A new protein of the thick filaments of vertebrate skeletal myofibrils. Extractions, purification and characterization

A new protein component of skeletal myofibrils has been isolated and characterized. It is prepared from impure myosin preparations and corresponds to band C, the principal contaminant observed in sodium dodecyl sulphate polyacrylamide gel electrophoresis patterns of such preparations (Starr and Offer, 1971).The C-protein, as we term it, is deduced to be a component of the skeletal myofibril because (i) glycerinated or fresh myoflbrils contain a component with a mobility identical to C-protein on sodium dodecyl sulphate gels, (ii) this component is extracted from myofibrils by the same solvent which extracts C-protein and (iii) C-protein may be prepared from preparations of isolated myofibrils. It is presumed to be a component of the thick filaments because it binds strongly to myosin at low ionic strength; immunological evidence which confirms this view is presented elsewhere.The quantity of C-protein in the myofibril has been estimated to be 2.0% by densitometry of sodium dodecyl sulphate gels of glycerinated myofibrils using actin as an internal reference. About forty molecules of C-protein are present in a thick filament.The properties of C-protein distinguish it from the other well-characterized myoflbrillar proteins. The C-protein molecule contains a single polypeptide chain of molecular weight 140,000. The intrinsic viscosity of 13.6 ml/g suggests that the molecule is neither completely globular nor as elongated as molecules like paramyosin or tropomyosin. The α-helical content is very low and the proline content higher than the other myofibrillar proteins. The molecule associates at low ionic strength.C-protein has no ATPase activity, nor does it affect the ATPase of pure myosin. But it reduces the activity of the actin-activated myosin ATPase by about half, this inhibition being independent of the level of Ca²⁺. C-protein does not bind Ca²⁺ in the presence of Mg²⁺. Its possible location and function are discussed.     

Novel thick filament protein of chicken pectoralis muscle: the 86 kd protein. I. Purification and characterization

A new thick-filament-associated protein, the 86 kd protein, of chicken pectoralis major muscle was isolated from a crude C-protein preparation by a method similar to that used to purify H-protein from rabbit skeletal muscle. However, the protein with an apparent Mr of 86,000 and 370,000 as estimated by gel electrophoresis and gel permeation, respectively, is not related to C-protein and differs from rabbit H-protein by its elution behaviour from hydroxyapatite columns, by its molecular weight, ultraviolet light spectrum, amino acid composition and localization, and by its amount present in myofibrils. The amino acid composition reveals a high content of proline and gel permeation indicates an either highly asymmetric or polymeric structure of the molecule. Antibodies raised in rabbits against the 86 kd protein were demonstrated by double immunodiffusion and immunoblotting experiments to be specific for this protein. They show no cross-reactivity with any other myofibrillar protein of chicken pectoralis muscle, e.g. myosin, M-band proteins, titin or C-protein, nor did they exhibit a significant cross-reactivity with H-protein from rabbit. The 86 kd protein, which has been purified also by antibody affinity chromatography from a freshly prepared Guba-Straub extract of washed myofibrils, is a specific myofibrillar component located within each half of the A-band.     

Degradation of rat cardiac myofibrils and myofibrillar proteins by a myosin-cleaving protease.

The degradation of rat cardiac myofibrils and their constituent proteins with a myosin-cleaving protease was studied. Electrophoretograms of the digestion products of myofibrils showed that myosin,M-protein, C-protein, and troponin were degraded, but actin and tropomyosin were not. Degradation of these constituents resulted in losses of the Mg2+-ATPase activity and its Ca2+-sensitivity of myofibrils. Incubation of myofibrils with the protease induced the release of alpha-actinin without degradation. Susceptibilities of myosin, actin, troponin, and alpha-actinin purified from rat and pig hearts to the protease were essentially identical to those of the assembled forms in myofibrils. Although the purified tropomyosin was readily degraded into five fragments with the protease, the tropomyosin assembled in myofibrils and actin-tropomyosin complex were insusceptible to the protease. Digestion of myosin in the filamentous state with the protease resulted in the disappearance of myosin heavy chain and light chain 2, producing two fragments having molecular weights of 130,000 and 94,000 which originated from the degradation of heavy chain. The Ca2+- and EDTA-ATPase activities of the degradation products remained unchanged during incubation for 22 h. The actin-activated ATPase activity of myosin was reduced by 30% during incubation for 6 h, and recovered to the original level on adding actin to give a ratio of actin to myosin of 2:1. The pH optima for degradation of myosin in the soluble and filamentous states were 8.5 and 7.0, respectively. The results indicate that cardiac myosin in the filamentous state was more readily degraded with the protease than the myosin in the soluble state.     

C-protein from rabbit soleus (red) muscle.

A new form of skeletal-muscle C-protein has been isolated from rabbit soleus (red) muscle. This new form of C-protein has been purified to homogeneity by a procedure similar to that used to purify C-protein from white skeletal muscle. In soleus muscle, only this new form of C-protein could be detected, whereas in psoas (white) muscle, only the previously identified form of C-protein was detected. The content of C-protein in rabbit soleus muscle is comparable with that found in psoas muscle. Other rabbit skeletal muscles composed of a mixture of fibre types contained at least two forms of C-protein. C-Protein derived from red skeletal muscle bound to myosin isolated from either red or white tissue, with maximum binding occurring at a ratio of approximately 13 microgram of red C-protein/100 microgram of myosin. Polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate indicated that C-protein isolated from red skeletal muscle has a molecular weight approx. 7% greater than that of C-protein isolated from white skeletal muscle. The amino acid content of both forms of C-protein was similar but major differences in the mol % of isoleucine and threonine were found. Antiserum against C-protein from white rabbit skeletal muscle formed a single precipitin line with rabbit C-protein on double in agar. This antiserum did not form a precipitin line when diffused against red C-protein from rabbit skeletal muscle. Also, this antiserum bound specifically to the A-band region of myofibrils isolated from psoas (white) muscle, but it did not bind to myofibrils prepared from soleus (red) muscle.     

Compositional studies of myofibrils from rabbit striated muscle

The localization of high-molecular-weight (80,000-200,000-daltons) proteins in the sarcomere of striated muscle has been studied by coordinated electron-microscopic and sodium dodecyl sulfate (SDS) gel electrophoretic analysis of native myofilaments and extracted and digested myofibrils. Methods were developed for the isolation of thick and thin filaments and of uncontracted myofibrils which are devoid of endoproteases and membrane fragments. Treatment of crude myofibrils with 0.5% Triton X-100 results in the release of a 110,000-dalton component without affecting the myofibrillar structure. Extraction of uncontracted myofibrils with a relaxing solution of high ionic strength results in the complete disappearance of the A band and M line. In this extract, five other protein bands in addition to myosin are resolved on SDS gels: bands M 1 (190,000 daltons) and M 2 (170,000 daltons), which are suggested to be components of the M line; M 3 (150,000 daltons), a degradation product; and a doublet M 4, M 5 (140,000 daltons), thick-filament protein having the same mobility as C protein. Extraction of myofibrils with 0.15% deoxycholate, previously shown to remove Z-line density, releases a doublet Z 1, Z 2 (90,000 daltons) with the same mobility as alpha-actinin, as well as proteins of 60,000 daltons and less, and small amounts of M 1, M 2, M 4, and M 5; these proteins were not extracted with 0.5% Triton X-100. The C, M-line, and Z-line proteins and/or their binding to myofibrils are very sensitive to tryptic digestion, whereas the M 3 (150,000 daltons) component and an additional band at 110,000 daltons are products of proteolysis. Gentle treatment of myofibrils with an ATP relaxing solution results in the release of thick and thin myofilaments which can be pelleted by 100,000-g centrifugation. These myofilaments lack M-and Z-line structure when examined with the electron microscope, and their electrophoretograms are devoid of the M 1, M 2, Z 1, and Z 2 bands. The M 4, M 5 (C-protein doublet), and M 3 bands, however, remain associated with the filaments.     

The binding of skeletal muscle C-protein to F-actin, and its relation to the interaction of actin with myosin subfragment-1.

C-protein is a component of thick filaments of skeletal muscle myofibrils. It is bound to the assembly of myosin tails that forms the filament backbone. We report here that C-protein can also bind to F-actin, with a limiting stoichiometry of approximately one C-protein molecule per 3 to 5 actin subunits and a dissociation constant in the micromolar range at ionic strength 0·07. The binding is not significantly affected by ATP, calcium ions or temperature, or by the presence of tropomyosin on the actin, but it is weakened by increasing ionic strength. Myosin subfragment-1 (S-1) competes with C-protein for binding to actin. In the absence of ATP, S-1 displaces nearly all bound C-protein from actin, while in the presence of ATP, C-protein inhibits the actin activation of S-1 ATPase. Although there is no direct evidence that interaction of C-protein with actin is physiologically significant, the lenght of the C-protein molecule is sufficient so that it could make contact with the thin filaments in muscle while remaining attached to the thick filaments.     

Phosphorylation of skeletal and cardiac muscle C-proteins by the catalytic subunit of cAMP-dependent protein kinase

Catecholamines are known to influence the contractility of cardiac and skeletal muscles, presumably via cAMP-dependent phosphorylation of specific proteins. We have investigated the in vitro phosphorylation of myofibrillar proteins by the catalytic subunit of cAMP-dependent protein kinase of fast- and slow-twitch skeletal muscles and cardiac muscle with a view to gaining a better understanding of the biochemical basis of catecholamine effects on striated muscles. Incubation of canine red skeletal myofibrils with the isolated catalytic subunit of cAMP-dependent protein kinase and Mg-[gamma-32P]ATP led to the rapid incorporation of [32P]phosphate into five major protein substrates of subunit molecular weights (MWs) 143,000, 60,000, 42,000, 33,000, and 11,000. The 143,000 MW substrate was identified as C-protein; the 42,000 MW substrate is probably actin; the 33,000 MW substrate was shown not to be a subunit of tropomyosin and, like the 60,000 and 11,000 MW substrates, is an unidentified myofibrillar protein. Isolated canine red skeletal muscle C-protein as phosphorylated to the extent of approximately 0.5 mol Pi/mol C-protein. Rabbit white skeletal muscle and bovine cardiac muscle C-proteins were also phosphorylated by the catalytic subunit of cAMP-dependent protein kinase, both in myofibrils and in the isolated state. Cardiac C-protein was phosphorylated to the extent of 5-6 mol Pi/mol C-protein, whereas rabbit white skeletal muscle C-protein was phosphorylated at the level of approximately 0.5 mol Pi/mol C-protein. As demonstrated earlier by others, C-protein of skeletal and cardiac muscles inhibited the actin-activated myosin Mg2+-ATPase activity at low ionic strength in a system reconstituted from the purified skeletal muscle contractile proteins (actin and myosin).(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunohistochemical analysis of C-protein isoforms in cardiac and skeletal muscle of the axolotl,Ambystoma mexicanum

Of the several proteins located within sarcomeric A-bands, C-protein, a myosin binding protein (MyBP) is thought to regulate and stabilize thick filaments during assembly. This paper reports the characterization of C-protein isoforms in juvenile and adult axolotls, Ambystoma mexicanum, by means of immunofluorescent microscopy and Western blot analyses. C-protein and myosin are found specifically within the A-bands, whereas tropomyosin and -actin are detected in the I-bands of axolotl myofibrils. The MF1 antibody prepared against the fast skeletal muscle isoform of chicken C-protein specifically recognizes a cardiac isoform (Axcard1) in juvenile and adult axolotls but does not label axolotl skeletal muscle. The ALD66 antibody, which reacts with the C-protein slow isoform in chicken, localizes only in skeletal muscle of the axolotl. This slow axolotl isoform (Ax_slow) displays a heterogeneous distribution in fibers of dorsalis trunci skeletal muscle. The C₃₁₅ antibody against the chicken C-protein cardiac isoform identifies a second axolotl cardiac isoform (Ax_card2), which is present also in axolotl skeletal muscle. No C-protein was detected in smooth muscle of the juvenile and adult axolotl with these antibodies.This work was supported by NIH grants HL-32184 and HL-37702 and a grant-in-aid from the American Heart Association to L.F.L.     

Effects of phosphorylated and unphosphorylated C-protein on cardiac actomyosin ATPase

C-protein, a component of the thick filaments of striated muscles, is reversibly phosphorylated and dephosphorylated in heart. It has been hypothesized that C-protein may be involved in regulating contraction, because the extent of C-protein phosphorylation correlates with the rate of cardiac relaxation. To test this hypothesis, the effects of phosphorylated and unphosphorylated C-protein on the actin-activated ATPase activity of myosin filaments prepared from DEAE-Sephadex-purified myosin were examined. Unphosphorylated C-protein (0.1 microM to 1.5 microM) stimulated actin-activated myosin ATPase activity in a dose-dependent manner. With a myosin: C-protein molar ratio of approximately 1, actin-activated myosin ATPase activity was elevated up to 3.2 times that of the control. Phosphorylated C-protein (2.5 mol PO4/mol C-protein) stimulated the activity somewhat less (2.5 times that of control). The stimulation of ATPase activity by C-protein was due to an increase in the Vmax value (from 0.25/second to 0.62/second) and a decrease in the Km value (from 11.9 microM to 6.7 microM). The addition of C-protein to actomyosin solutions produced an increase in the light-scattering of the actomyosin solution and a distinct precipitation of the actomyosin with time. Phosphorylated C-protein had a smaller effect on light-scattering than dephosphorylated C-protein. C-protein had a negligible effect on Ca-ATPase, EDTA-K-ATPase, or Mg-ATPase activities in the absence of actin. C-protein had only small effects on the actin-activated ATPase of heavy meromyosin. These results suggest that C-protein stimulates actin-activated myosin ATPase activity by enhancing the formation of stable aggregates between actin and myosin filaments.     

Isoforms of C-protein in adult chicken skeletal muscle: detection with monoclonal antibodies

Monoclonal antibodies (McAbs) specific for the C-proteins of chicken pectoralis major and anterior latissimus dorsi (ALD) muscles have been produced and characterized. Antibody specificity was demonstrated by solid phase radioimmunoassay (RIA), immunoblots, and immunofluorescence cytochemistry. Both McAbs MF-1 (or MF-21) and ALD-66 bound to myofibrillar proteins of approximately 150,000 daltons; the former antibody reacted with pectoralis but not ALD myofibrils, whereas the latter recognized ALD but not pectoralis myofibrils. Chromatographic elution of the antigens from DEAE-Sephadex, and their distribution in the A-band, support the conclusion that both of these antibodies recognize variant isoforms of C-protein. Since both McAbs react with a protein of similar molecular weight in the A-band of all myofibrils of the posterior latissimus dorsi (PLD) muscle, we suggest that either another isoform of C-protein exists in the PLD muscle or both pectoralis and ALD-like isoforms coexist in the A-bands of PLD muscle.     

Novel thick filament protein of chicken pectoralis muscle: the 86 kd protein. II. Distribution and localization

Antibodies specific for the novel 86 kd protein purified from chicken pectoralis myofibrils stained by indirect immunofluorescence the middle third of each half A-band of isolated myofibrils and myotubes. Pectoralis muscle 86 kd protein, like pectoralis C-protein, displayed a fibre-type specific distribution by being restricted to fast twitch fibres and absent in slow tonic and heart muscle fibres. This was demonstrated by immunoblotting experiments with tissue extracts and by immunofluorescence labelling of cryosections. In primary cell cultures prepared from embryonic chicken breast muscle, 86 kd protein, C-protein and myomesin were all detected in post-mitotic myoblasts where fluorescence was found in a cross-striated pattern along strands of nascent myofibrils. Fluorescence due to the 86 kd protein was restricted to myofibrils within myotubes and no significant labelling of the sarcoplasm was evident. Glycerinated fast twitch muscle fibres, after incubation with antibodies to 86 kd protein, revealed in each half of the A-band nine distinctly labelled stripes, spaced about 43 nm apart. Simultaneous incubation of fibres with antibodies against 86 kd protein and C-protein showed a co-localization of the seven C-protein stripes (stripes 5 to 11), with seven stripes of 86 kd protein. The two additional stripes (stripes 3 and 4) labelled by anti-86 kd antibody continued towards the M-band at the same periodicity from the last C-protein stripe (stripe 5). Thus, partial co-localization of two different thick filament proteins is demonstrated and the identity of transverse stripes at positions 3 and 4 attributed in part to the presence of the new 86 kd protein.     

Developmental relationship of myosin binding proteins (myomesin, connectin and C-protein) to myosin in chicken somites as studied by immunofluorescence microscopy

The developmental relationship of myosin binding proteins (myomesin, connectin and C-protein) to myosin was studied in chicken cervical somites by immunofluorescence microscopy. Muscle and non-muscle myosins initially appeared as slender rods at the same sites, and then, fused to form non-striated fibrils. As muscle myosin formed striated structures (A bands), non-muscle myosin disappeared from this structure. Myomesin (reactive with monoclonal antibodies MyB4 and MyBB78) and connectin (carboxy terminal region, reactive with monoclonal antibody T51) were seen as dots in the center of these myosin rods. These proteins then formed characteristic mature striations on non-striated fibrils of myosin. Earlier alignment of these myosin binding proteins rather than myosin indicates that the correct assembly of these proteins seems to be related to the formation of initial myosin rods as well as subsequent linear and periodic alignment of myosin molecules to form early A bands. Connectin spots reactive with 9D10 were scattered around myosin rods/myomesin dots/connectin T51 dots. These spots may represent radiating connectin filaments from these rods/dots to link myosin rods to the I-Z-I structures of myofibrils to be incorporated. Since the slow isoform of C-protein formed its characteristic bands ("doublets") prior to H zone formation within A bands by myosin, this isoform may help to precisely align myosin filaments within the A band region. The presence of the slow, then the slow and the cardiac, and finally the co-existence of the slow and the fast isoforms of C-protein may interfere with the incorporation and co-polymerization of non-adult isoforms into myofibrils.     

Cardiac myosin from pig heart ventricle. Purification and enzymatic properties.

A method is described for the preparation of high purity myosin from the left ventricle of pig heart. The purified myosin was free from nucleic acid, actin, tropomyosin, troponin, the 150,000 molecular weight protein and other contaminants. Analyses of subunits in the purified myosin were carried out on 3.5% acrylamide gel with 0.1% SDS. Of the total protein present in myosin, 11.3% was in the light chains; light chain 1 (LC1), 5.9% and light chain 2 (LC2), 5.4%. Urea gel electrophoresis of the purified myosin showed three closely spaced bands corresponding to the 20,000 dalton, the charge-modified 20,000 dalton and the phosphorylated 20,000 dalton components. The properties of the Ca2+-activated and K+-activated ATPases [EC 3.6.1.3] of the purified myosin were also studied. The Km values were 27 and 55 muM and the Vmax values were 0.263 and 0.317 mumole P1/mg/min for the Ca2+-activated and K+-activated ATPases, respectively. The pH-activity profiles and the effects of SH modification were of the skeletal myosin type except that the activities were lower.     

Mode of action of rabbit skeletal muscle cathepsin B towards myofibrillar proteins and the myofibrillar structure.

1. The mode of degradation of myofibrillar proteins and the structural changes in myofibrils due to the action of cathepsin B highly purified from rabbit skeletal muscle were studied. 2. Cathepsin B degraded myosin heavy chain, actin and troponin T, but not alpha-actinin, tropomyosin, troponin I or troponin C among myofibrillar proteins. 3. Cathepsin B optimally degraded myosin heavy chain, actin and troponin T at around pH 5. Degradation of myosin heavy chain produced 6 fragments, 180,000, 150,000, 87,000, 81,000, 75,000 and 69,000 Da, respectively. Actin was hydrolyzed into fragments of 41,000, 38,000 and 30,000 Da. Troponin T was degraded into fragments of 21,000, 12,000 and 10,000 Da. 4. Cathepsin B caused the fragmentation of myofibrils and disturbance of the lateral arrangement of myofibrils. 5. Cathepsin B partly disintegrated the Z-line and the M-line, and induced disordering of the arrangement of filaments in the I-band.     

Phosphorylation of C-protein, troponin I and phospholamban in isolated rabbit hearts.

Phosphorylation of myofibrillar and sacroplasmic-reticulum (SR) proteins was studied in Langendorff-perfused rabbit hearts subjected to various inotropic interventions. Stimulation of hearts with isoprenaline resulted in the phosphorylation of both troponin I (TnI) and C-protein in myofibrils and phospholamban in SR. Phosphorylation of phospholamban could be reversed by a 15 min perfusion with drug-free buffer, after a 1 minute pulse perfusion with isoprenaline, at which time the mechanical effects of isoprenaline stimulation had also been reversed. However, both TnI and C-protein remained phosphorylated at this time. Moreover, the inhibition of Ca2+ activation of the Mg2+-dependent ATPase (Mg-ATPase) activity associated with myofibrillar phosphorylation persisted in myofibrils prepared from hearts frozen after 15 min of washout of isoprenaline. To assess the contribution of C-protein phosphorylation in the decrease of Ca2+ activation of the myofibrillar Mg-ATPase activity, we reconstituted a regulated actomyosin system in which only C-protein was phosphorylated. In this system, C-protein phosphorylation did not contribute to the decrease in Ca2+ activation of Mg-ATPase activity, indicating that TnI phosphorylation is responsible for the diminished sensitivity of the myofibrils to Ca2+. These observations support the hypothesis that phospholamban phosphorylation plays a more dominant role than TnI or C-protein phosphorylation in the mechanical response of the mammalian heart to beta-adrenergic stimulation.     

Striated myofibrils in anti-myosin stained, isolated chicken gizzard smooth muscle cells.

Highly purified chicken gizzard myosin was used to induce antibody production in rabbits. The IgG fraction was separated from the antisera and coupled to fluorescein isothiocyanate (FITC). Specific antibody (AGM) was isolated from the IgG fraction by affinity purification. Comparisons of the specificity of IgG and AGM for chicken smooth muscle myosin revealed a much greater specificity by AGM. Staining with IgG led to an apparent cross-reactivity with guinea pig smooth muscles which was not seen with AGM staining. Therefore, staining of cells for localization of myosin was performed with AGM. Isolated cells were obtained from chicken gizzards either by collagenase digestion or by agitation of glycerinated pieces. Stained cells and cell fragments revealed the presence of myofibrils as structural units with diameters of about 1.0 micrometer. Stained myofibrils occasionally displayed regular banding patterns with a repeating period of about 1.5 +/- 0.2 micrometer. The presence of banded myofibrils in non-cultured cells shows that the organization of the contractile material is similar to that previously reported for cultured cells by Gr?schel-Stewart.     

Purification from Dictyostelium discoideum of a low-molecular-weight myosin that resembles myosin I from Acanthamoeba castellanii

A low-molecular-weight myosin has been purified 1500-fold from extracts of Dictyostelium discoideum, based on the increase in K+,EDTA-ATPase specific activity. The purified enzyme resembles the single-headed, low-molecular-weight myosins IA and IB from Acanthamoeba castellanii, and differs from the conventional two-headed, high-molecular-weight myosin previously isolated from Dictyostelium, in several ways. It has higher K+,EDTA-ATPase activity than Ca2+-ATPase activity; it has a native molecular mass of about 150,000 and a single heavy chain of about 117,000; the 117,000-dalton heavy chain is phosphorylated by Acanthamoeba myosin I heavy chain kinase; phosphorylation of its heavy chain enhances its actin-activated Mg2+-ATPase activity; and the 117,000-dalton heavy chain reacts with antibodies raised against the heavy chain of Acanthamoeba myosin IA. None of these properties is shared by the low-molecular-weight active fragment that can be produced by chymotryptic digestion of conventional Dictyostelium myosin. We conclude that Dictyostelium contains an enzyme of the myosin I type previously isolated only from Acanthamoeba.     

The inhibitory action of the light meromyosin component on the myofibrillar and actomyosin atp-ase.

The protein component of light meromyosin [LMM-1] was shown earlier to relax glycerinated muscle fibres and actomyosin. Presently its influence on ATP-ase activity of myofibrils, actomyosin, myosin and heavy meromyosin has been studied. LMM-1 decreases Mg-ATP-ase activity of myofibrils and of reconstructed actomyosin by 25-- 30% and does not change [or slightly increases] Ca-ATP-ase activity of this protein and of myosin; besides LMM-1 is able to increase Mg-ATP-ase of HMM substantially. LMM-1 markedly inhibits [preliminary data] the activation of ATP-ase activity of HMM by actin. It is suggested that LMM-1 protein interacts with myosin and decreases the actin-myosin affinity, displacing actin out of the complex. It reacts only with one of the heads of myosin. Probably this suggestion can account for a relatively slight inhibition of ATP-ase activity of complex by LMM-1. LMM-1 represents a natural and specific inhibitor of Mg-AM-ATP-ase activity, included in the structure of myosin protofibrils and interacting with the myosin active site region.     

H-protein and X-protein. Two new components of the thick filaments of vertebrate skeletal muscle

With a view to obtaining a more complete view of the composition and structure of the thick filaments of vertebrate skeletal muscle, we have isolated and characterized two new myofibrillar components, H-protein and X-protein. These were purified by hydroxyapatite column chromatography of an impure C-protein preparation itself made from impure myosin extracted from rabbit back and leg muscles. H-protein is the protein responsible for band H on sodium dodecyl sulphate/polyacrylamide gel electrophoresis of crude myosin. X-protein, although present in such preparations in significant quantities, was not detected previously since it is difficult to resolve from C-protein by sodium dodecyl sulphate/polyacrylamide gel electrophoresis. Physical-chemical parameters have been determined for the new proteins and compared with those of C-protein. The apparent chain weight of H-protein estimated by sodium dodecyl sulphate/polyacrylamide gel electrophoresis is 69,000, whereas that of X-protein (152,000) is only slightly greater than that of C-protein (140,000). The molecular weights of H- and X-proteins determined by sedimentation equilibrium centrifugation show that the molecules contain only a single polypeptide chain. The circular dichroism spectra indicate that the proteins have low alpha-helical contents. Both proteins, particularly H-protein, have a high proline content. Although X-protein is of similar chain weight to C-protein, the two show distinct differences in other properties. The sedimentation coefficient of X-protein is markedly lower than that of C-protein, suggesting X-protein is a more asymmetrical molecule. The amino acid compositions, although broadly similar, also show clear differences. Antibodies to H-protein, X-protein and C-protein have been raised in goats and shown not to cross-react.     

A Ca2+-activated protease possibly involved in myofibrillar protein turnover. Partial characterization of the purified enzyme.

The purified Ca2+-activated protease (CAF) isolated from porcine skeletal muscle and capable of removing Z-disks from intact myofibrils is optimally active on either myofibril or casein substrates at pH 7.5 and in the presence of 1 mM Ca2+ and at least 2 mM 2-mercaptoethanol. No CAF activity is detected when 1 mM Mg2+, Mn2+, Ba2+, Co2+, Ni2+, and Fe2+ are added singly. When added with 1 mM Ca2+, Co2+, Cu2+, Ni2+, and Fe2+ inhibit, whereas Mg2+, Mn2+, and Ba2+ have no effect on CAF activity. CAF is irreversibly inhibited by iodoacetate but is unaffected by soybean trypsin inhibitor. S0/20,W=5.90 S, and sedimentation equilibrium molecular weight - 112 000 for purified CAF. Because purified CAF migrates as two polypeptide chains with molecular weights of 80 000 and 30 000 in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the CAF molecule must consist of one each of these two polypeptide chains. Approximate molecular dimensions of 38 X 220 A can be calculated for CAF from calibrated gel permeation column data or from S0/20,W and the molecular weight. Amino acid composition and physical properties of purified CAF distinguish it from the known catheptic enzymes and from other proteases found in blood or in granulocytes. Purified CAF removes Z-disks the 400-A periodicity associated with troponin in the I band and partly degrades M lines but causes no other ultrastructurally detectable effects when incubated with myofibrils. These results agree with the earlier finding that purified CAF degrades troponin, tropomyosin, and C-protein but has no effect on myosin, actin, or alpha-actinin, and suggest that CAF may have a physiological role in disassembly of intact myofibrils during metabolic turnover of myofibrillar proteins.