Identification of Mg2+-binding sites and the role of Mg2+ on target recognition by calmodulin

The binding of Mg2+ to calmodulin (CaM) and the effect of Mg2+ on the binding of Ca2+-CaM to target peptides were examined using two-dimensional nuclear magnetic resonance and fluorescence spectroscopic techniques. We found that Mg2+ preferentially binds to Ca2+-binding sites I and IV of CaM in the absence of Ca2+ and that Ca2+-binding site III displays the lowest affinity for Mg2+. In contrast to the marked structural transitions induced by Ca2+ binding, Mg2+ binding causes only localized conformational changes within the four Ca2+-binding loops of CaM. Therefore, Mg2+ does not seem to be able to cause significant structural effects required for the interaction of CaM with target proteins. The presence of excess Mg2+ (up to 10 mM) does not change the order and cooperativity of Ca2+ binding to CaM, and as expected, the structure of Ca2+-saturated CaM is not affected by the presence of Mg2+. However, we found that the binding of Ca2+-saturated CaM to target peptides is affected by Mg2+ with the binding affinity decreasing as the Mg2+ concentration increases. Three different peptides, corresponding to the CaM binding domain of skeletal muscle myosin light-chain kinase (MLCK), CaM-dependent cyclic nucleotide phosphodiesterase (PDE), and smooth muscle caldesmon (CaD), were examined and show different reductions in their affinities toward CaM. The CaM-binding affinity of the MLCK peptide in the presence of 50 mM Mg2+ is approximately 40-fold lower than that seen in the absence of Mg2+, and a similar response was observed for the PDE peptide. The affinity of the CaD peptide for CaM also shows a Mg2+ dependence, though to a much lower magnitude. The Mg2+-dependent decrease in the affinities between CaM and its target peptides is an intrinsic property of Mg2+ rather than a nonspecific ionic effect, as other metal ions such as Na+ do not completely replicate the effect of Mg2+. The inhibitory effect of Mg2+ on the formation of complexes between CaM and its targets may contribute to the specificity of CaM in target activation in response to cellular Ca2+ concentration fluctuations.     

Sequence motifs for calmodulin recognition

Calmodulin (CaM) is recognized as a major calcium sensor and orchestrator of regulatory events through its interaction with a diverse group of cellular proteins. Many investigations have focused on defining the region of interaction between CaM and its cellular targets and the action of CaM on target protein function. Because CaM can bind with high affinity to a relatively small alpha-helical region of many proteins, success in clearly defining the essential elements of CaM binding motifs seems feasible and should provide a means of identifying CaM binding proteins. Three recognition motifs for CaM interaction are discussed in the context of experimental investigations of a variety of CaM target proteins. A modified version of the IQ motif as a consensus for Ca2+-independent binding and two related motifs for Ca2+-dependent binding, termed 18-14 and 1-5-10 based on the position of conserved hydrophobic residues, are proposed. Although considerable sequence diversity is observed among the different binding regions, these three classes of recognition motifs exist for many of the known CaM binding proteins.     

Blocking the Ca2+-induced conformational transitions in calmodulin with disulfide bonds

Calcium-dependent regulation of intracellular processes is mediated by proteins that on binding Ca2+ assume a new conformation, which enables them to bind to their specific target proteins and to modulate their function. Calmodulin (CaM) and troponin C, the two best characterized Ca2+-regulatory proteins, are members of the family of Ca2+-binding proteins utilizing the helix-loop-helix structural motif (EF-hand). Herzberg, Moult, and James (Herzberg, O., Moult, J., and James, M.N.G. (1986) J. Biol. Chem. 261, 2638-2644) proposed that the Ca2+-induced conformational transition in troponin C involves opening of the interface between the alpha-helical segments in the N-terminal domain of this protein. Here we have tested the hypothesis that a similar transition is the key Ca2+-induced regulatory event in calmodulin. Using site-directed mutagenesis we have substituted cysteine residues for Gln41 and Lys75 (CaM41/75) or Ile85 and Leu112 (CaM85/112) in the N-terminal and C-terminal domains, respectively, of human liver calmodulin. Based on molecular modeling, cysteines at these positions were expected to form intramolecular disulfide bonds in the Ca2+-free conformation of the protein, thus blocking the putative Ca2+-induced transition. We found that intramolecular disulfide bonds are readily formed in both mutants causing a decrease in affinity for Ca2+ and the loss of ability to activate target enzymes, phosphodiesterase and calcineurin. The regulatory activity is fully recovered in CaM41/75 and partially recovered in CaM85/112 upon reduction of the disulfide bonds with dithiothreitol and blocking the Cys residues by carboxyamidomethylation or cyanylation. These results indicate that the Ca2+-induced opening of the interfaces between helical segments in both domains of CaM is critical for its regulatory properties consistent with the Herzberg-Moult-James model.     

Inhibition of G protein-coupled receptor kinase subtypes by Ca2+/calmodulin

G protein-coupled receptor kinases (GRKs) are implicated in the homologous desensitization of G protein-coupled receptors. Six GRK subtypes have so far been identified, named GRK1 to GRK6. The functional state of the GRKs can be actively regulated in different ways. In particular, it was found that retinal rhodopsin kinase (GRK1), but not the ubiquitous betaARK1 (GRK2), can be inhibited by the photoreceptor-specific Ca2+-binding protein recoverin through direct binding. The present study was aimed to investigate regulation of other GRKs by alternative Ca2+-binding proteins such as calmodulin (CaM). We found that Gbetagamma-activated GRK2 and GRK3 were inhibited by CaM to similar extents (IC50 approximately 2 microM), while a 50-fold more potent inhibitory effect was observed on GRK5 (IC50 = 40 nM). Inhibition by CaM was strictly dependent on Ca2+ and was prevented by the CaM inhibitor CaMBd. Since Gbetagamma, which is a binding target of Ca2+/CaM, is critical for the activation of GRK2 and GRK3, it provides a possible site of interaction between these proteins. However, since GRK5 is Gbetagamma-independent, an alternative mechanism is conceivable. A direct interaction between GRK5 and Ca2+/CaM was revealed using CaM-conjugated Sepharose 4B. This binding does not influence the catalytic activity as demonstrated using the soluble GRK substrate casein. Instead, Ca2+/CaM significantly reduced GRK5 binding to the membrane. The mechanism of GRK5 inhibition appeared to be through direct binding to Ca2+/CaM, resulting in inhibition of membrane association and hence receptor phosphorylation. The present study provides the first evidence for a regulatory effect of Ca2+/CaM on some GRK subtypes, thus expanding the range of different mechanisms regulating the functional states of these kinases.     

Calcium-dependent and -independent interactions of the calmodulin-binding domain of cyclic nucleotide phosphodiesterase with calmodulin

The ubiquitous Ca2+-binding regulatory protein calmodulin (CaM) binds and activates a wide range of regulatory enzymes. The binding is usually dependent on the binding of Ca2+ to CaM; however, some target proteins interact with CaM in a calcium-independent manner. In this work, we have studied the interactions between CaM and a 20-residue synthetic peptide encompassing the major calmodulin-binding domain of cyclic nucleotide phosphodiesterase (PDE1A2). The binding was studied in the absence and presence of Ca2+ by far-UV and near-UV circular dichroism, fluorescence, and infrared spectroscopy. In addition, two-dimensional heteronuclear NMR studies with 13C-methyl-Met-CaM and uniformly 15N-labeled CaM were performed. Competition assays with smooth muscle myosin light chain kinase revealed a Kd of 224 nM for peptide binding to Ca2+-CaM, while binding of the peptide to apo-CaM is weaker. The peptide binds with an alpha-helical structure to both lobes of Ca2+-saturated CaM, and the single Trp residue is firmly anchored into the C-terminal lobe of CaM. In contrast, the Trp residue plays a minor role in the binding to the apo-protein. Moreover, when bound to apo-CaM, the PDE peptide is only partially helical, and it interacts solely with the C-terminal lobe of CaM. These results show that the Ca2+-induced activation of PDE involves a significant change in the structure and positioning of the CaM-bound PDE peptide domain.     

Peptide-specific antibodies as probes of the topography of the Ca2+-binging motifs in alphaIIbbeta3

Antibodies against synthetic peptides corresponding to four Ca2+-binding motifs of the alphaIIb subunit have been obtained and used as molecular probes to analyze the topography of the alphaIIbeta3 complex. The specificity of the antibodies has been characterized by ELISA and Western immunoblotting in terms of binding capacity and affinity to the isolated alphaIIbbeta3 and its alphaIIb subunit. Our data suggest that: (a) all four Ca2+-binding motifs of the alphaIIb are partially exposed on the surface of the intact molecule and accessible to antipeptide antibodies. However, they are not in close vicinity to the ligand recognition domain since the antibodies do not produce complete inhibition of platelet aggregation. (b) The conformation of amino acid stretches which form the second Ca2+-binding motif of alphaIIb is particularly dependent upon the presence of cation, and this region undergoes significant conformational alterations upon Ca2+ expulsion.     

Core mutations that promote the calcium-induced allosteric transition of bovine recoverin

Recoverin is a small calcium binding protein involved in regulation of the phototransduction cascade in retinal rod cells. It functions as a calcium sensor by undergoing a cooperative, ligand-dependent conformational change, resulting in the extrusion of the N-terminal myristoyl group from a hydrophobic pocket. To test the role of certain core residues in tuning this allosteric switch, we have made and characterized two mutants: W31K, which replaces Trp31 with Lys; and a double mutant, I52A/Y53A, in which Ile52 and Tyr53 are both replaced by Ala. These mutations decrease the hydrophobicity of the myristoyl binding pocket. They are thus expected to make sequestering of the myristoyl group less favorable and destabilize the Ca2+-free state. As predicted, the myristoylated forms of the mutants exhibit increased affinity for Ca2+, whether monitored by equilibrium binding of 45Ca2+ (Kd = 17.2, 7.9, and 8.1 microM for wild type, W31K, and I52A/Y53A, respectively) or by the change in tryptophan fluorescence associated with the conformational change (Kd = 17.9, 3.6, and 4.4 microM for wild type, W31K, and I52A/Y53A, respectively). The mutants also exhibit decreased cooperativity of binding (Hill coefficient = 1.2 and 1.0 for W31K and I52A/Y53A vs 1. 4 for wild type). Binding of the mutant proteins to rod outer segment membranes occurs at lower Ca2+ concentrations compared to wild-type protein (K1/2 = 5.6, 2.2, and 1.0 microM for wild type, W31K, and I52A/Y53A, respectively). The unmyristoylated forms of the mutants exhibit biphasic Ca2+ binding curves, nearly identical to that observed for wild type. The binding data for the two mutants can be explained by a concerted allosteric model in which the mutations affect only the equilibrium constant L between the two allosteric forms, T (the Ca2+-free form) and R (the Ca2+-bound form), without affecting the intrinsic binding constants for the two Ca2+ sites. Two-dimensional NMR spectra of the Ca2+-free forms of the mutants have been compared to the wild-type spectrum, whose peaks have been assigned to specific residues (1). Many resonances assigned to residues in the C-terminal domain (residues 100-202) in the wild-type spectrum are identical in the mutant spectra, suggesting that the backbone structure of the C-terminal domain is probably unchanged in both mutants. The N-terminal domain, in which both mutations are located, reveals in each case numerous changes of undetermined spatial extent.     

Calmodulin binding to myosin light chain kinase begins at substoichiometric Ca2+ concentrations: a small-angle scattering study of binding and conformational transitions

We have used small-angle scattering to study the calcium dependence of the interactions between calmodulin (CaM) and skeletal muscle myosin light chain kinase (MLCK), as well as the conformations of the complexes that form. Scattering data were measured from equimolar mixtures of a functional MLCK and CaM or a mutated CaM (B12QCaM) incompetent to bind Ca2+ in its N-terminal domain, with increasing Ca2+ concentrations. To evaluate differences between CaM-enzyme versus CaM-peptide interactions, similar Ca2+ titration experiments were performed using synthetic peptides based on the CaM-binding sequence from MLCK (MLCK-I). Our data show there are different determinants for CaM binding the isolated peptide sequence compared to CaM binding to the same sequences within the enzyme. For example, binding of either CaM or B12QCaM to the MLCK-I peptide is observed even in the presence of EGTA, whereas binding of CaM to the enzyme requires Ca2+. The peptide studies also show that the conformational collapse of CaM requires both the N and C domains of CaM to be competent for Ca2+ binding as well as interactions with each end of MLCK-I, and it occurs at approximately 2 mol of Ca2+/mol of CaM. We show that CaM binding to the MLCK enzyme begins at substoichiometric concentrations of Ca2+ (< or = 2 mol of Ca2+/mol of CaM), but that the final compact structure of CaM with the enzyme requires saturating Ca2+. In addition, MLCK enzyme does bind to 2Ca2+ x B12QCaM, although this complex is more extended than the complex with native CaM. Our results support the hypothesis that CaM regulation of MLCK involves an initial binding step at less than saturating Ca2+ concentrations and a subsequent activation step at higher Ca2+ concentrations.     

An optical method for evaluating ion selectivity for calcium signaling pathways in the cell

A method for evaluating a physiologically relevant ion selectivity of Ca2+ signaling pathways in biological cells based on a Ca(2+)-dependent on/off switch for cellular processes via calmodulin (CaM) chemistry is described. CaM serves as a primary ion receptor for Ca2+ and a given CaM-binding peptide as a target for a CaM-Ca2+ complex. Upon accommodating four Ca2+ ions in its binding sites, CaM undergoes a conformational change to form a CaM-Ca(2+)-target peptide ternary complex. This Ca(2+)-induced selective binding of the Ca(2+)-CaM complex to the target peptide was monitored by a surface plasmon resonance (SPR) technique. As a target peptide, a 26-amino acid residue of M13 derived from skeletal muscle myosin light-chain kinase was used. The target peptide was covalently immobilized in the dextran matrix on top of gold, over which sample solutions containing Ca2+ and CaM were injected in a flow system. Ca(2+)-dependent SPR signals were observed for Ca2+ concentrations from 3.2 x 10(-8) to 1.1 x 10(-5) M and it leveled off. The observed SPR signals were explained as due to an increase in the refractive indexes caused by a Ca2+ ion-switched protein/ peptide interaction, i.e., Ca2+ ion to CaM and subsequent additional binding of the thus formed complex with immobilized M13. No SPR signals were however, induced by Mg2+, K+, and Li+ at concentrations as high as 1.0 x 10(-1) M; these results and previous spectroscopic data taken together conclude that these ions do not induce CaM/peptide interaction. Large changes in SPR signals were observed with a Sr2+ ion concentration over 5.1 x 10(-4) M; Sr2+ ion behaved in this case as a strong agonist toward the Ca(2+)-dependent on/off switch of CaM. The present system thus exhibited "physiologically more relevant" ion selectivity in that relevant metal ions could switch on the CaM/peptide or -protein interaction rather than merely be bound to CaM causing no further signal transduction. The potential use of this finding for more widely evaluating cation selectivity toward the Ca2+ signaling process was discussed.     

15N NMR relaxation studies of calcium-loaded parvalbumin show tight dynamics compared to those of other EF-hand proteins

Dynamics of the rat alpha-parvalbumin calcium-loaded form have been determined by measurement of 15N nuclear relaxation using proton-detected heteronuclear NMR spectroscopy. The relaxation data were analyzed using spectral density functions and the Lipari-Szabo formalism. The major dynamic features for the rat alpha-parvalbumin calcium-loaded form are (1) the extreme rigidity of the helix-loop-helix EF-hand motifs and the linker segment connecting them, (2) the N and C termini of the protein being restricted in their mobility, (3) a conformational exchange occurring at the kink of helix D, and (4) the residue at relative position 2 in the Ca2+-binding sites having an enhanced mobility. Comparison of the Ca2+-binding EF-hand domains of alpha-parvalbumin-Ca2+, calbindin-Ca2+, and calmodulin-Ca2+ shows that parvalbumin is probably the most rigid of the EF-hand proteins. It also illustrates the dynamical properties which are conserved in the EF-hand domains from different members of this superfamily: (1) a tendency toward higher mobility of NH vectors at relative position 2 in the Ca2+-binding loop, (2) a restricted mobility for the other residues in the binding loop, and (3) an overall rigidity for the helices of EF-hand motifs. The differences in mobility between parvalbumin and the two EF-hand proteins occur mainly at the linker connecting the pair of EF hands and also at the C terminus of the last helix. In parvalbumin-Ca2+, these two regions are characterized by a pronounced rigidity compared to the corresponding more mobile regions in calbindin-Ca2+ and calmodulin-Ca2+.     

Synthesis and use of a biotinylated 3-azidophenothiazine to photolabel both amino- and carboxyl-terminal sites in calmodulin

The biotinylated probe, 3-azido-10-(4-(4-biotinyl-1-piperazinyl)butyl)phenothiazine, was used to examine the phenothiazine binding domains in calmodulin (CaM) by photolabeling. This phenothiazine, synthesized from 3-azido-10-(4-(1-piperazinyl)butyl)phenothiazine and d-biotinyl tosylate, inhibited the CaM-mediated activation of phosphodiesterase (PDE) with an I50 of 12.5 (+/- 2.8) microM. Photolabeling of CaM produced covalent adducts in excellent yield (32%) in a light- and Ca2+-dependent manner. Studies performed over a range of drug concentrations suggested a 2:1 stoichiometry for the binding of the phenothiazine probe to CaM. Limited trypsin digestion and purification of the resulting fragments by either SDS-PAGE or HPLC provided two principal phenothiazine-containing peptides. Amino acid composition and sequence analyses performed on these two peptides established that both the N- and C-terminal domains in CaM, particularly the regions amino terminal to Ca2+-binding loops 1 and 3, were modified by the photoactivated phenothiazine derivative. These data, particularly for the C-terminal domain, are in excellent agreement with the X-ray structure analysis of a 1:1 CaM-trifluoperazine complex.     

The paternal effect gene ms(3)sneaky is required for sperm activation and the initiation of embryogenesis in Drosophila melanogaster

Calcium sensor proteins translate transient increases in intracellular calcium levels into metabolic or mechanical responses, by undergoing dramatic conformational changes upon Ca2+ binding. A detailed analysis of the calcium binding-induced conformational changes in the representative calcium sensors calmodulin (CaM) and troponin C was performed to obtain insights into the underlying molecular basis for their response to the binding of calcium. Distance difference matrices, analysis of interresidue contacts, comparisons of interhelical angles, and inspection of structures using molecular graphics were used to make unbiased comparisons of the various structures. The calcium-induced conformational changes in these proteins are dominated by reorganization of the packing of the four helices within each domain. Comparison of the closed and open conformations confirms that calcium binding causes opening within each of the EF-hands. A secondary analysis of the conformation of the C-terminal domain of CaM (CaM-C) clearly shows that CaM-C occupies a closed conformation in the absence of calcium that is distinct from the semi-open conformation observed in the C-terminal EF-hand domains of myosin light chains. These studies provide insight into the structural basis for these changes and into the differential response to calcium binding of various members of the EF-hand calcium-binding protein family. Factors contributing to the stability of the Ca2+-loaded open conformation are discussed, including a new hypothesis that critical hydrophobic interactions stabilize the open conformation in Ca2+ sensors, but are absent in "non-sensor" proteins that remain closed upon Ca2+ binding. A role for methionine residues in stabilizing the open conformation is also proposed.     

NMR studies of caldesmon-calmodulin interactions

The binding of the calcium-regulatory protein calmodulin (CaM) to caldesmon (CaD) contributes to the regulation of smooth muscle contraction. Two regions of caldesmon have been identified as putative calmodulin-binding domains. We have earlier reported on the binding of one of these domains to calmodulin (Zhang & Vogel (1994) Biochemistry 33, 1163-1171). Here we have studied the binding of CaM to synthetic peptides of CaD which contain: (1) both the first and second CaM-binding domains; (2) the second CaM-binding domain; and (3) the sequence between the first and second CaM-binding domains. Two-dimensional transferred nuclear Overhauser enhancement proton NMR measurements as well as circular dichroism studies of a 22-residue peptide NKETAGLKVGVSSRINEWLTK, which contains the second CaM-binding domain, show that only the C-terminal half of the peptide becomes alpha-helical upon binding to CaM. Somewhat surprisingly, the shorter 9-residue peptide SRINEWLTK was sufficient to form a 1:1 complex with CaM; this peptide appears to bind as a 3(10)-helix. Proton-carbon-13 correlation NMR titration studies with specifically labeled [methyl-13C]methionine CaM were used to study the participation of the hydrophobic regions in both domains of the dumbbell shaped CaM in peptide binding. Binding of a 54-residue CaD peptide containing both CaM-binding domains affects all the 8 Met residues in the two hydrophobic domains of CaM (only Met 76 in the linker region of CaM is not involved), while binding of the second CaM-binding domain of CaD influences principally Met 51, 71, and Met 124, 144. Simultaneous binding to CaM of two peptides comprising the first and the second CaM-binding domains also caused changes to all Met residues except Met 76. Taken together, these data demonstrate that both CaM-binding domains of CaD can bind simultaneously to the two hydrophobic regions of CaM.     

Dynamics and thermodynamics of the regulatory domain of human cardiac troponin C in the apo- and calcium-saturated states

The contraction of cardiac and skeletal muscles is triggered by the binding of Ca2+ to their respective troponin C (TnC) proteins. Recent structural data of both cardiac and skeletal TnC in both the apo and Ca2+ states have revealed that the response to Ca2+ is fundamentally different for these two proteins. For skeletal TnC, binding of two Ca2+ to sites 1 and 2 leads to large changes in the structure, resulting in the exposure of a hydrophobic surface. For cardiac TnC, Ca2+ binds site 2 only, as site 1 is inactive, and the structures show that the Ca2+-induced changes are much smaller and do not result in the exposure of a large hydrophobic surface. To understand the differences between regulation of skeletal and cardiac muscle, we have investigated the effect of Ca2+ binding on the dynamics and thermodynamics of the regulatory N-domain of cardiac TnC (cNTnC) using backbone 15N nuclear magnetic resonance relaxation measurements for comparison to the skeletal system. Analysis of the relaxation data allows for the estimation of the contribution of changes in picosecond to nanosecond time scale motions to the conformational entropy of the Ca2+-binding sites on a per residue basis, which can be related to the structural features of the sites. The results indicate that binding of Ca2+ to the functional site in cNTnC makes the site more rigid with respect to high-frequency motions; this corresponds to a decrease in the conformational entropy (TdeltaS) of the site by 2.2 kcal mol(-1). Although site 1 is defunct, binding to site 2 also decreases the conformational entropy in the nonfunctional site by 0.5 kcal mol(-1). The results indicate that the Ca2+-binding sites in the regulatory domain are structurally and energetically coupled despite the inability of site 1 to bind Ca2+. Comparison between the cardiac and skeletal isoforms in the apo state shows that there is a decrease in conformational entropy of 0.9 kcal mol(-1) for site 1 of cNTnC and little difference for site 2.     

Location of the membrane-docking face on the Ca2+-activated C2 domain of cytosolic phospholipase A2

Docking of C2 domains to target membranes is initiated by the binding of multiple Ca2+ ions to a conserved array of residues imbedded within three otherwise variable Ca2+-binding loops. We have located the membrane-docking surface on the Ca2+-activated C2 domain of cPLA2 by engineering a single cysteine substitution at 16 different locations widely distributed across the domain surface, in each case generating a unique attachment site for a fluorescein probe. The environmental sensitivity of the fluorescein-labeled cysteines enabled identification of a localized region that is perturbed by Ca2+ binding and membrane docking. Ca2+ binding to the domain altered the emission intensity of six fluoresceins in the region containing the Ca2+-binding loops, indicating that Ca2+-triggered environmental changes are localized to this region. Similarly, membrane docking increased the protonation of six fluoresceins within the Ca2+-binding loop region, indicating that these three loops also are directly involved in membrane docking. Furthermore, iodide quenching measurements revealed that membrane docking sequesters three fluorescein labeling positions, Phe35, Asn64, and Tyr96, from collisions with aqueous iodide ion. These sequestered residues are located within the identified membrane-docking region, one in each of the three Ca2+-binding loops. Finally, cysteine substitution alone was sufficient to dramatically reduce membrane affinity only at positions Phe35 and Tyr96, highlighting the importance of these two loop residues in membrane docking. Together, the results indicate that the membrane-docking surface of the C2 domain is localized to the same surface that cooperatively binds a pair of Ca2+ ions, and that the three Ca2+-binding loops themselves provide most or all of the membrane contacts. These and other results further support a general model for the membrane specificity of the C2 domain in which the variable Ca2+-binding loops provide headgroup recognition at a protein-membrane interface stabilized by multiple Ca2+ ions.     

Mechanism of phospholipid binding by the C2A-domain of synaptotagmin I

Synaptotagmin I is a synaptic vesicle membrane protein that probably functions as a Ca2+ sensor in neurotransmitter release and contains two C2-domains which bind Ca2+. The first C2-domain of synaptotagmin I (the C2A-domain) binds phospholipids in a Ca2+-dependent manner similar to that of the C2-domains of protein kinase C, cytoplasmic phospholipase A2, and phospholipase Cdelta1. Although the tertiary structure of these C2-domains is known, the molecular basis for their Ca2+-dependent interactions with phospholipids is unclear. We have now investigated the mechanisms involved in Ca2+-dependent phospholipid binding by the C2A-domain of synaptotagmin I. Our data show that the C2A-domain binds negatively charged liposomes in an electrostatic interaction that is determined by the charge density of the liposome surface but not by the phospholipid headgroup. At the tip of the C2A-domain, three tightly clustered Ca2+-binding sites are formed by five aspartates and one serine. Mutations in these aspartate and serine residues demonstrated that all three Ca2+-binding sites are required for phospholipid binding. The Ca2+ binding sites at the top of the C2A-domain are surrounded by positively charged amino acids that were shown by mutagenesis to be also involved in phospholipid binding. Our results yield a molecular picture of the interactions between a C2-domain and phospholipids. Binding is highly electrostatic and occurs between the surfaces of the phospholipid bilayer and of the tip of the C2A-domain. The data suggest that the negatively charged phospholipid headgroups interact with the basic side chains surrounding the Ca2+-binding sites and with bound Ca2+ ions, thereby filling empty coordination sites and increasing the apparent affinity for Ca2+. In addition, insertion of hydrophobic side chains may contribute to phospholipid binding. This model is likely to be general for other C2-domains, with the relative contributions of electrostatic and hydrophobic interactions dictated by the exposed side chains surrounding the Ca2+-binding region.     

The Ca2+-dependent binding of calmodulin to an N-terminal motif of the heterotrimeric G protein beta subunit

Ca2+ ion concentration changes are critical events in signal transduction. The Ca2+-dependent interactions of calmodulin (CaM) with its target proteins play an essential role in a variety of cellular functions. In this study, we investigated the interactions of G protein betagamma subunits with CaM. We found that CaM binds to known betagamma subunits and these interactions are Ca2+-dependent. The CaM-binding domain in Gbetagamma subunits is identified as Gbeta residues 40-63. Peptides derived from the Gbeta protein not only produce a Ca2+-dependent gel mobility shifting of CaM but also inhibit the CaM-mediated activation of CaM kinase II. Specific amino acid residues critical for the binding of Gbetagamma to CaM were also identified. We then investigated the potential function of these interactions and showed that binding of CaM to Gbetagamma inhibits the pertussis toxin-catalyzed ADP-ribosylation of Galphao subunits, presumably by inhibiting heterotrimer formation. Furthermore, we demonstrated that interaction with CaM has little effect on the activation of phospholipase C-beta2 by Gbetagamma subunits, supporting the notion that different domains of Gbetagamma are responsible for the interactions of different effectors. These findings shed light on the molecular basis for the interactions of Gbetagamma with Ca2+-CaM and point to the potential physiological significance of these interactions in cellular functions.     

Biochemical evidence for a calmodulin-stimulated calcium-dependent protein kinase in maize

We provide biochemical evidence for the presence of a Ca2+-dependent calmodulin (CaM)-stimulated protein kinase (CCaMK) from etiolated maize coleoptiles. The kinase, with a molecular mass of 72.3 kDa, was purified to homogeneity by means of ammonium sulphate precipitation, DEAE-Sephacel chromatography. CaM-Sepharose chromatography and gel purification. The purified kinase required 5 mM Mg2+ for activity and had an optimum pH of 7.5. The kinase is a Ca2+-binding protein, as was evident by 45Ca2+-binding and Ca2+ mobility-gel-shift assays. 1 microM Ca2+ stimulated the kinase activity about 12-fold and was further stimulated by the addition of exogenous CaM (approximately 100 nM). Addition of Ca2+ and CaM antagonists decreased the kinase activity. Under in vitro assay conditions the kinase phosphorylated preferentially syntide-2, histone IIIS and casein. Syntide-2 and histone IIIS were phosphorylated at serine residues, showing that the kinase belongs to the serine/threonine family of protein kinases. Autophosphorylation of CCaMK occurred on threonine residue(s) and was Ca2+ dependent. Addition of exogenous CaM had no effect on autophosphorylation. The properties of the maize kinase suggests that it is a CCaMK that shows dual stimulation with Ca2+ and CaM for substrate phosphorylation and only Ca2+ requirement for autophosphorylation. Antibodies raised against the kinase cross-reacted with maize total proteins to give a single band of 72 kDa and precipitated substrate (syntide-2 and histone IIIS)-phosphorylation and autophosphorylation activities in a specific manner. Localisation studies with antibodies showed that the kinase is ubiquitous.     

Synaptotagmin-syntaxin interaction: the C2 domain as a Ca2+-dependent electrostatic switch

Synaptotagmin I is a synaptic vesicle protein that is thought to act as a Ca2+ sensor in neurotransmitter release. The first C2 domain of synaptotagmin I (C2A domain) contains a bipartite Ca2+-binding motif and interacts in a Ca2+-dependent manner with syntaxin, a central component of the membrane fusion complex. Analysis by nuclear magnetic resonance spectroscopy and site-directed mutagenesis shows that this interaction is mediated by the cooperative action of basic residues surrounding the Ca2+-binding sites of the C2A domain and is driven by a change in the electrostatic potential of the C2A domain induced by Ca2+ binding. A model is proposed whereby synaptotagmin acts as an electrostatic switch in Ca2+-triggered synaptic vesicle exocytosis, promoting a structural rearrangement in the fusion machinery that is effected by its interaction with syntaxin.