Characterization of regulatory light chain-a myosin kinase from smooth muscle of scallop, Patinopecten yessoensis

The protein kinase that phosphorylates the regulatory light chain-a (RLC-a) of scallop smooth muscle myosin was isolated from scallop smooth muscle (Sohma, H. & Morita, F. (1986) J. Biochem. 100, 1155-1163). The enzymatic properties of this kinase (aMK) were investigated using RLC-a as the substrate. The Km value for ATP was 6.5 microM in the presence of 27 microM RLC-a at pH 7.0, and that for RLC-a was 133 microM in the presence of 1 mM ATP. The Vm value at saturation of both RLC-a and ATP was 0.25 s-1 at pH 7.0. The pH activity curve for aMK was bell-shaped with a maximum at around pH 7.8. The aMK activity was inhibited strongly by an increase in the KCl concentration. aMK required Mg2+, but was inhibited by high concentrations of Mg2+. The optimum activity was seen at 3 mM MgCl2. The mode of inhibition of the aMK activity by Ca2+ was studied. Assuming that the binding of Ca2+ to aMK induces the inhibition, the dissociation constant of Ca2+ was estimated to be 64 microM. aMK also phosphorylated LC20 of chicken gizzard myosin at a similar rate to that for RLC-a and the DTNB light chain of rabbit skeletal muscle myosin at a more lower rate. The helix and beta-sheet contents of aMK were estimated to be 19 and 30%, respectively, from the CD spectrum.     

The steady state intermediate of scallop smooth muscle myosin ATPase and effect of light chain phosphorylation. A molecular mechanism for catch contraction

The ATP-induced difference UV-absorption spectrum of myosin isolated from the opaque portion of scallop smooth muscle (opaque myosin) was Ca2+-sensitive at 40 mM KCl and 1.5 M sucrose. On adding sucrose to 1.5 M, the turbidity of myosin decreased to 24% and the characteristic two forms of the difference spectrum, the ATP-form and ADP-form (Morita, F. (1967) J. Biol. Chem. 242, 4501-4506), were distinguishable. In the presence of Ca2+, the difference spectrum was the ATP-form first and then decayed into the ADP-form with the depletion of ATP. In the absence of Ca2+, however, only the ADP-form was observed. The ADP-form observed in the absence of Ca2+ returned to the ATP-form when the regulatory light chain-a (RLC-a), one of the regulatory light chains of opaque myosin, was phosphorylated. These results suggest that the main intermediate at the steady state of opaque myosin ATPase is converted depending on the concentration of Ca2+, from EPADP in the presence of Ca2+ to EADP in the absence of Ca2+. It changes to EPADP in the absence of Ca2+ on the phosphorylation of RLC-a. Consistent results were obtained by measuring the ATP-induced Trp-fluorescence increase of opaque myosin in the absence of sucrose. Since the opaque portion of scallop smooth muscle is known to be responsible for catch contraction (Ruegg, J.C. (1961) Proc. R. Soc. London Ser. B 154, 224-249), these findings lead us to suppose that the opaque myosin in vivo may stay in the E.ADP complex during the catch state. It changes to EPADP by the phosphorylation of RLC-a, which may terminate the catch state.     

Purification of a myosin phosphatase from bovine aortic smooth muscle

A myosin phosphatase has been purified to homogeneity from bovine aortic smooth muscle. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the enzyme eluted from nondenaturing gels revealed two subunits (Mr = 67,000 and 38,000). Densitometric scans of the subunits indicated a molar ratio of 1:1. Several phosphoproteins were substrates for the phosphatase including histone II-A, isolated 20,000-dalton smooth muscle myosin light chains, phosphorylase a, and smooth muscle myosin. In the presence of 0.25 M NaCl and a substrate concentration of 2 microM, myosin was preferentially dephosphorylated. The specific activity of the phosphatase for myosin at a concentration of 10 microM was found to be 5 mumol/mg/min. The phosphatase required Mn2+ or Co2+ ions for activity. Mg2+, Ca2+, or Mg-ATP would not substitute for Mn2+ or Co2+ at equimolar concentrations. This phosphatase may play an important role in regulating actin-myosin interaction in smooth muscle by serving to dephosphorylate myosin.     

Regulatory light chain-a myosin kinase (aMK) catalyzes phosphorylation of smooth muscle myosin heavy chains of scallop, Patinopecten yessoensis

Regulatory light chain-a myosin kinase (aMK), which phosphorylates one of the myosin regulatory light chains, RLC-a, contained in the catch muscle of scallop, was also found to phosphorylate heavy chains of scallop myosin. After incubation of myosin isolated from the opaque portion of scallop smooth muscle (opaque myosin) with aMK in the presence of [gamma-32P]ATP, about 2 mol of 32P was incorporated per mol of the myosin. The radioactivity was mostly found in the heavy chain at 0.26 M KCl. The pH-activity curve and MgCl2 requirement for the heavy chain phosphorylation were similar to those for RLC-a phosphorylation. In contrast, the dependency of activity on KCl concentration was different from that for RLC-a. The heavy chain phosphorylation activity decreased with increase in KCl concentration up to 0.06 M, and then increased at concentrations over 0.06 M to a maximum at around 0.26 M KCl. This complicated profile probably reflects the solubility of myosin, and the phosphorylation site may be located in the rod portion insoluble at low KCl concentrations. Phosphorylation of heavy chain did not change the solubility of the opaque myosin molecule at all. The acto-opaque myosin ATPase activity in the presence of Ca2+ was found to be decreased to less than one-fourth by the heavy chain phosphorylation.     

Escherichia coli S-adenosylhomocysteine/5''-methylthioadenosine nucleosidase. Purification, substrate specificity and mechanism of action.

Ca2+-activated protein phosphatase activity was demonstrated in mouse pancreatic acinar cytosol with alpha-casein and skeletal-muscle phosphorylase kinase as substrates. This phosphatase activity preferentially dephosphorylated the alpha subunit of phosphorylase kinase. After DEAE-cellulose chromatography, the Ca2+-activated phosphatase activity became dependent on exogenous calmodulin for maximal activity. Half-maximal activation was achieved at 0.5 +/- 0.1 microM-Ca2+. Trifluoperazine completely inhibited Ca2+-activated phosphatase activity, with half-maximal inhibition occurring at 8.5 +/- 0.6 microM. Mn2+, but not Mg2+, at 1 mM concentration could substitute for Ca2+ in eliciting full enzyme activation. The apparent Mr of the phosphatase as determined by Sephadex G-150 chromatography was 93000 +/- 1000. Submitting active fractions obtained after Sephadex chromatography to calmodulin affinity chromatography resulted in the resolution of a major protein of Mr 55500 +/- 300. In conclusion, Ca2+-activated protein phosphatase activity has been identified in exocrine pancreas and has several features in common with Ca2+-activated calmodulin-dependent protein phosphatases previously isolated from brain and skeletal muscle. It is possible that this Ca2+-activated phosphatase may utilize as substrates certain acinar-cell phosphoproteins previously shown to undergo dephosphorylation in response to Ca2+-mediated secretagogues.     

Calcium sensitivity of contractile proteins from chicken gizzard muscle.

Actin, myosin, and "native" tropomyosin (NTM) were separately isolated from chicken gizzard muscle and rabbit skeletal muscle. With various combinations of the isolated contractile proteins, Mg-ATPase activity and superprecipitation activity were measured. It was thus found that gizzard myosin and gizzard NTM behaved differently from skeletal myosin and skeletal NTM, whereas gizzard actin functioned in the same wasy as skeletal actin. It was also found that gizzard myosin preparations were often Ca-sensitive, that is, that the two activities of gizzard myosin plus actin without NTM were activated by low concentrations of Ca2+. The Mg-ATPase activity of a Ca-insensitive preparation of gizzard myosin was not activated by actin even in the presence of Ca2+. When Ca-sensitive gizzard myosin was incubated with ATP (and Mg2+) in the presence of Ca2+, a light-chain component of gizzard myosin was phosphorylated. The light-chain phosphorylation also occurred when Ca-insensitive myosin was incubated with gizzard NTM and ATP (plus Mg2+) in the presence of Ca2+. In either case, the light-chain phosphorylation required Ca2+. Phosphorylated gizzard myosin in combination with actin was able to exhibit superprecipitation, and Mg-ATPase of the phosphorylated gizzard myosin was activated by actin; the actin activation and superprecipitation were found to occur even in the absence of Ca2+ and NTM or tropomyosin. The phosphorylated light-chain component was found to be dephosphorylated by a partially purified preparation of gizzard myosin light-chain phosphatase. Gizzard myosin thus dephosphorylated behaved exactly like untreated Ca-insensitive gizzard myosin; in combination with actin, it did not superprecipitate either in the presence of Ca2+ or in its absence, but did superprecipitated in the presence of NTM and Ca2+. Ca-activated hydrolysis of ATP catalyzed by gizzard myosin B proceeded at a reduced rate after removal of Ca2+ (by adding EGTA), whereas that catalyzed by a combination of actin, gizzard myosin, and gizzard NTM proceeded at the same rate even after removal of Ca2+. However, addition of a partially purified preparation of gizzard myosin light-chain phosphatase was found to make the recombined system behave like myosin B. Based on these findings, it appears that myosin light-chain kinase and myosin light-chain phosphatase can function as regulatory proteins for contraction and relaxation, respectively, of gizzard muscle.     

The divalent cation dependence of bovine brain calmodulin-dependent phosphatase

The divalent cation dependence of a calmodulin-stimulated phosphatase from bovine brain has been characterized kinetically using phosphorylated myelin basic protein and casein as substrates. At saturating concentrations of calmodulin, dephosphorylation of both myelin basic protein and casein was catalyzed 8- to 10-fold more rapidly at saturating concentrations of Mn2+ than at saturating concentrations of Ca2+. Half-maximal rates of dephosphorylation of both substrates occurred at either 15 microM Mn2+ or 1 microM Ca2+, and the Kact for each ion was not influenced appreciably by the presence of calmodulin. Half-maximal rates of dephosphorylation were observed at concentrations of calmodulin ranging from 3 X 10(-8) to 10(-6) M at saturating concentrations of divalent cations depending on the substrate used and the particular cation chosen. Trypsin treatment of the phosphatase activated the enzyme several-fold, eliminated its calmodulin dependence, but did not alter the Mn2+ concentration dependence of the activity. Ca2+ (10 microM) increased dephosphorylation rates without altering the Mn2+ concentration dependence of the phosphatase activity regardless of the presence of calmodulin. Mg2+ at millimolar concentrations did not alter the Ca2+ or Mn2+ concentration dependence of the activity. As measured without calmodulin, Ca2+ (90 microM) or Mn2+ (200 microM) produced nearly identical alterations of the far ultraviolet circular dichroic spectrum of the phosphatase.     

Calcium binding and conformation of regulatory light chains of smooth muscle myosin of scallop

Calcium binding was studied with two regulatory light chains (RLC-a and RLC-b) of smooth muscle myosin of scallop. With the equilibrium dialysis method, the binding of 0.98 mol Ca2+ per mol of RLC-b was observed with a dissociation constant of 2.3 X 10(-5) M. Similar values for RLC-b, 1.9 X 10(-5) M, and RLC-a, 1.5 X 10(-5) M, were obtained by measuring the difference absorption spectrum induced by Ca2+. The difference molar absorption coefficient at 288 nm was 159 and 209 M-1 X cm-1 for RLC-a and RLC-b, respectively, while it was -34 M-1 X cm-1 for the regulatory light chain of striated muscle myosin of scallop (RLC-st). Proton NMR spectra of the three light chains were very similar to each other and were broader than those of other Ca2+ binding proteins, parvalbumin and calmodulin. The regulatory light chains may be more rigid than in these Ca2+ binding proteins. CD spectra were measured for the three light chains, and the estimated helix contents were 27, 29, and 24%, respectively, for RLC-a, RLC-b, and RLC-st. All these results in comparison with the primary structures led us to suppose that the polypeptide of regulatory light chains is folded in such a way that domain 4 becomes near to the calcium binding site of domain 1. The decrease in intact light chains on trypsin digestion was determined for the gel electrophoretic patterns. RLC-a was 6 times more susceptible to the tryptic digestion than RLC-b.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification of a protein kinase phosphorylating myosin regulatory light chain-a (RLC-a) from smooth muscle of scallop, Patinopecten yessoensis

A protein kinase activity phosphorylating regulatory light chain-a (RLC-a) of scallop smooth muscle myosin was found to be present in scallop smooth muscle homogenate. The kinase was purified to homogeneity and named RLC-a myosin kinase (aMK). aMK was extracted from the muscle homogenate with a low salt solution and was purified by successive DE-32 ion exchange chromatography, gel filtration on Ultrogel AcA 44, and affinity chromatography on Sepharose 4B-6-aminohexyl-1-pyrophosphate. The molecular weight of aMK was estimated to be 40-kDa from the mobility on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and 35-kDa from the elution volume on Sephadex G-150 gel filtration. The phosphorylation site of RLC-a by aMK was determined to be Ser residue(s). Only RLC-a was phosphorylated; the other regulatory light chain, RLC-b, was not. The phosphorylatable Ser of RLC-a is, therefore, considered to be Ser-11, which is located in the N-terminal region having a different amino acid sequence from that of RLC-b. RLC-a was phosphorylated by aMK 3 times faster in the free state than in the bound state to myosin. aMK does not require calmodulin and is rather inhibited by CaCl2.     

Myosin may stay in EADP species during the catch contraction in scallop smooth muscle

Myosin (opaque myosin) isolated from the opaque portion of scallop smooth muscle, a catch muscle, was subjected to limited digestion by trypsin during the steady-state ATPase reaction. The 200-kDa heavy chain of opaque myosin was cleaved into 125- and 74-kDa fragments. The proteolytic rate in the absence of Ca2+ was lower than that in the presence of Ca2+, and was similar to that in the presence of ADP and absence of Ca2+. The results suggest that the steady-state intermediate of opaque myosin ATPase in the absence of Ca2+ is EADP, which is consistent with the previous results based on the difference UV-absorption spectrum (Takahashi, M., Sohma, H., & Morita, F. (1988) J. Biochem. 104, 102-107). In the presence of F-actin, the proteolytic rates were decreased, but the digestive patterns by trypsin were similar to those of myosin alone. Even in the presence of F-actin, the proteolytic rate during the ATPase reaction in the absence of Ca2+ was lower than that in the presence of Ca2+, and was similar to that in the presence of ADP and absence of Ca2+. In addition, there was another trypsin-susceptible site which is probably located at 18 kDa from the N-terminal of the heavy chain. The site in the absence of Ca2+ was hardly cleaved when ATP or ADP was present. Similar tendencies were observed even in the presence of F-actin. These findings suggest that the intermediate of opaque myosin ATPase at the steady state in the absence of Ca2+ is EADP even in the presence of F-actin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Site-specific dephosphorylation of smooth muscle myosin light chain kinase by protein phosphatases 1 and 2A.

Smooth muscle myosin light chain kinase is phosphorylated at two sites (A and B) by different protein kinases. Phosphorylation at site A increases the concentration of Ca2+/calmodulin required for kinase activation. Diphosphorylated myosin light chain kinase was used to determine the site-specificity of several forms of protein serine/threonine phosphatase. These phosphatases readily dephosphorylated myosin light chain kinase in vitro and displayed differing specificities for the two phosphorylation sites. Type 2A protein phosphatase specifically dephosphorylated site A, and binding of Ca2+/calmodulin to the kinase had no effect on dephosphorylation. The purified catalytic subunit of type 1 protein phosphatase dephosphorylated both sites in the absence of Ca2+/calmodulin but only dephosphorylated site A in the presence of Ca2+/calmodulin. A protein phosphatase fraction was prepared from smooth muscle actomyosin by extraction with 80 mM MgCl2. On the basis of sensitivity to okadaic acid and inhibitor 2, this activity was composed of multiple protein phosphatases including type 1 activity. This phosphatase fraction dephosphorylated both sites in the absence of Ca2+/calmodulin. However, dephosphorylation of both sites A and B was completely blocked in the presence of Ca2+/calmodulin. These results indicate that two phosphorylation sites of myosin light chain kinase are dephosphorylated by multiple protein serine/threonine phosphatases with unique catalytic specificities.     

Regulation of smooth muscle contractile proteins by calmodulin and cyclic AMP

The various protein components of a reversible phosphorylating system regulating smooth muscle actomyosin Mg-ATPase activity have been purified. The enzyme catalyzing phosphorylation of smooth muscle myosin, myosin-kinase, requires Ca2+ and the Ca2+-binding protein calmodulin for activity and binds calmodulin in a ratio of 1 mol calmodulin to 1 mol of myosin kinase. Myosin kinase can be phosphorylated by the catalytic subunit of cyclic AMP (cAMP)-dependent protein kinase, and phosphorylation of myosin kinase that does not have calmodulin bound results in a marked decrease in the affinity of this enzyme for Ca2+-calmodulin. This effect is reversed when myosin kinase is dephosphorylated by a phosphatase purified from smooth muscle. When the various components of the smooth muscle myosin phosphorylating-dephosphorylating system are reconstituted, a positive correlation is found between the state of myosin phosphorylation and the actin-activated Mg-ATPase activity of myosin. Unphosphorylated and dephosphorylated myosin cannot be activated by actin, but the phosphorylated and rephosphorylated myosin can be activated by actin. The same relationship between phosphorylation and enzymatic activity was found for a chymotryptic peptide of myosin, smooth muscle heavy meromyosin. The findings reported here suggest one mechanism by which Ca2+ and calmodulin may act to regulate smooth muscle contraction and how cAMP may modulate smooth muscle contractile activity.     

Activation of brain calcineurin phosphatase towards nonprotein phosphoesters by Ca2+, calmodulin, and Mg2+

Calcineurin purified from bovine brain was found to be active towards beta-naphthyl phosphate greater than p-nitrophenyl phosphate greater than alpha-naphthyl phosphate much greater than phosphotyrosine. In its native state, calcineurin shows little activity. It requires the synergistic action of Ca2+, calmodulin, and Mg2+ for maximum activation. Ca2+ and Ca2+ X calmodulin exert their activating effects by transforming the enzyme into a potentially active form which requires Mg2+ to express the full activity. Ni2+, Mn2+, and Co2+, but not Ca2+ or Zn2+, can substitute for Mg2+. The pH optimum, and the Vm and Km values of the phosphatase reaction are characteristics of the divalent cation cofactor. Ca2+ plus calmodulin increases the Vm in the presence of a given divalent cation, but has little effect on the Km for p-nitrophenyl phosphate. The activating effects of Mg2+ are different from those of the transition metal ions in terms of effects on Km, Vm, pH optimum of the phosphatase reaction and their affinity for calcineurin. Based on the Vm values determined in their respective optimum conditions, the order of effectiveness is: Mg2+ greater than or equal to Ni2+ greater than Mn2+ much greater than Co2+. The catalytic properties of calcineurin are markedly similar to those of p-nitrophenyl phosphatase activity associated with protein phosphatase 3C and with its catalytic subunit of Mr = 35,000, suggesting that there are common features in the catalytic sites of these two different classes of phosphatase.     

Myosin light chain phosphatase. Effect on the activation and relaxation of gizzard smooth muscle skinned fibers

Skinned cells of chicken gizzard were used to study the effect of a smooth muscle phosphatase (SMP-IV) on activation and relaxation of tension. SMP-IV has previously been shown to dephosphorylate light chains on myosin. When this phosphatase was added to submaximally Ca2+-activated skinned cells, tension increased while phosphorylation of myosin light chains decreased. In contrast, when the myosin phosphatase was added to cell bundles activated in the absence of Ca2+ by a Ca2+-insensitive myosin light chain kinase, tension and phosphorylation of the myosin light chains both decreased. These data suggest that Ca2+ inhibits the deactivation of tension even when myosin light chains are dephosphorylated to a low level. Furthermore, comparison of Ca2+-activated cells caused to relax in CTP, in the presence or absence of Ca2+, shows that cells in the presence of Ca2+ do not relax completely, whereas in the absence of Ca2+ cells completely relax. Solutions containing Ca2+ and CTP, however, are incapable of generating tension from the resting state. Endogenous myosin light chain kinase is not active in solutions containing CTP and dephosphorylation of myosin light chains occurs in CTP solutions both in the presence and absence of Ca2+. These data imply that Ca2+ inhibits relaxation even though myosin light chains are dephosphorylated. These data are consistent with a model wherein an obligatory Ca2+-activated myosin light chain phosphorylation is followed by a second Ca2+ activation process for further tension development or maintenance.     

A cAMP-dependent regulatory protein for RLC-a myosin kinase catalyzing the phosphorylation of scallop smooth muscle myosin light chain

A cAMP-dependent regulatory protein which modulates the phosphorylation of scallop myosin regulatory light chain-a (RLC-a) by RLC-a myosin kinase (aMK) (Sohma, H. & Morita, F. (1986) J. Biochem. 100, 1155-1163) was purified from the scallop smooth muscle. RLC-a is abundant in the opaque portion of scallop smooth muscle, one of the catch muscles. The regulatory protein for aMK was purified by employing successively DEAE Toyopearl ion exchange chromatography, Sepharose 4B-8(6-aminohexylamino)cAMP affinity chromatography, and Sephadex G 100 gel filtration. The molecular mass of the regulatory protein was 41 kDa, based on the mobility in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. With increasing amounts of the regulatory protein, the aMK activity decreased, and complete inhibition was observed at the concentration of twice that of aMK. The aMK activity inhibited by the regulatory protein was restored by the addition of cAMP. These results suggest that aMK is similar to a catalytic subunit of cAMP-dependent protein kinase, and the protein reported here is similar to its regulatory subunit. aMK may exist as an inactive form, as a combination with this regulatory protein, in vivo and be deinhibited by an increase in the intracellular concentration of cAMP. We discuss a possible correlation between the phosphorylation of RLC-a in myosin catalyzed by aMK and the catch state of the opaque portion of scallop smooth muscle.     

Requirement of phosphorylation of Physarum myosin heavy chain for thick filament formation, actin activation of Mg2+-ATPase activity, and Ca2+-inhibitory superprecipitation

In an attempt to elucidate the Ca2+-regulated mechanism of motility in Physarum plasmodia, we improved the preparation method for myosin B and pure myosin. The obtained results are as follows: 1. We obtained two types of myosin B which are distinguishable from each other with respect to their sensitivity to Ca2+. The inactive type of myosin B had low superprecipitation activities both in the presence and in the absence of Ca2+. The active type showed very high superprecipitation activity in EGTA, and the activity was conspicuously inhibited by Ca2+. The active type was converted into the inactive type by treatment with potato acid phosphatase. Also the inactive type or the phosphatase-treated active type was converted into the active type upon reacting with ATP-gamma-S. 2. In the reaction with ATP-gamma-S, only the myosin HC of myosin B was phosphorylated. The phosphorylation was independent of Ca2+ and calmodulin, and the extent was about 1 mol/mol HC. 3. The Ca2+ sensitivity in the superprecipitation of the active type was not decreased by adding an excess amount of F-actin. Besides, the actin-activated Mg2+-ATPase activity of purified phosphorylated myosin was not Ca2+-sensitive. Therefore, presence of a Ca2+-dependent inhibitory factor(s) that could bind to myosin was suggested. 4. The Mg2+-ATPase activity of purified phosphorylated myosin was 7-8 times enhanced by F-actin, but that of dephosphorylated myosin was hardly activated at all. 5. In a gel filtration in 0.5 M KCl, phosphorylated myosin was eluted behind dephosphorylated myosin. Electron microscopy applying the rotary-shadow method showed significant difference in flexibility in the tail between phosphorylated and dephosphorylated myosin molecules. 6. In 40 mM KCl and 5-10 mM MgCl2, phosphorylated myosin formed thick filaments, but dephosphorylated myosin did not, whether there was ATP or not. The above results clearly show that the phosphorylation of myosin HC is indispensable to ATP-induced superprecipitation, the actin-activated Mg2+-ATPase activity, and the formation of thick filaments of myosin. A myosin-linked factor(s) that inhibits an actin-myosin interaction in a Ca2+-dependent manner may exist.     

Activation of bovine brain calmodulin-dependent protein phosphatase by limited trypsinization

A calmodulin-dependent protein phosphatase isolated from bovine brain [Tallant, E.A., & Cheung, W.Y. (1983) Biochemistry 22, 3630-3635] is stimulated by limited trypsinization to the same activity level as that by calmodulin. Prolonged trypsinization caused gradual loss of phosphatase activity, a process retarded in the presence of Ca2+, and even more in the presence of calmodulin. Trypsinized phosphatase, when fully activated, had a molecular weight of 60 000 and was composed of two protein species of 43 000 and 16 000 daltons. Trypsinization decreased the Km of phosphatase for casein from 10.8 to 1.2 microM and increased the Vmax from 4.9 to 30.9 nmol (mg of protein)-1 min-1. The proteolyzed enzyme was insensitive to calmodulin and did not bind to a calmodulin-Sepharose affinity column. It was, however, stimulated by Ca2+, requiring 0.4 microM Ca2+ for half-maximal activation. Both native and trypsinized phosphatase were stimulated by Mn2+ to a level considerably higher than that by Ca2+.     

Inhibitory effect of MgATP on the release of regulatory light chain from scallop myosin and light chain composition of scallop myosin hybridized with abalone light chain 2 at 30 degrees C

The experimental conditions for release of the regulatory light chain (RLC) of scallop myosin at 30 degrees C were studied. Substantially all RLC was released from myosin by incubation for 5 min in medium containing buffer and KCl. This release of RLC was inhibited strongly by Ca2+, while the effect of Mg2+ was about 10,000 times weaker than that of Ca2+. Even in the absence of Ca2+, MgATP and MgADP inhibited the release of RLC, while the protective effect of AMPPNP was negligible. Other Mg nucleotides also showed some protective effect, though appreciably less than MgATP. The incubation of scallop myosin with abalone regulatory light chain (LC2) at 30 degrees C for 5 min produced a hybrid myosin. In the presence of 5 mM MgCl2, 1 of the 2 mol of RLC per mol of scallop myosin was exchanged with 1 mol of LC2. In the presence of Ca2+ or MgATP, myosin bound 1 extra mole of LC2 besides the 2 mol each of SH-LC and RLC.     

Ca2+ stimulates the Mg2(+)-ATPase activity of brush border myosin I with three or four calmodulin light chains but inhibits with less than two bound.

Brush border myosin I from chicken intestinal microvilli is a membrane-associated, single-headed myosin composed of a 119-kDa heavy chain and several calmodulin light chains. We first describe in detail a new procedure for the rapid purification of brush border myosin I in greater than 99% purity with a yield of 40%, significantly higher than for previous methods. The subunit stoichiometry was determined to be 4 calmodulin light chains/myosin I heavy chain by amino acid compositional analysis of the separated subunits. We have studied the effects of Ca2+ and temperature on dissociation of calmodulin from myosin I and on myosin I Mg2(+)-ATPase and contractile activities. At 30 degrees C the actin-activable ATPase activity is stimulated 2-fold at 10-700 microM Ca2+. Dissociation of 1 calmodulin occurs at 25-50 microM Ca2+, but this has no effect on actin activation. The contractile activity of myosin I, expressed as superprecipitation, is greatly enhanced by Ca2+ under conditions in which 1 calmodulin is dissociated. This calmodulin is thus not essential for actin activation or superprecipitation. Myosin I was found to be highly temperature-sensitive, with an increase to 37 degrees C resulting in dissociation of 1 calmodulin at below 10(-7) M Ca2+ and an additional 1.5 calmodulins at 1-10 microM Ca2+. A complete loss of actin activation accompanies the Ca2(+)-induced calmodulin dissociation at 37 degrees C. Our conclusion is that physiological levels of Ca2+ can either stimulate or inhibit the mechanoenzyme activities of brush border myosin I in vitro, with the mode of regulation determined by the number of associated calmodulin light chains.     

Dephosphorylation of neuromodulin by calcineurin

Neuromodulin (p57, GAP-43, F1, B-50) is a major neural-specific, calmodulin binding protein found in brain, spinal cord, and retina that is associated with membranes. Phosphorylation of neuromodulin by protein kinase C causes a significant reduction in its affinity for calmodulin (Alexander, K. A., Cimler, B. M., Meirer, K. E., and Storm, D. R. (1987) J. Biol. Chem. 262, 6108-6113). It has been proposed that neuromodulin may function to bind and concentrate calmodulin at specific sites within neurons and that activation of protein kinase C causes the release of free calmodulin at high concentrations near its target proteins. It was the goal of this study to determine whether bovine brain contains a phosphoprotein phosphatase that will utilize phosphoneuromodulin as a substrate. Phosphatase activity for phosphoneuromodulin was partially purified from a bovine brain extract using DEAE-Sephacel and Sephacryl S-200 gel filtration chromatography. The neuromodulin phosphatase activity was resolved into two peaks by Affi-Gel Blue chromatography. One of these phosphatases, which represented approximately 60% of the total neuromodulin phosphatase activity, was tentatively identified as calcineurin by its requirement for Ca2+ and calmodulin (CaM) and inhibition of its activity by chlorpromazine. Therefore, bovine brain calcineurin was purified to homogeneity and examined for its phosphatase activity against bovine phosphoneuromodulin. Calcineurin rapidly dephosphorylated phosphoneuromodulin in the presence of micromolar Ca2+ and 3 microM CaM. The apparent Km and Vmax for the dephosphorylation of neuromodulin, measured in the presence of micromolar Ca2+ and 2 microM CaM, were 2.5 microM and 70 nmol Pi/mg/min, respectively, compared to a Km and Vmax of 4 microM and 55 nmol Pi/mg/min, respectively, for myosin light chain under the same conditions. Dephosphorylation of neuromodulin by calcineurin was stimulated 50-fold by calmodulin in the presence of micromolar free Ca2+. Half-maximal stimulation was observed at a calmodulin concentration of 0.5 microM. We propose that phosphoneuromodulin may be a physiologically important substrate for calcineurin and that calcineurin and protein kinase C may regulate the levels of free calmodulin available in neurons.