Calponin-Like Protein from Mussel Smooth Muscle Is a Competitive Inhibitor of Actomyosin ATPase.

The goal of this work was to elucidate the mechanism of inhibition of the actin-activated ATPase of myosin subfragment-1 (S1) by the calponin-like protein from mussel bivalve muscle. The calponin-like protein (Cap) is a 40-kDa actin-binding protein from the bivalve muscle of the mussel Crenomytilus grayanus. Kinetic parameters Vmax and KATPase of actomyosin ATPase in the absence and the presence of Cap were determined to investigate the mechanism of inhibition. It was found that Cap mainly causes increase in KATPase value and to a lesser extent the decrease in Vmax, which indicates that it is most likely a competitive inhibitor of actomyosin ATPase. Analysis of Vmax and KATPase parameters in the presence of tropomyosin revealed that the latter is a noncompetitive inhibitor of the actomyosin ATPase.

[Modulation of S-1 conformation and inhibition of the skeletal muscle S-1-ATPase by calponin of the mussel].

A novel 40 kDa protein has been detected in native thin filaments from catch muscles of the mussel Crenomytilus grayanus. In this study, using skeletal muscle actin and S-1, we investigated the effects of the mussel 40-kDa actin-binding protein on the acto · S-1 ATPase activity. On increasing the 40-kDa actin-binding protein (CaP-40) concentration, the actin-activated ATPase activity decreased, and was inhibited 80% at a CaP-40 to actin ratio of 0.5. Polarized fluorimetry technique and glycerinated muscle fibers were used to study effects of CaP-40 on the orientation and mobility of fluorescent label 1.5-IAEDANS specifically bound to CyS-707 of myosin subfragment-1 in the absence of nucleotide, and in the presence of MgADP or MgATP. We have concluded that CaP-40 binding to actin affects the strong binding of myosin to actin but has no effect on the weak binding. Thus, the influence of the CaP-40 on the formation of strong actomyosin binding forms A · M and A · M · ADP manifests itself by a decrease in the relative content of myosin cross-bridges strongly bound with actin, which probably results in a decrease in the relative content of "switch on" actin monomers in thin filaments. This suggests that, as calponin CaP-40 selects its target the phase of strong actomyosin binding binding which preceded by a phase generating power stroke.

40-kDa protein from thin filaments of the mussel Crenomytilus grayanus changes the conformation of F-actin during the ATPase cycle.

Polarized fluorimetry was used to study in ghost muscle fibers the influence of a 40-kDa protein from the thin filaments of the mussel Crenomytilus grayanus on conformational changes of F-actin modified by the fluorescent probes 1,5-IAEDANS and FITC-phalloidin during myosin subfragment (S1) binding in the absence of nucleotides and in the presence of MgADP or MgATP. The fluorescence probes were rigidly bound with actin, which made the absorption and emission dipoles of the probes sensitive to changes in the orientation and mobility of both actin monomer and its subdomain-1 in thin filaments of the muscle fiber. On modeling different intermediate states of actomyosin, the orientation and mobility of oscillators of the dyes were changed discretely, which suggests multistep changes in the actin conformation during the cycle of ATP hydrolysis. The 40-kDa protein influenced the orientation and mobility of the fluorescent probes markedly, suppressing changes in their orientation and mobility in the absence of nucleotides and in the presence of MgADP, but enhancing these changes in the presence of MgATP. The calponin-like 40-kDa protein is supposed to prevent formation of the strong binding state of actomyosin in the absence of nucleotides and in the presence of MgADP but to activate formation of this state in the presence of MgATP.

40-kDa actin-binding protein of thin filaments of the mussel Crenomytilus grayanus inhibits the strong bond formation between actin and myosin head during the ATPase cycle.

Mobility and spatial orientation of a novel 40-kDa actin-binding protein from the smooth muscle of the mussel Crenomytilus grayanus was studied by polarized fluorometry. The influence of this protein on orientation and mobility of the myosin heads was investigated during modeling the different stages of the ATPase cycle. The 40-kDa actin-binding protein affected the strong actin-myosin binding. We suggest that the 40-kDa actin-binding protein is involved in regulation of the actin-myosin interaction in the smooth muscle of the mussel.

[Expression of several domains of twitchin and myorod in the ontogenesis of mussel Mytilus trossulus].

The expression of MLCK- and PEVK-domains of twitchin, as well as the unique N-terminal domain of myorod in early development of the mussel Mytilus trossulus has been studied. The MLCK-domain of twitchin and the unique N-terminal domain of myorod appear at the early stages of development, whereas the PEVK-domain of twitchin is present only in muscles of adult mussel. The sizes of genes of the N-terminal domain of myorod, obtained at the blastula stage and from the adult animal are similar, but the proteins have significant differences in the amino acid sequences. Consequently, myorod and twitchin appear at early stages of larval mussels before the formation of "adult" muscles capable of catch contraction, and at these stages both proteins are isoforms, which differ from the isoforms of adult animals. It is possible that the MLCK-domain in the "larval" isoform of twitchin is necessary for regulating the formation of the contractile apparatus of molluscan smooth muscles, while the PEVK-domain is important for the regulation of the catch state in muscles of adult animals.

[Thin filaments of molluscan catch muscles contain a calponin-like protein].

A novel 40 kDa protein was detected in native thin filaments from catch muscles of the mussel Crenomytilus grayanus. The MALDY-TOF analysis of the protein showed a 40% homology with the calponin-like protein from the muscle of Mytilus galloprovincialis (45 kDa), which has a 36% homology with smooth muscle calponin from chicken gizzard (34 kDa). The amount of the calponin-like protein in thin filaments depends on isolation conditions and varies from the complete absence to the presence in amounts comparable with that of tropomyosin. The most significant factor that determines the contact of the protein in thin filaments is the temperature of solution in which thin filaments are sedimented by ultracentrifugation during isolation. At 22 degrees C and optimal values of both pH and ionic strength of the extraction solution, total calponin-like protein coprecipitates with thin filaments. At 2 degrees C it remains in the supernatant. The 40 kDa calponin-like protein from the mussel Crenomytilus grayanus has similar properties with smooth muscle calponin (34 kDa). It is thermostable and inhibits the actin-activated Mg -ATPase activity of actomyosin. In addition, the 40 kDa calponin-like protein isolated without using thermal treatment contains endogenous kinases. It was found that the calponin-like protein can be phosphorylated by endogenous kinases in the Ca -independent manner. These results indicate that the calponin-like protein from the catch muscle of the mussel Crenomytilus grayanus is a new member of the calponin family. The role of proteins from this family both in muscle and ponmuscle cells is still obscure. We suggest that the calponin-like protein is involved in the Ca -independent regulation of smooth muscle contraction.

Expression of thick filament proteins during ontogenesis of the mussel Mytilus trossulus (Mollusca: Bivalvia).

The appearance of thick filament proteins organized into supramolecular complexes was studied by SDS-PAGE and Western-blot analysis at different developmental stages of the mussel Mytilus trossulus. Paramyosin appeared at the egg stage, while twitchin and myorod appeared at the blastula stage (12 h after fertilization). In addition, RT-PCR analysis showed that the twitchin genes were expressed starting from the blastula stage. Thus, the proteins forming thick filaments of the contractile apparatus of mussel muscles are expressed long before the formation of the first well-organized muscle system of the veliger larvae (55 h). Further, the ratios actin/myosin heavy chain (MHC) and paramyosin/MHC at the veliger stage (96 h) distinctly differed from those in the adult mussel.

[Polymerization of myorod, a surface protein of thick filaments of molluscan smooth muscle].

The study is concerned with the polymerization of myorod, a protein from thick filaments of molluscan smooth muscles, which is an alternative product of the gene of myosin heavy chains. The dependences of the properties and polymer structure of myorod on the conditions of its formation were investigated. It was shown that myorod loses the ability to form viscous polymers after proteolytic removal of the unique sequence. It was supposed that the specificity of polymerization of myorod are determined by its unique N-terminal sequence.

[N-ethylmaleimide inhibits polymerization of myorod, a contractile protein of thick filaments of molluscan smooth muscles]. / N-étilmaleimid ingibiruet polimerizatsiiu mioroda--sokratitel'nogo belka tolstykh nitei gladkikh myshts molliuskov.

The effect of N-ethylmaleimide on the polymerization of myorod, a protein of molluscan smooth muscles, which is colocalized with myosin on the surface of paramyosin core of thick filaments and is a product of the alternative splicing of the gene of heavy myosin chains, was studied. It was shown that myorod modified by N-ethylmaleimide completely loses the polymerization ability but acquires the ability to aggregate in the presence of Mg2+. At the same time, treatment of molluscan myosin with N-ethylmaleimide did not affect its polymerization. It was supposed that the effect of N-ethylmaleimide on myorod polymerization is related to the modification of the myorod SH domain containing Cys722.

Proteolytic substructure of myorod, a thick filament protein of molluscan smooth muscles.

Myorod (MR), a new thick filament protein of molluscan smooth muscles, is an alternatively spliced product of the myosin (Mn) heavy chain gene. We studied digestion of MR and Mn from the posterior adductor of Crenomytilus grayanus and the outer portion of adductor of Mizuchopecten (Patinopecten) yessoensis by papain and constructed the proteolytic substructure of MR, that is an analogue to Mn substructure. There are a head domain (analogue of Mn S1) and a rod domain (analogue of Mn rod); the junction between them is split at low ionic strength. The rod, in turn, consists of a neck domain (analogue of Mn S2) and a tail domain (identical to light meromyosin); the junction between them is split at high ionic strength. The localization and possible function of MR are discussed.

Myorod, a thick filament protein in molluscan smooth muscles: isolation, polymerization and interaction with myosin.

Myorod, a new protein of molluscan smooth muscles, is localized on the surface of paramyosin core of thick filaments together with myosin [Shelud'ko et al. (1999) Comp Biochem Physiol, 122, 277]. This protein is an alternatively spliced product of the myosin heavy chain gene. It contains the C-terminal rod part of myosin and a unique N-terminal domain [Yamada et al. (2000) J Mol Biol, 295, 169]. In the present study, the methods of myorod and myorod-free myosin preparation are developed and some properties of myorod are compared with those of myosin and myosin rod. We found that, in spite of the identity of filament-forming domains, the properties of polymeric myorod are clearly distinct from those of myosin and myosin rod. Myorod is much more soluble at intermediate ionic strength. The critical monomer concentration for polymerization of myorod is many times higher. The size of polymer particles of myorod is considerably smaller than that of myosin and myosin rod. The pure polymeric myorod forms a low turbid and unexpectedly high viscous suspension. The low-shear intrinsic viscosity of myorod is an order of magnitude higher than that of myosin or myosin rod and is close to that of F-actin. A trace admixture of myosin in myorod preparations or a small addition of myosin (0.2-1.0%) to myorod drastically alters the myorod polymerization. The suspensions of polymeric myorod nucleated by myosin have a high turbidity and low viscosity and consist of large particles. As judged from the changes in particle size distribution during polymerization, these particles are formed by successive dimerization steps. Electron micrographs show that the particles are typically spindle-shaped filaments in contrast to polymers of pure myorod which forms a network-like structure consisting of small particles. Possible participation of myorod in the catch-contraction of molluscan smooth muscles is discussed.

[A mechanism for dual-stage kinetics of actomyosin superprecipitation]. / Mekhanizm dvustadiinoi kinetiki superpretsipitatsii aktomiozina.

It has been shown that a step-like superprecipitation of actomyosin is determined by parallel processes of two types of superprecipitation: "immediate", which is characterized by a rapid one-step increase in turbidity, and "spontaneous", when slow increase growth of turbidity follows a clear phase. It is suggested that this phenomenon is based on heterogeneous nature of particle sizes in the original suspension, which, under certain conditions, leads to "constriction" of larger particles and "clearing" of smaller ones.

[Change in the size of particles in actomyosin suspensions during superprecipitation]. / Izmenenie razmera chastits v suspenziiakh aktomiozina v protsesse superpretsipitatsii.

Changes in the properties of natural actomyosin suspensions, such as turbidity, light scattering, volume concentration, particle size and particle size distribution during superprecipitation (SPP) of actomyosin in media of different compositions have been investigated. Two sets of changes indicating the existence of two SPP types--the "immediate" SPP characterized by a rapid one-step rise in turbidity and the "spontaneous" SPP, when the slow increase in turbidity follows the clear phase, have been revealed. In both cases the mechanism of the increase in the suspension turbidity is assumed to be similar and is conditioned by an increase in the refraction index (density) of the particles; however, the ways of formation of dense particles are different. During the "immediate" SPP, the particle density increases due to particle striction, whereas during the "spontaneous" SPP dense particles are formed as a result of ordered lateral association of myosin and actin filaments.

[The causes for changes in optical properties of myofibril suspensions during relaxation]. / O prichinakh izmeneniia opticheskikh svoistv suspenzii miofibrill pri rasslablenii.

Increase in the asymmetry of light scattering diagram of myofibril suspensions resulting from their relaxation was shown to be not associated with essential alterations of the myofibrillar size. Optical changes caused by relaxation appear to be conditioned by the inner rearrangement of the myofibrillar structure.

Optical properties of myofibril and actomyosin suspensions. 1. Angular dependence of light scattering by myofibril suspensions and its changes under myofibril contraction.

The angular dependence of light scattering by myofibril suspensions has been measured within the angle range of 0.05 degrees and 160 degrees at different suspension concentrations and wavelengths. Angular diagrams appear to be highly asymmetry, and extended forward in the direction of the primary light propagation. A suspension with the concentration of 0.1 mg/ml at 550 nm scatters, for example, no less than 90% light at angles of less than 6 degrees. The scattering diagram becomes less asymmetric upon increasing the suspension concentration and decreasing the wavelength of the light. Upon addition of MgATP in the presence of Ca2+, a myofibril suspension undergoes two kinds of optical change, namely, fast ones corresponding to myofibril contraction, and slow ones correlating with the subsequent aggregation of the contracted myofibrils. Fast changes are believed to be due to the increase of the refractive index of the contracting myofibrils, and slow changes to the increase in the size of the suspension particles resulting from aggregation. Light scattering by myofibril and actomyosin suspensions seems to be due not only to the particle as a whole, but also to its internal structure.

[Aggregation of isolated myofibrils stimulated by their contraction. II. Aggregation mechanism]. / Agregatsiia izolirovannykh miofibrill, stimuliruemaia ikh sokrashcheniem. II. Mekhanizm agregatsii.

Aggregation of contracted myofibrils was studied as a function of experimental conditions at myofibril contraction. The aggregation rate increased at higher concentrations of suspensions and at increased ionic strength of the medium to achieve the maximum at 0.1 M KCL in the last case. The aggregate sizes grow with an increase of ionic strength and concentration of MgATP and reduce with addition of F-actin. Aggregation of myofibrils develops only in the case of their complete or significant contraction. It was suggested that aggregation is stimulated by dehydration of myofibril at contraction.

[Aggregation of isolated myofibrils stimulated by their contraction. I. Origin of the second phase of optical changes during myofibril contraction]. / Agregatsiia izolirovannykh miofibrill, stimuliruemaia ikh sokrashcheniem. I. Proiskhozhdenie vtoroi fazy opticheskikh izmenenii pri sokrashchenii miofibrill.

Aggregation of contracted myofibrils was shown to be responsible for spontaneous: slow reduction of optical density of myofibril suspension on the final stage of their contraction. This effect faded with an increase in light wavelength, with increased angle of view of the photocell and diminished sizes of myofibrils.

[The causes of the nonuniform thermostability of Mg-ATPase and of the contractility of muscle models]. / Prichiny neodinakovoi teploustoichivosti Mg-ATFazy i sokratimosti myshechnykh modelei.

With longer periods of preliminary heat-treatment of actomyosin suspension the decrease in the rate of superprecipitation (SPP) is followed by that in the extent of SPP, and, finally, in the Mg-ATPase activity. A similar uncoupling of mechanical and enzymatic activities is observed when the ratio between the native and the inactivated myosin in reconstructed actomyosin varied. This uncoupling is supposed to result from the formation during heat-treatment of myosin bridges incapable of dissociating in the presence of Mg-ATP. The bridges affect largely the mechanical properties of actomyosin, and in a lesser degree, its enzymatic properties.

[Interrelated effects of ATP and ionic strength on Ca2+-sensitivity of isolated myofibrils]. / Vzaimozavisimoe vliianie ATF i ionnoi sily na Ca2+-chuvstvitel'nost' izolirovannykh miofibrill.

Ability of isolated myofibrils for relaxation was studied in a medium with KCl concentrations of 6 to 250 mM with ATP content varying from 0.01 to 1.0 mM. It was shown that myofibrils can relax at all the studied values of the ionic strength, but ATP concentration required for the relaxation is to increase with decreasing the ionic strength A stable state of Ca2+-sensitive system of myofibrils is maintained at approximately the same values of ATP and KCl concentrations. A possible mechanism of this phenomenon is discussed.

[Changes in the mechano-chemical properties of actomyosin during desensitization]. / Izmenenie mekhanokhimicheskikh svoistv aktomiozina pri desensibilizatsii.

The loss of Ca2+-sensitivity by natural actomyosin (desensitisation) after treatment with low ionic strength solutions results in marked deceleration of protein superprecipitation. This phenomenon is not due to the removal of minor proteins, since a similar effect was observed during "desensitisation" of synthetic actomyosin containing only myosin and actin. However, addition to desensitised actomyosin of tropomyosin, especially in combination with alpha-actinin markedly restores the initial parameters of superprecipitation and ATPase activity. It was assumed that desensitisation has a direct modifying influence on actomyosin, whose effect is weakened in the presence of tropomyosin and alpha-actinin.