Immobilization of actin and myosin.

Using glutaric dialdehyde, the muscle proteins myosin, actin, actomyosin and heavy meromyosin subfragment-1 (S-1) have been immobilized on capron fibers. The ATPase activity of myosin and its capability to interact with actin have been preserved whereas the ATPase activity of its subfragment decreased significnatly. Immobilization on capron fibers changes the pH dependence of the ATPase activity of myosin and of S-1 shifting the maximum towards the acid zone (pH 5.5) and increases the thermal stability of the enzyme. Calcium ions produce a stimulatory effect on ATPase; Mg2+ions yield no effect on myosin and S-1 but enhance the activity in the case of immobilized actomyosin though to a lesser degree than the ions of Ca2+. Immobilized actin retains its ability to form actomyosin complex.     

Effect of skeletal muscle myosin light chain 2 on the Ca2+-sensitive interaction of myosin and heavy meromyosin with regulated actin

A low-speed centrifugation assay has been used to examine the binding of myosin filaments to F-action and to regulated actin in the presence of MgATP. While the cross-linking of F-actin by myosin was Ca2+ insensitive, much less regulated actin was cross-linked by myosin in the absence of Ca2+ than in its presence. Removal of the 19000-dalton, phosphorylatable light chain from myosin resulted in the loss of this Ca2+ sensitivity. Readdition of this light chain partially restored the Ca2+-sensitive cross-linking of regulated actin by myosin. Urea gel electrophoresis has been used to distinguish that fraction of heavy meromyosin which contains intact phosphorylatable light chain from that which contains a 17000-dalton fragment of this light chain. In the absence of Ca2+, heavy meromyosin which contained digested light chain bound to regulated actin in MgATP about 10-fold more tightly than did heavy meromyosin which contained intact light chain. The regulated actin-activated ATPases of heavy meromyosin also showed that cleavage of this light chain causes a substantial increase in the affinity of heavy meromyosin for regulated actin in the absence of Ca2+. Thus, the binding of both myosin and heavy meromyosin to regulated actin is Ca2+ sensitive, and this sensitivity is dependent on the phosphorylatable light chain.     

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.     

Actin crosslinked with glutaraldehyde: evidence to suggest an active role for actin in the regulatory mechanism.

Actin crosslinked with glutaraldehyde retains the ability to activate the Mg²⁺-ATPase activity of heavy meromyosin subfragment 1, but the resultant ATPase activity is not controlled by the regulatory proteins, troponin and tropomyosin. Fluorescent energy transfer measurements imply that the crosslinked actin is frozen in the active state. These results indicate that the conformation of actin is important in the regulatory mechanism, and suggest that actin plays a more active role in this mechanism than thought previously.     

Depolymerization of F-actin by deoxyribonuclease I.

Deoxyribonuclease I causes depolymerization of filamentous muscle actin to form a stable complex of 1 mole DNAase I:1 mole actin. The regulatory proteins tropomyosin and troponin bind to filamentous actin and slow down but do not prevent the depolymerization. In the absense of ATP, heavy meromyosin binds tightly to actin filaments and blocks completely the DNAase I: actin filament interaction. Addition of ATP releases heavy meromyosin; DNAase I is then rapidly inhibited and the actin filaments are depolymerized.     

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).     

Both heads of tissue-derived smooth muscle heavy meromyosin bind to actin in the presence of ADP

The effect of ADP and phosphorylation upon the actin binding properties of heavy meromyosin was investigated using three fluorescence methods that monitor the number of heavy meromyosin heads that bind to pyrene-actin: (i) amplitudes of ATP-induced dissociation, (ii) amplitudes of ADP-induced dissociation of the pyrene-actin-heavy meromyosin complex, and (iii) amplitudes of the association of heavy meromyosin with pyrene-actin. Both heads bound to pyrene-actin, irrespective of regulatory light chain phosphorylation or the presence of ADP. This behavior was found for native regulated heavy meromyosin prepared by proteolytic digestion of chicken gizzard myosin with between 5 and 95% heavy chain cleavage at the actin-binding loop, showing that two-head binding is a property of heavy meromyosin with uncleaved heavy chains. These data are in contrast to a previous study using an uncleaved expressed preparation (Berger, C. E., Fagnant, P. M., Heizmann, S., Trybus, K. M., and Geeves, M. A. (2001) J. Biol. Chem. 276, 23240-23245), which showed that one head of the unphosphorylated heavy meromyosin-ADP complex bound to actin and that the partner head either did not bind or bound weakly. Possible explanations for the differences between the two studies are discussed. We have shown that unphosphorylated heavy meromyosin appears to adopt a special state in the presence of ADP based upon analysis of actin-heavy meromyosin association rate constants. Data were consistent with one head binding rapidly and the second head binding more slowly in the presence of ADP. Both heads bound to actin at the same rate for all other states.     

Interaction of actin with myosin A and heavy meromyosin.

Ca2+ "free" actomyosin suspensions as well as actin heavy meromyosin (HMM) solutions in the presence of Ca2+ showed no contractile response (superprecipitation) and had low steady-state Mg2+-ATPase activity. Under the same experimental conditions both the enzymatic activity increased and contractile response was restored if the solubility of the proteins was depressed by the addition of polyethylene glycol 4000 (PEG-4000). The stability of the enzymatically active actomyosin or actin HMM complexes was 10 times lower in cleared solutions than in the insoluble actomyosin or actin HMM suspensions. It was concluded that soluble actomyosin or actin HMM solutions are inadequate test tube models for studying muscular contraction.     

The effects of caldesmon on smooth muscle heavy actomeromyosin ATPase activity and binding of heavy meromyosin to actin

Caldesmon was purified to homogeneity from both chicken gizzard and bovine aortic smooth muscles. Caldesmon purified from bovine aorta was slightly larger than caldesmon purified from chicken gizzards (Mr = 140,000) when the two were compared electrophoretically. Caldesmon bound tightly to actin saturating at a molar ratio of 1 caldesmon monomer per 6.6 actin monomers. Ca2+-calmodulin appeared to reduce the affinity of caldesmon for actin. Caldesmon was also a potent inhibitor of heavy actomeromyosin ATPase activity producing a maximal effect at a ratio of 1 caldesmon monomer per 7-10 actin monomers. This effect was also antagonized by Ca2+-calmodulin. While caldesmon inhibited heavy actomeromyosin ATPase activity, it greatly enhanced binding of both unphosphorylated and phosphorylated heavy meromyosin to actin in the presence of MgATP, reducing the Kd for binding by a factor of 40 for each form of heavy meromyosin. Although we did identify a Ca2+-calmodulin-stimulated "caldesmon kinase" activity in caldesmon preparations purified under nondenaturing conditions, we observed no effect of phosphorylation (2 mol of PO4/mol of caldesmon) on the capacity to inhibit heavy actomeromyosin ATPase activity. Our results suggest that caldesmon could serve some role in smooth muscle function by enhancing cross-bridge affinity while inhibiting actomyosin ATPase activity.     

Regulatory light chain influences alterations of myosin head induced by actin.

The effect of magnesium-for-calcium exchange and phosphorylation of regulatory light chain (LC2) on structural organization of rabbit skeletal myosin head was studied by limited tryptic digestion. In the presence of actin, exchange of magnesium bound to LC2 by calcium in dephosphorylated myosin accelerates the digestion of myosin and heavy meromyosin heavy chain and increases the accumulation of a 50 kDa fragment. This effect is significantly diminished in the case of phosphorylated myosin. Thus, both phosphorylation and cation exchange influences the effect of actin binding on the structural organization of myosin head.     

Actomyosin kinetics and in vitro motility of wild-type Drosophila actin and the effects of two mutations in the Act88F gene.

Two missense mutations of the flight muscle-specific actin gene of Drosophila melanogaster, Act88F, assemble into normally structured myofibrils but affect the flight ability of flies and the mechanical kinetics of isolated muscle fibers. We describe the isolation of actin from different homozygous Act88F strains, including wild-type, an Act88F null mutant (KM88), and two Act88F single point mutations (E316K and G368E), their biochemical interactions with rabbit myosin subfragment 1 (S1), and behavior with rabbit myosin and heavy meromyosin in in vitro motility assays. The rabbit and wild-type Drosophila actins have different association rate constants with S1 (2.64 and 1.77 microM-1 s-1, respectively) and in vitro motilities (2.51, 1.60 microns s-1) clearly demonstrating an isoform-specific difference. The G368E mutation shows a reduced affinity for rabbit S1 compared with the wild type (increasing from 0.11 to 0.17 microM) and a reduced velocity in vitro (reduced by 19%). The E316K mutant actin has no change in affinity for myosin S1 or in vitro motility with heavy meromyosin but does have a reduced in vitro motility (15%) with myosin. These results are discussed with respect to the recently published atomic models for the actomyosin structure and our findings that G368E fibers show a reduced rate constant for delayed tension development and increased fiber stiffness. We interpret these results as possibly caused either by effects on A1 myosin light chain binding or conformational changes within the subdomain 1 of actin, which contains the myosin binding site. E316K is discussed with respect to its likely position within the tropomyosin binding site of actin.     

Cross-linking of actin filaments by heavy meromyosin.

The structure of acto-heavy meromyosin has been examined by electron microscopy. When heavy meromyosin is mixed with actin at ~ 2 mg/ml a gel is formed. At lower actin concentrations more ordered assemblies are formed in which the actin filaments are in “rafts” about 300 Å apart cross-linked by heavy meromyosin. These results indicate that in solution the two heads of a heavy meromyosin molecule can bind to different actin filaments.     

Cooperative binding of tropomyosin to muscle and Acanthamoeba actin.

Analyses of the binding of tropomyosin to muscle and Acanthamoeba actin by the use of Scatchard plots indicate that the binding exhibits strong positive cooperativity in the presence of Mg2+. The cooperative nature of the binding is not affected by the presence of 80 mm KCl, but appears to decrease somewhat in the presence of heavy meromyosin or subfragment-1. Heavy meromyosin, subfragment-1, and KCl each increase the binding affinity of actin for tropomyosin; depending on the experimental condition and the type of actin involved, the apparent binding constant, Kapp, is in the range of 1 to 4 x 10(6) M-1. Muscle actin cross-linked with glutaraldehyde failed to bind tropomyosin even when heavy meromyosin, subfragment-1, or KCl were added as inducers, although the cross-linked actin still markedly activated the heavy meromyosin ATPase.     

Proximity relationships between sites on myosin and actin. Resonance energy transfer determination of the following distances, using a hybrid myosin: those between Cys-55 on the Mercenaria regulatory light chain, SH-1 on the Aequipecten myosin heavy chain, and Cys-374 of actin

Resonance energy transfer measurements have been made on hybrid myosins in order to map distances between sites on the regulatory light chain, heavy chain, and actin as well as to assess potential conformational changes of functional importance. Using scallop (Aequipecten) myosin hybrid molecules possessing clam (Mercenaria) regulatory light chains, we have been able to map the distance between Cys-55 on the regulatory light chain and the fast-reacting thiol on the myosin heavy chain (SH-1). This distance is shown to be approximately 6.4 nm, and it is not altered by the presence or absence of Ca2+, MgATP, or actin. Experiments performed at low ionc strength on heavy meromyosin (HMM) derived from these hybrid myosins gave results similar to those performed on the soluble parent myosin preparations. The distances between Cys-374 on actin and each of the above sites were also measured. Mercenaria regulatory light-chain Cys-55, within the hybrid myosin molecule, was found to be greater than 8.0 nm away from actin Cys-374. Scallop heavy-chain SH-1 is shown to be approximately 4.5 nm away from actin Cys-374, in broad agreement with earlier measurements made by others in nonregulatory myosins. The significance of our results is discussed with respect to putative conformational changes within the region of the heavy chain connecting SH-1 to the N-terminal region of the light chain.     

Ca2+ dependence of the ATPase activity of phosphorylated smooth muscle myosin: effects of tropomyosin and actin

Calcium ions produce a 3-4-fold stimulation of the actin-activated ATPase activities of phosphorylated myosin from bovine pulmonary artery or chicken gizzard at 37 degrees C and at physiological ionic strengths, 0.12-0.16 M. Actins from either chicken gizzard or rabbit skeletal muscle stimulate the activity of phosphorylated myosin in a Ca2+-dependent manner, indicating that the Ca2+ sensitivity involves myosin or a protein associated with it. Partial loss of Ca2+ sensitivity upon treatment of phosphorylated gizzard myosin with low concentrations of chymotrypsin and the lack of any change on similar treatment of actin supports the above conclusion. Although both actins enhance ATPase activity, activation by gizzard actin exhibits Ca2+ dependence at higher temperatures or lower ionic strengths than does activation by skeletal muscle actin. The Ca2+ dependence of the activity of phosphorylated heavy meromyosin is about half that of myosin and is affected differently by temperature, ionic strength and Mg2+, being independent of temperature and optimal at lower concentrations of NaCl. Raising the concentration of Mg2+ above 2-3 mM inhibits the activity of heavy meromyosin but stimulates that of myosin, indicating that Mg2+ and Ca2+ activate myosin at different binding sites.     

The use of actin labelled with N-(1-pyrenyl)iodoacetamide to study the interaction of actin with myosin subfragments and troponin/tropomyosin.

A pyrene label attached to Cys-374 of actin has been shown to be a useful probe for monitoring the interaction of actin with myosin subfragments [Kouyama & Mihashi (1981) Eur. J. Biochem. 114, 33-38]. We report that the presence of this label decreases the affinity of actin for myosin subfragment 1 by less than a factor of 2. The rate of actin binding is unaffected by the label and the dissociation rate is increased by up to a factor of 2. Both the rate of actin binding to, and the rate of actin dissociation from, heavy meromyosin show two phases when monitored by pyrene fluorescence. Thin filiments reconstituted from pyrene-labelled actin show a 5% increase in pyrene fluorescence on binding Ca2+.     

Light chain dependent effects of actin binding on the S-1/S-2 swivel in myosin

The S-1/S-2 swivel in myosin provides a flexible link between the head and tail portions of the molecule. We have investigated the properties of the swivel by employing limited proteolysis methods. Our results indicate that the binding of actin to heavy meromyosin inhibits both the chymotryptic and papain cleavage of the S-1/S-2 swivel, and that this effect is dependent on the presence of intact LC-2 light chains. Actin did not slow digestions carried out using heavy meromyosin previously treated with proteases to nick the LC-2 chains to 17,000 or 14,000 Mr fragments. Although the integrity of the LC-2 light chain appears to be required to transmit the effects of actin binding from the myosin head to the S-1/S-2 swivel, the binding of Ca2+ to the 17,000 Mr LC-2 fragment can still affect the chemical reactivity of SH1 thiol groups. Both chymotryptic and papain digestions of heavy meromyosin containing intact or fragmented LC-2 light chain show substantial temperature sensitivity between 5 degrees C and 35 degrees C. Calculated apparent activation energies for this process indicate that the S-1/S-2 swivel in myosin can undergo temperature-dependent structural changes independently of the state of the LC-2 light chain. Thus, both actin binding and temperature variations can induce structural transitions in the S-1/S-2 swivel.     

Isolation and characterization of actin from Entamoeba histolytica

Actin has been identified and purified partially from trophozoites of Entamoeba histolytica HMI-IMSS by a procedure that minimizes proteolysis. In cellular extracts, Entamoeba actin would copolymerize with muscle actin, but would not bind to DNase I or form microfilaments. Fractionation of the extracts by DEAE-cellulose and Sephadex G-150 chromatography yielded a purified actin that would copolymerize with rabbit skeletal muscle actin or polymerize alone into long filaments at 24 degrees C upon addition of 100 mM KC1 and 2 mM MgCl2. These filaments are not cold-stable and will depolymerize at 4 degrees C in 1 or 2 h. Entamoeba actin filaments bind phallotoxin with the same affinity as muscle actin and decorate with rabbit skeletal muscle heavy meromyosin. Entamoeba actin filaments activate the Mg2+ ATPase of heavy meromyosin to the same Vmax as muscle actin, but the Kapp is 2.8 times higher. Entamoeba actin is a single species with a slightly higher molecular weight than muscle actin (45,000) and a more acidic pI (5.4). The purified actin does not bind to DNase I, produce inhibition of the enzymatic activity, or block the binding of muscle actin. Comparison of the peptides obtained by limit digest with protease V8 from Staphylococcus aureus shows sequences with common mobility between alpha-actin and Entamoeba actin, but additional peptides are present which may account for the different properties of the Entamoeba actin. Finally, in vitro translation of mRNA from trophozoites produces a single polypeptide equivalent to the molecule purified from Entamoeba extracts.     

The phosphorylated L2 light chain of skeletal myosin is a modifier of the actomyosin ATPase

Incubation of rabbit skeletal myosin with an extract of light chain kinase plus ATP phosphorylated the L2 light chain and modified the steady state kinetics of the actomyosin ATPase. With regulated actin, the ATPase activity of phosphorylated myosin (P-myosin) was 35 to 181% greater than that of unphosphorylated myosin when assayed with 0.05 to 5 micro M Ca2+. Phosphorylation had no effect on the Ca2+ concentration required for half-maximal activity, but it did increase the ATPase activity at low Ca2+. With pure actin, the percentage of increase in the actomyosin ATPase activity correlated with the percentage of phosphorylation of myosin. Steady state kinetic analyses of the actomyosin system indicated that 50 to 82% phosphorylation of myosin decreased significantly the Kapp of actin for myosin with no significant effect on the Vmax. Phosphorylaton of heavy meromyosin similarly modified the steady state kinetics of the acto-heavy meromyosin system. Both the K+/EDTA- and Mg-ATPase activities of P-myosin and phosphorylated heavy meromyosin were within normal limits indicating that phosphorylaiion had not altered significantly the hydrolytic site. Phosphatase treatment of P-myosin decreased both the level of phosphorylation of L2 and the actomyosin ATPase activity to control levels for unphosphorylated myosin. It is concluded levels for unphosphorylated myosin. It is concluded from these results that the ability of P-myosin to modify the steady state kinetics of the actomyosin ATPase was: 1) specific for phosphorylation; 2) independent of the thin filament regulatory proteins.     

Calcium ions modulate regulation of smooth muscle contraction mediated by phosphorylation of myosin regulatory light chains

The effect of calcium ions on conformational changes of F-actin initiated by decoration of thin filaments with phosphorylated and dephosphorylated heavy meromyosin from smooth muscles was studied by fluorescence polarization spectroscopy. It is shown that heavy meromyosin with phosphorylated regulatory light chains (pHMM) promotes structural changes of F-actin which are typical for the "strong" binding of actin to the myosin heads. Heavy meromyosin with dephosphorylated regulatory light chains (dpHMM) causes conformational changes of F-actin which are typical for the "weak" binding of actin to the myosin heads. The presence of calcium enhances the pHMM effect and attenuates the dpHMM effect. We propose that a Ca2+-dependent mechanism exists in smooth muscles which modulates the regulation of actin--myosin interaction occurring via phosphorylation of myosin regulatory light chains.