Calmodulin binding domains: characterization of a phosphorylation and calmodulin binding site from myosin light chain kinase

Potent peptide inhibitors of smooth muscle myosin light chain kinase: mapping of the pseudosubstrate and calmodulin binding domains

Smooth muscle myosin light chain kinase (MLCK) is activated by calcium-calmodulin and, in turn, phosphorylates and activates the smooth muscle actomyosin ATPase, resulting in muscle contraction. The amino acid sequence of the regulatory domain of MLCK is known, and it contains a region that binds calmodulin and also bears a strong homology to the phosphorylation site in the substrate. Thus, it has been called the "pseudosubstrate". It has been proposed that calmodulin activates MLCK by binding to and reversing the autoinhibitory function of the pseudosubstrate. Synthetic peptides based on this sequence inhibit MLCK both by binding to calmodulin and by competing with the substrate at the active site. In the work reported here, we have synthesized a large number of peptides from the regulatory region of MLCK (MLCK 480-516). The region was systematically analyzed by dividing it into fragments of two to six amino acids, each containing one or more basic residues, in order to map in detail the calmodulin binding site and the autoinhibitory region. It was observed that both calmodulin binding and autoinhibition are mediated by several different fragments of the regulatory sequence. Two nonoverlapping peptides, MLCK 480-493 and MLCK 494-504, are similar in potency in inhibiting the enzyme (IC50's of 2 and 6 microM, respectively). Larger fragments, combining multiple inhibitory regions, are more potent inhibitors. For example, MLCK 480-504 is extremely potent, with an IC50 of 13 nM. The calmodulin binding site and active site directed inhibitory regions overlap, but are not identical. Residues 505-512 are important only for calmodulin binding.

[125I]azidosalicylyl melittin binding domains: evidence for a polypeptide receptor on the gastric (H+ + K+)ATPase

We have previously shown that melittin, a bee venom peptide, potently inhibited the catalytic and transport functions of rabbit gastric (H+ + K+)ATPase. A radioactive photoaffinity analog of melittin, ([125I]azidosalicylyl melittin), labeled the (H+ + K+)ATPase. These results suggested that melittin exerted inhibitory effects through direct interaction with the (H+ + K+)ATPase. In this study we attempt to define the melittin-binding domain of the (H+ + K+)ATPase using conformation-dependent proteolytic fragmentation of [125I]azidosalicylyl melittin-labeled hog gastric (H+ + K+)ATPase. In the presence of KCl (E2 form) the 95,000-Da [125I]-azidosalicylyl melittin-labeled (H+ + K+)ATPase was cleaved by trypsin to a 40,000-Da NH2-terminal tryptic fragment and a 56,000-Da COOH-terminal fragment through cleavage at Arg 454 of the (H+ + K+)ATPase. The 40,000-Da fragment was labeled by [125I]-azidosalicylyl melittin. The 56,000-Da fragment was not labeled. When unmodified (H+ + K+)ATPase was trypsinized in the presence of KCl, and the fragments were then reacted with [125I]azidosalicylyl melittin, similar tryptic fragmentation results were obtained. In the absence of KCl (E1 form), the 56,000- and 40,000-Da fragments did not accumulate. Chymotryptic hydrolysis of [125I]azidosalicylyl melittin-labeled (H+ + K+)-ATPase was very slow in the presence of KCl (E2 form). In the absence of KCl (E1 form), chymotryptic hydrolysis was more rapid, with accumulation of a major 42,000-Da fragment which was radiolabeled. The melittin-binding region on the (H+ + K+)ATPase is N-terminal to Arg 454 of the (H+ + K+)ATPase. This region is known to contain the aspartyl phosphate residue (Asp 385), the site of phosphoenzyme formation on the (H+ + K+)ATPase. Melittin is also known to bind to calmodulin and other proteins. Another known calmodulin-binding peptide with a different sequence but similar structure, Trp-3, (Leu-Lys-Trp-Lys-Lys-Leu-Leu-Lys-Leu-Leu-Lys-Lys-Leu-Leu-Lys-Leu-Gly) also inhibited the (H+ + K+)ATPase and label incorporation by [125I]azidosalicylyl melittin. These Trp-3 results suggested that the (H+ + K+)ATPase contains a peptide-binding domain which is similar to the peptide-binding domains found on other melittin-binding proteins.

Mode of inhibition of smooth muscle myosin light chain kinase by synthetic peptide analogs of the regulatory site

The functions associated with the inhibitory region and calmodulin binding region of smooth muscle myosin light chain kinase (MLCK) were studied using various synthetic peptide analogs. Peptides 480-501 and 483-498 strongly inhibited 61 kDa Ca2+/calmodulin-independent MLCK activity with Ki of 25 nM. Peptides 493-512 and 493-504 were considerably less effective as inhibitor of the Ca2+/calmodulin-independent MLCK and Kiapp. were 2 and 3 microM, respectively. Inhibition of Ca2+/calmodulin-independent MLCK by the peptides 480-501 and 483-498 were competitive with ATP and 20,000 dalton smooth muscle myosin light chain. The inhibition of native MLCK by peptide 493-512 was explained by the calmodulin depletion model in which the peptide binds to free calmodulin and prevents it from activating MLCK. On the other hand, the inhibition of native MLCK by the peptides 480-501 and 483-498 was explained by the binding of these peptides to the MLCK-calmodulin complex. The present study suggests that the inhibitory region of MLCK directly binds to MLCK active site and competes with both ATP and 20,000 dalton light chain so as to inhibit the enzyme.

Phosphorylation of smooth muscle myosin light chain kinase by Ca2+/calmodulin-dependent protein kinase II: comparative study of the phosphorylation sites

Smooth muscle myosin light chain kinase (MLC-kinase) was rapidly phosphorylated in vitro by the autophosphorylated form of Ca2+/calmodulin-dependent protein kinase II (CaM-kinase II) to a molar stoichiometry of 2.77 +/- 0.15 associated with a threefold increase in the concentration of calmodulin (CaM) required for half-maximal activation of MLC-kinase. Binding of CaM to MLC-kinase markedly reduced the phosphorylation stoichiometry to 0.21 +/- 0.05 and almost completely inhibited phosphorylation of sites in two peptides (32P-peptides P1 and P2) with reduced phosphorylation of peptide P3. By analogy, cAMP-dependent protein kinase phosphorylated MLC-kinase to a stoichiometry of 3.0 or greater in the absence of CaM with about a threefold decrease in the apparent affinity of MLC-kinase for CaM. Binding of CaM to MLC-kinase inhibited the phosphorylation to 0.84 +/- 0.13. Complete tryptic digests contained two major 32P-peptides as reported previously. One of the peptides, whose phosphorylation was inhibited in the presence of excess calmodulin, appeared to be the same as P2. Automated Edman sequence analysis suggested that both CaM-kinase II and cAMP-dependent protein kinase phosphorylated this peptide at the second of the two adjacent serine residues located at the C-terminal boundary of the CaM-binding domain. However, the other peptide phosphorylated by cAMP-dependent protein kinase, regardless of whether CaM was bound, was different from P1 and P3. Thus, MLC-kinase has a regulatory phosphorylation site(s) that is phosphorylated by the autophosphorylated form of CaM-kinase II and is blocked by Ca2+/CaM-binding.

Members of the 70-kilodalton heat shock protein family contain a highly conserved calmodulin-binding domain

The 70-kilodalton heat shock protein (hsp70) family members appear to be essential components in a number cellular protein-protein interactions. We report here on the characterization of a new functional region in hsp70, a calmodulin-binding site. We have identified a 21-amino-acid sequence within the hsp70 protein that contains a calmodulin-binding domain. The peptide formed a potential amphipathic alpha helix and bound calmodulin with high affinity. Comparison of amino acid homology of this calmodulin-binding sequence with analogous hsp70 sequences from other species showed a high degree of conservation.

Members of the 70-kilodalton heat shock protein family contain a highly conserved calmodulin-binding domain

The 70-kilodalton heat shock protein (hsp70) family members appear to be essential components in a number cellular protein-protein interactions. We report here on the characterization of a new functional region in hsp70, a calmodulin-binding site. We have identified a 21-amino-acid sequence within the hsp70 protein that contains a calmodulin-binding domain. The peptide formed a potential amphipathic alpha helix and bound calmodulin with high affinity. Comparison of amino acid homology of this calmodulin-binding sequence with analogous hsp70 sequences from other species showed a high degree of conservation.

How calmodulin binds its targets: sequence independent recognition of amphiphilic alpha-helices

Calmodulin (CaM) is a protein capable of recognizing positively charged, amphiphilic alpha-helical peptides independent of their precise amino acid sequences; this structural feature has also been found in many CaM-binding proteins. Recent work involving crystallography and site-directed mutagenesis of CaM along with studies of photoreactive and fluorescent CaM-binding peptides have helped define how calmodulin interacts with amphiphilic helices.

The secondary structure of turkey gizzard myosin light chain kinase and the nature of its interaction with calmodulin

The enzymatic activities of native myosin light chain kinases are subject to modification by interaction with Ca2(+)-calmodulin (CaM). The interaction between myosin light chain kinase isolated from turkey gizzard (tgMLCK) and calmodulin isolated from bovine testes (CaMbt) and wheat germ (CaMwg) has been examined by means of the intrinsic tryptophan fluorescence of tgMLCK and the fluorescence of extrinsic fluorescent labels located at Cys-27 and Tyr-139 of CaMwg and Tyr-99 of CaMbt. Static and dynamic fluorescence measurements provide evidence for the involvement of the former two sites in the zone of contact with lesser involvement of the site marked by the probe at Tyr-99. Complex formation protected the primary cleavage site in CaMbt (Lys-77) from proteolysis by trypsin. These results are consistent with involvement of the N- and C-terminal lobes of CaM in stabilization of the complex with tgMLCK, but cannot rule out participation of the connecting strand in the interaction. CD measurements extending to 175 nm, obtained using synchroton radiation, indicate the following secondary structure content for tgMLCK: 17 +/- 2% alpha-helix, 22 +/- 3% antiparallel beta-sheet, 3 +/- 1% parallel beta-sheet, 24 +/- 2% beta-turns, and 34 +/- 2% random coil. Similar measurements of the CD spectra of CaMbt and of the 1:1::CaMbt:tgMLCK complex presently indicate that neither protein undergoes major secondary structure rearrangement during their interaction, although subtle changes in the CD spectrum of tgMLCK appear to be correlated with the interaction with CaM.

Mutant analysis approaches to understanding calcium signal transduction through calmodulin and calmodulin regulated enzymes

An example set of site-specific mutagenesis studies of calmodulin has been discussed in terms of strategy and how the results can provide insight into the functioning of calmodulin. A set of common examples for the study of calcium binding and enzyme activation were discussed. Essentially, site-specific mutagenesis in these initial studies is a perturbation approach. From these perturbation studies, structural features can be correlated in future studies with function and mechanisms of action proposed. More importantly, the approach allows efficient testing of proposed mechanisms and further probing of the molecular aspects of the signal transduction pathways. Clearly, the key functional feature that must be addressed in future studies is how the calcium binding steps in the mechanism are coupled to the enzyme activation step, which is the final step of the calmodulin-enzyme binding mechanism.

Calcium/calmodulin-dependent protein kinase II

There is a great deal known about the in vitro properties of CaM kinase II, both in terms of its substrate specificity and its regulation by calmodulin and autophosphorylation. Much of this characterization is based on experiments performed with the rat brain isozyme of CaM kinase II, although in the aspects examined to date isozymes of the kinase from other tissues appear to behave in a broadly similar manner in vitro. However, relatively little is known about the functions of the kinase in vivo. The proteins phosphorylated by the kinase (with the probable exception of synapsin I and tyrosine hydroxylase) and the role of kinase autophosphorylation in vivo remain largely unknown. Investigation of the physiological role of the kinase in brain and other tissues will be a particularly exciting area for future work. The current knowledge of the in vitro properties and the availability of cDNA clones will hopefully expedite this research.

Model for the interaction of amphiphilic helices with troponin C and calmodulin

Crystals of troponin C are stabilized by an intermolecular interaction that involves the packing of helix A from the N-terminal domain of one molecule onto the exposed hydrophobic cleft of the C-terminal domain of a symmetry related molecule. Analysis of this molecular recognition interaction in troponin C suggests a possible mode for the binding of amphiphilic helical molecules to troponin C and to calmodulin. From the template provided by this troponin C packing, it has been possible to build a model of the contact region of mastoporan as it might be bound to the two Ca2+ binding proteins. A possible binding mode of melittin to calmodulin is also proposed. Although some of the characteristics of binding are similar for the two amphiphilic peptides, the increased length of melittin requires a significant bend in the calmodulin central helix similar to that suggested recently for the myosin light chain kinase calmodulin binding peptide (Persechini and Kretsinger: Journal of Cardiovascular Pharmacology 12:501-512, 1988). Not only are the hydrophobic interactions important in this model, but there are several favorable electrostatic interactions that are predicted as a result of the molecular modeling. The regions of troponin-C and calmodulin to which amphiphilic helices bind are similar to the regions to which the neuroleptic drugs such as trifluoperazine have been predicted to bind (Strynadka and James: Proteins 3:1-17, 1988).

Cloning of human calcineurin A: evidence for two isozymes and identification of a polyproline structural domain

Two types (I and II) of cDNAs encoding the large (A) subunit of calcineurin, a calmodulin-regulated protein phosphatase, were isolated from human basal ganglia and brainstem mRNA. The complete sequences of the two calcineurin clones are identical except for a 54-base-pair insert in the type I clone and different 3' ends including part of the coding sequence for the C termini of the two proteins. These findings suggest that calcineurin A consists of at least two isozymes that may result from alternative splicing events. The two forms of the enzyme differ in the C terminus, which contains an inhibitory domain rapidly severed by limited proteolysis. With the exception of an 18-amino acid insert, the central parts of the molecules, which harbor the catalytic domains, are identical and show extended similarities with the entire catalytic subunits of protein phosphatases 1 and 2A, defining a distinct family of protein phosphatases. The 40-residue N-terminal fragment, specific for calcineurin, contains a sequence of 11 successive prolines that is also found in bovine brain calcineurin by peptide sequencing. A role in the calmodulin activation of calcineurin is proposed for this novel structural element.

Turkey gizzard caldesmon: molecular weight determination and calmodulin binding studies

Sedimentation equilibrium and sedimentation velocity measurements demonstrate that turkey gizzard caldesmon is an elongated molecule of molecular mass 75 +/- 2 kDa. The frictional ratio (2.14) is consistent with a prolate ellipsoid of axial ratio 24, corresponding to an apparent length and width of 516 and 21.5 A, respectively. As was previously determined for chicken gizzard caldesmon [Graceffa, P., Wang, C.-L.A., & Stafford, W.F. (1988) J. Biol. Chem. 263, 14196-14202], this molecular weight is appreciably smaller than the value (approximately 135,000) estimated from the results of NaDodSO4 gel electrophoresis experiments. However, a significant difference between the true molecular weights of turkey and chicken gizzard caldesmons--75,000 versus 93,000--also points to probable molecular weight variations within the subclass. Binding measurements, based on perturbation of the intrinsic tryptophan fluorescence of caldesmon in the presence of calmodulin, show that the interaction between the two proteins is strongly ionic strength and temperature dependent. Dissociation constants of 0.075 and 0.38 microM were determined in solutions containing 0.1 and 0.2 M KCl, respectively, at 24.3 degrees C. Fluorescence emission spectra and fluorescence anisotropy excitation spectra indicate that the tryptophanyl residues of caldesmon are located in solvent-accessible regions of the molecule, where they exhibit a high degree of mobility even when calmodulin is bound.

Calmodulin-binding proteins as calpain substrates

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mRNAs for plasma membrane calcium pump isoforms differing in their regulatory domain are generated by alternative splicing that involves two internal donor sites in a single exon

cDNA clones coding for human plasma membrane Ca2+ pump isoforms have been isolated from a fetal skeletal muscle cDNA library. Compared with the sequence of a teratoma cDNA-encoded pump these clones specify isoforms that contain either 29- or 38-amino acid insertions within the calmodulin-binding region. Replacement of two basic arginine residues by an aspartic acid and a glutamine residue could influence the binding of calmodulin to these isoforms. RNase mapping shows that RNA species containing the 29-residue-encoding insertion are particularly abundant in skeletal muscles. The sequences coding for the insertions are present on a single 154-base-pair exon, as demonstrated by an analysis of the corresponding genomic region, and they are included in their respective mRNAs by alternative splicing involving the differential usage of two internal "cryptic" donor splice sites in the presence of a nearby canonical one. Inclusion of the complete 154-base-pair exon results in an mRNA coding for a pump protein with a shorter C-terminal amino acid sequence that lacks a consensus site for phosphorylation by the cAMP-dependent kinase. Exclusion, inclusion, or partial inclusion of the same exon can thus lead to the production of four different mRNAs from a single gene. When expressed as protein, these mRNAs encode Ca2+ pump isoforms that differ in their C-terminal regulatory domains.

A calmodulin-binding peptide relaxes skinned muscle from guinea-pig taenia coli

During smooth muscle activation the calcium calmodulin complex interacts with myosin light chain kinase (MLCK) whereby activating it. A synthetic peptide analogue (RS20) corresponding to the calmodulin recognition sequence of MLCK has been synthesized and previously found to inhibit the calmodulin stimulated light chain kinase activity. Here we studied the effect of this peptide on skinned fibers from guinea pig taenia coli. Maximal contractions induced by 30 microM Ca2+ at 0.1 microM calmodulin could be completely relaxed by the peptide at 1 microM. The inhibitory effect was accompanied by partial dephosphorylation only of the regulatory myosin light chain. Relaxation could be reversed by addition of calmodulin which also increased the extent of light chain phosphorylation. The calmodulin concentration required for reversing the inhibition depended on the concentration of the inhibitory peptide suggesting that the peptide competed with MLCK for the calmodulin binding site. As the calcium-calmodulin-peptide mixture constitutes a calmodulin buffer, our results suggest, that the peptide is a calmodulin antagonist unique in terms of its potency and that less than nanomolar concentrations of free calmodulin may be required for inducing smooth muscle contractions.

35 kDa fragment of h-caldesmon conserves two consensus sequences of the tropomyosin-binding domain in troponin T

Using a tropomyosin-coupled affinity column, we have demonstrated a direct association between the chymotryptic 35 kDa fragment of h-caldesmon, which is located at the C-terminal of the parent molecule, and gizzard tropomyosin. We have subsequently determined the nucleotide sequence of cDNA clones encoding the 35 kDa fragment from the cDNA library prepared from chick embryo gizzards, and have deduced the amino acid sequence. Calculating from the predicted sequence, the 35 kDa fragment is composed of 306 amino acid residues. In agreement with the tropomyosin-binding ability, the 35 kDa fragment conserves two consensus sequences of the tropomyosin-binding domain in troponin T. These results suggest that the 35 kDa fragment of h-caldesmon, at least in part, has a common property to the striated muscle troponin T.

Effects of modulators of myosin light-chain kinase activity in single smooth muscle cells

Phosphorylation of myosin light chains by a calmodulin-myosin light-chain kinase (MLCK) pathway is considered to be responsible for coupling increased calcium concentration with contraction in smooth muscle. This simple view has, however, recently been questioned. To test this hypothesis directly, we microinjected individual smooth muscle cells with modulators of the MLCK pathway while measuring contraction and calcium-ion concentration. Injection of a constitutively active proteolyzed form of MLCK causes contraction but no change in calcium concentration. By contrast, injection of peptide inhibitors of MLCK blocks contraction in response to K+ depolarization, despite the fact that the change in calcium concentration in response to stimulation was enhanced over controls. These results provide a direct demonstration at the level of a single cell that activation of the calmodulin-MLCK pathway is both necessary and sufficient to trigger contraction of smooth muscle.

Calcium/calmodulin-dependent protein kinase II

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Computational and site-specific mutagenesis analyses of the asymmetric charge distribution on calmodulin

Calmodulin's calculated electrostatic potential surface is asymmetrically distributed about the molecule. Concentrations of uncompensated negative charge are localized near certain alpha-helices and calcium-binding loops. Further calculations suggest that these charge features of calmodulin can be selectively perturbed by changing clusters of phylogenetically conserved acidic amino acids in helices to lysines. When these cluster charge reversals are actually produced by using cassette-based site-specific mutagenesis of residues 82-84 or 118-120, the resulting proteins differ in their interaction with two distinct calmodulin-dependent protein kinases, myosin light chain kinase and calmodulin-dependent protein kinase II. Each calmodulin mutant can be purified to apparent chemical homogeneity by an identical purification protocol that is based on conservation of its overall properties, including calcium binding. Although cluster charge reversals result in localized perturbations of the computed negative surface, single amino acid changes would not be expected to alter significantly the distribution of the negative surface because of the relatively high density of uncompensated negative charge in the region around residues 82-84 and 118-120. However, this does not preclude the possibility of single amino acid charge perturbations having a functional effect on the more intimate, catalytically active complex. The electrostatic surface of calmodulin described in this report may be a feature that would be altered only by cluster charge reversal mutations. Overall, the results suggest that the charge properties of calmodulin are one of several properties that are important for the efficient assembly of calmodulin-protein kinase signal transduction complexes in eukaryotic cells.

Characterization of a cDNA clone encoding the calmodulin-binding domain of mouse brain calcineurin

A cDNA clone corresponding to a portion of the catalytic subunit of calmodulin (CaM)-dependent phosphoprotein phosphatase (calcineurin) was isolated from a murine brain library by expression vector immunoscreening. A beta-galactosidase fusion protein that reacted on Western blots with anti-calcineurin antibodies and biotinylated CaM was purified in preparative amounts using CaM-Sepharose affinity chromatography. Partial digestion of the hybrid protein with Staphylococcus aureus V-8 protease produced several immunoreactive peptides that appeared identical to fragments generated from authentic brain calcineurin. The 1111-base-pair (bp) EcoRI insert contained an open reading frame encoding a protein of 35 kDa followed by a 190-bp 3' noncoding region; seven peptides obtained by partial amino acid sequencing of the bovine brain enzyme were found in the deduced sequence. A domain approximately 12 kDa from the carboxyl terminus was deduced to be the CaM-binding site based on consensus structural features and a sequence of seven amino acids highly related to smooth muscle myosin light-chain kinase. Two regions with identity to protein phosphatases 1 and 2A were found in the amino half of the cloned sequence; however, the intervening sequence contained apparent insertions, suggesting splicing of subdomains. Thus, the structure of calcineurin is chimeric, consisting of conserved catalytic elements and a regulatory CaM-binding domain.

The conformation of calmodulin: a substantial environmentally sensitive helical transition in Ca4-calmodulin with potential mechanistic function

The conformation of Ca4-calmodulin in solution, as assessed by far-UV peptide circular dichroism, contains significantly less alpha-helix than the proposed X-ray crystal structure. We now show that Ca4-calmodulin adopts significant additional helical structure in solution in the presence of a helicogenic solvent (50%, v/v, aqueous 2,2,2-trifluoroethanol or 50%, v/v, methylpentane-5,5-diol). We suggest that the long continuous helix (residues 66-92 of the crystal structure) is not necessarily a normal feature of the calmodulin structure in solution, and may be due in part to the conditions of crystallisation. This result is supported by time-resolved tyrosine fluorescence anisotropy studies indicating that Ca4-calmodulin in solution is an essentially compact globular structure which undergoes isotropic rotational motion. We conclude that, under appropriate ionic and apolar environmental conditions, Ca4-calmodulin undergoes a substantial helical transition, which may involve residues in the central region of the molecule. Such a transition could have an important function in determining specificity and affinity in interactions of calmodulin with different target sequences of Ca2+-dependent regulatory enzymes.