Solubility-determining domain of smooth muscle myosin rod

Chymotryptic digestion of chicken gizzard light meromyosin (LMM) produced a 72 kDa core fragment, which was fully soluble at 150 mM KCl, pH 6.5–7.5. The fragment showed weak self-association at 50 mM KCl. The homology of the N-terminus amino acid sequence of this fragment with the sequence of the rabbit skeletal myosin rod suggested that the N-terminus of the core fragment originated 5 kDa from the hinge common to both smooth and skeletal myosin rod. Sedimentation experiments indicated that the domain specifying the insolubility of the intact LMM was 13 kDa long. Progressive proteolytic shortening of this region produced LMM fragments of progressively increasing solubility. Electron microscopy of segments formed from full-length LMM and from LMM core suggested that this 13 kDa domain specified the 43 nm parallel and antiparallel molecular overlaps characteristic of self-assembled intact myosin.     

The Two Myosin Isoenzymes of Chicken Anterior Latissimus dorsi Muscle Contain Different Myosin Heavy Chains Encoded by Separate mRNAs

Abstract. The two myosin isozymes (SM1 and SM2) of the anterior latissimus dorsi muscle of the chicken change in relative concentration during development. As SM1 decreases from 13 days of embryonic growth through 1 year of adult maturation, SM2 increases. In the adult muscle SM2 accounts for over 95% of the total myosin. The myosin heavy chains of the two isozymes are distinctly different and may be separated from each other by 5% SDS polyacrylamide gel electrophoresis. The faster migrating myosin heavy chain is identified as originating from SM1 and the slower migrating myosin heavy chain from SM2 myosin isozymes. The myosin heavy chains change in relative concentration during development exactly parallel with changes in SM1 and SM2 isozyme levels. Peptide map analysis also reveals that SM1 myosin heavy chains and SM2 myosin heavy chains are distinctly different. When RNA from the ALD muscle is added to reticulocyte lysate protein synthesizing systems the translation products are shown to include both SM1 and SM2 myosin heavy chains. These comigrate exactly on 5% SDS polyacrylamide gels with authentic counterparts from ALD muscle. Finally, when peptide maps of SM1 and SM2 myosin heavy chains synthesized in the reticulocyte lysate are compared they are again found to be distinctly different and each is identical to a peptide map of respective authentic SM1 and SM2 myosin heavy chains. It is concluded that the myosin heavy chains of SM1 and SM2 myosin isozymes of ALD muscle have different primary structures and that they are encoded by two distinctly different mRNAs.     

Metabolism of benzo[a]pyrene. Effect of substrate concentration and 3-methylcholanthrene pretreatment on hepatic metabolism by microsomes from rats and mice.

Digestion of insoluble myosin with soluble papain produces heavy meromyosin subfragment 1 (HMM-S-1) having ATPase activity and the ability to combine with actin. These fragments of myosin do not undergo appreciable changes in ATPase activity, chromatographic behavior, or actin combining ability during digestion up to 2 h but, as shown by sodium dodecyl sulfate gel electrophoresis, several splits occur in both the heavy and light polypeptide chains. The largest fragment of heavy chain present in fast, slow, cardiac and embryonic HMM-S-1 has a mass of 89,000 daltons. This fragment undergoes further degradation resulting in fragments having masses of the order of 70,000, 50,000, and 27,000 daltons. The latter fragment and other material resulting from the proteolysis of myosin appear as bands in that region of the gels where the light chains are found in electrophoretograms of the parent myosin. The precise size of the fragments and the rates of their formation depend on the type of myosin; slow and cardiac HMM-S-1 and their fragments show greater stability. Embryonic myosin has properties intermediate between those of fast skeletal and cardiac myosin. Experiments involving the combination of HMM-S-1 with actin and experiments with glutaraldehyde cross linking and chromatography on Sephadex G-200 indicate that the fragments separated by sodium dodecyl sulfate gel electrophoresis are held together by noncovalent forces in HMM-S-1.     

Proteolytic fragmentation of brain myosin and localisation of the heavy-chain phosphorylation site

The heavy chains and the 19-kDa and 20-kDa light chains of bovine brain myosin can by phosphorylated. To localise the site of heavy-chain phosphorylation, the myosin was initially subjected to digestion with chymotrypsin and papain under a variety of conditions and the fragments thus produced were identified. Irrespective of the ionic strength, i.e. whether the myosin was monomeric or filamentous, chymotryptic digestion produced two major fragments of 68 kDa and 140 kDa; the 140-kDa fragment was further digested by papain to yield a 120-kDa and a 23-kDa fragment. These fragments were characterised by (a) a gel overlay technique using 125I-labelled light chains, which showed that the 140-kDa and 23-kDa polypeptides contain the light-chain-binding sites; (b) using myosin photoaffinity labelled at the active site with [3H]UTP, which showed that the 68-kDa fragment contained the catalytic site, and (c) electron microscopy, using rotary shadowing and negative-staining techniques, which demonstrated that after chymotryptic digestion the myosin head remains attached to the tail whereas on papain digestion isolated heads and tails were observed. Thus the 120-kDa polypeptide derived from the 140-kDa fragment is the tail of the myosin, and the 68-kDa fragment containing the catalytic site and the 23-kDa fragment, with the light-chain-binding sites, form the head (S1) portion of the myosin. When [32P]-phosphorylated brain myosin was digested with chymotrypsin and papain it was shown that the heavy-chain phosphorylation site is located in a 5-kDa peptide at the C-terminal end of the heavy chain, i.e. the end of the myosin tail. Using hydrodynamic and electron microscopic techniques, no significant effect of either light-chain or heavy-chain phosphorylation on the stability of brain myosin filaments was observed, even in the presence of MgATP. Brain myosin filaments appear to be more stable than those of other non-muscle myosins. Light-chain phosphorylation did, however, have an effect on the conformation of brain myosin, for example in the presence of MgATP non-phosphorylated myosin molecules were induced to fold into a very compact folded state.     

Pig cardiac myosin isoenzymes

Pig heart myosins isolated from the free wall of the right ventricle and the free wall of the left ventricle were compared with respect to structural and enzymatic properties. The following parameters were studied (1) activation of myosin ATase by Ca2+ and K+j(2) molecular weight of the heavy and light chains of myosins as determined by electrophoretic migration in polyacrylamide sodium dodecyl sulfate (SDS) gels; (3) ability of the heavy chains to form aggregates at low ionic strength as revealed by electron microscopy; (4) sensitivity to the action of chymotrypsin. Differences were observed between left and right ventricular myosins (L-myosin and R-myosin) for all these parameters except for the molecular weight of heavy and light chains. The existence of large amounts of short synthetic filaments for R-myosin compared with L-myosin as revealed by the length repartition of the filaments, and the production of smaller quantities of HMM-S by chymotryptic digestion for R-myosin, strongly suggest the presence of different cardiac myosin heavy chain species.     

Structural and functional changes of myosin during development: comparison with adult fast, slow and cardiac myosin.

ATPase (Ca²⁺ and K⁺ activated) activity of myosin prepared from muscles of 3–4 week rabbit embryos (EM) is slighly lower than that of adult fast muscle myosin (FM), but in contrast to the less active adult slow muscle myosin (SM) is stable on exposure to pH 9.2. Studies of the time course, by means of Na dodecyl-SO₄ polyacrylamide gel electrophoresis, of changes in the pattern of polypeptides released by tryptic digestion show that in this regard EM is closest to SM. The light chain complement of EM appears identical with that of FM rather than of SM or cardiac myosin (CM) by the criteria of coelectrophoresis and removal by 5,5′-dithio-2-dinitrobenzoate treatment of LC₂ except that the relative amount of LC₃ is less in EM than in FM. The staining pattern of light meromyosin (EMM) paracrystals prepared from EM is distinct from either the FM, SM or CM LMM staining pattern. These studies suggest that different genes are involved in the coding for embryonic and adult heavy chains.     

Melting of myosin rod as revealed by electron microscopy. II. Effects of temperature and pH on length and stability of myosin rod and its fragments

Effects of temperature and pH on intact rabbit and chicken myosin, isolated myosin rods, rabbit subfragment-2 (61 kDa, 53 kDa, and 34 kDa) and chicken light meromyosin (LMM) fragments were tested to induce a phase transition from alpha-helix to coil conformation, within the hinge region. The influence of temperature and pH were studied directly with length determination by electron microscopy. An increase of temperature to 50 degrees C yielded a shortening of 16 nm, 8 to 9 nm and 7 to 11 nm for intact myosin, isolated rods and long S-2 fragments, respectively. The length of the 34 kDa short S-2 and LMM fragments were unchanged. An increase of pH from neutral to pH 8.0 yielded values that were somewhat smaller, e.g. 12 nm, 6 nm and 6 to 8 nm for intact myosin, isolated rods and long S-2 fragments, respectively, whereas the 34 kDa short S-2 LMM fragments were also unaffected. Thus, melting and subsequent shortening is confined to the region between LMM and short S-2 segment, that is the hinge region. Alteration of temperature had a stronger shortening effect than alteration of pH, and shortening of long S-2 was more pronounced under physiological salt conditions as compared with high (0.3 M) salt. The shortening of rods in intact myosin amounted to twice the value observed with isolated rods. The amount of contraction was somewhat smaller in rods than in the 61 kDa and 53 kDa long S-2 fragments.     

Hinging of rabbit myosin rod

The question of hinging in myosin rod from rabbit skeletal muscle has been reexamined. Elastic light scattering and optical rotation have been used to measure the radius of gyration and fraction helix, respectively, as a function of temperature for myosin rod, light meromyosin (LMM), and long subfragment 2 (long S-2). The radius of gyration vs temperature profile of myosin rod is shifted with respect to the optical rotation melting curve by about -5 degrees C. Similar studies on both LMM and long S-2 show virtually superimposable profiles. To correlate changes in the secondary structure with the overall conformation, plots of radius of gyration vs fraction helix are presented for each myosin subfragment. Myosin rod exhibits a marked decrease in the radius of gyration from 43 nm to approximately 35 nm, while the fraction helix remains at nearly 100%. LMM and long S-2 did not show this behavior. Rather, a decrease in the radius of gyration of these fragments occurred with comparable changes in fraction helix. These results are interpreted in terms of hinging of the myosin rod within the LMM/S-2 junction.     

Myosin degradation fragments in skeletal muscle

Myosin heavy chain degradation fragments produced in vivo have been identified in chicken pectoralis muscle. The fragments were identified by electrophoresis of unfractionated extracts of chicken pectoralis muscle on sodium dodecyl sulfate/polyacrylamide gels followed by immunoblotting on nitrocellulose sheets. Monoclonal antibodies directed against the S2 and light meromyosin subfragments as well as type II myosin-specific polyclonal antibodies directed against the entire myosin heavy chain were used to characterize the fragments, which range in molecular weight from approximately 80,000 to 180,000. All fragments contain the extreme carboxy-terminal portion of the molecule and are distinct from the classical proteolytic fragments such as heavy and light meromyosin, S1, S2 or rod. These fragments appear to be produced in vivo by proteolytic cleavage of peptides from the amino-terminal (S1) end of the heavy chain while the myosin molecule is still embedded in the thick filament. Fragment concentrations are estimated to be approximately 5 to 10% of that of the intact myosin heavy chain. These fragments are not the result of artifactual damage to myosin, e.g. proteolysis or hydrodynamic shear. The techniques described in this paper provide a probe into the early stages of myosin and thick filament degradation in vivo.     

Effect of the integrity of the myofibrillar structure on the tryptic accessibility of a hinge region of the myosin rod

Limited proteolysis has been used to study the influence of actin, in the absence or presence of regulatory proteins of the thin filament (tropomyosin and troponin), as well as that of the myofibrillar structure on the tryptic cleavage of the heavy meromyosin (HMM)/light meromyosin (LMM) hinge region in myosin heavy chain. Cleavage at the HMM/LMM hinge is almost absent in myofibrils, whereas this hinge is accessible to tryptic digestion in actomyosin, in native thin filaments attached to myosin and in myosin heavy chain alone. This observation indicates that it is the myofibrillar structure which profoundly affects the tryptic accessibility of this specific hinge region of myosin. This provides a good example of the manner by which a highly organized supramolecular structure might affect the chemical properties of a specific site in a macromolecule.     

Localization of a light-chain binding site on smooth muscle myosin revealed by light-chain overlay of sodium dodecyl sulfate-polyacrylamide electrophoretic gels

The interactions of smooth muscle myosin and its light chains have been examined by incubating sodium dodecyl sulfate-polyacrylamide gels of myosin with radioactively labeled regulatory or essential light chains. The technique involves sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fixation with methanol and acetic acid followed by an extensive series of washes. The gel is incubated overnight with labeled light chains in the presence of bovine serum albumin and then washed extensively to remove unbound protein. Following staining and destaining, the gel is autoradiographed to reveal which protein bands have bound light chain. The myosin heavy chain was able to rebind labeled regulatory or essential light chains despite the harsh procedure described above. By fragmenting the myosin heavy chain proteolytically, we were able to determine the binding site for both types of light chains to be within the 26,000-Da COOH-terminal segment of smooth muscle subfragment 1 (S-1) or the 20,000-Da COOH-terminal segment of skeletal muscle S-1. The extent of binding was 0.1-0.4 mol of light chain/mol of S-1 heavy chain. No binding was observed to portions of the myosin molecule which do not contain this segment such as myosin rod, light meromyosin, S-2, or the NH2-terminal 75,000-Da segment of S-1.     

Myosin and actomyosin from human skeletal muscle.

Human skeletal natural actomyosin contained actin, tropomyosin, troponin and myosin components as judged by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Purified human myosin contained at least three light chains having molecular weights (+/-2000) of 25 000, 18 000 and 15 000. Inhibitory and calcium binding components of troponin were identified in an actin-tropomyosin-troponin complex extracted from acetone-dried muscle powder at 37 degrees C. Activation of the Mg-ATPase activity of Ca2+-sensitive human natural or reconstituted actomyosin was half maximal at approximately 3.4 muM Ca2+ concentration (CaEGTA binding constant equals 4.4 - 10(5) at pH 6.8). Subfragment 1, isolated from the human heavy meromyosin by digestion with papain, appeared as a single peak after DEAE-cellulose chromatography. In the pH 6-9 range, the Ca2+-ATPase activity of the subfragment 1 was 1.8- and 4-fold higher that the original heavy meromyosin and myosin, respectively. The ATPase activities of human myosin and its fragments were 6-10 fold lower than those of corresponding proteins from rabbit fast skeletal muscle. Human myosin lost approximately 60% of the Ca2+-ATPase activity at pH 9 without a concomitant change in the number of distribution of its light chains. These findings indicate that human skeletal muscle myosin resembles other slow and fast mammalian muscles. Regulation of human skeletal actomyosin by Ca2+ is similar to that of rabbit fast or slow muscle.     

The tail of myosin reduces actin filament velocity in the in vitro motility assay

It has been observed that heavy meromyosin (HMM) propels actin filaments to higher velocities than native myosin in the in vitro motility assay, yet the reason for this difference has remained unexplained. Since the major difference between these two proteins is the presence of the tail in native myosin, we tested the hypothesis that unknown interactions between actin and the tail (LMM) slow motility in native myosin. Chymotryptic HMM and LMM were mixed in a range of molar ratios (0-5 LMM/HMM) and compared to native rat skeletal myosin in the in vitro motility assay at 30 degrees C. Increasing proportions of LMM to HMM slowed actin filament velocities, becoming equivalent to native myosin at a ratio of 3 LMM/HMM. NH4+ -ATPase assays demonstrated that HMM concentrations on the surface were constant and independent of LMM concentration, arguing against a simple displacement mechanism. Relationships between velocity and the number of available heads suggested that the duty cycle of HMM was not altered by the presence of LMM. HMM prepared with a lower chymotrypsin concentration and with very short digestion times moved actin at the same high velocity. The difference between velocities of actin filament propelled by HMM and HMM/LMM decreased with increasing ionic strength, suggesting that ionic bonds between myosin tail and actin filaments may play a role in slowing filament velocity. These data suggest the high velocities of actin filaments over HMM result from the absence of drag generated by the myosin tail, and not from proteolytic nicking of the motor domain.     

Separation of two different heavy meromyosins. Evidence for the presence of myosin isozymes in rabbit skeletal muscle.

Heavy meromyosin prepared from rabbit skeletal myosin by chymotryptic digestion was separated into two different heavy meromyosins by Sepharose 4B-6 aminohexyl PPi column chromatography. SDS-gel electrophoresis of one fraction of heavy meromyosin, which was eluted with 75 mM ammonium acetate, showed that it contained the small polypeptide chains, g3 and g2, as well as the large chains. The other fraction of heavy meromyosin, which was eluted with 85 mM ammonium acetate, contained g1 and g2. We concluded that the two heavy meromyosins arose from two different populations (isozymes) of myosin. No significant difference in Ca2+-ATPase activity was detected between the two heavy meromyosins.     

The substructure of heavy meromyosin. The effect of Ca2+ and Mg2+ on the tryptic fragmentation of heavy meromyosin.

Heavy meromyosin, obtained by tryptic digestion of myosin, containing two main polypeptides whose masses were estimated as 81,000 and 74,000 dlatons from Na dodecyl-SO4 polyacrylamide gel electrophoresis, was further digested with trypsin. The Ca2+-activated ATPase activity remainded unchanged and the K+-EDTA activity increased while various smaller fragments were formed. The formation of some of these fragments is affected by Ca2+ or Mg2+ as first shown by Bálint et al. (Bálint, M., Schaefer, A., Biro, N. A., Menczel, L., AND Fejes, E. (1971) J. Physiol. Chem. Phys. 3, 455). On the basis of the time course of the appearance of fragments the following relationship emerges: see article. The 64K leads to 60K step is inhibited by divalent cations, while the breakdown of the 74K fragment is accelerated. The effect of Ca2+ was maximal at 0 similar to 0.1 muM, that of Mg2+ at 10 muM. The original light chains of myosin are not present in the heavy meromyosin serving as the starting material, but peptide material appears on electrophoresis in positions starting material, but peptide material appears on electrophoresis in positions where the light chains would be found. The fragments marked by an asterisk are considered to ba alpha-helical on the basis of their solubility at low ionic strength after precipitation with ethanol (Bálint et al.). The fact that alpha helical fragments are derived from the 60,000-dalton fragment indicateds that it is adjacent to the light meromyosin in the intact myosin while the 74,000- dalton fragment would be part of heavy meromysoin subfragment 1. Chromatography of Sephadex G-200 separates fractions with ATPase activity corresponding to heavy meromyosin and heavy meromyosin subfragment 1. Electrophoresis of these Sephadex fractions suggests that the main peptide constituting heavy meromysoin subfragment 1 is connected by noncobalent forces to a portion of the rod that is not immediately adjacent to it in the primary sequence. The significance of this finding is discussed in terms of the flexibility of the myosin head.     

Studies of myosin and its proteolytic fragments by laser Raman spectroscopy.

Two bands in the Raman spectrum of myosin, at 1,304 cm-1 and 1,270 cm-1, are attributable to alpha-helical structure. The first of these, also present in the spectrum of light meromyosin (LMM) but not in that of subfragment-1 (S-1), is assigned to the coiled-coil tail region of myosin; the second, seen in spectra of S-1 or heavy meromyosin (HMM), is largely absent from the spectrum of light meromyosin and is likely to correspond to the alpha-helical segments of the head region. When myosin or LMM aggregates, spectral bands attributable to backbone and sidechain groups sharpen suggesting a reduction in motional freedom. This sharpening is particularly apparent in the 902 cm-1 C--C stretching mode. Mg2+ broadens and shifts the peak at 1,244 cm-1 to 1,237 cm-1 and diminishes the intensity from 1,230 to 1,240 cm-1, changes which appear to be associated the S-1 region. MgPPi produces changes in the 1,300 cm-1 region attributable to alpha-helical regions in coiled-coil structures suggesting that MgPPi affects not only S-1, but also some part of the myosin rod.     

Myosin and actomyosin from human skeletal muscle

Human skeletal natural actomyosin contained actin, tropomyosin, troponin and myosin components as judged by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Purified human myosin contained at least three light chains having molecular weights (±2000) of 25 000, 18 000 and 15 000. Inhibitory and calcium binding components of troponin were identified in an actin-tropomyosin-troponin complex extracted from acetone-dried muscle powder at 37°C. Activation of the Mg-ATPase activity of Ca²⁺-sensitive human natural or reconstituted actomyosin was half maximal at approximately 3.4 μM Ca²⁺ concentration (CaEGTA binding constant = 4.4 · 10⁵ at pH 6.8). Subfragment 1, isolated from the human heavy meromyosin by digestion with papain, appeared as a single peak after DEAE-cellulose chromatography. In the pH 6–9 range, the Ca²⁺-ATPase activity of the subfragment 1 was 1.8-and 4-fold higher that the original heavy meromyosin and myosin, respectively. The ATPase activities of human myosin and its fragments were 6–10 fold lower than those of corresponding proteins from rabbit fast skeletal muscle. Human myosin lost approximately 60% of the Ca²⁺-ATPase activity at pH 9 without a concomitant change in the number of distribution of its light chains. These findings indicate that human skeletal muscle myosin resembles other slow and fast mammalian muscles. Regulation of human skeletal actomyosin by Ca²⁺ is similar to that of rabbit fast or slow muscle     

Studies on the interaction between titin and myosin.

This study examines the interaction of titin and myosin. In order to analyze the domains of myosin contributing to the binding for titin, we conducted a solid phase binding assay. Different portions of myosin (heavy chains, light chains and myosin fragments) were coated on the microtiter wells and reacted with biotinylated titin. Then the binding of biotinylated titin to these polypeptides was detected by using the avidinbiotin-peroxidase method. The results demonstrated that light meromyosin and subfragment 1 were the major domains of myosin interacting with titin. Titin fragments obtained by trypsin digestion were allowed to react with myosin in an affinity column, and the bound fragments were isolated by an acidic elution. Immunoblot analysis of myosin-bound titin fragments revealed that an A-band domain of titin was responsible for the binding of myosin. In addition, biotinylated titin labelled the outer A-bands and Z-bands in intact myofibrils, thus confirming the in situ binding of titin to myosin.     

Effects of actin and calcium ion on chymotryptic digestion of skeletal myosin and their implications to the function of light chains

Experiments have been carried out to assess the involvement of the myosin light chains [obtained by treatment of myosin with 5,5'-dithiobis(2-nitrobenzoic acid) (Nbs2)] in the control of cross-bridge movement and actomyosin interactions. Chymotryptic digestions of myosin, actomyosin, and myofibrils do not detect any Ca2+-induced change in the subfragment 2 region of myosin. Actin, like Ca2+, protects the in situ Nbs2 light chains from proteolysis and causes a partial switch in the digestion product of myosin from subfragment 1 to heavy meromyosin. This effect is independent of the state of aggregation of myosin, and it persists in acto heavy meromyosin and in actinomyosin in 0.6 M NaCl. Digestions and sedimentation studies indicate that there is no direct acto light chain interaction. Proteolysis of myosin shows a gradual transition from production of heavy meromyosin to subfragment 1 with lowering of the salt level. In the presence of Ca2+ heavy meromyosin is generated both in digestions of polymeric and of monomeric myosin. These results are explained in terms of localized changes within the Nbs2 light chains and subfragment 1. Subunit interactions in the myosin head lead to a Ca2+-induced reduction in the affinity of heavy meromyosin for actin in the presence of MgATP. The resulting Ca2+ inhibition of the actin-activated ATPase of myosin can be detected at high salt concentrations(75 mM KCl).     

Solubility properties of a 65-kDa peptide prepared by restricted digestion of myosin with astacin-like squid metalloprotease

Substructure of the myosin rod and its correlation to filament formation is largely based on studies of proteolytic digests and expressed proteins. However, tryptic digestion of myosin always produces polymorphous peptides. Consequently, it is difficult to determine the relation between myosin substructure and filament formation. Similarly, filament formation with recombinant myosin protein is also difficult to interpret because it is never clear whether the recombinant protein folds like the native protein. We recently reported a novel metal protease isolated from squid liver, astacin-like squid metalloprotease (ALSM), which can specifically hydrolyze in vitro myosin heavy chain. In the present study, we examined the solubility properties of the 65-kDa peptide and light meromyosin (LMM) prepared by ALSM isoform II and trypsin digestion, respectively. The 65-kDa peptide is much less soluble than LMM under physiological conditions, even though the length of 65-kDa peptide is shorter than that of LMM. These results suggest that a novel substructure of myosin drives filament assembly.