Phosphorylation of a second site for myosin light chain kinase on platelet myosin

The 20,000-dalton light chain of bovine platelet myosin is phosphorylated at two sites by myosin light chain kinase. The first and second phosphorylation sites are at a serine and a threonine residue, respectively. The location of the phosphorylation sites was determined by using limited proteolysis. The N-terminal sequence of the 17,000-dalton tryptic fragment of platelet myosin 20,000-dalton light chain was found to be identical with that of gizzard 20,000-dalton light chain from Ala-17 to Phe-33. On the basis of these results and the distribution of 32P among the proteolytic fragments, it was concluded that serine-19 and threonine-18 were the two phosphorylation sites. Phosphorylation at the threonine residue markedly increases the actin-activated ATPase activity of myosin. It was found that platelet myosin forms 10S and 6S conformations and its Mg2+-ATPase activity parallels the transition from the 6S to the 10S conformation. The conformational transition was influenced by phosphorylation at both sites, and the phosphorylation at the threonine residue further shifted the equilibrium toward the 6S conformation. The phosphorylation at the threonine residue also induced thick filament formation in the presence of ATP. These results suggest that the phosphorylation at the threonine residue as well as at the serine residue may play an important role in the contractility of nonmuscle cells.     

Phosphorylation of the 20,000-dalton light chain of smooth muscle myosin by the calcium-activated, phospholipid-dependent protein kinase. Phosphorylation sites and effects of phosphorylation

Smooth muscle heavy meromyosin (HMM) is phosphorylated by the Ca2+-activated phospholipid-dependent protein kinase, i.e. protein kinase C, at three sites on each 20,000-dalton light chain. Phosphorylation of three sites also is observed with isolated 20,000-dalton light chain and HMM subfragment 1. The phosphorylation sites are serine 1, serine 2, and threonine 9. Threonine is phosphorylated most rapidly followed by either serine 1 or 2. Phosphorylation of the third site occurs only on prolonged incubation. Phosphorylation is a random process. HMM phosphorylated at two sites per light chain by protein kinase C can be dephosphorylated, as shown using two phosphatase preparations. Increasing levels of phosphorylation of HMM by protein kinase C causes a progressive inhibition of the subsequent rate of phosphorylation of serine 19 by myosin light chain kinase and causes a progressive inhibition of actin-activated ATPase activity of HMM, prephosphorylated by myosin light chain kinase. Inhibition of ATPase activity is due to a decreased affinity of HMM for actin rather than a change in Vmax. Previous results with HMM and protein kinase C (Nishikawa, M., Sellers, J. R., Adelstein, R. S., and Hidaka, H. (1984) J. Biol. Chem. 259, 8808-8814) examined effects induced by phosphorylation of the threonine residues. Our results confirm these and consider also the influence of higher levels of phosphorylation by protein kinase C.     

Identification, phosphorylation, and dephosphorylation of a second site for myosin light chain kinase on the 20,000-dalton light chain of smooth muscle myosin

At relatively high concentrations of myosin light chain kinase, a second site on the 20,000-dalton light chain of smooth muscle myosin is phosphorylated (Ikebe, M., and Hartshorne, D. J. (1985) J. Biol. Chem. 260, 10027-10031). In this communication the site is identified and kinetics associated with its phosphorylation and dephosphorylation are described. The doubly phosphorylated 20,000-dalton light chain from turkey gizzard myosin was hydrolyzed with alpha-chymotrypsin and the phosphorylated peptide was isolated by reverse phase chromatography. Following amino acid analyses and partial sequence determinations the second site of phosphorylation is shown to be threonine 18. This site is distinct from the threonine residue phosphorylated by protein kinase C. The time courses of phosphorylation of serine 19 and threonine 18 in isolated light chains follow a single exponential indicating a random process, although the phosphorylation rates differ considerably. The values of kcat/Km for serine 19 and threonine 18 for isolated light chains are 550 and 0.2 min-1 microM-1, respectively. With intact myosin, phosphorylation of serine 19 is biphasic; kcat/Km values are 22.5 and 7.5 min-1 microM-1 for the fast and slow phases, respectively. In contrast, phosphorylation of threonine 18 in intact myosin is a random, but markedly slower process, kcat/Km = 0.44 min-1 microM-1. Dephosphorylation of doubly phosphorylated myosin (approximately 4 mol of phosphate/mol of myosin) and isolated light chains (approximately 2 mol of phosphate/mol of light chain) follows a random process and dephosphorylation of the serine 19 and threonine 18 sites occurs at similar rates.     

Phosphorylation of bovine platelet myosin by protein kinase C

Bovine platelet myosin is phosphorylated by protein kinase C at multiple sites. Most of the phosphate is incorporated in the 20,000-dalton light chain although some phosphate is incorporated in the heavy chain. Phosphorylation of the 20,000-dalton light chain of platelet myosin is 10 times faster than the phosphorylation of smooth muscle myosin. Platelet myosin light chain is first phosphorylated at a threonine residue followed by a serine residue. Dominant phosphorylation sites of the 20,000-dalton light chain are estimated as serine-1, serine-2, and threonine-9. Prolonged phosphorylation by protein kinase C resulted in an additional phosphorylation site which, on the basis of limited proteolysis, appears to be either serine-19 or threonine-18. Phosphorylation by protein kinase C causes an inhibition of actin-activated ATPase activity of platelet myosin prephosphorylated by myosin light chain kinase. Inhibition of ATPase activity is due to a decreased affinity of myosin for actin, and no change in Vmax is observed. It is shown that platelet myosin also exhibits the 6S to 10S conformation transition as judged by viscosity and gel filtration methods. Mg2(+)-ATPase activity of platelet myosin is paralleled with the 10S-6S transition. Phosphorylation by protein kinase C affects neither the 10S-6S transition nor the myosin filament formation. Therefore, the inhibition of actin-activated ATPase activity of platelet myosin is not due to the change in the myosin conformation.     

Actin-induced local conformational change in the myosin molecule. I. Effect of metal ions and nucleotides on the conformational change around a specific thiol group (S2) of heavy meromyosin.

As previously reported when a specific thiol group, S2, of myosin reacts with N-ethylmaleimide (NEM), its Ca2+-ATPase activity is decreased. Therefore, the reactivity of S2 can be estimated by measuring the decrement of the enzymatic activity. Using the change in the reactivity as a structural probe, we investigated whether F-actin affects the conformation around the region containing S2 under physiological conditions (at neutral pH and low ionic strength). 1. Experiments were carried out with heavy meromyosin (HMM), S1 of which had heen blocked with NEM, to observe the reactivity of S2 alone. In the experiments done in the presence of F-actin, the Ca2+-ATPase activity was measured using the heavy meromyosin fraction after actin had been removed by centrifugation and gel filtration. 2. ATP and other nucleotides activated the reactivity of S2 in the presence of Mg2+. On the other hand, F-actin markedly activated the reactivity of S2 which had been increased by ATP, but not by the other nucleotides. 3. The above cooperative action of F-actin with ATP was not observed in the presence of Ca2+ instead of Mg2+, or above 0.2 M KCl. These results suggest that the S2 region of the myosin molecule is a key region in the molecular interaction of the actin myosin-ATP system under physiological conditions.     

Filament formation and actin-activated ATPase activity are abolished by proteolytic removal of a small peptide from the tip of the tail of the heavy chain of Acanthamoeba myosin II

Actin-activated Mg2+-ATPase activity of myosin II from Acanthamoeba castellanii is regulated by phosphorylation of three serine residues located at the carboxyl-terminal end of each of the two 185,000-Da heavy chains; the phosphorylated molecule has full Ca2+-ATPase activity but no actin-activated Mg2+-ATPase activity. Under controlled conditions, chymotrypsin removes a small peptide containing all three phosphorylation sites from the ends of the myosin II heavy chains producing a molecule with heavy chains of 175,000 Da and undigested light chains. The length of the myosin II tail decreased from 89 to 76 nm. Chymotrypsin-cleaved myosin II has complete Ca2+-ATPase activity but no actin-activated Mg2+-ATPase activity under standard assay conditions and binds to F-actin as well as undigested myosin II in the absence, but not in the presence, of MgATP. In the presence of MgCl2, undigested myosin II forms biopolar filaments but chymotrypsin-cleaved myosin II forms only parallel (monopolar) dimers, as assessed by analytical ultra-centrifugation and rotary shadow electron microscopy. We conclude that the short segment very near the end of the myosin II tail that contains the three phosphorylatable serines is necessary for the formation of biopolar filaments and, probably as a consequence of filament formation, for the high-affinity binding of myosin II to F-actin in the presence of ATP and the actin-activated Mg2+-ATPase activity of native myosin II. This supports our previous conclusion that actin-activated Mg2+-ATPase of native myosin II is expressed only when the enzyme is in bipolar filaments with the proper conformation as determined by the state of phosphorylation of the heavy chains.     

SH1 (cysteine 717) of smooth muscle myosin: its role in motor function.

To determine if a thiol group called SH1 has an important role in myosin's motor function, we made a mutant heavy meromyosin (HMM) without the thiol group and analyzed its properties. In chicken gizzard myosin, SH1 is located on the cysteine residue at position 717. By using genetic engineering techniques, this cysteine was substituted with threonine in chicken gizzard HMM, and that mutant HMM and unmutated HMM were expressed in biochemical quantities using a baculovirus system. The basal EDTA-, Ca(2+)-, and Mg(2+)-ATPase activities of the mutant were similar to those of HMM whose SH1 was modified by N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (IAEDANS). However, while the chemically modified HMM lost the function of the light chain phosphorylation-dependent regulation of the actin-activated ATPase activity, the mutant HMM exhibited the normal light chain-regulated actin-activated ATPase activity. Using an in vitro motility assay system, we found that the IAEDANS-modified HMM was unable to propel actin filaments but that the mutant HMM was able to move actin filaments in a manner indistinguishable from filament sliding generated by unmutated HMM. These results indicate that SH1 itself is not essential for the motor function of myosin and suggest that various effects observed with HMM modified by thiol reagents such as IAEDANS are caused by the bulkiness of the attached probes, which interferes with the swinging motion generated during ATP hydrolysis.     

Phosphorylation of smooth muscle myosin at two distinct sites by myosin light chain kinase

The 20,000-dalton light chain of turkey gizzard myosin is phosphorylated at two sites. Dual phosphorylation is observed when both intact myosin and isolated light chains are used as substrates. Phosphorylation of the second site is not observed at higher ionic strength (e.g. 0.35 M KCl). The first phosphorylation site (serine 19) is phosphorylated preferentially to the second site. The latter is phosphorylated more slowly than the first site, and its phosphorylation requires relatively high concentrations of myosin light chain kinase. It is suggested that myosin light chain kinase catalyzes the phosphorylation of both sites on the light chain, and several reasons are cited that make it unlikely that a contaminant kinase is involved. The second phosphorylation site is a threonine residue. Based on the results of limited proteolysis of the light chain, it is concluded that the threonine residue is close to serine 19, and possible locations are threonines 9, 10, and 18. At all concentrations of MgCl2, phosphorylation of the second site markedly increases the actin-activated ATPase activity of myosin and accelerates the superprecipitation response of myosin plus actin.     

Correlation of enzymatic properties and conformation of bovine erythrocyte myosin

Myosin was purified from bovine erythrocytes by chromatography on DEAE-cellulose, Sepharose CL-4B, hydroxylapatite, and DEAE-5PW. The yield was about 200 micrograms/L of packed cells. From SDS-polyacrylamide gels, the purity was estimated to be greater than 95%. The bovine erythrocyte myosin is composed of heavy chains of 200 kDa and light chains of 20 and 17 kDa, in a molar stoichiometry of 1. Myosin was also purified from human erythrocytes by the same method. The molecular weights of two light chains were 26K and 19.5K which confirmed the earlier reports [Fowler, V. M., Davis, J. Q., & Bennet, V. (1985) J. Cell Biol. 100, 47-55; Wong, A. J., Kiehart, D. P., & Pollard, T.D. (1985) J. Biol. Chem. 260, 46-49]. Phosphorylation by gizzard myosin light chain kinase, to a level of 1 mol of phosphate/mol of 20-kDa light chain, increased actin-activated ATPase, and the extent of activation was dependent on the MgCl2 concentration. Both Ca2+-ATPase and Mg2+-ATPase activities were dependent on KCl concentration and markedly decreased below 0.3 M KCl. Mg2+-ATPase of phosphorylated myosin, while more resistant to decreasing ionic strength, was also decreased below 0.2 M KCl. These results are similar to those obtained with smooth muscle myosin and suggest that the 10S-6S transition occurs. In confirmation of this, gel filtration, viscosity, and electron microscopy (rotary shadowing) show that erythrocyte myosin forms extended and folded conformations in high and low salt, respectively. It is proposed that each conformation is characterized by distinct enzymatic properties.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonlinear dependence of actin-activated Mg2+-ATPase activity on the extent of phosphorylation of gizzard myosin and H-meromyosin

1. The actin-activated Mg2+-ATPase activity of gizzard HMM increased in proportion to the square of the extent of LC phosphorylation. This result indicates that the LCs of HMM are randomly phosphorylated, and the phosphorylation of both heads of HMM is required for the activation of HMM Mg2+-ATPase by F-actin. 2. In 75 mM KCl, the Mg2+-ATPase activity of gizzard myosin was activated by F-actin only slightly when a half of the total LC was phosphorylated. From 1 to 2 mol LC phosphorylation, the activity was enhanced by F-actin almost linearly. In 30 mM KCl, the activity of acto-gizzard myosin increased sigmoidally with increase in the extent of LC phosphorylation. On electron microscopy, side-by-side aggregates of myosin filaments were observed in 30 mM KCl, but not in 75 mM KCl. It was suggested that the activation of the Mg2+-ATPase activity of acto-gizzard myosin LC phosphorylation is modified by formation of myosin filaments and their aggregates. 3. The relationship between the actin-activated Mg2+-ATPase activity of HMM or myosin and the extent of LC phosphorylation was unaffected by tropomyosin.     

Flexibility of Acanthamoeba myosin rod minifilaments.

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

The effect of troponin-tropomyosin on the binding of heavy meromyosin to actin in the presence of ATP

In the presence of ATP and the absence of Ca2+, the binding of myosin subfragment-1 to actin is only slightly inhibited by troponin-tropomyosin, while the actin-activated subfragment-1 ATPase rate is 95% inhibited (Chalovich, J. M., Chock, P. B., and Eisenberg, E. (1981) J. Biol. Chem. 256, 575-578). On the other hand, it has been reported the troponin-tropomyosin markedly inhibits the binding of heavy meromyosin (HMM) to actin in the presence of ATP and the absence of Ca2+, providing that the HMM has intact light chain 2 (Wagner, P. D., and Stone, D. (1982) Biochemistry 22, 1334-1342). In the present study, we reinvestigated the binding of HMM with 85% intact light chain 2, to regulated actin. If we assume that only a single population of HMM is present, the binding constant of HMM to regulated actin at 19 mM ionic strength is only about 3 times larger in the presence of Ca2+ than in the absence of Ca2+ (2.4 X 10(4) M-1 compared to 8.8 X 10(3) M-1). On the other hand, if we correct for the population of HMM with degraded light chain 2, the difference in the binding constants in the presence and absence of Ca2+ may be as great as 5-fold. A double binding experiment also suggested that HMM with intact light chain 2 binds at most 5 times more strongly to regulated actin in the presence of Ca2+ than in its absence. We conclude that, just as with subfragment-1, the primary effect of troponin-tropomyosin in regulating the acto HMM ATPase activity is to inhibit a kinetic step in the ATPase cycle. However, our data with HMM also suggest that, in addition to this primary effect, troponin-tropomyosin may modulate the binding of the cross-bridge to actin in relaxed muscle to a small extent.     

Regulation of the actin-activated ATPase and in vitro motility activities of monomeric and filamentous Acanthamoeba myosin II.

The actin-activated Mg(2+)-ATPase activity of filamentous Acanthamoeba myosin II is inhibited by phosphorylation of 3 serine residues at the tip of the tail of each heavy chain. From previous studies, it had been concluded that the activity of each molecule in the filament was regulated by the global state of phosphorylation of the filament and was independent of its own phosphorylation state. The actin-activated Mg(2+)-ATPase activity of monomeric phosphorylated myosin II was not known because it polymerizes under the ionic conditions necessary for the expression of this activity. We have now found conditions to maintain myosin II monomeric and active during the enzyme assay. The actin-activated Mg(2+)-ATPase activities of monomeric dephosphorylated and phosphorylated myosin II were found to be the same as the activity of filamentous dephosphorylated myosin II. These results support the conclusion that phosphorylation regulates filamentous myosin II by affecting filament conformation. Consistent with their equivalent enzymatic activities, monomeric and filamentous dephosphorylated myosin II were equally active in an in vitro motility assay in which myosin adsorbed to a surface drives the movement of F-actin. In contrast to their very different enzymatic activities, however, filamentous and monomeric phosphorylated myosin II had similar activities in the in vitro motility assay; both were much less active than monomeric and filamentous dephosphorylated myosin II. One interpretation of these results is that the rate-limiting steps in the two assays are different and that, while the rate-limiting step for actin-activated Mg(2+)-ATPase activity is regulated only at the level of the filament, the rate-limiting step for motility can also be regulated at the level of the monomer.     

Reverse reaction of smooth muscle myosin light chain kinase. Formation of ATP from phosphorylated light chain plus ADP

Incubation of smooth muscle phosphorylated heavy meromyosin in the presence of myosin light chain kinase, calmodulin, ADP, and Ca2+ results in a decrease of the protein-bound phosphate. The dephosphorylation is not due to phosphatase activity and is dependent on the presence of ADP and the active ternary myosin light chain kinase complex. Using 32P-labeled phosphorylated 20,000-dalton light chains as the phosphate donor, the formation of ATP from ADP can be demonstrated. This reaction requires the presence of Ca2+, calmodulin, and myosin light chain kinase. These results indicate that myosin light chain kinase can catalyze a reverse reaction and form ATP from ADP and phosphorylated substrate. The rate of the reverse reaction, kcat/KLC approximately 0.21 min-1 microM-1, is considerably slower than the forward reaction under similar conditions and is therefore detectable only at relatively high concentrations of myosin light chain kinase. For the reverse reaction, KmADP is approximately 30 microM and ATP is a competitive inhibitor, KIATP approximately 88 microM. For the forward reaction, measured with both isolated light chains and intact myosin, KmATP is approximately 100 microM and ADP is a competitive inhibitor, KiADP approximately 140 microM (myosin) and 120 microM (light chains). Thus, the affinity of ATP for the forward and reverse reactions is similar, but the affinity of ADP is higher for the reverse reaction. From the light chain dependence of the two reactions, the following was calculated: forward, Km = 5 microM, kcat = 1720 min-1, and reverse, Km = 130 microM, kcat = 27 min-1. In contrast to the data obtained with isolated light chains, it is suggested that, with intact myosin as substrate, the Km term is primarily responsible for determining the rate of the reverse reaction. With light chains phosphorylated at serine 19 and threonine 18, it was shown that both sites act as a phosphate donor, although the reverse reaction for threonine 18 is slower than that for serine 19.     

Steady-state magnesium ion-adenosine triphosphatase activities of myosin and its subfragment 1 derivative

The Mg2+-ATPase activity of myosin and its subfragment 1 (ATP phosphohydrolase, EC 3.6.1.3) always followed normal Michaelis-Menten kinetics for ATP concentrations less than 10 microM. The average Km values at pH 7.4 and 25 degrees C are 0.33 +/- 0.04 microM for myosin and 0.43 +/- 0.11 microM for subfragment 1. At low salt concentration myosin yields a second hyperbolic increase in Mg2+-ATPase activity as the ATP rises from 10.2 microM to 153 microM: V doubles with a Km of 11 +/- 5 microM. This second low-salt-dependent increase in Mg2+-ATPase activity occurred between pH 6.8 and pH 8.7. It was not affected by the presence of 0.10 M EGTA to remove Ca2+ contamination. Solubilization of the catalytic sites by assaying myosin for ATPase activity in the presence of 0.60 M NaCl or by conversion of myosin to subfragment 1 eliminated the secondary hyperbolic increase. Subfragment 1 has a significantly different pH-activity curve from that of myosin. Subfragment 1 has an activity peak at pH 6.0, a rising activity as the pH goes from 8.7 to 9.8, and a deep activity valley between pH 6.8 and pH 8.4. Myosin has a very shallow trough of activity at pH 6.8 to 8.4, and in 1.0 mM ATP its activity drops as the pH decreases from 6.8 to 6.0. NaCl is a noncompetitive inhibitor of the Mg2+-ATPase activity of myosin and subfragment 1. Myosin has a greater affinity for NaCl (Ki = 0.101 +/- 0.004 M) than does subfragment 1 (Ki = 0.194 +/- 0.009 M).     

Effect of myosin DTNB light chain on the actin-myosin interaction in the presence of ATP.

The influence of the DTNB light chain of myosin on its enzymatic activities was examined by studying the superprecipitation of actomyosin and the actin-activated ATPase of heavy meromyosin (HMM) [EC 3.6.1.3]. Although the Ca2+-, Mg2+-, and EDTA-ATPase activities of control and DTNB myosin were practically the same, the superprecipitation of actomyosin prepared from actin and DTNB myosin occurred more slowly than that of control myosin. The apparent binding constant obtained from double-reciprocal plots of actin-activated ATPase of DTNB HMM was lower than that of control HMM. Recombination of DTNB myosin and HMM with DTNB light chains restored the original properties of myosin and HMM. The removal of DTNB light chain from myosin had no effect on the formation of the rigor complex between actin and myosin. These results suggest that the DTNB light chain participates in the interaction of myosin with actin in the presence of ATP.     

平滑肌肌球蛋白轻链激酶及ATP结合位点突变体对ATP酶活性的调节作用

目的：探寻MLCK的非激酶活性区域对MLCK活性的影响,进一步阐明MLCK的非激酶活性在调节平滑肌收缩过程中的分子机制。方法：利用编码MLCK全长的pColdI表达载体对其ATP结合位点进行定点突变,获得无激酶活性的MLCK突变体;应用Glycerol—PAGE鉴定肌球蛋白磷酸化水平;应用孔雀绿方法检测重组MLCK对肌球蛋白ATP酶活性的影响。结果：MLCK／△ATP（突变型）失去磷酸化肌球蛋白轻链的激酶活性;重组MLCK（野生型）和MLCK／AATP（突变型）均可以在非钙条件下激活非磷酸化肌球蛋白Mg2＋-ATP酶活性,抑制磷酸化肌球蛋白的Mg2＋．ATP酶活性,而且激活与抑制作用均随着MLCK浓度的增加而增大,但二者对肌球蛋白的ATP酶活性的作用没有显著差异（P〉0．05）。结论：平滑肌肌球蛋白轻链激酶及ATP结合位点突变体具有激活非磷酸化肌球蛋白ATP酶活性的作用。     

Effect of multiple phosphorylations of smooth muscle and cytoplasmic myosins on movement in an in vitro motility assay

The Nitella-based in vitro motility assay developed by Sheetz and Spudich (Sheetz, M.P., and Spudich, J. A. (1983) Nature 303, 31-35) is a quantitative assay for measuring the velocity of myosin-coated beads over an organized substratum of actin. We have used this assay to analyze the effect of phosphorylation of various sites on the 20,000-Da light chain of smooth muscle and cytoplasmic myosins. Phosphorylation by myosin light chain kinase at serine 19 on the 20,000-Da light chain subunit of smooth muscle myosin from turkey gizzard, bovine trachea and aorta, and of cytoplasmic myosin from human platelets was required for bead movement. The individual phosphorylated myosin-coated beads moved at characteristic rates under the same conditions (turkey gizzard myosin, 0.2 micron/s; aorta or trachea myosin, 0.12 micron/s; and platelet myosin, 0.04 micron/s; in contrast, rabbit skeletal muscle myosin, 2 micron/s). Myosin light chain kinase can also phosphorylate threonine 18 in addition to serine 19, and this phosphorylation resulted in an increase in the actin-activated MgATPase activity (Ikebe, M., and Hartshorne, D.J. (1985) J. Biol. Chem. 260, 10027-10031). Phosphorylation at this site had no effect on the velocity of smooth muscle myosin-coated beads. Protein kinase C (Ca2+/phospholipid-dependent enzyme) can also phosphorylate two to three sites on the 20,000-Da light chain, and this phosphorylation alone did not result in the movement of myosin-coated beads. When myosin that had been previously phosphorylated by myosin light chain kinase at serine 19 was also phosphorylated by protein kinase C, myosin-coated beads moved at the same velocity as beads coated with myosin phosphorylated by myosin light chain kinase alone. Tropomyosin binding to actin also had an activating effect on the actin-activated MgATPase activity through an effect on the Vmax and also resulted in an increase in the velocity of myosin-coated beads.     

Separation of subfragment-1 of H-meromyosin into two equimolar fractions with and without formation of the reactive enzyme-phosphate-ADP complex.

H-Meromyosin (HMM) was digested with insoluble papain [EC 3.4.22.2]. Neither the size of the initial burst of Pi liberation (0.5 mole/mole of myosin head) nor the Mg2+-ATPase [EC 3.6.1.3] activity of HMM in the steady state was affected by this treatment. Acto-S-1 was obtained by mixing F-actin with HMM digested with insoluble papain (HMM-S-1). The size of the initial burst of Pi liberation of acto-S-1 was 0.35 mole/mole of S-l at an ATP concentration of 0.5 mole/mole of S-1, and 0.5 mole/moleof S-1 at ATP concentrations above 1 mole/mole of S-1...     

Interaction of smooth muscle tropomyosin and smooth muscle myosin. Effect on the properties of myosin

Several techniques were used to investigate the possibility that smooth muscle tropomyosin interacts with smooth muscle myosin. These experiments were carried out in the absence of actin. The Mg2+-ATPase activity of myosin was activated by tropomyosin. This was most marked at low ionic strength but also occurred at higher ionic strength with monomeric myosin. For myosin and HMM, the activation of Mg2+-ATPase by tropomyosin was greater at low levels of phosphorylation. There was no detectable effect of tropomyosin on the Mg2+-ATPase activity of S1. The KCl dependence of myosin viscosity was influenced by tropomyosin, and in the presence of tropomyosin, the 6S to 10S transition occurred at lower KCl concentrations. From the viscosity change, an approximate stoichiometry of 1:1 tropomyosin to myosin was estimated. The phosphorylation dependence of viscosity, which reflects the 10S-6S transition, also was altered in the presence of tropomyosin. An interaction between myosin and tropomyosin was detected by fluorescence measurements using tropomyosin labeled with dansyl chloride. These results indicate that an interaction occurs between myosin and tropomyosin. In general, the interaction is favored at low ionic strength and at low levels of phosphorylation. This interaction is not expected to be competitive with the formation of the actin-tropomyosin complex, but the possibility is raised that a direct interaction between myosin and tropomyosin bound to the thin filament could modify contractile properties in smooth muscle.