Long-term effects of whole-body vibration on motor unit contractile function and myosin heavy chain composition in the rat medial gastrocnemius.

Structural and physiological mechanisms underling functional adaptations of a muscle to chronic whole-body vibration (WBV) are poorly understood. The study aimed at examining the contractile properties of motor units and the myosin heavy chain (MHC) expression in rat medial gastrocnemius muscle in response to 3- or 6-month periods of the WBV. The three-month WBV induced modifications of contractile properties principally in slow (S) and fast resistant to fatigue (FR) motor units. In S units an increase in the maximum tetanus force, a reduction in the twitch force and a decrease in the twitch-to-tetanus force ratio were found. In FR units a shortening in the twitch time parameters, a decrease in the twitch-to-tetanus ratio and an increase in the fatigue resistance were observed. In addition, a decrease in the type I and an increase in the type IIax MHC content were revealed. The six-month WBV caused a decrease in the twitch-to-tetanus force ratio in S and FR units. Other structural and physiological changes in MU properties previously seen were no longer apparent. In conclusion, responses to the long-term WBV stimulus vary between particular types of motor units, what suggests that multiple adaptive processes in muscle tissue are involved.

The content of myosin heavy chains in hindlimb muscles of female and male rats.

The aim of the study was to test whether the considerable differences in the hindlimb muscles mass, the number and diameter of muscles fibers were connected with differences in the myosin heavy chain isoform content (expressed as the percentage of the given isoform in respect to total myosin heavy chains). Therefore, the content of myosin heavy chain (MHC) isoforms was studied in four hindlimb muscles: flexor digitorum brevis, soleus, tibialis anterior and gastrocnemius medialis of female and male rats by means of polyacrylamide gel electrophoresis supplemented with densitometric analyses. Muscles were isolated and homogenized prior to electrophoretic analysis. The most interesting result concerned considerably different composition of myosin isoforms for male and female subjects in the slow soleus muscles, which contained predominantly slow MHC isoform (MHC I). However, in the male muscle about 13% of IIa isoform (MHC IIa) was also detected; this isoform was not found in the majority of the studied female muscles (81% of muscle samples). This dimorphic difference was further confirmed by immunofluorescence stainining for slow and fast skeletal myosin isoforms and by assessment of the fiber ATPase activity. For the three remaining fast muscles (flexor digitorum brevis, tibialis anterior and gastrocnemius medialis) all four MHC isoforms were detected with the fast isoforms being dominant ones. However, there were not statistically significant differences observed between males and females, with the exception of IIx isoform, which was more frequent in male tibialis anterior muscle.

Division of motor units into fast and slow of the basis of profile of 20 Hz unfused tetanus.

In the medial gastrocnemius muscle of intact rats, division of motor units (MUs) into slow (S) or fast (F) types is typically based on presence of a sag phenomenon in 40 Hz unfused tetanic contraction. MUs with sag are classified as F, while those without sag as S. However, in rats one month after spinal cord injury this phenomenon almost completely disappears and cannot be used as a basis for MUs differentiation, whereas the twitch contraction time increased significantly. Analysis of myosin heavy chain (MHC) isoform composition confirmed transformational changes of muscle fibres after spinal cord transection and indicated unchanged proportion of type I MHC isoforms, disappearance of type IIa MHC isoforms, and increase of type IIb MHC isoforms. We proposed an additional method for division of MUs into types when standard criteria are not applicable. It was observed that relative effectiveness of force summation during 20 Hz tetanus, described as a ratio of the force of the last contraction of this tetanus to the force of the first contraction, did not change after spinal cord injury. This ratio for S MUs both in intact and spinal rats exceeded 2.0, whereas for F units was lower than 2.0. Calculations of this ratio made for better fused tetani, evoked by 30 Hz or 40 Hz stimulation, showed overlapping values. We conclude that this 20 Hz tetanus index appears to be an alternative method useful for division of motor units into S and F types.

Characterisation of the Rac/PAK pathway in Amoeba proteus.

Molecular mechanisms underlying the unique locomotion of the highly motile Amoeba proteus still remain poorly understood. Recently, we have shown that blocking the endogenous amoebal Rac-like protein(s) leads to distinct and irreversible changes in the appearance of these large migrating cells as well as to a significant inhibition of their locomotion. To elucidate the mechanism of the Rac pathway in Amoeba proteus, we tested the effects of blocking the endogenous myosin I heavy chain kinase (MIHCK), one of the Rac effectors in Acanthamoeba castellanii and Dictyostelium discoideum, with anti-MIHCK antibodies in migrating amoebae, as well as the effect of inhibiting Rac and MIHCK on the actin polymerisation process. Antibodies against A. castellanii MIHCK detected an A. proteus protein with a molecular mass (ca. 95 kDa) similar to the A. castellanii kinase. The cellular distribution of MIHCK in A. proteus was very similar to those of Rac-like protein in amoebae and MIHCK in A. castellanii. Amoebae microinjected with anti-MIHCK antibodies moved slower and protruded fewer wide pseudopodia (5-6) than the control cells (9-10), resembling to some extent the phenotype of cells microinjected with anti-Rac antibodies. The in vitro studies indicate that the A. proteus Rac-like protein, but not the MIHCK isoform, is engaged in the regulation of the nucleation step of the actin polymerisation process. These observations suggest that MIHCK may be one of the effectors for Rac in these extremely large cells.

Rho/Rho-dependent kinase affects locomotion and actin-myosin II activity of Amoeba proteus.

The highly motile free-living unicellular organism Amoeba proteus has been widely used as a model to study cell motility. However, the molecular mechanisms underlying its unique locomotion are still scarcely known. Recently, we have shown that blocking the amoebae's endogenous Rac- and Rho-like proteins led to distinct and irreversible changes in the appearance of these large migrating cells as well as to a significant inhibition of their locomotion. In order to elucidate the mechanism of the Rho pathway, we tested the effects of blocking the endogenous Rho-dependent kinase (ROCK) by anti-ROCK antibodies and Y-27632, (+)-(R)-trans-4-(1-aminoethyl)-N-(4-pyridyl)cyclohexanecarboxamide dihydrochloride, a specific inhibitor of ROCK, on migrating amoebae and the effect of the Rho and ROCK inhibition on the actin-activated Mg-ATPase of the cytosolic fraction of the amoebae. Amoebae microinjected with anti-ROCK inhibitors remained contracted and strongly attached to the glass surface and exhibited an atypical locomotion. Despite protruding many pseudopodia that were advancing in various directions, the amoebae could not effectively move. Immunofluorescence studies showed that ROCK-like protein was dispersed throughout the cytoplasm and was also found in the regions of actin-myosin II interaction during both isotonic and isometric contraction. The Mg-ATPase activity was about two- to threefold enhanced, indicating that blocking the Rho/Rho-dependent kinase activated myosin. It is possible then that in contrast to the vertebrate cells, the inactivation of Rho/Rho-dependent kinase in amoebae leads to the activation of myosin II and to the observed hypercontracted cells which cannot exert effective locomotion.

Effect of Rho family GTP-binding proteins on Amoeba proteus.

While there is a number of studies on the effects of Rho GTPases on the actin-based cytoskeleton in higher eukaryotes, studies in protozoans are rather limited. The problem seems to be intriguing since the structure of protozoan cytoskeletons is distinct from most vertebrate cells. By blocking endogenous Rho family proteins of highly motile Amoeba proteus with C3 transferase and antibodies against human RhoA and Rac1, we tried to assess the in vivo role of these proteins in amoebae. In migrating amoebae, both proteins are concentrated in the cortical layer and seem to colocalize with filamentous actin. Endogenous Rac1, but not RhoA, is accumulated in the perinuclear cytoskeleton. Blocking Rac- or Rho-like proteins caused distinct and irreversible changes in the locomotive shape of the examined amoebae and significant inhibition of their migration. Amoebae microinjected with anti-Rac1 antibodies were contracted, shortened, and developed only few wide pseudopodia. More pronounced changes were observed in cells treated with anti-RhoA antibodies. They exhibited an atypical locomotion not leading to their effective displacement. After treatment with 50 microg of C3 transferase per ml, cells rapidly contracted and almost completely rounded up, became refractile with the granules beaten into a dense mass, detached from the surface and died. Ten times lower concentration of the enzyme caused similar changes as the inhibition of endogenous RhoA-like protein. These results indicate that Rho family-based regulation plays a key role in amoebic migration.

Regulation of nonmuscle myosins by heavy chain phosphorylation.

Functional activities of many nonmuscle myosin isoforms are (or are postulated to be) regulated by heavy chain phosphorylation. Depending on the myosin isoform, the serine or threonine residues located within the head (myosin I or myosin VI) or within the C-terminal tail domains (myosin II or myosin V) can be phosphorylated by more or less specific endogenous kinases. In some isoforms phosphorylation can occur both in the head and tail domains, as it has been found for myosin III. There are also isoforms that can be regulated both by the heavy and regulatory light chain phosphorylation, as for the example myosin II from slide mold Dictyostelium discoideum. The goal of this review was to describe recent findings on regulation of myosin I, myosin II, myosin III, myosin V and myosin VI isoforms by their heavy chain phosphorylation including the short charcteristics of the relevant kinases. The biological aspects of the phosphorylation are also discussed.

Interaction of the N-terminal part of the A1 essential light chain with the myosin heavy chain.

The kinetics of actin-dependent MgATPase activity of skeletal muscle myosin subfragment 1 (S1) isoform containing the A1 essential light chain differ from those of the S1 isoform containing the A2 essential light chain. The differences are due to the presence of the extra N-terminal peptide comprising 42 amino acid residues in the A1 light chain. This peptide can interact with actin; heretofore, there have no been reports of the direct interaction between this peptide and the heavy chain of S1. Here, using the zero-length cross-linker 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) and S. aureus V8 protease, we show for the first time that the N-terminal part of the A1-light chain can interact with the 22-kDa fragment of the S1 heavy chain. No such interaction has been observed for the S1(A2) isoenzyme. Localization of residues which can possibly react with the cross-linker suggests that the interaction might involve the N-terminal residues of the A1 light chain and the converter region of the heavy chain.

Phenylglyoxal reveals phosphorylation-dependent difference in the conformation of Acanthamoeba myosin II active site.

Acanthamoeba myosin II is regulated in an unique way by phosphorylation of three serine residues located within nonhelical tailpiece of the rod domain. Phosphorylation inhibits functions associated with the NH2-terminal motor domain, i.e., actin-activated activity and ability to move actin filaments. Number of data indicate functional communication between these distant domains. In this work, effect of modification of arginine residues with phenylglyoxal on the Ca2+-ATPase activity and susceptibility to endoproteinase ArgC cleavage of monomeric phospho- and dephosphomyosin II has been investigated. Upon the phenylglyoxal treatment the activity of dephosphomyosin II was decreasing faster that the activity of phosphomyosin. The modification also affected the proteolytic fragmentation of phospho- and dephosphomyosin II: the cleavage of heavy chain was further inhibited for phosphomyosin and enhanced for dephosphomyosin with a concomitant exposure of an additional cleavage site within the head domain. No difference in the quantity of modified arginines was observed. These results indicate a difference between the conformation of active sites of phospho- and dephosphomyosin II.

Myosins and deafness.

The discovery in the past few years of a huge diversity within the myosin superfamily has been coupled with an understanding of the role of these motor proteins in various cellular functions. Extensive studies have revealed that myosin isoforms are not only involved in muscle contraction but also in crucial functions of many specialized mammalian cells such as melanocytes, kidney and intestinal brush border microvilli, nerve growth cones or inner ear hair cells. A search for genes involved in the pathology of human genetic deafness resulted in identification of three novel myosins: myosin VI, myosin VIIA and, very recently, myosin XV. The structure, tissue and cellular distribution of these myosin isoforms, as well as mutations detected within their genes that have been found to affect the hearing process, are described in this review.

Flexibility of Acanthamoeba myosin rod minifilaments.

Previous electric birefringence experiments have shown that the actin-activated Mg2+-ATPase activity of Acanthamoeba myosin II correlates with the ability of minifilaments to cycle between flexible and stiff conformations. The cooperative transition between conformations was shown to depend on Mg2+ concentration, on ATP binding, and on the state of phosphorylation of three serines in the C-terminal end of the heavy chains. Since the junction between the heavy meromyosin (HMM) and light meromyosin (LMM) regions is expected to disrupt the alpha-helical coiled-coil structure of the rod, this region was anticipated to be the flexible site. We have now cloned and expressed the wild-type rod (residues 849-1509 of the full-length heavy chain) and rods mutated within the junction in order to test this. The sedimentation and electric birefringence properties of minifilaments formed by rods and by native myosin II are strikingly similar. In particular, the Mg2+-dependent flexible-to-stiff transitions of native myosin II and wild-type rod minifilaments are virtually superimposable. Mutations within the junction between the HMM and LMM regions of the rod modulate the ability of Mg2+ to stabilize the stiff conformation. Less Mg2+ is required to induce minifilament stiffening if proline-1244 is replaced with alanine. Deleting the entire junction region (25 amino acids) results in a even greater decrease in the Mg2+ concentration necessary for the transition. The HMM-LMM junction does indeed seem to act as a Mg2+-dependent flexible hinge.

Two-state thermal unfolding of a long dimeric coiled-coil: the Acanthamoeba myosin II rod.

Acanthamoeba myosin II rod is a long alpha-helical coiled-coil with a flexible hinge containing a helix-breaking proline. The thermal stability of the complete rod domain of myosin II (residues 849-1509), a mutant in which the hinge proline was replaced by alanine (P398A), and a mutant with the whole hinge region deleted (delta(384-408)) was studied in 0.6 and 2.2 M KCl, pH 7.5. In analytical ultracentrifugation studies, the purified myosin II rods sedimented as monodisperse dimers with sedimentation coefficients s(20,w) = 3.8 S (wild-type, Mr = 149,000) and 3.6 S (P398A and delta(384-408)). Circular dichroism (CD) and differential scanning calorimetry (DSC) showed that the thermal unfolding of the myosin II rod is reversible and highly cooperative. The unfolding of the rod is coupled to a dissociation of the chains, as shown by HPLC gel filtration at high temperatures and by the concentration dependence of the transition temperature. The CD and DSC data are consistent with a two-state mechanism (Tm approximately 40 degrees C, deltaH approximately 400 kcal/mol) in which the dimeric rod unfolds with concomitant formation of two unfolded monomers. We found no evidence for independent unfolding of the two rod domains that are separated by the hinge region. The only difference observed in the unfolding of the mutant rods from that of the wild type was a approximately 2 degrees C increase in the thermal stability of the hinge-deletion mutant. Thus, the mechanism of unfolding the Acanthamoeba myosin II rod is different from those of skeletal muscle myosin rod and tropomyosin, for which non-two-state thermal transitions have been observed. The cooperative unfolding of the entire coiled-coil rod of Acanthamoeba myosin II may underlie the previously reported regulatory coupling between its N-terminal head and C-terminal tail.

Nucleotides increase the internal flexibility of filaments of dephosphorylated Acanthamoeba myosin II.

The actin-activated Mg(2+)-ATPase activity of Acanthamoeba myosin II minifilaments is dependent both on Mg2+ concentration and on the state of phosphorylation of three serine sites at the C-terminal end of the heavy chains. Previous electric birefringence experiments on minifilaments showed a large dependence of signal amplitude on the phosphorylation state and Mg2+ concentration, consistent with large changes in filament flexibility. These observations suggested that minifilament stiffness was important for function. We now report that the binding of nucleotides to dephosphorylated minifilaments at Mg2+ concentrations needed for optimal activity increases the flexibility by about 10-fold, as inferred from the birefringence signal amplitude increase. An increase in flexibility with nucleotide binding is not observed for dephosphorylated minifilaments at lower Mg2+ concentrations or for phosphorylated minifilaments at any Mg2+ concentrations examined. The relaxation times for minifilament rotations that are sensitive to the conformation myosin heads are also observed to depend on phosphorylation, Mg2+ concentration, and nucleotide binding. These latter experiments indicate that the actin-activated Mg2+ concentration, and nucleotide binding. These latter experiments indicate that the actin-activated Mg(2+)-ATPase activity of Acanthamoeba myosin II correlates with both changes in myosin head conformation and the ability of minifilaments to cycle between stiff and flexible conformations coupled to nucleotide binding and release.

Thermal unfolding of Acanthamoeba myosin II and skeletal muscle myosin.

Studies on the thermal unfolding of monomeric Acanthamoeba myosin II and other myosins, in particular skeletal muscle myosin, using differential scanning calorimetry (DSC) are reviewed. The unfolding transitions for intact myosin or its head fragment are irreversible, whereas those of the rod part and its fragments are completely reversible. Acanthamoeba myosin II unfolds with a high degree of cooperativity from ca. 40-45 degrees C at pH 7.5 in 0.6 M KCl, producing a single, sharp endotherm in DSC. In contrast, thermal transitions of rabbit skeletal muscle myosin occur over a broader temperature range (ca. 40-60 degrees C) under the same conditions. The DSC studies on the unfolding of the myosin rod and its fragments allow identification of cooperative domains, each of which unfolds according to a two-state mechanism. Also, DSC data show the effect of the nucleotide-induced conformational changes in the myosin head on the protein stability.

Thermally induced unfolding of Acanthamoeba myosin II and skeletal muscle myosin: nucleotide effects.

The thermal unfolding of monomeric Acanthamoeba myosin II and rabbit skeletal muscle myosin at pH 7.5 in 0.6 M KCl has been studied by differential scanning calorimetry (DSC) and circular dichroism. A single endotherm (at approximately 40 to 45 degrees C) with a maximum at 41.7 +/- 0.1 degrees C and delta H approximately 1080 +/- kcal/mol is observed for both dephospho- and phospho-myosin II. Skeletal muscle myosin unfolds with less cooperativity over a wider temperature range (approximately 40 to 60 degrees C) with delta H approximately 2500 kcal/mol. The thermal unfolding of either myosin results in a loss of approximately 70% of alpha-helical structures. Saturation of dephospho- or phospho-myosin II with 5'-adenylylimidodiphosphate (AMPPNP) in the presence of Mg2+ produces a second endotherm with a maximum at approximately 49 degrees C. The latter observation is attributed to a stabilization of head regions by nucleotide binding. Indeed, a purified N-terminal myosin II head fragment has been found to unfold with Tmax approximately 41 and approximately 48 degrees C in the absence and presence of AMPPNP, respectively. The stabilization of the head regions is less with ADP+Pi and still smaller with ADP alone. In summary, thermally induced unfolding of myosin II is affected by nucleotide binding to heads, but not by phosphorylation or even removal of a 66-amino-acid tailpiece containing phosphorylation sites. The observed differences in the cooperativity of unfolding myosin II and skeletal muscle myosin relate to differences between rod structures and possibly also head-rod interactions.

Effects of phosphorylation and nucleotides on the conformation of myosin II from Acanthamoeba castellanii.

The actin-activated Mg(2+)-ATPase activity of filamentous Acanthamoeba myosin II is inactivated by phosphorylation of a short non-helical tailpiece at the C-terminal end of each heavy chain even though the catalytic sites are in the N-terminal globular head. Consistent with this effect, phosphorylation at the tip of the tail alters the conformation of the head as shown by a shift in the principal site of cleavage by endoproteinase Arg-C (Ganguly, C., Martin, B., Bubb, M., and Korn, E. D. (1992) J. Biol. Chem. 267, 20905-20908). We now show that the sedimentation coefficient of monomeric phospho-myosin II is 1.3-4.6% lower than that of dephospho-myosin II, which suggests that phosphorylation produces a less compact conformation with a small increase in frictional coefficient. As shown by changes in papain digestion patterns, bound nucleotide also affects the conformation of the head region of monomeric phospho- and dephospho-myosin II, the conformation of the head region of filamentous phospho- and dephospho-myosin II, and the conformation of the C-terminal region of the tail of filamentous phospho-myosin II. Conformational differences between the dephospho- and phospho-forms of myosin II in the presence of nucleotide, as detected by susceptibility to proteolysis, therefore, appear to be greater in filaments than in monomers. These results provide additional evidence for communication between the N-terminal heads and C-terminal tails of Acanthamoeba myosin II.

Conformational transitions within the head and at the head-rod junction in smooth muscle myosin studied with a limited proteolysis method.

It was previously shown that tryptic digestion of subfragment 1 (S1) of skeletal muscle myosins at 0 degree C results in cleavage of the heavy chain at a specific site located 5 kDa from the NH2-terminus. This cleavage is enhanced by nucleotides and suppressed by actin and does not occur at 25 degrees C, except in the presence of nucleotide. Here we show a similar temperature sensitivity and protection by actin of an analogous chymotryptic cleavage site in the heavy chain of gizzard S1. The results support the view that the myosin head, in general, can exist in two different conformational states even in the absence of nucleotides and actin, and indicate that the heavy chain region 5 kDa from the NH2-terminus is involved in the communication between the sites of nucleotide and actin binding. We also show here for the first time that the S1-S2 junction in gizzard myosin can be cleaved by chymotrypsin and that this cleavage (observed in papain-produced S1 devoid of the regulatory light chain) is also temperature-dependent but insensitive to nucleotides and actin. It is suggested that the temperature-dependent alteration in the flexibility of the head-rod junction, which is apparent from these and similar observations on skeletal muscle myosin [Miller, L. & Reisler, E. (1985) J. Mol. Biol. 182, 271-279; Redowicz, M.J. & Strzelecka-Golaszewska, H. (1988) Eur. J. Biochem. 177, 615-624], may contribute to the temperature dependence of some steps in the cross-bridge cycle.

Dependence of the length of the heavy chain of chymotryptic subfragment 1 on the temperature of myosin digestion.

Limited digestion of filamentous myosin with chymotrypsin at 0 degrees C in the absence of divalent cations generates two forms of subfragment 1 (S1), with heavy chains of 95 kDa and 98 kDa. The difference is at the C-terminal end of the chain. The 98 kDa form prevails, in contrast to the preparations obtained by digestion at room temperature which consist of the shorter species and only traces of the longer one. The results support the idea of a temperature-dependent conformational transition at the head-rod junctional region of the myosin heavy chain.

Temperature-dependent conformational transition in the head-rod junctional region of the myosin molecule.

The effects of temperature, Mg2+, ATP, and actin on the conformation of the neck region of the myosin head were studied by limited proteolysis of heavy meromyosin (HMM) and subfragment 1 (S1) preparations obtained by papain digestion of myosin in the presence of Mg2+ (Mg-S1) or EDTA (EDTA-S1). The preparations were fluorescently labelled at the SH1 thiol group to enable identification of the COOH-terminal fragments of the head portion of the heavy chain where this group is located. The results indicate that the head-rod junctional region of the myosin heavy chain contains at least three different sites readily susceptible to trypsin at 25 degrees C if the light chain LC2 or its LC2' fragment are absent. The susceptibility of one of these sites dramatically decreases when the temperature is lowered to 0 degree C, indicating a temperature-dependent conformational transition in the head-rod junction. With the method used, this transition is detectable only in LC2/LC'2-deficient preparations since all three sites are protected, although to different extents, by LC2 and its LC'2 derivative. It is, however, most probable that the effect of the light chain is confined to steric hindrance of trypsin access and that the temperature-dependent structural transition in the head-rod junction can occur in the presence of intact LC2 as well and may contribute to the temperature sensitivity of force generation in muscle.