Modeling of the mussel catch muscle contractile apparatus in actomyosin suspension.

In this paper, we tried to create a contractile model from proteins of the catch muscle of the Gray mussel, similar to the well-described suspension contractile model of vertebrate skeletal muscles. This model makes it possible to characterize the processes in the reconstructed contractile apparatus with the help of monitoring the two characteristics of muscle suspensions - the optical density and the particle size. Contractile model of the catch muscle we constructed was the simplest model consisting of two proteins, actin and myosin. During this work we compared the optical manifestations of the contraction and relaxation states of constructed model with earlier data on the actomyosin suspension of skeletal muscles. It appeared that the approach used in the study of skeletal muscle actomyosin relaxing - the use of an increased amount of ATP - cannot be applied to the contractile model of the molluscan catch muscle. Nevertheless we managed to reach relaxed state of this model with modifying calcium concentration. As a result, we laid the foundation for further reconstruction of the third state of the catch muscle - the catch tone.

Protein composition of thick filaments from molluscan catch muscle and the role of twitchin in the catch-state formation.

In the work, we performed densitometry of thick filaments of the Gray's mussel catch muscle; densitometry included determination of electrophoretic dye binding constants of proteins. The results of densitometry showed that the content of twitchin in thick filaments is significantly (10 times) lower than the content of myosin. We performed an in vitro simulation of the contractile apparatus of the catch muscle and showed that with such content, links formed by twitchin cannot stop "relaxation". So, we doubt that the role of twitchin in the formation of the catch state is to form load-bearing links between thin and thick filaments that keep the muscle in the contracted state. At the same time, densitometry has shown that the content of the unique catch-muscle protein - myorod - significantly exceeds the content of twitchin and reaches the level of myosin. Like twitchin, myorod is capable of forming regulated cross-links between thick and thin filaments. Such a high content of this protein may indicate that it is myorod, and not twitchin, that is responsible for the formation of catch load-bearing cross-links.

Troponin-like regulation in muscle thin filaments of the mussel Crenomytilus grayanus (Bivalvia: Mytiloida).

Muscles of bivalve molluscs have double calcium regulation--myosin-linked and actin-linked. While the mechanism of myosin-linked regulation is sufficiently studied, there is still no consensus on the mechanism of actin-linked regulation. Earlier we showed a high degree of Ca2+-sensitivity of thin filaments from the adductor muscle of the mussel Crenomytilus grayanus (Mytiloida). In order to elucidate the nature of this regulation, we isolated the fraction of minor proteins from the mussel thin filaments, which confers Ca2+-sensitivity to reconstituted actomyosin-tropomyosin. Proteins of this fraction, ABP-19, ABP-20, and ABP-28, were chromatographically purified and identified. According to the results of mass spectrometry and Western blot analysis, as well as by their functional properties, these mussel actin-binding proteins appeared to correspond to the troponin components from the skeletal muscles of vertebrates (TnC, TnI and TnT). The reconstituted mussel troponin complex confers to actomyosin-tropomyosin more than 80% Ca2+-sensitivity. The in vivo molar ratio of actin/tropomyosin/troponin was calculated to be 7:1:0.5, i.e., the content of troponin in mussel thin filaments is two times lower than in thin filaments of skeletal muscles of vertebrates. These data demonstrate that troponin-like regulation found in the catch muscle of the mussel C. grayanus is present at least in two suborders of bivalves: Pectinoida and Mytiloida.

Non-Straub type actin from molluscan catch muscle.

We have developed a method of obtaining natural actin from smooth muscles of the bivalves on the example of the Сrenomytilus grayanus catch muscle. The muscles were previously rigorized to prevent a loss of thin filaments during homogenization and washings. Thin filaments were isolated with a low ionic strength solution in the presence of ATP and sodium pyrophosphate. Surface proteins of thin filaments-tropomyosin, troponin, calponin and some minor actin-binding proteins-were dissociated from actin filaments by increasing the ionic strength to 0.6 M KCL. Natural fibrillar actin obtained in that way depolymerizes easily in low ionic strength solutions commonly used for the extraction of Straub-type actin from acetone powder. Purification of natural actin was carried out by the polymerization-depolymerization cycle. The content of inactivated actin remaining in the supernatant is much less than at a similar purification of Straub-type actin. A comparative investigation was performed between the natural mussel actin and the Straub-type rabbit skeletal actin in terms of the key properties of actin: polymerization, activation of Mg-ATPase activity of myosin, and the electron-microscopic structure of actin polymers.

Hybrid and non-hybrid actomyosins reconstituted with actin, myosin and tropomyosin from skeletal and catch muscles.

In this study, we investigated hybrid and non-hybrid actomyosin models including key contractile proteins: actin, myosin, and tropomyosin. These proteins were isolated from the rabbit skeletal muscle and the catch muscle of the mussel Crenomytilus grayanus. Our results confirmed literature data on an unusual ability of bivalve's tropomyosin to inhibit Mg-ATPase activity of skeletal muscle actomyosin. We have shown that the degree of inhibition depends on the environmental conditions and may vary within a wide range. The inhibitory effect of mussel tropomyosin was not detected in non-hybrid model (mussel myosin + mussel actin + mussel tropomyosin). This effect was revealed only in hybrid models containing mussel tropomyosin + rabbit (or mussel) actin + rabbit myosin. We assume that mussel and rabbit myosins have mismatched binding sites for actin. In addition, mussel tropomyosin interacting with actin is able to close the binding sites of rabbit myosin with actin, which leads to inhibition of Mg-ATPase activity.

Molluscan smooth catch muscle contains calponin but not caldesmon.

We isolated Ca(2+)-regulated thin filaments from the smooth muscle of the mussel Crenomytilus grayanus and studied the protein composition of different preparations from this muscle: whole muscle, heat-stable extract, fractions from heat-stable extract, thin filaments and intermediate stages of thin filaments purification. Among the protein components of the above-listed preparations, we did not find caldesmon (CaD), although two isoforms of a calponin-like (CaP-like) protein, which along with CaD is characteristic of vertebrate smooth muscle, were present in thin filaments. Thus, CaD is not Ca(2+)-regulator of thin filaments of this muscle. On the other hand, the mussel CaP-like protein is also not such Ca(2+)-regulator since we have shown that this protein can be selectively removed from isolated mussel thin filaments without loss of their Ca(2+)-sensitivity. We suggest that thin filaments in the smooth catch muscle possess other type of Ca(2+)-regulation, different from that in vertebrate smooth muscles.

Twitchin can regulate the ATPase cycle of actomyosin in a phosphorylation-dependent manner in skinned mammalian skeletal muscle fibres.

The effect of twitchin, a thick filament protein of molluscan muscles, on the actin-myosin interaction at several mimicked sequential steps of the ATPase cycle was investigated using the polarized fluorescence of 1.5-IAEDANS bound to myosin heads, FITC-phalloidin attached to actin and acrylodan bound to twitchin in the glycerol-skinned skeletal muscle fibres of mammalian. The phosphorylation-dependent multi-step changes in mobility and spatial arrangement of myosin SH1 helix, actin subunit and twitchin during the ATPase cycle have been revealed. It was shown that nonphosphorylated twitchin inhibited the movements of SH1 helix of the myosin heads and actin subunits and decreased the affinity of myosin to actin by freezing the position and mobility of twitchin in the muscle fibres. The phosphorylation of twitchin reverses this effect by changing the spatial arrangement and mobility of the actin-binding portions of twitchin. In this case, enhanced movements of SH1 helix of the myosin heads and actin subunits are observed. The data imply a novel property of twitchin incorporated into organized contractile system: its ability to regulate the ATPase cycle in a phosphorylation-dependent fashion by changing the affinity and spatial arrangement of the actin-binding portions of twitchin.

Catch muscle of bivalve molluscs contains myosin- and twitchin-associated protein kinase phosphorylating myorod.

We have shown previously that myorod, a molluscan thick filament protein of unknown function, is phosphorylated by vertebrate smooth myosin light chain kinase (MLCK) in N-terminal unique region. The aim of the present study was to clarify whether such phosphorylation may occur in molluscan muscles. We detected three kinases endogenous to molluscan catch muscle, namely, to the complex of surface thick filament proteins that consists of twitchin, myosin, and myorod. The first kinase was a protein kinase A because it was inhibited by a specific inhibitor; the second one was associated with twitchin and phosphorylated myorod at its N-terminal unique region independently of Ca(2+); and the third kinase was bound to myosin and phosphorylated myorod as well as myosin in the C-terminal part of both proteins. The myosin-associated kinase was inhibited by micromolar concentration of calcium ions. This enzyme could be separated from myosin by chromatography, whereas the kinase associated with twitchin could not be separated from twitchin. Since twitchin has a MLCK-like domain, it is possible that this domain was responsible for myorod phosphorylation. Phosphorylation of myorod within the twitchin-myosin-myorod complex increased the actin-activated Mg(2+)-ATPase activity of myosin. Taken together, these results indicate that phosphorylation of myorod by kinases associated with key proteins of catch contraction may contribute to the functional activity of myorod in molluscan smooth muscle.

Molluscan catch muscle myorod and its N-terminal peptide bind to F-actin and myosin in a phosphorylation-dependent manner.

Myorod is expressed exclusively in molluscan catch muscle and localizes on the surface of thick filaments together with twitchin and myosin. This protein is an alternatively spliced product of the myosin heavy-chain gene containing the C-terminal rod part of myosin and a unique N-terminal domain. We have recently reported that this unique domain is a target for phosphorylation by gizzard smooth muscle myosin light chain kinase (MLCK) and molluscan twitchin, which contains a MLCK-like domain. To elucidate the role of myorod phosphorylation in catch muscle, a peptide corresponding to the specific N-terminal region of the protein was synthesized in phosphorylated and unphosphorylated form. We report, for the first time, that unphosphorylated full-length myorod and its unphosphorylated N-terminal synthetic peptide are able to interact with rabbit F-actin and thin filaments from molluscan catch muscle. The binding between thin filaments and the peptide was Ca²+-dependent. In addition, we found that phosphorylated N-terminal peptide of myorod has higher affinity for myosin compared to the unphosphorylated peptide. Together, these observations suggest the direct involvement of the N-terminal domain of myorod in the regulation of molluscan catch muscle.

A new property of twitchin to restrict the "rolling" of mussel tropomyosin and decrease its affinity for actin during the actomyosin ATPase cycle.

A new evidence on the regulatory function of twitchin, a titin-like protein of molluscan muscles, at muscle contraction has been obtained at studying the movements of IAF-labeled mussel tropomyosin in skeletal ghost fibers during the ATP hydrolysis cycle simulated using nucleotides and non-hydrolysable ATP analogs. For the first time, myosin-induced multistep changes in mobility and in the position of mussel tropomyosin strands on the surface of the thin filament during the ATP hydrolysis cycle have been demonstrated directly. Unphosphorylated twitchin shifts the tropomyosin towards the position typical for muscle relaxation, decreases the tropomyosin affinity to actin and inhibits its movements during the ATPase cycle. Phosphorylation of twitchin by the catalytic subunit of protein kinase A reverses this effect. These data imply that twitchin is a thin filament regulator that controls actin-myosin interaction by "freezing" tropomyosin in the blocked position, resulting in the inhibition of the transformation of weak-binding states into strong-binding ones during ATPase cycle.

Molluscan twitchin can control actin-myosin interaction during ATPase cycle.

The effect of twitchin, a thick filament protein of molluscan muscles, on actin-myosin interaction at several mimicked sequential steps of the ATPase cycle was investigated using fluorescent probes specifically bound to Cys707 of myosin subfragment-1 and Cys374 of actin incorporated into ghost muscle fibers. The multi-step changes in mobility and spatial arrangement of myosin SH1 helix and actin subdomain-1 during the ATPase cycle have been revealed. For the first time, the inhibition of movement of myosin SH1 helix and actin subdomain-1 during the ATPase cycle and the decrease in the myosin head and actin affinity in the presence of unphosphorylated twitchin have been demonstrated. Phosphorylation of twitchin by the catalytic subunit of protein kinase A reversed this effect. These data imply a novel property of twitchin consisting in its ability to regulate in a phosphorylation-dependent manner the actin-myosin interaction during the ATPase cycle by the inhibition of transformation of the weak-binding actomyosin states into the strong-binding ones.

Crenomytilus grayanus 40kDa calponin-like protein: cDNA cloning, sequence analysis, tissue expression, and post-translational modifications.

Calponin-like protein (CaP-40), a third major protein after actin and tropomyosin, has recently been identified by us in the Ca2+-regulated thin filaments of mussel Crenomytilus grayanus. It contains calponin homology domain, five calponin family repeats and possesses similar biochemical properties as vertebrate smooth muscle calponin. In this paper, we report a full-length cDNA sequence of CaP-40, study its expression pattern on mRNA and protein levels, evaluate CaP-40 post-translational modifications and perform protein-protein interaction analysis. The full-length sequence of CaP-40 consists of 398 amino acids and has high similarity to calponins among molluscan species. CaP-40 gene is widely expressed in mussel tissues, with the highest expression in adductor and mantle. Comparison of these data with protein content established by mass-spectrometry analysis revealed that the high mRNA content is mirrored by high protein levels for adductor smooth muscles. To provide unbiased insight into the function of CaP-40 and effect of its over-expression in adductor smooth muscle, we built protein-protein interaction network of identified Crenomytilus grayanus proteome. In addition, we showed that CaP-40 is subjected to post-translational N- and C-terminal acetylation at N127, G229 and G349 sites which potentially regulates its function in vivo.

Catch muscle myorod modulates ATPase activity of Myosin in a phosphorylation-dependent way.

Myorod is expressed exclusively in molluscan catch muscle and localizes on the surface of thick filaments together with twitchin and myosin. Myorod is an alternatively spliced product of the myosin heavy-chain gene that contains the C-terminal rod part of myosin and a unique N-terminal domain. The unique domain is a target for phosphorylation by gizzard smooth myosin light chain kinase (smMLCK) and, perhaps, molluscan twitchin, which contains a MLCK-like domain. To elucidate the role of myorod and its phosphorylation in the catch muscle, the effect of chromatographically purified myorod on the actin-activated Mg2+-ATPase activity of myosin was studied. We found that phosphorylation at the N-terminus of myorod potentiated the actin-activated Mg2+-ATPase activity of mussel and rabbit myosins. This potentiation occurred only if myorod was phosphorylated and introduced into the ATPase assay as a co-filament with myosin. We suggest that myorod could be related to the catch state, a function specific to molluscan muscle.

Twitchin of mollusc smooth muscles can induce "catch"-like properties in human skeletal muscle: support for the assumption that the "catch" state involves twitchin linkages between myofilaments.

Molluscan catch muscles can maintain tension with low or even no energy utilization, and therefore, they represent ideal models for studying energy-saving holding states. For many decades it was assumed that catch is due to a simple slowing of the force-generating myosin head cross-bridge cycles. However, recently evidences increased suggesting that catch is rather caused by passive structures linking the myofilaments in a phosphorylation-dependent manner. One possible linkage structure is the titin-like thick filament protein twitchin, which could form bridges to the thin filaments. Twitchin is known to regulate the catch state depending on its phosphorylation state. Here, we found that twitchin induces a catch-like stiffness in skinned human skeletal muscle fibres, when these fibres are exposed to this protein. Subsequent phosphorylation of twitchin reduces the stiffness. These findings support the assumption that catch of molluscan smooth muscle involves twitchin linkages between thick and thin filaments.

"Twitchin-actin linkage hypothesis" for the catch mechanism in molluscan muscles: evidence that twitchin interacts with myosin, myorod, and paramyosin core and affects properties of actomyosin.

"Twitchin-actin linkage hypothesis" for the catch mechanism in molluscan smooth muscles postulates in vivo existence of twitchin links between thin and thick filaments that arise in a phosphorylation-dependent manner [N.S. Shelud'ko, G.G. Matusovskaya, T.V. Permyakova, O.S. Matusovsky, Arch. Biochem. Biophys. 432 (2004) 269-277]. In this paper, we proposed a scheme for a possible catch mechanism involving twitchin links and regulated thin filaments. The experimental evidence in support of the scheme is provided. It was found that twitchin can interact not only with mussel myosin and rabbit F-actin but also with the paramyosin core of thick filaments, myorod, mussel thin filaments, "natural" F-actin from mussel, and skeletal myosin from rabbit. No difference was revealed in binding of twitchin with mussel and rabbit myosin. The capability of twitchin to interact with all thick filament proteins suggests that putative twitchin links can be attached to any site of thick filaments. Addition of twitchin to a mixture of actin and paramyosin filaments, or to a mixture of Ca(2+)-regulated actin and myosin filaments under relaxing conditions caused in both cases similar changes in the optical properties of suspensions, indicating an interaction and aggregation of the filaments. The interaction of actin and myosin filaments in the presence of twitchin under relaxing conditions was not accompanied by an appreciable increase in the MgATPase activity. We suggest that in both cases aggregation of filaments was caused by formation of twitchin links between the filaments. We also demonstrate that native thin filaments from the catch muscle of the mussel Crenomytilus grayanus are Ca(2+)-regulated. Twitchin inhibits the ability of thin filaments to activate myosin MgATPase in the presence of Ca(2+). We suggest that twitchin inhibition of the actin-myosin interaction is due to twitchin-induced switching of the thin filaments to the inactive state.

Phosphorylation of myorod (catchin) by kinases tightly associated to molluscan and vertebrate smooth muscle myosins.

Myorod, also known as catchin, a newly discovered component of molluscan smooth muscle thick filaments, is an alternative product of the myosin heavy chain gene. It contains a C-terminal rod part that is identical to that part of myosin and a unique N-terminal domain that is very small relative to the myosin head domain. The role of myorod in contraction or relaxation of this muscle type is unknown. In the present study we demonstrated that myorod was phosphorylated not only by a kinase endogenous to molluscan myosin and twitchin but also to vertebrate smooth muscle myosin light chain kinase (MLCK). The rates and maximal levels of phosphorylation were up to threefold higher than those observed by protein kinase A with clear optima at the physiological salt concentrations. Using a mild digestion with chymotrypsin we isolated an 11 kDa phosphopeptide and showed that the phosphorylation site was located at the N-terminal domain of myorod at Thr 141 position. The sequence around this site exhibited a high degree of similarity to that expected for the substrate recognition site of MLCK. The phosphorylation rates strongly depended on the ionic conditions indicating that this site could be readily sterically blocked during myorod polymerization. Another component of the thick filaments involved in regulation of the catch state, twitchin, was phosphorylated by MLCK and exhibited endogenous myorod kinase and MLCK activities. A possible role of these phosphorylation reactions in the regulation of molluscan smooth muscles is discussed.