Purification of smooth-muscle myosin free of calmodulin and myosin light-chain kinase. Susceptibility to oxidation.

Smooth-muscle myosin purified as described by Persechini & Hartshorne [(1983) Biochemistry 22, 470-476] contains trace amounts of calmodulin and myosin light-chain kinase, which can be removed by Ca2+-dependent hydrophobic-interaction chromatography followed by calmodulin-Sepharose affinity chromatography. The resultant column-purified myosin exhibits properties similar to those of the non-purified myosin, e.g. actin activation of the Mg2+-ATPase requires Ca2+/calmodulin-dependent phosphorylation of the two 20 kDa light chains. However, unlike the non-purified myosin, the column-purified myosin undergoes a time-dependent transition to a form which no longer requires phosphorylation for actin activation of the myosin Mg2+-ATPase. This transition is identified as a time-dependent change in conformation of the column-purified myosin from a 10 S to 6 S form and is caused by slow oxidation of the column-purified myosin, since it could be prevented by storage under N2 and reversed by 5 mM-dithiothreitol.     

Calmodulin antagonists inhibit activity of myosin light-chain kinase independent of calmodulin

In order to identify the molecule components carrying polyglycosyl chains on cell surfaces a two-step enzymatic method was developed. In the first step, the cells were incubated with endo-beta-galactosidase to selectively expose terminal N-acetylglucosamine residues of the lactosamine backbone to the chains. In the second step these residues were glycosylated by incubation with galactosyltransferase and radioactive UDP-galactose. As many as 2.5-3.0 X 10(6) residues per cell could be transferred to human erythrocytes. Negligible amounts of labeling occurred if either of the enzymes was omitted from the incubations. Of the label 80% was found in glycoproteins. In accordance with previous observations, bands 3 and 4.5 were found to be the main carriers of polyglycosyl chains. In human promyelotic HL-60 leukemia cells, a major band of apparent molecular weight of 110000-140000 was labeled. In addition, bands of lower molecular weight which appear to have escaped detection by previous methods were also labeled. The novel labeling method was found to be simple to perform, uses commercially available reagents, and leads to the efficient and highly specific labeling of cell surface molecules carrying polyglycosyl chains.     

Structure of the smooth muscle myosin light-chain kinase calmodulin-binding domain peptide bound to calmodulin

The interaction between the peptide corresponding to the calmodulin-binding domain of the smooth muscle myosin light-chain kinase and (Ca2+)4-calmodulin has been studied by multinuclear and multidimensional nuclear magnetic resonance methods. The study was facilitated by the use of 15N-labeled peptide in conjunction with 15N-edited and 15N-correlated 1H spectroscopy. The peptide forms a 1:1 complex with calcium-saturated calmodulin which is in slow exchange with free peptide. The 1H and 15N resonances of the bound have been assigned. An extensive set of structural constraints for the bound peptide has been assembled from the analysis of nuclear Overhauser effects and three-bond coupling constants. The backbone conformation of the bound peptide has been determined using these constraints by use of distance geometry and related computational methods. The backbone conformation of the peptide has been determined to high precision and is generally indicative of helical secondary structure. Nonhelical backbone conformations are seen in the middle and at the C-terminal end of the bound peptide. These studies provide the first direct confirmation of the amphiphilic helix model for the structure of peptides bound to calcium-saturated calmodulin.     

Solution structure of calmodulin and its complex with a myosin light chain kinase fragment.

The solution structure of Ca2+ ligated calmodulin and of its complex with a 26-residue peptide fragment of skeletal muscle myosin light chain kinase (skMLCK) have been investigated by multi-dimensional NMR. In the absence of peptide, the two globular domains of calmodulin adopt the same structure as observed in the crystalline form. The so-called 'central helix' which is observed in the crystalline state is disrupted in solution. 15N relaxation studies show that residues Asp78 through Ser81, located near the middle of this 'central helix', form a very flexible link between the two globular domains. In the presence of skMLCK target peptide, the peptide-protein complex adopts a globular ellipsoidal shape. The helical peptide is located in a hydrophobic channel that goes through the center of the complex and makes an angle of approximately 45 degrees with the long axis of the ellipsoid.     

The ascidian embryo as a prototype of vertebrate neurogenesis

Ascidian tadpole larvae, composed of only about 2500 cells, have a primitive nervous system which is derived from the neural plate. The stereotyped cell cleavage pattern and well characterized cell lineage in these animals allow the isolation and culture of identified blastomeres in variable combinations. Ascidian embryos express cell-type-specific markers corresponding to their cell fates, even when cultured under cleavage-arrest by cytochalasin B. This system provides us with a unique opportunity to study the roles of cell lineage and cell contact in early neuronal differentiation in the absence of events associated with complex morphogenesis. In addition, the isolated, cleavage-arrested blastomeres are ideally suited to electrical recording, permitting the use of ionic channels as specific markers for differentiation. In the cleavage-arrested embryos, suppression of one type of K+ channel, and induction of two types of Na+ channels, occur following cell contact with the vegetal blastomere. The combination of molecular and electrophysiological analyses on this simple animal system may provide insights into the nature of the cell interactions important in early neurogenesis, both in ascidians and in vertebrates.     

Calmodulin and myosin light-chain kinase of rabbit fast skeletal muscle.

1. It is confirmed that myosin light-chain kinase is a protein of mol.wt. about 80,000 that is inactive in the absence of calmodulin. 2. In the presence of 1 mol of calmodulin/mol of kinase 80-90% of the maximal activity is obtained. 3. Crude preparations of the whole light-chain fraction of rabbit fast-skeletal-muscle myosin contain enough calmodulin to activate the enzyme. A method for the preparation of calmodulin-free P light chain is described. 4. A procedure is described for the isolation of calmodulin from rabbit fast skeletal muscle. 5. Rabbit fast-skeletal-muscle calmodulin is indistinguishable from bovine brain calmodulin in its ability to activate myosin light-chain kinase. The other properties of these two proteins are also very similar. 6. Rabbit fast-skeletal-muscle troponin C was about 10% as effective as calmodulin as activator for myosin light-chain kinase. 7. By chromatography on a Sepharose-calmodulin affinity column evidence was obtained for the formation of a Ca2+-dependent complex between calmodulin and myosin light-chain kinase. 8. Troponin I from rabbit fast skeletal muscle and histone IIAS were phosphorylated by fully activated myosin light-chain kinase at about 1% of the rate of the P light chain.     

Rabbit skeletal muscle myosin light chain kinase. The calmodulin binding domain as a potential active site-directed inhibitory domain

A synthetic peptide modeled after the calmodulin (CaM)-binding domain of rabbit skeletal muscle myosin light chain kinase, Lys-Arg-Arg-Trp-Lys5-Lys-Asn-Phe-Ile-Ala10-Val-Ser-Ala-Ala-+ ++Asn15-Arg-Phe-Glycyl amide (M5), inhibited the CaM-independent chymotryptic fragment of the enzyme, C35 (Edelman, A. M., Takio, K., Blumenthal, D. K., Hansen, R. S., Walsh, K. A., Titani, K., and Krebs, E. G. (1985) J. Biol. Chem. 260, 11275-11285), with a Ki of 3.2 +/- 2.1 microM. Inhibition was competitive with respect to the peptide substrate Lys-Lys-Arg-Ala-Ala5-Arg-Ala-Thr-Ser-Asn10-Val-Phe-Ala and was of the noncompetitive linear mixed type with respect to ATP. M5 and homologues with a serine residue substituted at positions 9, 13, or 14 were phosphorylated with the following order of preference: M5(Ser9) greater than M5(Ser13) much greater than M5(Ser14) greater than M5. The order of preference observed agreed with that predicted by comparison of the sequence of these peptides with the phosphorylation sites of myosin P-light chains. Both inhibition of C35 by M5 and phosphorylation of M5 and its serine-substituted homologues were severely curtailed by the addition of a stoichiometric excess of CaM over peptide. Thus, synthetic peptides modeled after the CaM-binding domain of skeletal muscle myosin light chain kinase can function as calmodulin-regulated active site-directed inhibitors of the enzyme.     

Purification and properties of myosin light-chain kinase from fast skeletal muscle.

1. A procedure is described for the isolation of myosin light-chain kinase from rabbit fast skeletal muscle as a homogeneous protein. 2. Myosin light-chain kinase is a monomeric enzyme of mol.wt. 77000. Under some conditions of storage it is converted into components of mol.wts. about 50000 and 30000 that possess enzymic activity. 3. The enzyme is clearly different in structure and properties from any other protein kinase so far isolated from muscle. 4. The enzyme is highly specific for the P-light chain (18000-20000-dalton light chain) of myosin and requires Ca2+ for activity. 5. The P-light chain is phosphorylated at a similar rate whether isolated or associated with the rest of the myosin molecule. 6. The effects of pH, bivalent cation and other nucleotides on the enzymic activity are described. 7. The role of the phosphorylation of the P-light chain of myosin in muscle function is discussed.     

Purification of modulator-deficient myosin light-chain kinase by modulator protein-Sepharose affinity chromatography.

Modulator-deficient myosin light-chain kinase from rabbit skeletal muscle was purified by modulator protein-Sepharose 4B affinity chromatography. The purified protein showed a single band (MW 80,000) on polyacrylamide gel electrophoresis in sodium dodecyl sulfate, and it exists as a monomer in the native state as determined by gel filtration. The modulator-deficient myosin light-chain kinase (MW 80,000), modulator protein (MW 16,500) and Ca2+ were essential for the kinase activity. The half-maximal activity of the kinase in the presence of excess modulator protein with 10 mM MgCl2 was at pCa 5.1, where full activity of actomyosin-ATPase is observed in the presence of the troponin--tropomyosin system. Assuming a rapid equilibrium between myosin light-chain kinase and two substrates, ATP and g2 light-chain, Km values for ATP and g2 light chain were evaluated as 0.28 mM and 0.024 mM, respectively. Vm/e was 5.7 s-1.     

Isolation of the native form of chicken gizzard myosin light-chain kinase.

A simple and rapid procedure for the purification of the native form of chicken gizzard myosin light-chain kinase (Mr 136000) is described which eliminates problems of proteolysis previously encountered. During this procedure, a calmodulin-binding protein of Mr 141000, which previously co-purified with the myosin light-chain kinase, is removed and shown to be a distinct protein on the basis of lack of kinase activity, different chymotryptic peptide maps, lack of cross-reactivity with a monoclonal antibody to turkey gizzard myosin light-chain kinase, and lack of phosphorylation by the purified catalytic subunit of cyclic AMP-dependent protein kinase. This Mr-141000 calmodulin-binding protein is identified as caldesmon on the basis of Ca2+-dependent interaction with calmodulin, subunit Mr, Ca2+-independent interaction with skeletal-muscle F-actin, Ca2+-dependent competition between calmodulin and F-actin for caldesmon, and tissue content.     

Purification and characterization of myosin light-chain kinase from the rat pancreas.

We have partially purified a protein kinase from rat pancreas that phosphorylates two light-chain subunits of pancreatic myosin, a doublet with components of 18 and 20 kDa. This protein kinase was purified approx. 1000-fold by sequential (NH4)2SO4 fractionation, gel filtration, ion-exchange and affinity chromatography on calmodulin-Sepharose 4B. The resultant enzyme preparation is free of cyclic AMP-dependent protein kinase, protein kinase C and calmodulin-dependent type I or II kinase activities. The purified protein kinase is completely dependent on Ca2+ and calmodulin, and phosphorylates a 20 kDa light-chain subunit of intact gizzard myosin, suggesting that it belongs to a class of enzymes known as myosin light-chain kinase (MLCK). The apparent Km values of the putative pancreatic MLCK for ATP (73 microM), gizzard myosin light chains (18 microM) and calmodulin (2 nM) are similar to those reported for MLCKs isolated from smooth muscle, platelet and other sources. The enzyme is half-maximally activated at a free Ca2+ concentration of 2.5 microM. A single component of the affinity-purified kinase reacts with antibodies to turkey gizzard MLCK. The apparent molecular mass of this component is 138 kDa. Immunoprecipitation of a pancreatic homogenate with these antibodies decreases calmodulin-dependent kinase activity for pancreatic myosin by over 85%. The immunoprecipitate contains a single electrophoretic band of 138 kDa. Tryptic phosphopeptide analyses of pancreatic myosin, phosphorylated by either gizzard or pancreatic MLCK, are identical. Thus the enzyme that we have purified from rat pancreas is a MLCK, as judged by (1) absolute dependence on Ca2+ and calmodulin, (2) high affinity for calmodulin, (3) narrow substrate specificity for the light-chain subunit of myosin, and (4) reactivity with antibodies to turkey gizzard MLCK. These studies establish the existence of a pancreatic MLCK which may be responsible for regulating myosin phosphorylation and enzyme secretion in situ.     

The MAP kinase cascade. Discovery of a new signal transduction pathway

Using biochemical techniques similar to those used by Krebs and Fischer in elucidating the cAMP kinase cascade, a protein kinase cascade has been found that represents a new pathway for signal transduction. This pathway is activated in almost all cells that have been examined by many different growth and differentiations factors suggesting control of different cell responses. At this writing, four tiers of growth factor regulated kinases, each tier represented by more than one enzyme, have been reconstitutedin vitro to form the MAP kinase cascade. Preliminary findings suggesting multiple feedback or feedforward regulation of several components in the cascade predict higher complexity than a simple linear pathway.     

Myosin light-chain kinase regulates endothelial calcium entry and endothelium-dependent vasodilation.

Activation of smooth muscle myosin light-chain kinase (MLCK) causes contraction. Here we have proven that MLCK controls Ca2+ entry (CE) in endothelial cells (ECs): MLCK antisense oligonucleotides strongly prevented bradykinin (BK)- and thapsigargin (TG)-induced endothelial Ca2+ response, while MLCK sense did not. We also show that the relevant mechanism is not phosphorylation of myosin light-chain (MLC): MLC phosphorylation by BK required CE, but MLC phosphorylation caused by the phosphatase inhibitor calyculin A did not trigger Ca2+ response. Most important, we provide for the first time strong evidence that, in contrast to its role in smooth muscle cells, activation of MLCK in ECs stimulates the production of important endothelium-derived vascular relaxing factors: MLCK antisense and MLCK inhibitors abolished BK- and TG-induced nitric oxide production, and MLCK inhibitors substantially inhibited acetylcholine-stimulated hyperpolarization of smooth muscle cell membrane in rat mesenteric artery. These results indicate that MLCK controls endothelial CE, but not through MLC phosphorylation, and unveils a hitherto unknown physiological function of the enzyme: vasodilation through its action in endothelial cells. The study discovers a counter-balancing role of MLCK in the regulation of vascular tone.     

Activation of skeletal muscle myosin light chain kinase by calcium(2+) and calmodulin

Many biological processes are now known to be regulated by Ca2+ via calmodulin (CM). Although a general mechanistic model by which Ca2+ and calmodulin modulate many of these activities has been proposed, an accurate quantitative model is not available. A detailed analysis of skeletal muscle myosin light chain kinase activation was undertaken in order to determine the stoichiometries and equilibrium constants of Ca2+, calmodulin, and enzyme catalytic subunit in the activation process. The analysis indicates that activation is a sequential, fully reversible process requiring both Ca2+ and calmodulin. The first step of the activation process appears to require binding of Ca2+ to all four divalent metal binding sites on calmodulin for form the complex, Ca42+-calmodulin. This complex then interacts with the inactive catalytic subunit of the enzyme to form the active holoenzyme complex, Ca42+-calmodulin-enzyme. Formation of the holoenzyme follows simply hyperbolic kinetics, indicating 1:1 stoichiometry of Ca42+-calmodulin to catalytic subunit. The rate equation derived from the mechanistic model was used to determine the values of KCa2+ and KCM, the intrinsic activation constants for each step of the activation process. KCa2+ and KCM were found to have values of 10 microM and 0.86 nM, respectively, at 10 mM Mg2+. The rate equation using these equilibrium constants accurately predicts the extent of enzyme activation over a wide range of Ca2+ and calmodulin concentrations. The kinetic model and analytical techniques employed herein may be generally applicable to other enzymes with similar regulatory schemes.     

A signal transduction pathway model prototype II: Application to Ca2+-calmodulin signaling and myosin light chain phosphorylation

An agonist-initiated Ca(2+) signaling model for calmodulin (CaM) coupled to the phosphorylation of myosin light chains was created using a computer-assisted simulation environment. Calmodulin buffering was introduced as a module for directing sequestered CaM to myosin light chain kinase (MLCK) through Ca(2+)-dependent release from a buffering protein. Using differing simulation conditions, it was discovered that CaM buffering allowed transient production of more Ca(2+)-CaM-MLCK complex, resulting in elevated myosin light chain phosphorylation compared to nonbuffered control. Second messenger signaling also impacts myosin light chain phosphorylation through the regulation of myosin light chain phosphatase (MLCP). A model for MLCP regulation via its regulatory MYPT1 subunit and interaction of the CPI-17 inhibitor protein was assembled that incorporated several protein kinase subsystems including Rho-kinase, protein kinase C (PKC), and constitutive MYPT1 phosphorylation activities. The effects of the different routes of MLCP regulation depend upon the relative concentrations of MLCP compared to CPI-17, and the specific activities of protein kinases such as Rho and PKC. Phosphorylated CPI-17 (CPI-17P) was found to dynamically control activity during agonist stimulation, with the assumption that inhibition by CPI-17P (resulting from PKC activation) is faster than agonist-induced phosphorylation of MYPT1. Simulation results are in accord with literature measurements of MLCP and CPI-17 phosphorylation states during agonist stimulation, validating the predictive capabilities of the system.