Calcium-induced changes in calmodulin structural dynamics and thermodynamics

The thermodynamics of the interaction between Ca(2+) and calmodulin (CaM) was examined using isothermal titration calorimetry (ITC). The chemical denaturation of calmodulin was monitored spectroscopically to determine the stability of Ca(2+)-free (apo) and Ca(2+)-loaded (holo) CaMs. We explored the conformational and structural dynamics of CaM using amide hydrogen-deuterium (H-D) exchange coupled with Fourier transform infrared (FT-IR) spectroscopy. The results of H-D exchange and FT-IR suggest that CaM activation by Ca(2+) binding involves significant conformational changes. The results have also revealed that while the overall conformation of holo-CaM is more stable than that of the apo-CaM, some part of its α-helix structures, most likely the EF-hand domain region, has more solvent exposure, thus, has a faster H-D exchange rate than that of the apo-CaM. The ITC method provides a new strategy for obtaining site-specific Ca(2+) binding properties and a better estimation of the cooperativity and conformational change contributions of coupled EF-hand proteins.     

Interactions of calmodulin with metal ions and with its target proteins revealed by conformation-sensitive monoclonal antibodies

Two monoclonal antibodies (mAbs) raised against bovine calmodulin (CaM), CAM1 and CAM4, enable one to monitor conformational changes that occur in the molecule. The interaction of CAM1 with CaM depends on the Ca2+ occupancy of its Ca(2+)-binding sites. CAM4, in contrast, interacts with CaM in a Ca(2+)-independent manner, interacting with both holoCaM and EGTA-treated CaM to a similar extent. Their interaction with various CaMs, CaM tryptic fragments and chemically modified CaM, as well as molecular graphics, led to identification of the CAM1 and CAM4 epitopes on the C- and N-terminal lobes of CAM respectively. The two mAbs were used as macromolecular probes to detect conformational changes occurring in the CaM molecule upon binding of metal ions and target proteins and peptides. MAb CAM1 successfully detected changes associated with Al3+ binding even in the presence of Ca2+, indicating that Al3+ and Ca2+ ions may bind to the protein simultaneously, leading to a new conformation of the molecule. MAbs CAM1 and CAM4 were used to follow the interactions of CaM with its target peptides and proteins. Complexes with melittin, mastoparan, calcineurin and phosphodiesterase showed different immunological properties on an immuno-enzyme electrode, indicating unique structural properties for each complex.     

Solution structures of the N-terminal domain of yeast calmodulin: Ca2+-dependent conformational change and its functional implication

We have determined solution structures of the N-terminal half domain (N-domain) of yeast calmodulin (YCM0-N, residues 1-77) in the apo and Ca(2+)-saturated forms by NMR spectroscopy. The Ca(2+)-binding sites of YCM0-N consist of a pair of helix-loop-helix motifs (EF-hands), in which the loops are linked by a short beta-sheet. The binding of two Ca(2+) causes large rearrangement of the four alpha-helices and exposes the hydrophobic surface as observed for vertebrate calmodulin (CaM). Within the observed overall conformational similarity in the peptide backbone, several significant conformational differences were observed between the two proteins, which originated from the 38% disagreement in amino acid sequences. The beta-sheet in apo YCM0-N is strongly twisted compared with that in the N-domain of CaM, while it turns to the normal more stable conformation on Ca(2+) binding. YCM0-N shows higher cooperativity in Ca(2+) binding than the N-domain of CaM, and the observed conformational change of the beta-sheet is a possible cause of the highly cooperative Ca(2+) binding. The hydrophobic surface on Ca(2+)-saturated YCM0-N appears less flexible due to the replacements of Met51, Met71, and Val55 in the hydrophobic surface of CaM with Leu51, Leu71, and Ile55, which is thought to be one of reasons for the poor activation of target enzymes by yeast CaM.     

Conformational changes upon calcium binding and phosphorylation in a synthetic fragment of calmodulin

We have recently investigated by far-UV circular dichroism (CD) the effects of Ca(2+) binding and the phosphorylation of Ser 81 for the synthetic peptide CaM [54-106] encompassing the Ca(2+)-binding loops II and III and the central alpha helix of calmodulin (CaM) (Arrigoni et al., Biochemistry 2004, 43, 12788-12798). Using computational methods, we studied the changes in the secondary structure implied by these spectra with the aim to investigate the effect of Ca(2+) binding and the functional role of the phosphorylation of Ser 81 in the action of the full-length CaM. Ca(2+) binding induces the nucleation of helical structure by inducing side chain stacking of hydrophobic residues. We further investigated the effect of Ca(2+) binding by using near-UV CD spectroscopy. Molecular dynamics simulations of different fragments containing the central alpha-helix of CaM using various experimentally determined structures of CaM with bound Ca(2+) disclose the structural effects provided by the phosphorylation of Ser 81. This post-translational modification is predicted to alter the secondary structure in its surrounding and also to hinder the physiological bending of the central helix of CaM through an alteration of the hydrogen bond network established by the side chain of residue 81. Using quantum mechanical methods to predict the CD spectra for the frames obtained during the MD simulations, we are able to reproduce the relative experimental intensities in the far-UV CD spectra for our peptides. Similar conformational changes that take place in CaM [54-106] upon Ca(2+) binding and phosphorylation may occur in the full-length CaM.     

Regulatory interaction of sodium channel IQ-motif with calmodulin C-terminal lobe

An increasing number of ion channels have been found to be regulated by the direct binding of calmodulin (CaM), but its structural features are mostly unknown. Previously, we identified the Ca(2+)-dependent and -independent interactions of CaM to the voltage-gated sodium channel via an IQ-motif sequence. In this study we used the trypsin-digested CaM fragments (TR(1)C and TR(2)C) to analyze the binding of Ca(2+)-CaM or Ca(2+)-free (apo) CaM with a sodium channel-derived IQ-motif peptide (NaIQ). Circular dichroic spectra showed that NaIQ peptide enhanced alpha-helicity of the CaM C-terminal lobe, but not that of the CaM N-terminal lobe in the absence of Ca(2+), whereas NaIQ enhanced the alpha-helicity of both the N- and C-terminal lobes in the presence of Ca(2+). Furthermore, the competitive binding experiment demonstrated that Ca(2+)-dependent CaM binding of target peptides (MLCKp or melittin) with CaM was markedly suppressed by NaIQ. The results suggest that IQ-motif sequences contribute to prevent target proteins from activation at low Ca(2+) concentrations and may explain a regulatory mechanism why highly Ca(2+)-sensitive target proteins are not activated in the cytoplasm.     

Solution X-ray scattering data show structural differences among chimeras of yeast and chicken calmodulin: implications for structure and function

We present here the first evidence, obtained by the use of small-angle X-ray scattering, of the solution structures of chimeras constructed from yeast (Saccharomyces cerevisiae, Sc) and chicken (Gallus gallus, Gg) calmodulin (CaM). The chimeric proteins used in this study are Sc(1-129)/Gg(130-148), Sc(1-128)/Gg(129-148), Sc(1-87)/Gg(88-148), and Sc(1-72)/Gg(73-148) CaMs, in which Sc(1-)(n)() and Gg(()(n)(+1)-148) descend from yeast and chicken CaM in the chimeric proteins, respectively. Under the Ca(2+)-saturated condition, the solution structure of Sc(1-128)/Gg(129-148) CaM has a dumbbell-like shape which is characteristic of vertebrate-type CaM, while that of Sc(1-129)/Gg(130-148) CaM takes an intermediate structure between the dumbbell-like shape and a compact globular shape. The results provide the direct evidence that the replacement of Asp(129) with Ser(129) induces an interaction between two lobes of Sc(1-129)/Gg(130-148) CaM and brings them close together. It implies that a site interacting with the N-lobe is induced in the C-lobe, although site IV that is unable to bind Ca(2+) hinders the ability of the C-lobe to undergo the conformational change to the full open state. In the presence of both Ca(2+) and a peptide synthesized to mimic the CaM binding domain on myosin light chain kinase, MLCK-22p, the solution structures of these chimeric CaMs take a similar compact globular shape but their interactions are quite different. The solution structure and interactions of Sc(1-72)/Gg(73-148) CaM are similar to those of Sc(1-87)/Gg(88-148) CaM. The structure of Sc(1-87)/Gg(88-148) CaM is similar to that of Sc(1-128)/Gg(129-148) CaM, but their interactions are different. The result indicates that the replacement of Glu(119) with Ala(119) has a critical effect on their interactions. Thus, the functional differences among these chimeric CaMs, which have been reported previously [Nakashima, K., et al. (1996) Biochemistry 35, 5602-5610], have been interpreted on the basis of the structures and interactions.     

RC3/Neurogranin and Ca2+/calmodulin-dependent protein kinase II produce opposing effects on the affinity of calmodulin for calcium

The interaction of calmodulin with its target proteins is known to affect the kinetics and affinity of Ca(2+) binding to calmodulin. Based on thermodynamic principles, proteins that bind to Ca(2+)-calmodulin should increase the affinity of calmodulin for Ca(2+), while proteins that bind to apo-calmodulin should decrease its affinity for Ca(2+). We quantified the effects on Ca(2+)-calmodulin interaction of two neuronal calmodulin targets: RC3, which binds both Ca(2+)- and apo-calmodulin, and alphaCaM kinase II, which binds selectively to Ca(2+)-calmodulin. RC3 was found to decrease the affinity of calmodulin for Ca(2+), whereas CaM kinase II increases the calmodulin affinity for Ca(2+). Specifically, RC3 increases the rate of Ca(2+) dissociation from the C-terminal sites of calmodulin up to 60-fold while having little effect on the rate of Ca(2+) association. Conversely, CaM kinase II decreases the rates of dissociation of Ca(2+) from both lobes of calmodulin and autophosphorylation of CaM kinase II at Thr(286) induces a further decrease in the rates of Ca(2+) dissociation. RC3 dampens the effects of CaM kinase II on Ca(2+) dissociation by increasing the rate of dissociation from the C-terminal lobe of calmodulin when in the presence of CaM kinase II. This effect is not seen with phosphorylated CaM kinase II. The results are interpreted according to a kinetic scheme in which there are competing pathways for dissociation of the Ca(2+)-calmodulin target complex. This work indicates that the Ca(2+) binding properties of calmodulin are highly regulated and reveals a role for RC3 in accelerating the dissociation of Ca(2+)-calmodulin target complexes at the end of a Ca(2+) signal.     

Mastoparan/Mastoparan X altered binding behavior of La3+ to calmodulin in ternary complexes

Ca(2+) binds to calmodulin (CaM) and triggers the interaction of CaM with its target proteins; CaM binding proteins (CaMBPs) can also regulate the metal binding to CaM. In the present paper, La(3+) binding to CaM was studied in the presence of the CaM binding peptides, Mastoparan (Mas) and Mas X, using ultrafiltration and titration of fluorescence. Ca(2+) binding was used as an analog to understand La(3+) binding in intact CaM and isolated N/C-terminal CaM domain of metal-CaM binary system and metal-CaM-CaMBPs ternary system. Mas/Mas X increased binding affinity of La(3+) to CaM by 0.5 approximately 3 orders magnitude. The metal ions binding affinity to the C-terminal or the N-terminal CaM domain suggested that in the first phase of binding process both Ca(2+) and La(3+) bind to C-terminal of CaM in the presence of Mas/Mas X. In the presence of CaM binding peptides, La(3+) binding preference was substantially altered from the metal-CaM binary system where La(3+) slightly preferred binding to the N-terminal sites of CaM. Our results will be helpful in understanding La(3+) interactions with CaM in the biological systems.     

Restoration of the calcium binding activity of mutant calmodulins toward normal by the presence of a calmodulin binding structure

The altered calcium binding activity of calmodulins (CaM) with point mutations can be restored toward that of wild type CaMs by the formation of a complex between CaM and a CaM binding sequence. Three different site-specific mutations resulted in selective effects on the apparent stoichiometry and affinity of CaM for calcium, with maintenance of the ability to activate myosin light chain kinase. The effects on calcium binding, however, were suppressed when the mutant CaMs were complexed with RS20, a peptide analog of a myosin light chain kinase CaM binding site. The mutations included: 1) a Glu----Ala mutation at two phylogenetically conserved calcium ligands in the second (E67A-CaM) and fourth (E140A-CaM) sites; and 2) a Ser----Phe mutation at residue 101 (S101F-CaM) which affects ion channel regulation. The mutant CaMs bind 4 calciums in the absence of magnesium, but two sites have approximately 60- to 300-fold weaker binding than wild-type CaM (SYNCAM CaM). E67A-CaM and E140A-CaM bound only two calciums and S101F-CaM bound 4 calciums in the presence of magnesium. E67A-CaM and E140A-CaM recovered the ability to bind 4 calcium ions in the presence of the RS20 CaM binding peptide. These results are consistent with models in which the calcium binding activity of CaM within a supramolecular complex is different from purified CaM and raise the possibility that the selective functional effects of in vivo mutations in the calcium binding sites of CaM might be partially due to the ability of some CaM binding proteins to select and utilize CaM conformations with calcium ligation structures different from the so-called canonical EF-hand.     

The solution structure of apocalmodulin from Saccharomyces cerevisiae implies a mechanism for its unique Ca2+ binding property

We have determined the solution structure of calmodulin (CaM) from yeast (Saccharomyces cerevisiae) (yCaM) in the apo state by using NMR spectroscopy. yCaM is 60% identical in its amino acid sequence with other CaMs, and exhibits its unique biological features. yCaM consists of two similar globular domains (N- and C-domain) containing three Ca(2+)-binding motifs, EF-hands, in accordance with the observed 3 mol of Ca(2+) binding. In the solution structure of yCaM, the conformation of the N-domain conforms well to the one of the expressed N-terminal half-domains of yCaM [Ishida, H., et al. (2000) Biochemistry 39, 13660-13668]. The conformation of the C-domain basically consists of a pair of helix-loop-helix motifs, though a segment corresponding to the forth Ca(2+)-binding site of CaM deviates in its primary structure from a typical EF-hand motif and loses the ability to bind Ca(2+). Thus, the resulting conformation of each domain is essentially identical to the corresponding domain of CaM in the apo state. A flexible linker connects the two domains as observed for CaM. Any evidence for the previously reported interdomain interaction in yCaM was not observed in the solution structure of the apo state. Hence, the interdomain interaction possibly occurs in the course of Ca(2+) binding and generates a cooperative Ca(2+) binding among all three sites. Preliminary studies on a mutant protein of yCaM, E104Q, revealed that the Ca(2+)-bound N-domain interacts with the apo C-domain and induces a large conformational change in the C-domain.     

The solution structures of two soybean calmodulin isoforms provide a structural basis for their selective target activation properties

The intracellular calcium ion is one of the most important secondary messengers in eukaryotic cells. Ca(2+) signals are translated into physiological responses by EF-hand calcium-binding proteins such as calmodulin (CaM). Multiple CaM isoforms occur in plant cells, whereas only a single CaM protein is found in animals. Soybean CaM isoform 1 (sCaM1) shares 90% amino acid sequence identity with animal CaM (aCaM), whereas sCaM4 is only 78% identical. These two sCaM isoforms have distinct target-enzyme activation properties and physiological functions. sCaM4 is highly expressed during the self-defense reaction of the plant and activates the enzyme nitric-oxide synthase (NOS), whereas sCaM1 is incapable of activating NOS. The mechanism of selective target activation by plant CaM isoforms is poorly understood. We have determined high resolution NMR solution structures of Ca(2+)-sCaM1 and -sCaM4. These were compared with previously determined Ca(2+)-aCaM structures. For the N-lobe of the protein, the solution structures of Ca(2+)-sCaM1, -sCaM4, and -aCaM all closely resemble each other. However, despite the high sequence identity with aCaM, the C-lobe of Ca(2+)-sCaM1 has a more open conformation and consequently a larger hydrophobic target-protein binding pocket than Ca(2+)-aCaM or -sCaM4, the presence of which was further confirmed through biophysical measurements. The single Val-144 --> Met substitution in the C-lobe of Ca(2+)-sCaM1, which restores its ability to activate NOS, alters the structure of the C-lobe to a more closed conformation resembling Ca(2+)-aCaM and -sCaM4. The relationships between the structural differences in the two Ca(2+)-sCaM isoforms and their selective target activation properties are discussed.     

Dictyostelium calmodulin: affinity isolation and characterization

The Ca2+-binding regulatory protein calmodulin (CaM) has been purified from the cellular slime mold, Dictyostelium discoideum. Isolation of homogeneous Dictyostelium CaM was accomplished in high yield by ion-exchange chromatography and Ca2+-dependent affinity chromatography on phenothiazine-Sepharose 4B. This isolate has been demonstrated to possess the following physicochemical and functional properties characteristic of other CaM isolates: (i) a molecular weight ca. 16,000; (ii) an amino acid composition similar to other CaMs--with the notable exception that Dictyostelium CaM, as first determined by Bazari and Clarke [(1981) J. Biol. Chem. 256, 3598-3603] lacks the single trimethylated lysine (Tml) residue identified in nearly all CaMs purified to date; (iii) a CNBr peptide map similar to that of other CaMs; (iv) a Ca2+-dependent shift in migration during native- and sodium dodecyl sulfate-polyacrylamide gel electrophoretic analyses; (v) ability to form Ca2+-dependent complexes with rabbit skeletal muscle troponin I; and (vi) ability to activate in a Ca2+-dependent manner bovine brain cyclic nucleotide phosphodiesterase.     

Calcium-dependent and -independent binding of soybean calmodulin isoforms to the calmodulin binding domain of tobacco MAPK phosphatase-1

The recent finding of an interaction between calmodulin (CaM) and the tobacco mitogen-activated protein kinase phosphatase-1 (NtMKP1) establishes an important connection between Ca(2+) signaling and the MAPK cascade, two of the most important signaling pathways in plant cells. Here we have used different biophysical techniques, including fluorescence and NMR spectroscopy as well as microcalorimetry, to characterize the binding of soybean CaM isoforms, SCaM-1 and -4, to synthetic peptides derived from the CaM binding domain of NtMKP1. We find that the actual CaM binding region is shorter than what had previously been suggested. Moreover, the peptide binds to the SCaM C-terminal domain even in the absence of free Ca(2+) with the single Trp residue of the NtMKP1 peptides buried in a solvent-inaccessible hydrophobic region. In the presence of Ca(2+), the peptides bind first to the C-terminal lobe of the SCaMs with a nanomolar affinity, and at higher peptide concentrations, a second peptide binds to the N-terminal domain with lower affinity. Thermodynamic analysis demonstrates that the formation of the peptide-bound complex with the Ca(2+)-loaded SCaMs is driven by favorable binding enthalpy due to a combination of hydrophobic and electrostatic interactions. Experiments with CaM proteolytic fragments showed that the two domains bind the peptide in an independent manner. To our knowledge, this is the first report providing direct evidence for sequential binding of two identical peptides of a target protein to CaM. Discussion of the potential biological role of this interaction motif is also provided.     

Calcium-binding sites of calmodulin and electron transfer by inducible nitric oxide synthase

Like that of the neuronal nitric oxide synthase (nNOS), the binding of Ca(2+)-bound calmodulin (CaM) also regulates the activity of the inducible isoform (iNOS). However, the role of each of the four Ca(2+)-binding sites of CaM in the activity of iNOS is unclear. Using a series of single-point mutants of Drosophila melanogaster CaM, the effect that mutating each of the Ca(2+)-binding sites plays in the transfer of electrons within iNOS has been examined. The same Glu (E) to Gln (Q) mutant series of CaM used previously [Stevens-Truss, R., Beckingham, K., and Marletta, M. A. (1997) Biochemistry 36, 12337-12345] to study the role of the Ca(2+)-binding sites in the activity of nNOS was used for these studies. We demonstrate here that activity of iNOS is dependent on Ca(2+) being bound to sites II (B2Q) and III (B3Q) of CaM. Nitric oxide ((*)NO) producing activity (as measured using the hemoglobin assay) of iNOS bound to the B2Q and B3Q CaMs was found to be 41 and 43% of the wild-type activity, respectively. The site I (B1Q) and site IV (B4Q) CaM mutants only minimally affected (*)NO production (95 and 90% of wild-type activity, respectively). These results suggest that NOS isoforms, although all possessing a prototypical CaM binding sequence and requiring CaM for activity, interact with CaM differently. Moreover, iNOS activation by CaM, like nNOS, is not dependent on Ca(2+) being bound to all four Ca(2+)-binding sites, but has specific and distinct requirements. This novel information, in addition to helping us understand NOS, should aid in our understanding of CaM target activation.     

Prediction of volatile anesthetic binding sites in proteins

Computational methods designed to predict and visualize ligand protein binding interactions were used to characterize volatile anesthetic (VA) binding sites and unoccupied pockets within the known structures of VAs bound to serum albumin, luciferase, and apoferritin. We found that both the number of protein atoms and methyl hydrogen, which are within approximately 8 A of a potential ligand binding site, are significantly greater in protein pockets where VAs bind. This computational approach was applied to structures of calmodulin (CaM), which have not been determined in complex with a VA. It predicted that VAs bind to [Ca(2+)](4)-CaM, but not to apo-CaM, which we confirmed with isothermal titration calorimetry. The VA binding sites predicted for the structures of [Ca(2+)](4)-CaM are located in hydrophobic pockets that form when the Ca(2+) binding sites in CaM are saturated. The binding of VAs to these hydrophobic pockets is supported by evidence that halothane predominantly makes contact with aliphatic resonances in [Ca(2+)](4)-CaM (nuclear Overhauser effect) and increases the Ca(2+) affinity of CaM (fluorescence spectroscopy). Our computational analysis and experiments indicate that binding of VA to proteins is consistent with the hydrophobic effect and the Meyer-Overton rule.     

Unique features in the C-terminal domain provide caltractin with target specificity

Caltractin (centrin) is a member of the calmodulin (CaM) superfamily of EF-hand calcium-binding proteins. It is an essential component of the centrosomal structures in a wide range of organisms. Caltractin and calmodulin apparently function in distinct calcium signaling pathways despite substantial sequence similarity. In an effort to understand the structural basis for such differences, the high-resolution three-dimensional solution structure of the complex between the Ca(2+)-activated C-terminal domain of Chlamydomonas reinhardtii caltractin (CRC-C) and a 19 residue peptide fragment comprising the putative cdc31p-binding region of Kar1p (K(19)) has been determined by multi-dimensional heteronuclear NMR spectroscopy. Formation of the complex is calcium-dependent and is stabilized by extensive interactions between CRC-C and three key hydrophobic anchors (Trp10, Leu13 and Leu14) in the peptide as well as favorable electrostatic interactions at the protein-peptide interface. In-depth comparisons have been made to the structure of the complex of Ca(2+)-activated calmodulin and R(20), the CaM-binding domain of smooth muscle myosin light-chain kinase. Although the overall structures of CRC and CaM domains in their respective complexes are very similar, differences in critical regions in the sequences of these proteins and their targets lead to clear differences in the complementarity of their respective binding surfaces. These subtle differences reveal the structural basis for the Ca(2+)-dependent regulation of distinct cellular signaling events by CRC and CaM.     

Purification of myristoylated and nonmyristoylated neuronal calcium sensor-1 using single-step hydrophobic interaction chromatography

Neuronal calcium sensors (NCSs) belong to a family of Ca(2+)-binding proteins, which serve important functions in neurotransmission, and are highly conserved from yeast to humans. Overexpression of the neuronal calcium sensor-1, called frequenin in the fruit fly and in frog, increases the release of neurotransmitters. Studying the functional role of frequenin in mammals and understanding its structural dynamics is critically dependent on the availability of active purified protein. Neuronal calcium sensors like other members of the family share common structural features: they contain four EF-hands as potential binding sites for Ca(2+) and an N-terminal consensus sequence for myristoylation. Previously, recoverin, distantly related to NCSs, has been expressed and purified from Escherichia coli, involving a combination of different chromatographic steps. NCS-1 has earlier been purified adopting a two-step procedure used for recoverin purification. We have overexpressed NCS-1 from rat in its myristoylated and nonmyristoylated form in E. coli and purified it from crude lysates using a single-step hydrophobic interaction chromatography. The purified protein was identified by Western blotting and mass spectrometry and assayed for its ability to bind Ca(2+) using a Ca(2+) shift assay, terbium fluorescence, and Stains-all binding. The present protocol provides a rapid, more efficient and simplified, single-step method for purifying NCS-1 for structural and functional studies. This method can also be applied to purify related proteins of the superfamily.     

Binding of La3+ to calmodulin and its effects on the interaction between calmodulin and calmodulin binding peptide, polistes mastoparan

Binding of La(3+) to calmodulin (CaM) and its effects on the complexes of CaM and CaM-binding peptide, polistes mastoparan (Mas), were investigated by nuclear magnetic resonance (NMR) spectroscopy, fluorescence and circular dichroism spectroscopy, and by the fluorescence stopped-flow method. The four binding sites of La(3+) on CaM were identified as the same as the binding sites of Ca(2+) on CaM through NMR titration of La(3+) to uniformly (15)N-labeled CaM. La(3+) showed a slightly higher affinity to the binding sites on the N-terminal domain of CaM than that to the C-terminal. Large differences between the (1)H-(15)N heteronuclear single quantum coherence (HSQC) spectra of Ca(4)CaM and La(4)CaM suggest conformational differences between the two complexes. Fluorescence and CD spectra also exhibited structural differences. In the presence of Ca(2+) and La(3+), a hybrid complex, Ca(2)La(2)CaM, was formed, and the binding of La(3+) to the N-terminal domain of CaM seemed preferable over binding to the C-terminal domain. Through fluorescence titration, it was shown that La(4)CaM and Ca(2)La(2)CaM had similar affinities to Mas as Ca(4)CaM. Fluorescence stopped-flow experiments showed that the dissociation rate of La(3+) from the C-terminal domain of CaM was higher than that from the N-terminal. However, in the presence of Mas, the dissociation rate of La(3+) decreased and the dissociation processes from both global domains were indistinguishable. In addition, compared with the case of Ca(4)CaM-Mas, the slower dissociations of Mas from La(4)CaM-Mas and Ca(2)La(2)CaM-Mas complexes indicate that in the presence of La(3+), the CaM-Mas complex became kinetically inert. A possible role of La(3+) in the Ca(2+)-CaM-dependent pathway is discussed.     

Multiple calcium binding sites make calmodulin multifunctional

Protein-protein or protein-ion interactions with multisite proteins are essential to the regulation of intracellular and extracellular events. There is, however, limited understanding of how ligand-multisite protein interactions selectively regulate the activities of multiple protein targets. In this paper, we focus on the important calcium (Ca(2+)) binding protein calmodulin (CaM), which has four Ca(2+) ion binding sites and regulates the activity of over 30 other proteins. Recent progress in structural studies has led to significant improvements in the understanding of Ca(2+)-CaM-dependent regulation mechanisms. However, no quantitative model is currently available that can fully explain how the structural diversity of protein interaction surfaces leads to selective activation of protein targets. In this paper, we analyze the multisite protein-ligand binding mechanism using mathematical modelling and experimental data for Ca(2+)-CaM-dependent protein targets. Our study suggests a potential mechanism for selective and differential activation of Ca(2+)-CaM targets by the same CaM molecules, which are involved in a variety of intracellular functions. The close agreement between model predictions and experimental dose-response curves for CaM targets available in the literature suggests that such activation is due to the selective activity of CaM conformations in complexes with variable numbers of Ca(2+) ions. Although the paper focuses on the Ca(2+)-CaM pair as a particularly data rich example, the proposed model predictions are quite general and can easily be extended to other multisite proteins. The results of the study may therefore be proposed as a general explanation for multifunctional target regulation by multisite proteins.     

Structural investigation into the differential target enzyme regulation displayed by plant calmodulin isoforms

The conserved calmodulin (CaM) isoform SCaM-1 and the divergent SCaM-4 from soybean bind to many of the same target enzymes, but differentially activate or competitively inhibit them. Class 1 target enzymes are activated by both calcium (Ca(2+))-bound SCaM-1 (Ca(2+)-SCaM-1) and Ca(2+)-bound SCaM-4 (Ca(2+)-SCaM-4), while class 2 enzymes are activated by Ca(2+)-SCaM-1 but competitively inhibited by Ca(2+)-SCaM-4, and class 3 enzymes are activated by Ca(2+)-SCaM-4 but competitively inhibited by Ca(2+)-SCaM-1. To determine whether these differences can be attributed to unique interactions with the CaM-binding domains (CaMBD) of these enzymes, we have studied the binding of each protein to peptides derived from the CaMBD of a representative target enzyme from each of these three classes. Using a combination of NMR spectroscopy and isothermal titration calorimetry, we demonstrate that the N- and C-domains of either Ca(2+)-SCaM bind to each peptide to form structurally compact complexes driven by the burial of hydrophobic surfaces. Interestingly, the interactions with the CaMBD peptides from classes 1 and 2 are similar for the two proteins; however, binding to the peptide from class 3 is structurally and thermodynamically distinct for Ca(2+)-SCaM-1 and -4. We also demonstrate that both calcium-free SCaM-1 (apo-SCaM-1) and calcium-free SCaM-4 (apo-SCaM-4) bind to the CaMBD from cyclic nucleotide phosphodiesterase, and that the interactions are similar to each other and to the interactions with apo-mammalian CaM. Therefore, the apo-SCaMs are also capable of binding to the same target enzymes, which could provide an additional mechanism for CaM-dependent signaling in plants.