Role of the regulatory light chains in skeletal muscle actomyosin ATPase and in minifilament formation

Incubation of myosin with myopathic hamster protease results in substantial (more than 80%) removal of light chain 2 (LC2) with limited breakdown of the heavy chains. LC2-deficient myosin, purified by ion exchange chromatography, migrates as a single, monodisperse boundary in the analytical ultracentrifuge. The Ca2+- and EDTA-activated ATPases of LC2-deficient myosin are similar to those of the control and LC2-recombined myosins indicating that no denaturation occurred in its preparation. Double reciprocal plots for LC2-deficient, control, and LC2-recombined myosins reveal a biphasic behavior i.e. at actin concentrations above 11 microM, there is a sharp break in the 1/V versus 1/[actin] plots for all samples. The Vm values for LC2-deficient myosin are 50% lower (at low actin, Vm = 3.0 s-1, and at high actin, Vm = 4.2 s-1) than those for control myosin (Vm = 5.3 s-1 at low actin and 8.3 s-1 at high actin). Readdition of LC2 to LC2-deficient myosin restores the actin-activated ATPase to control levels. Electron microscopy of shadow cast preparations reveals a subtle difference between LC2-deficient myosin, and control or recombined myosin. In control and recombined myosins, S1 heads appear "pear"-shaped, whereas in LC2-deficient myosin, the S1 heads are rounder and display a "thinning" of mass in the "neck" region, suggesting that LC2 binds at the S1/S2 junction. Furthermore, removal of LC2 apparently influences the assembly of myosin into minifilaments, as revealed to a certain degree, by an increase in the width of the bare zone, accompanied by a decrease in the stability of these minifilaments.     

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.     

Proteolysis of smooth muscle myosin by Staphylococcus aureus protease: preparation of heavy meromyosin and subfragment 1 with intact 20 000-dalton light chains

The proteolysis of gizzard myosin by Staphylococcus aureus protease produces both heavy meromyosin and subfragment 1 in which the 20 000-dalton light chains are intact, and conditions are suggested for the preparation of each. Cleavage of the myosin heavy chain to produce subfragment 1 is dependent on the myosin conformation. Proteolysis of myosin in the 10S conformation yields predominantly heavy meromyosin, and myosin in the 6S conformation yields mostly subfragment 1 and some heavy meromyosin. Two sites are influenced by myosin conformation, and these are located at approximately 68 000 and 94 000 daltons from the N-terminus of the myosin heavy chain. The latter site is thought to be located at the subfragment 1-subfragment 2 junction, and cleavage at this site results in the production of subfragment 1. The time courses of phosphorylation of both heavy meromyosin and subfragment 1 can be fit by a single exponential. The actin-activated Mg2+-ATPase activity of heavy meromyosin is markedly activated by phosphorylation of the 20 000-dalton light chains. From the actin dependence of Mg2+-ATPase activity the following values are obtained: for phosphorylated heavy meromyosin, Vmax approximately 5.6 s-1 and Ka (the apparent dissociation constant for actin) approximately 2 mg/mL; for dephosphorylated heavy meromyosin, Vmax approximately 0.2 s-1 and Ka approximately 7 mg/mL. The actin-activated ATPase activity of subfragment 1 is not influenced by phosphorylation, and Vmax and Ka for both the phosphorylated and dephosphorylated forms are 0.4 s-1 and 5 mg/mL, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of the actin-activated ATPase of aorta smooth muscle myosin

Phosphorylation of the 20,000-Da light chains, LC20, of vertebrate smooth muscle myosins is thought to be the primary mechanism for regulating the actin-activated ATPase activities of these myosins and consequently smooth muscle contraction. While actin stimulates the MgATPase activities of phosphorylated smooth muscle myosins, it is generally believed that the MgATPase activities of the unphosphorylated myosins are not stimulated by actin. However, under conditions where both unphosphorylated (5% phosphorylated LC20) and phosphorylated calf aorta myosins are mostly filamentous, the maximum rate, Vmax, of the actin-activated ATPase of the unphosphorylated myosin is one-half that of the phosphorylated myosin. While LC20 phosphorylation causes only a modest increase in Vmax, in the presence of tropomyosin, this phosphorylation does cause up to a 10-fold decrease in Kapp, the actin concentration required to achieve 1/2 Vmax. In the presence of low concentrations of tropomyosin/actin, a linear relationship is obtained between the fraction of LC20 phosphorylated and stimulation of the actin-activated ATPase. The relatively high actin-activated ATPase activity of unphosphorylated aorta myosin suggests that other proteins may be involved in the regulation of smooth muscle contraction. In contrast to the results presented here for aorta myosin, it has been reported that actin does not activate the MgATPase activity of unphosphorylated gizzard myosin and that the actin-activated ATPase of gizzard myosin increases more slowly than LC20 phosphorylation.     

Formation and characterization of myosin hybrids containing essential light chains and heavy chains from different muscle myosins

Light chain exchange in 4.7 M NH4Cl was used to hybridize the essential light chain of cardiac myosin with the heavy chain of fast muscle myosin subfragment 1, S-1. The actin-activated ATPase properties of this hybrid were compared to those of the two fast S-1 isoenzymes, S-1(A1), fast muscle subfragment 1 which contains only the alkali-1 light chain, and S-1(A2), fast muscle myosin subfragment 1 which contains only the alkali-2 light chain. This hybrid S-1 behaved like S-1(A1)., At low ionic strength in the presence of actin, this hybrid had a maximal rate of ATP hydrolysis about the same as that of S-1(A1) and about one-half that of S-1(A2), while at higher ionic strengths the actin-activated ATPases of these three S-2 species were all similar. Light chain exchange in NH4Cl was also used to hybridize the essential light chains of fast muscle myosin with the heavy chains of cardiac myosin and to hybridize the essential light chains of cardiac myosin with the heavy chains of fast muscle myosin. In 60 and 100 mM KCl, the actin-activated ATPases of these two hybrid myosins were very different from those of the control myosins with the same essential light chains but were very similar to those of the control myosins with the same heavy chains, differing at most by one-third.     

Inhibition of conformational change in smooth muscle myosin by a monoclonal antibody against the 17-kDa light chain

Monoclonal antibodies against gizzard smooth muscle myosin were generated and characterized. One of these antibodies, designated MM-2, recognized the 17-kDa light chain and modulated the ATPase activities and hydrodynamic properties of smooth muscle myosin. Rotary shadowing electron microscopy showed that MM-2 binds 51 (+/- 25) A from the head-rod junction. The depression of Ca2+- and Mg2+-ATPase activities of myosin and Ca2+-ATPase activity of heavy meromyosin at low KCl concentration were abolished by MM-2. Viscosity measurement indicated that MM-2 inhibits the transition of 6 S myosin to 10 S myosin. While the rate of the production of subfragment-1 by papain proteolysis of 6 S myosin was inhibited by MM-2, the rate of proteolysis of the heavy chain of 10 S myosin was enhanced by MM-2 and reached the same rate as that of 6 S myosin plus MM-2. These results suggest that MM-2 inhibits the formation of 10 S myosin by binding to the 17-kDa light chain which is localized at the head-neck region of the myosin molecule. MM-2 increased the Vmax of actin-activated Mg2+-ATPase activities of both dephosphorylated myosin and dephosphorylated heavy meromyosin about 10- and 20-fold, respectively. MM-2 also activated the actin-activated Mg2+-ATPase activity of phosphorylated myosin at a low MgCl2 concentration and thus abolished the Mg2+-dependence of acto phosphorylated myosin ATPase activity. These results suggest that MM-2 inhibits the formation of 10 S myosin, and this results in the activation of actin-activated Mg2+-ATPase activity even in the absence of phosphorylation.     

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).     

Actin-activated Mg-ATPase activity of Dictyostelium myosin II. Effects of filament formation and heavy chain phosphorylation.

The actin-activated Mg-ATPase activities of unphosphorylated and heavy chain phosphorylated Dictyostelium myosin II and of a Dictyostelium myosin II heavy meromyosin (HMM) fragment were examined at different Mg2+ and KCl concentrations. The Mg-ATPase activity of HMM displayed a maximum rate, Vmax, of about 4.0/s and a Kapp (actin concentration required to achieve 1/2 Vmax) that increased from 8 to 300 microM as the KCl concentration increased from 0 to 120 mM. When assayed with greater than 5 mM Mg2+ and 0 mM KCl the unphosphorylated Dictyostelium myosin II yielded a Kapp of 0.25 microM and a Vmax of 2.8/s. At lower Mg2+ concentrations or with 50 mM KCl the data were not fit well by a single hyperbolic curve and Kapp increased to 25-100 microM. The increase in Kapp did not correlate with the loss of sedimentable filaments. At KCl concentrations above 100 mM Vmax increased to greater than 4/s. Heavy chain phosphorylated myosin (3.5 mol of phosphate/mol myosin) displayed a Vmax of about 5/s and a Kapp of 50 microM under all conditions tested. Thus, heavy chain phosphorylation inhibited the actin-activated Mg-ATPase activity of Dictyostelium myosin II in 5-10 mM Mg2+ and low ionic strength through an increase in Kapp.     

ATPase activities and actin-binding properties of subfragments of Acanthamoeba myosin IA

Previous studies had led to the conclusion that the globular, single-headed myosins IA and IB from Acanthamoeba castellanii contain two actin-binding sites: one associated with the catalytic site and whose binding to F-actin activates the Mg2+-ATPase activity and a second site whose binding results in the cross-linking of actin filaments and makes the actin-activated ATPase activity positively cooperative with respect to myosin I concentration. We have now prepared a 100,000-Da NH2-terminal peptide and a 30,000-Da COOH-terminal peptide by alpha-chymotryptic digestion of the myosin IA heavy chain. The intact 17,000-Da light chain remained associated with the 100,000-Da fragment, which also contained the serine residue that must be phosphorylated for expression of actin-activated ATPase activity by native myosin IA. The 30,000-Da peptide, which contained 34% glycine and 21% proline, bound to F-actin with a KD less than 0.5 microM in the presence or absence of ATP but had no ATPase activity. The 100,000-Da peptide bound to F-actin with KD = 0.4-0.8 microM in the presence of 2 mM MgATP and KD less than 0.01 microM in the absence of MgATP. In contrast to native myosin IA, neither peptide cross-linked actin filaments. The phosphorylated 100,000-Da peptide had actin-activated ATPase activity with the same Vmax as that of native phosphorylated myosin IA but this activity displayed simple, noncooperative hyperbolic dependence on the actin concentration in contrast to the complex cooperative kinetics observed with native myosin IA. These results provide direct experimental evidence for the presence of two actin-binding sites on myosin IA, as was suggested by enzyme kinetic and filament cross-linking data, and also for the previously proposed mechanism by which monomeric myosins I could support contractile activities.     

Effects of removal of light chain 2 on the ATPase activities of cardiac myosin from normal and thyrotoxic rabbits

Steady-state ATPase activities of cardiac myosin from thyroxine-treated rabbit hearts have been determined before and after removal of the 18-kDa light-chain subunit (LC2) of myosin. LC2 was selectively removed from myosin by treatment with a myofibrillar protease according to the method of Kuo and Bhan (Biochem. Biophys. Res. Commun. 92, 570-576 (1980) ). The effects of removal of LC2 on the enzymatic properties of thyrotoxic myosin were compared with the results obtained for cardiac myosin from normal rabbits by parallel studies. It has been found that removal of LC2 does not affect the Ca2+- and K+ (EDTA)-ATPase activities of these myosins. The actin-activated myosin Mg2+-ATPase activities of intact and LC2-deficient thyrotoxic myosin were 0.18 +/- 0.03 and 0.36 +/- 0.03 mumol Pi/mg per min, respectively, whereas the actin-activated myosin Mg2+-ATPase activities of intact and LC2-deficient normal myosin were 0.12 +/- 0.02 and 0.18 +/- 0.03 mumol Pi/mg per min, respectively. Thus, removal of LC2 increases the actin-activated myosin Mg2+-ATPase activity of thyrotoxic myosin by 100%, and the same activity is increased about 50% for normal myosin, indicating that the degree of potentiation of actin-activated myosin Mg2+-ATPase activity as a result of LC2 removal is 2-fold greater in thyrotoxic myosin than that obtained for normal myosin. These results suggest that LC2 does not influence the increased actomyosin ATPase activity of thyrotoxic myosin and that potentiation of actomyosin ATPase following LC2 removal may depend on the variations of the heavy-chain domain where LC2 interacts.     

Ca(2+)-dependent effects of C-protein on the actin-activated ATPase of phosphorylated and dephosphorylated skeletal muscle myosin.

The effects of C-protein on actin-activated myosin ATPase depending on Ca(2+)-level and LC2-phosphorylation were studied. Column-purified myosin and non-regulated actin were used. At ionic strength of 0.06 C-protein inhibits actomyosin ATPase activity both in the presence and in the absence of calcium, more effective in the case of dephosphorylated myosin. For this myosin, at mu = 0.12 C-protein activates actomyosin ATPase at pCa4, but slightly inhibits at pCa8. No such effects have been observed in the case of phosphorylated myosin. The possibility of coordinative action of LC2-chains and C-protein in regulatory mechanism of skeletal muscle contraction is discussed.     

Enzymatic properties of the heavy meromyosin subfragment of cardiac myosin from normal and thyrotoxic rabbits.

Myosin from the hearts of thyrotoxic animals (myosin-T) exhibits elevated Ca2+-ATPase activity. To clarify the physiological significance of this increased activity, we have investigated the steady state kinetics of the interaction of actin and MgATP with the double-headed heavy meromyosin subfragment of cardiac myosin from thyrotoxic rabbits (HMM-T). The enhanced Ca2+-ATPase activity of myosin-T was completely retained in HMM-T. The Vmax for actin-activated MgATP hydrolysis by HMM-T (1.08 +/- 0.10 mumol of Pi/mg/min). Under physiological ionic conditions, the Vmax was 0.14 +/- 0.02 mumol of Pi/mg/min as compared with the normal value of 0.08 +/- 0.01 mumol of Pi/mg/min. Furthermore, the salt dependence of Vmax and Kapp for the actin-activated ATPase of HMM-T differed markedly from normal and resembled that usually associated with the single-headed (S1) cleavage product of myosin. These results suggest that the changes in enzymatic properties of myosin-T are responsible for the increased speed of contraction observed in the hearts of thyrotoxic animals. Also, the alteration in the interaction of HMM-T with actin suggests that a loss of cooperativity between the myosin heads may occur.     

The actomyosin ATPase of synthetic myosin minifilaments, filaments, and heavy meromyosin

The actin-activated ATPase activities of myosin minifilaments and heavy meromyosin are similar at high actin concentrations. Under low ionic strength conditions, the minifilaments in Tris citrate buffer yield the same maximal turnover rate (Vmax) and apparent dissociation constant of actin from myosin (Kapp) as heavy meromyosin in standard low salt conditions. The time course of actin-activated ATP hydrolysis of minifilaments is similar to that observed for standard myosin preparations. Depending on the exact protein composition of the assay mixture, either the ATPase activity declines continuously with time, or is accelerated at the onset of superprecipitation. In analogy with myosin filaments, the ATPase of minifilaments shows a biphasic dependence on actin concentration. Super-precipitation of minifilaments follows a well resolved clearing phase during which their structural integrity appears to be fully preserved. These results indicate that minifilaments or similar small assemblies of myosin can fulfill contractile functions.     

Actin from Saccharomyces cerevisiae.

Inhibition of DNase I activity has been used as an assay to purify actin from Saccharomyces cerevisiae (yeast actin). The final fraction, obtained after a 300-fold purification, is approximately 97% pure as judged by sodium dodecyl sulfate-gel electrophoresis. Like rabbit skeletal muscle actin, yeast actin has a molecular weight of about 43,000, forms 7-nm-diameter filaments when polymerization is induced by KCl or Mg2+, and can be decorated with a proteolytic fragment of muscle myosin (heavy meromyosin). Although heavy meromyosin ATPase activity is stimulated by rabbit muscle and yeast actins to approximately the same Vmax (2 mmol of Pi per min per mumol of heavy meromyosin), half-maximal activation (Kapp) is obtained with 14 micro M muscle actin, but requires approximately 135 micro M yeast actin. This difference suggests a low affinity of yeast actin for muscle myosin. Yeast and muscle filamentous actin respond similarly to cytochalasin and phalloidin, although the drugs have no effect on S. cerevisiae cell growth.     

Preparation and characterization of heavy meromyosin and subfragment 1 from vertebrate cytoplasmic myosins

The soluble fragments of myosin, heavy meromyosin (HMM), and subfragment 1 (S-1) have been instrumental in elucidating the kinetic mechanisms of the actin-activated MgATPase activity of both skeletal and smooth muscle myosin. To date, relatively little has been published on these fragments from vertebrate cytoplasmic myosins. We now describe the preparation and steady-state kinetic characterization of S-1 and HMM from human platelet and avian intestinal epithelial brush border myosin. The HMM prepared from each of these tissues was similar both in their SDS-polyacrylamide gel pattern and in their steady-state kinetic properties. The Vmax of the actin-activated MgATPase activity varied between 0.8 and 2.5 s-1, and the KATPase (the apparent dissociation constant derived from a double-reciprocal plot of the MgATPase activity) was about 1-2 microM. This low value for the apparent dissociation constant was similar to the dissociation constant of HMM for actin directly measured under similar conditions and is about 40 times lower than that determined with avian smooth muscle HMM. The KATPase of the cytoplasmic HMM was only slightly increased when the ionic strength was raised from 12 to 112 mM.     

Effects of Ca2+ on the conformation and enzymatic activity of smooth muscle myosin

The influence of Ca2+ on the enzymatic and physical properties of smooth muscle myosin was studied. The actin-activated ATPase activity of phosphorylated gizzard myosin and heavy meromyosin is higher in the presence of Ca2+ than in its absence, but this effect is found only at lower MgCl2 concentrations. As the MgCl2 concentration is increased, Ca2+ sensitivity is decreased. The concentration of Ca2+ necessary to activate ATPase activity is higher than that required to saturate calmodulin. The similarity of the pCa dependence of ATPase activity and of Ca2+ binding to myosin and the competition by Mg2+ indicate that these effects involved the Ca2+-Mg2+ binding sites of gizzard myosin. For the actin dependence of ATPase activity of phosphorylated myosin at low concentrations of MgCl2, both Vmax and Ka are influenced by Ca2+. The formation of small polymers by phosphorylated myosin in the presence of Ca2+ could account for the alteration in the affinity for actin. For the actin dependence of phosphorylated heavy meromyosin at low MgCl2 concentrations, Ca2+ induces only an increase in Vmax. To detect alterations in physical properties, two techniques were used: viscosity and limited papain hydrolysis. For dephosphorylated myosin, 6 S or 10 S, Ca2+-dependent effects are not detected using either technique. However, for phosphorylated myosin the decrease in viscosity corresponding to the 6 S to 10 S transition is shifted to lower KCl concentrations by the presence of Ca2+. In addition, a Ca2+ dependence of proteolysis rates is observed with phosphorylated myosin but only at low ionic strength, i.e. under conditions where myosin assumes the folded conformation.     

Cooperativity of actin-activated ATPase of gizzard heavy meromyosin in the presence of gizzard tropomyosin

The mechanism for the potentiation of the actin-activated ATPase of smooth muscle myosin by tropomyosin is investigated using smooth muscle actin, tropomyosin, and heavy meromyosin. In the presence of tropomyosin, an increase in Vmax occurs with no effect on KATPase and Kbinding at 20 mM ionic strength. Utilizing N-ethylmaleimide-treated subfragment-1, which forms rigor complexes with actin in the presence of ATP but does not have ATPase activity, experiments were carried out to determine if the tropomyosin-actin complex exists in both the turned-off and turned-on forms as in the skeletal muscle system. At both 60 and 100 mM ionic strengths, the presence of rigor complexes on the smooth muscle actin filament containing bound tropomyosin causes a 2-3-fold increase in Vmax and about a 3-fold increase in KATPase, resulting in about a 4-fold increase in ATPase activity at moderate actin concentration. The increase in KATPase is correlated with an increase in Kbinding. The finding that rigor complexes increase Vmax and the binding constant for heavy meromyosin to tropomyosin-actin at an ionic strength close to physiological conditions indicates that the tropomyosin-actin complex can be turned on by rigor complexes in a cooperative manner. However, in contrast to the situation in the skeletal muscle system, the increase in KATPase is associated with a corresponding increase in Kbinding. Furthermore, there is only a 3-fold increase in KATPase in the smooth muscle system rather than a 10-fold increase as in the skeletal muscle system.     

Studies on the amino groups of myosin ATPase. Trinitrophenylation of reactive lysyl residue in ventricular and atrial myosins

Myosin and heavy meromyosin from ventricular, atrial, and skeletal muscle were purified and trinitrophenylated by 2,4,6-trinitrobenzene sulfonate. The trinitrophenylation reaction followed a complex kinetics consisting of a fast and slow reaction in all preparations studied. Reactive lysine residues were trinitrophenylated during the fast reaction with a concomitant decrease in K⁺ (EDTA)-activated ATPase and an increase in Mg²⁺-stimulated ATPase activities of myosin. The extent of increase in Mg²⁺-mediated ATPase was the highest with skeletal and the lowest with atrial myosin. The trinitrophenylation of the less reactive lysyl residues continued during the slow reaction. The rate constants of the reactions and the number of reactive lysine residues were evaluated by computer analyses of the trinitrophenylation curves. Two reactive lysine residues were found in skeletal and ventricular myosins while their number in atrial myosin was somewhat lower. The rate of trinitrophenylation in skeletal muscle myosin or heavy meromyosin was always higher than in the two cardiac myosin isozymes. Addition of KCl increased the trinitrophenylation of both highly reactive and slowly reactive lysyl residues in all of the three heavy meromyosins, however, the effect was more profound with cardiac heavy meromyosins. Addition of MgADP induced spectral changes in trinitrophenylated skeletal but not in cardiac myosins. Similar changes occurred in skeletal and to a lesser degree in ventricular heavy meromyosin, but no definite spectral changes were observed in atrial heavy meromyosin. The findings suggest that structural differences exist around the reactive lysyl residue in the head portion of the three myosins.     

Control of filament length by the regulatory light chains in skeletal and cardiac myosins

The possible role of the regulatory light chains (LC2) in in vitro assembly of rabbit skeletal and dog cardiac myosins was examined by formation of minifilaments and synthetic thick filaments. After LC2 was removed, the resulting myosin preparations exhibited little aggregation in 0.5 M KCl and 0.05 M potassium phosphate (pH 6.5). Minifilaments migrated as a single, hypersharp peak during sedimentation velocity, but electron microscopic analysis revealed a more destabilized structure for LC2-deficient minifilaments. Thick filaments were formed in buffers containing 0.15 M KCl and the following: 20 mM imidazole; 20 mM imidazole, 5 mM ATP; or 20 mM imidazole, 5 mM ATP, and 5 mM MgCl2, all at pH 7.0. Skeletal and cardiac myosin filaments formed in imidazole buffer alone were bipolar, tapered at both ends, and about 1.6 micron long. Removal of LC2 resulted in the formation of shorter thick filaments (1.2 micron long). This effect could be reversed by reassociation with LC2. Inclusion of ATP in the buffer disrupted the filament structure, resulting in irregular, short filaments (less than 0.6 micron); addition of both ATP and MgCl2 largely reversed the effects of ATP alone. In cardiac myosin filaments, the bare zone diameter increased from 16 nm as measured in control and LC2-recombined samples to 20 nm in LC2-deficient myosin assemblies. These results implicate LC2 in an active role in controlling synthetic thick filament length in both skeletal and cardiac muscles.     

Further studies on the interaction of actin with heavy meromyosin and subfragment 1 in the presence of ATP.

It has been postulated that, during the hydrolysis of ATP, both normal and SH1-blocked heavy meromyosin undergo a rate-limiting transition from a refractory state which cannot bind to actin to a nonrefractory state which can bind to actin. This model leads to several predictions which were studied in the present work. First, the fraction of heavy meromysin or subfragment 1 which remains unbound to actin when the ATPase equals Vmax should have the same properties as the original protein. In the present study it was determined that the unbound protein has normal ATPase activity which suggests that it is unbound to actin for a kinetic reason rather than because it is a permanently altered form of the myosin. Second, if the heavy meromyosin heads act independently half as much subfragment 1 as heavy meromyosin should bind to actin. Experiments in the ultracentrifuge demonstrate that about half as much subfragment 1 as heavy meromyosin sediments with the actin at Vmax. Third, the ATP turnover rate per actin monomer at infinite heavy meromyosin concentration should be much higher than the ATP turnover rate per heavy meromyosin head at infinite actin concentration. This was found to be the case for SH1-blocked heavy meromyosin since, even at very high concentrations of SH1-blocked heavy meromyosin, in the presence of a fixed actin concentration, the actin-activated ATPase rate remained proportional to the SH1-blocked heavy meromyosin concentration. All of these results tend to confirm the refractory state model for both SH1-blocked heavy meromyosin and unmodified heavy meromyosin and subfragment 1. However, the nature of the small amount of heavy meromyosin which does bind to actin in the presence of ATP at high actin concentration remains unclear.