (32)P-labeled twitchin from permeabilized muscles showed that the D1 site represented about 50% of the (32)P labeling. Proteolysis of in-situ twitchin with thermolysin suggested that the D1 and D2 sites were at the N- and C-terminal ends of the molecule, respectively. Thermolysin proteolysis also indicated that D1 and D2 were major sites of phosphorylation by PKA. The direct phosphorylation of twitchin by PKA is consistent with a regulatory role for twitchin in the catch mechanism and probably involves phosphorylation at the D1 and D2 sites.
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