Conformation of the calmodulin-binding domain of metabotropic glutamate receptor subtype 7 and its interaction with calmodulin

Calmodulin (CaM), a Ca(2+)-binding protein, is a well-known regulator of various cellular functions. One of the targets of CaM is metabotropic glutamate receptor 7 (mGluR7), which serves as a low-pass filter for glutamate in the pre-synaptic terminal to regulate neurotransmission. Surface plasmon resonance (SPR), circular dichroism (CD) spectroscopy and nuclear magnetic spectroscopy (NMR) were performed to study the structure of the peptides corresponding to the CaM-binding domain of mGluR7 and their interaction with CaM. Unlike well-known CaM-binding peptides, mGluR7 has a random coil structure even in the presence of trifluoroethanol. Moreover, NMR data suggested that the complex between Ca(2+)/CaM and the mGluR7 peptide has multiple conformations. The mGluR7 peptide has been found to interact with CaM even in the absence of Ca(2+), and the binding is directed toward the C-domain of apo-CaM rather than the N-domain. We propose a possible mechanism for the activation of mGluR7 by CaM. A pre-binding occurs between apo-CaM and mGluR7 in the resting state of cells. Then, the Ca(2+)/CaM-mGluR7 complex is formed once Ca(2+) influx occurs. The weak interaction at lower Ca(2+) concentrations is likely to bind CaM to mGluR7 for the fast complex formation in response to the elevation of Ca(2+) concentration.     

Structurally homologous binding of plant calmodulin isoforms to the calmodulin-binding domain of vacuolar calcium-ATPase

The discovery that plants contain multiple calmodulin (CaM) isoforms having variable sequence identity to mammalian CaM has sparked a flurry of new questions regarding the intracellular role of Ca(2+) regulation in plants. To date, the majority of research in this field has focused on the differential enzymatic regulation of various mammalian CaM-dependent enzymes by the different plant CaM isoforms. However, there is comparatively little information on the structural recognition of target enzymes found exclusively in plant cells. Here we have used a variety of spectroscopic techniques, including nuclear magnetic resonance, circular dichroism, and fluorescence spectroscopy, to study the interactions of the most conserved and most divergent CaM isoforms from soybean, SCaM-1, and SCaM-4, respectively, with a synthetic peptide derived from the CaM-binding domain of cauliflower vacuolar calcium-ATPase. Despite their sequence divergence, both SCaM-1 and SCaM-4 interact with the calcium-ATPase peptide in a similar calcium-dependent, stoichiometric manner, adopting an antiparallel binding orientation with an alpha-helical peptide. The single Trp residue is bound in a solvent-inaccessible hydrophobic pocket on the C-terminal domain of either protein. Thermodynamic analysis of these interactions using isothermal titration calorimetry demonstrates that the formation of each calcium-SCaM-calcium-ATPase peptide complex is driven by favorable binding enthalpy and is very similar to the binding of mammalian CaM to the CaM-binding domains of myosin light chain kinases and calmodulin-dependent protein kinase I.     

Energetics of calmodulin domain interactions with the calmodulin binding domain of CaMKII

Calmodulin (CaM) is an essential eukaryotic calcium receptor that regulates many kinases, including CaMKII. Calcium‐depleted CaM does not bind to CaMKII under physiological conditions. However, binding of (Ca²⁺)₄‐CaM to a basic amphipathic helix in CaMKII releases auto‐inhibition of the kinase. The crystal structure of CaM bound to CaMKIIp, a peptide representing the CaM‐binding domain (CaMBD) of CaMKII, shows an antiparallel interface: the C‐domain of CaM primarily contacts the N‐terminal half of the CaMBD. The two domains of calcium‐saturated CaM are believed to play distinct roles in releasing auto‐inhibition. To investigate the underlying mechanism of activation, calcium‐dependent titrations of isolated domains of CaM binding to CaMKIIp were monitored using fluorescence anisotropy. The binding affinity of CaMKIIp for the domains of CaM increased upon saturation with calcium, with the C‐domain having a 35‐fold greater affinity than the N‐domain. Because the interdomain linker of CaM regulates calcium‐binding affinity and contribute to conformational change, the role of each CaM domain was explored further by investigating effects of CaMKIIp on site‐knockout mutants affecting the calcium‐binding sites of a single domain. Investigation of the thermodynamic linkage between saturation of individual calcium‐binding sites and CaM‐domain binding to CaMKIIp showed that calcium binding to Sites III and IV was sufficient to recapitulate the behavior of (Ca²⁺)₄‐CaM. The magnitude of favorable interdomain cooperativity varied depending on which of the four calcium‐binding sites were mutated, emphasizing differential regulatory roles for the domains of CaM, despite the high degree of homology among the four EF‐hands of CaM. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

Characterization of the secondary structure of calmodulin in complex with a calmodulin-binding domain peptide.

The interaction between calcium-saturated chicken calmodulin and a peptide corresponding to the calmodulin-binding domain of the chicken smooth muscle myosin light chain kinase has been studied by multinuclear and multidimensional nuclear magnetic resonance methods. Extensive 1H and 15N resonance assignments of calmodulin in the complex have been obtained from the analysis of two- and three-dimensional nuclear magnetic resonance spectra. The assignment of calmodulin in the complex was facilitated by the use of selective labeling of the protein with alpha-15N-labeled valine, alanine, lysine, leucine, and glycine. These provided reference points during the main-chain-directed analysis of three-dimensional spectra of complexes prepared with uniformly 15N-labeled calmodulin. The pattern of nuclear Overhauser effects (NOE) seen among main-chain amide NH, C alpha H, and C beta H hydrogens indicates that the secondary structure of the globular domains of calmodulin in the complex closely corresponds to that observed in the calcium-saturated state of the protein in the absence of bound peptide. However, the backbone conformation of residues 76-84 adopts an extended chain conformation upon binding of the peptide in contrast to its helical conformation in the absence of peptide. A sufficient number of NOEs between the globular domains of calmodulin and the bound peptide have been found to indicate that the N- and C-terminal regions of the peptide interact with the C- and N-terminal domains of calmodulin, respectively. The significance of these results are discussed in terms of recently proposed models for the structure of calmodulin-peptide complexes.     

Conformational dynamics of calmodulin in complex with the calmodulin-dependent kinase kinase alpha calmodulin-binding domain

As the primary intracellular calcium sensor, calcium-saturated calmodulin (CaM) regulates numerous and diverse proteins. Several mechanisms, including tissue-specific expression, localization, and sequestration, work in concert to limit the total number of available targets of calmodulin within a cell. While the free energies of binding of calmodulin-binding domains of regulated proteins by CaM have been shown to be highly similar, they result from vastly different enthalpic and entropic contributions. Here, we report the backbone and side-chain methyl dynamics of calcium-activated calmodulin in complex with a peptide corresponding to the CaM-binding domain of calmodulin kinase kinase, along with the thermodynamic underpinnings of complex formation. The results show a considerable reduction in side-chain mobility throughout CaM upon binding the CaMKKalpha peptide, which is consistent with the enthalpically driven nature of the binding. Site-specific comparison to another kinase-derived peptide complex with similar thermodynamic values reveals significant differences in dynamics largely localized to the hydrophobic binding sites.     

Affinity-purified melittin antibody recognizes the calmodulin-binding domain on calmodulin target proteins

Melittin is a 26-amino acid amphipathic peptide which binds to calmodulin in a calcium-dependent manner. The utility of melittin as a peptide replica of the calmodulin-binding region of calmodulin acceptor proteins (CaMBPs) was investigated. Antibody against melittin was raised and purified by antigen affinity chromatography. Interaction of the antibody with CaMBPs was initially suggested by the ability of anti-melittin-Sepharose, but not nonimmune IgG-Sepharose, to bind calmodulin-dependent cyclic AMP phosphodiesterase. Direct interaction of melittin antibody with the calmodulin-binding domain of acceptor proteins was demonstrated by quantitative inhibition of calmodulin binding to the purified CaMBPs, myosin light chain kinase, and eel electric organ CaMBP55. These results indicate that melittin antibody identifies regions of structural similarity between calmodulin acceptor proteins, and this region includes a common calmodulin-binding domain.     

Structural basis for simultaneous binding of two carboxy-terminal peptides of plant glutamate decarboxylase to calmodulin

Activation of glutamate decarboxylase (GAD) by calcium-bound calmodulin (CaM) is required for normal plant growth through regulation of gamma-aminobutyrate and glutamate metabolism. The interaction of CaM with the C-terminal domain of GAD is believed to induce dimerization of the enzyme, an event implicated for Ca(2+)-dependent enzyme activation. Here, we present the solution structure of CaM in complex with a dimer of peptides derived from the C-terminus of Petunia hybrida GAD. The 23 kDa ternary complex is pseudo-symmetrical with each domain of CaM bound to one of the two antiparallel GAD peptides, which form an X-shape with an interhelical angle of 60 degrees. To accommodate the dimeric helical GAD target, the two domains of CaM adopt an orientation markedly different from that seen in other CaM-target complexes. Although the dimeric GAD domain is much larger than previously studied CaM-binding peptides, the two CaM domains appear closer together and make a number of interdomain contacts not observed in earlier complexes. The present structure of a single CaM molecule interacting with two target peptides provides new evidence for the conformational flexibility of CaM as well as a structural basis for the ability of CaM to activate two enzyme molecules simultaneously.     

A role for glutamate decarboxylase during tomato ripening: the characterisation of a cDNA encoding a putative glutamate decarboxylase with a calmodulin-binding site

A tomato fruit cDNA library was differentially screened to identify mRNAs present at higher levels in fruit of the tomato ripening mutant rin (ripening inhibitor). Complete sequencing of a unique clone ERT D1 revealed an open reading frame with homology to several glutamate decarboxylases. The deduced polypeptide sequence has 80% overall amino acid sequence similarity to a Petunia hybrida glutamate decarboxylase (petGAD) which carries a calmodulin-binding site at its carboxyl terminus and ERT D1 appears to have a similar domain. ERT D1 mRNA levels peaked at the first visible sign of fruit colour change during normal tomato ripening and then declined, whereas in fruit of the ripening impaired mutant, rin, accumulation of this mRNA continued until at least 14 days after the onset of ripening. This mRNA was present at much lower levels in other tissues, such as leaves, roots and stem, and was not increased by wounding. Possible roles for GAD, and its product -aminobutyric acid (GABA) in fruit, are discussed.     

Recombinant preparation and characterization of interactions for a calmodulin-binding chromogranin A peptide and calmodulin.

Chromogranin-derived peptides have important and varied biological activities. They affect a wide spectrum of targets such as fungal membranes, blood vessels, myocardial cells, and pancreatic cells. Despite the biological significance and the diverse activities, the molecular mechanisms of the interactions between the peptides and the target proteins have not been well understood. Here, we studied the interaction between a chromogranin A-derived peptide (CGA40-65) and its target protein, calmodulin, with NMR spectroscopy. Calmodulin was easily prepared with standard recombinant technology, but CGA40-65 posed challenges requiring multistep procedures. The recombinantly produced peptide retained the calmodulin-binding property of the full-length CGA, as shown by the HSQC binding experiment. By applying resonance assignments, we identified the residues in calmodulin involved in the CGA40-65 binding. We also found that the peak changes are close to those exhibited by the peptides having the wrap-around binding mechanism. Further analysis revealed that the CGA40-65-induced changes are more similar to those by CaMKIp peptide than those by smMLCKp peptide among the wrap-around binding peptides, suggesting that CGA40-65 can be categorized as a CaMKIp-like peptide. Our report is the first residue-resolution mechanistic study involving chromogranin peptides and their target proteins. Our approaches should be applicable to interaction studies involving other chromogranin-derived peptides and their cellular target proteins.     

Cofactor interactions and the regulation of glutamate decarboxylase activity

More than 50% of glutamate decarboxylase (GAD) in brain is present as apoenzyme. Recent work has opened the possibility that apoGAD can be studied in brain by labeling with radioactive cofactor. Such studies would be aided by a compound that inhibits specific binding. One possibility is 4-deoxy-pyridoxine 5-phosphate, a close structural analog of the cofactor pyridoxal 5-phosphate. The effects of deoxypyridoxine-P on the cyclic series of reactions that interconverts apo- and holoGAD was investigated and found to be consistent with simple competitive inhibition of the activation of apoGAD by pyridoxal-P. As expected from the cycle GAD was inactivated when incubated with glutamate and deoxypyridoxine-P even though cofactor was present, but no inactivation was observed with deoxypyridoxine-P in the absence of glutamate. Deoxypyridoxine-P also stabilized apoGAD against heat denaturation. These effects were quantitatively accounted for by a kinetic model of the apo-holoGAD cycle. Deoxypyridoxine-P inhibited the labeling by [³²P]pyridoxal-P of GAD isolated from rat brain. Hippocampal extracts were labeled with [³²P]pyridoxal-P and analyzed by SDS-polyacrylamide gel electrophoresis. Remarkably few bands were strongly labeled. The major labeled band (at 63 kDa) corresponded to one of the forms of GAD. Other strongly-labeled bands were observed at 65 kDa (corresponding to the higher molecular weight form of GAD) and at 69–72 kDa. Labeling of the 63- and 65-kDa bands was inhibited by deoxypyridoxine-P, but the 69–72 kDa bands were unaffected, suggesting that the latter were non-specifically labeled. The results suggest that the 63-kDa form of GAD makes up the majority of apoGAD in hippocampus.Special issue dedicated to Dr. Eugene Roberts.     

Methionine oxidation in the calmodulin-binding domain of calcineurin disrupts calmodulin binding and calcineurin activation

Calcineurin is a Ca (2+)/calmodulin-activated Ser/Thr phosphatase important in cellular actions resulting in memory formation, cardiac hypertrophy, and T-cell activation. This enzyme is subject to oxidative inactivation by superoxide at low micromolar concentrations and by H 2O 2 at low millimolar concentrations. On the basis of the hypothesis that oxidation of Met residues in calmodulin-binding domains inhibits binding to calmodulin, purified calcineurin was used to study the susceptibility of Met residues to oxidation by H 2O 2. The rate for oxidation of Met 406 in the calmodulin-binding domain was determined to be 4.4 x 10 (-3) M (-1) s (-1), indicating a high susceptibility to oxidation. Functional repercussions of Met 406 oxidation were evaluated using native enzyme and a calcineurin mutant in which Met 406 was exchanged for Leu. Measurement of fluorescent calmodulin binding demonstrated that oxidation of Met 406 results in a 3.3-fold decrease in the affinity of calmodulin for calcineurin. Calcineurin activation exhibited a loss in cooperativity with respect to calmodulin following Met 406 oxidation as shown by a reduction in the Hill slope from 1.88 to 0.86. Maximum phosphatase activity was unaffected by Met oxidation. Changes in the calcineurin-calmodulin interaction were accompanied by a 40% loss in the ability of calmodulin to stimulate binding of immunophilin/immunosuppressant to calcineurin. All effects on calmodulin binding to the native enzyme by the treatment with H 2O 2 could be reversed by treating the enzyme with methionine sulfoxide reductase. These results indicate that the calmodulin-binding domain of calcineurin is susceptible to oxidation at Met 406 and that oxidation disrupts calmodulin binding and enzyme activation. Oxidation-dependent decreases in the affinity of calmodulin for calcineurin can potentially modulate calmodulin-dependent signaling and calmodulin distribution.     

Molecular analysis of the glutamate decarboxylase locus in Streptococcus thermophilus ST110

γ-aminobutyric acid (GABA) is generated from glutamate by the action of glutamic acid decarboxylase (GAD) and characterized by hypotensive, diuretic, and tranquilizing effects in humans and animals. The production of GABA by lactic acid starter bacteria would enhance the functionality of fermented dairy foods including cheeses and yogurt. The survey of 42 strains of the yogurt starter culture Streptococcus thermophilus by PCR techniques indicated the presence of a glutamate decarboxylase gene (gadB) in 16 strains. DNA sequencing data indicated that the GAD/GABA antiporter locus (gadB/gadC) in GAD(+) S. thermophilus strains is flanked by transposase elements (5' and 3') and positioned between the luxS (5') and the HD-superfamily hydrolase genes (3'). The PCR amplification product of a ca. 2-kb genomic fragment that included the gadB and its putative promoter region was inserted into a shuttle vector, which was used to transform Escherichia coli DH5α. Subsequently, the recombinant plasmid pMEU5a-1/gadB (7.24 kb) was electrotransformed into the GAD-negative strain S. thermophilus ST128. The ST128 transformants carrying the plasmid-encoded gadB produced functional GAD enzyme as evidenced by the conversion of glutamate to GABA at a rate similar to strains with the gadB/gadC operon located on the chromosome. The results demonstrated the potential to impart to non-GABA-producing strains of S. thermophilus and other lactic acid bacteria the GAD(+) phenotype that improves their appeal in possible applications in the development of health-promoting functional foods.     

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

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

Fluorescence probe study of Ca2+-dependent interactions of calmodulin with calmodulin-binding peptides of the ryanodine receptor

We have used a highly environment-sensitive fluorescent probe 6-bromoacetyl-2-dimethylaminonaphthalene (badan) to study the interaction between calmodulin (CaM) and a CaM-binding peptide of the ryanodine receptor (CaMBP) and its sub-fragments F1 and F4. Badan was attached to the Thr34Cys mutant of CaM (CaM-badan). Ca(2+) increase in a physiological range of Ca(2+) (0.1-2 microM) produced about 40 times increase in the badan fluorescence. Upon binding to CaMBP, the badan fluorescence of apo-CaM showed a small increase at a slow rate; whereas that of Ca-CaM showed a large decrease at a very fast rate. Upon binding of CaM to the badan-labeled CaMBP, the badan fluorescence showed a small and slow increase at low Ca(2+), and a large and fast increase at high Ca(2+). Thus, the badan probe attached to CaM Cys(34) can be used to monitor conformational changes occurring not only in CaM, but also those in the CaM-CaMBP interface. Based on our results we propose that both the interaction interface and the global conformation of the CaM-CaMBP complex are altered by calcium.     

The lipid-binding peptide from the plasma membrane Ca2+ pump binds calmodulin, and the primary calmodulin-binding domain interacts with lipid.

Peptide G25 (KKAVKVPKKEKSVLQGKLTRLAVQI) representing the putative lipid-binding region (G region) of the erythrocyte Ca2+ pump was synthesized. This peptide interacted with acidic lipids, as shown by the increase in size of phosphatidylserine liposomes in its presence. This lipid interaction is consistent with the previous evidence suggesting that the portion of the pump from which this peptide was taken is responsible for the activation of the pump by acidic lipid. G25 also bound to calmodulin, as was shown by its cause of a shift in the fluorescence of 5-dimethylamino naphthalene-1-sulfonyl- (dansyl)-calmodulin, and by its competition with Ca2+ pump for calmodulin. Its Kd for dansyl-calmodulin was much higher (0.8 microM) than that of the peptides representing the primary calmodulin-binding region (C region) of the Ca2+ pump. Although the presence of the G region provided the possibility of a second calmodulin-binding site, activation of the pump by calmodulin always could be fitted by simple saturation kinetics. The calmodulin-binding peptide from the C region of the pump, C28R2, also interacted with lipid with even greater effectiveness than G25. When the C region of the pump was saturated with calmodulin, acidic lipid activation of the pump followed simple saturation kinetics. However, when calmodulin was omitted, a higher concentration of lipid was needed for saturation and the kinetics became complex. The data are consistent with the idea that calmodulin activates the pump only by interaction at the C region, but that acidic lipid activates by interaction at both of the C and G regions.     

C-terminal residues of plant glutamate decarboxylase are required for oligomerization of a high-molecular weight complex and for activation by calcium/calmodulin

Bacterial glutamate decarboxylase (GAD) is a homohexameric enzyme of about 330 kDa. Plant GAD differs from the bacterial enzyme in having a C-terminal extension of 33 amino acids within which resides a calmodulin (CaM)-binding domain. In order to assess the role of the C-terminal extension in the formation of GAD complexes and in activation by Ca2+/CaM, we examined complexes formed with the purified full-length recombinant petunia GAD expressed in E. coli, and with a 9 amino acid C-terminal deletion mutant (GADDeltaC9). Size exclusion chromatography revealed that the full-length GAD formed complexes of about 580 kDa and 300 kDa in the absence of Ca2+/CaM, whereas in the presence of Ca2+/CaM all complexes shifted to approximately 680 kDa. With deletion of 9 amino acids from the C-terminus (KKKKTNRVC(500)), the ability to bind CaM in the presence of Ca2+, and to purify it by CaM-affinity chromatography was retained, but the formation of GAD complexes larger than 340 kDa and enzyme activation by Ca2+/CaM were completely abolished. Hence, responsiveness to Ca2+/CaM is associated with the formation of protein complexes of 680 kDa, and requires some or all of the nine C-terminal amino acid residues. We suggest that evolution of plant GAD from a bacterial ancestral enzyme involved the formation of higher molecular weight complexes required for activation by Ca2+/CaM.     

Cloning of plant cDNAs encoding calmodulin-binding proteins using35S-labeled recombinant calmodulin as a probe

Radiolabelled calmodulin has previously been used to screen cDNA expression libraries to isolate calmodulin-binding proteins. We have modified this technique for the isolation of plant calmodulin-binding proteins. [³⁵S]-methionine was used instead of the inorganic [³⁵S]-sulfate, or¹²⁵I used in previous methods. In addition, theE. coli pET expression system was chosen to obtain high levels of recombinant calmodulin at the time of labelling. The procedure thus takes into account both the specific activity of the probe and the amount of protein necessary for screening a large number of filters. Here we describe in detail a procedure for the production and purification of [³⁵S]-recombinant calmodulin and the use of the radiolabelled protein as a probe to screen plant cDNA expression libraries. The [³⁵S]-labeled calmodulin probe easily detects the λICM-1 phage encoding a partial mouse calmodulin-dependent protein kinase II that was previously isolated using a [¹²⁵I]-calmodulin probe (Sikela and Hahn, 1987). Subsequently, a tobacco root cDNA expression library was screened and a positive clone encoding a calcium-dependent calmodulin-binding protein was isolated.     

Distinctive interactions in the holoenzyme formation for two isoforms of glutamate decarboxylase

The interactions between glutamate decarboxylase (GAD) and its cofactor pyridoxal phosphate (PLP) play a key role in the regulation of GAD activity. The enzyme has two isoforms, GAD65 and GAD67. A comparison of binding constants, rate constants, and kinetic profiles for the formation of holoenzyme (holoGAD65 and holoGAD67) revealed that the two isoforms interact distinctively with the cofactor. GAD67 exhibits a higher binding constant for PLP binding, making it more difficult to dissociate PLP from holoGAD67 than holoGAD65. Meanwhile, PLP binding occurs at a much slower rate for GAD67 than GAD65, as evidenced by lower rate constants and a slower initial rate of the holoenzyme formation. Job's plots revealed a stoichiometry of 1:1 for PLP binding to GAD65 before and after the saturation level of PLP, while 1:2 for PLP binding to GAD67 prior to the saturation of PLP and 1:1 at the saturation level of PLP. These results suggested that the two binding sites of GAD65 exhibit similar affinities for PLP. In contrast, one binding site of GAD67 exhibits a significantly higher affinity for PLP than the other binding site. Based on these findings, it was proposed that a slower PLP binding to GAD67 than GAD65 and a less ease to dissociate PLP from holoGAD67 than holoGAD65 are important underlying factors. This attributes to GAD67 being more highly saturated by PLP and GAD65 being less saturated by PLP. A larger conformation change constant for GAD67 than GAD65 supported a significant conformational change induced by the initial PLP binding to GAD67, which affects the other binding site affinity of GAD67. The present studies provided valuable insights into distinctive properties between the two isoforms of GAD.