Identification of the Binding and Inhibition Sites in the Calmodulin Molecule for Ophiobolin A by Site-Directed Mutagenesis

Ophiobolin A, a fungal toxin that affects maize and rice, has previously been shown to inhibit calmodulin by reacting with the lysine (Lys) residues in the calmodulin. In the present study we mutated Lys-75, Lys-77, and Lys-148 in the calmodulin molecule by site-directed mutagenesis, either by deleting them or by changing them to glutamine or arginine. We found that each of these three Lys residues could bind one molecule of ophiobolin A. Normally, only Lys-75 and Lys-148 bind ophiobolin A. Lys-77 seemed to be blocked by the binding of ophiobolin A to Lys-75. Lys-75 is the primary binding site and is responsible for all of the inhibition of ophiobolin A. When Lys-75 was removed, Lys-77 could then react with ophiobolin A to produce inhibition. Lys-148 was shown to be a binding site but not an inhibition site. The Lys-75 mutants were partially resistant to ophiobolin A. When both Lys 75 and Lys-77 or all three Lys residues were mutated, the resulting calmodulins were very resistant to ophiobolin A. Furthermore, Lys residues added in positions 86 and/or 143 (which are highly conserved in plant calmodulins) did not react with ophiobolin A. None of the mutations seemed to affect the properties of calmodulin. These results show that ophiobolin A reacts quite specifically with calmodulin.     

Characterization of the interaction of ophiobolin A and calmodulin

1. The fungal toxin ophiobolin A reacts with the epsilon-amino group of lysine to give a conjugated enamine produce with lambda max at 272 nm and a molar extinction of 19,200 per M/cm. 2. Bovine brain calmodulin reacts with ophiobolin A to give a lambda max at 272 nm. 3. One mol of calmodulin reacts with two moles of ophiobolin A. Reaction of 1 mol of ophiobolin A inactivates 1 mol of calmodulin. 4. Ophiobolin A-treated calmodulin is resistant to tryptic cleavage at lysine 77. 5. Ophiobolin A also inhibits Dictyostelium calmodulin which has glutamine instead of lysine at residue 77.     

自旋标记钙调蛋白与酸枣仁皂甙A相互作用研究

中草药有效成份酸枣仁皂甙A是钙调蛋白CaM的一种天然非竞争性拮抗剂。利用氮氧自由基马来酰亚胺衍生物标记CaM研究了二者的相互作用。结果表明,每分子CaM至少可以结合二个分子的酸枣仁皂钙A,二者的作用影响CaM上Lys残基主要是75,94)的环境,推测酸枣仁皂钙A是通过疏水作用结合到CaM分子两端的疏水沟区。通过比较三氟拉嗪TFP与酸枣仁皂甙A的结构特点,抑制性质与结合位点,提出了CaM调节环核苷酸磷酸二酯酶PDE的模式。     

The effects of calcium site occupancy and reagent length on reactivity of calmodulin lysyl residues with heterobifunctional aryl azides. Mapping interaction domains with specific calmodulin photoprobe derivatives.

The relationship of structural and functional moieties on calmodulin is important in all venues of cell activity. In this study, we investigate the effect of lysine modification on calmodulin function. Azidosalicylate reagents containing different "linker arm" lengths, between the photoactive terminus and an amine-reactive N-hydroxysuccinimidyl ester moiety were used to modify calmodulin lysines at three different positions in a calcium-dependent manner. The short cross-linker, (ASNE-2 (where ASNE represents azidosalicylate N-hydroxysuccinimidyl ester), modifies Lys-75, whereas the longer reagent, ASNE-6, modifies lysines 21, 75, and 94. The modification of these different lysines is shown to be calcium-dependent. At 1-100 microM levels of calcium, only Lys-94 is modified, suggesting that modification of this residue is directed by both the binding of calcium to calcium-binding loops III and IV and the hydrophobic pocket exposed between these two loops as a result of calcium binding. At higher calcium concentrations (> 200 microM), where sites I and II become filled, modification of Lys-21 or Lys-75 also was observed. All the modified calmodulins were able to stimulate 3',5'-cyclic-nucleotide phosphodiesterase fully although the Kact for the Lys-75 and Lys-21 derivatives increased 10- and 50-fold, respectively. None of the modifications affected the activation of erythrocyte plasma membrane Ca(2+)-ATPase. Only the ASNE-6 Lys-75 derivative showed efficient (40%) photocross-linking to the Ca(2+)-ATPase. The ASNE-2 Lys-75 derivative as well as the ASNE-6 Lys-21 and Lys-94 derivatives did not show efficient calcium-dependent photocross-linking to this enzyme.     

Association of calmodulin and smooth muscle myosin light chain kinase: application of a label selection technique with trace acetylated calmodulin

A method is described for rapidly surveying the effects of modifying individual amino acid residues of a protein on its ability to interact specifically with another macromolecule. The procedure has been used to examine the individual roles of the seven lysyl residues of calmodulin in its ability to bind to smooth muscle myosin light chain kinase; previous studies by Jackson et al. (J. Biol. Chem. 261:1226-12232, 1986) have suggested that certain lysines may be located close to the interaction site. Trace [3H]-acetylated calmodulin, consisting predominantly of molecules acetylated at single sites together with unmodified protein, was incubated in excess (five- to 20-fold) with smooth muscle MLC kinase to allow the modified and unmodified molecules to compete for binding to the enzyme. Subsequently, the calmodulin-enzyme complex was separated from unbound calmodulin, and the level of acetylation of each of the seven lysines of the bound fraction of calmodulin was determined and compared to that of each corresponding group of the starting preparation. Significant changes were found at only two of the lysines, 21 and 75, where the extent of acetylation in the bound fraction was three- and fivefold lower, respectively, than that in the original preparation. These results were reproducible in three separate selection experiments employing both chicken and turkey gizzard MLC kinase. It is concluded that acetylation of calmodulin at either lysine 21 or 75 markedly reduces its affinity for MLC kinase, but acetylation at any of the other lysines (13, 30, 77, 94, or 148) has only minor effects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of calmodulin inhibition in the mode of action of ophiobolin a

Calmodulin has been isolated from the root of Zea mays. It activates the bovine brain calmodulin-dependent cyclic nucleotide phosphodiesterase and has electrophoretic mobility very similar to that of bovine brain calmodulin. Ophiobolin A, a fungal toxin, interacts with the maize calmodulin. The interaction is not reversed by dilution or denaturation in SDS and results in the loss of ability of the calmodulin to activate the phosphodiesterase. The inhibition is much faster in the presence than in the absence of Ca²⁺. The electrophoretic mobility of ophiobolin A-treated calmodulin is less than that of untreated calmodulin. Several similarities are found between the inhibition of maize calmodulin by ophiobolin A in vitro and the effects of ophiobolin A on excised roots. Both are irreversible and time-dependent. The concentration of ophiobolin A for half-maximal inhibition of calmodulin in the phosphodiesterase assay is similar to that for phytotoxicity. In both cases ophiobolin A derivatives behave similarly, i.e. 18-bromo-19-methoxyophiobolin A is as potent as ophiobolin A, while 3-anhydro-ophiobolin A and 6-epi-ophiobolin A are less potent. A smaller amount of active calmodulin was measured in the extract from ophiobolin A-treated roots than in those from untreated roots. The present study suggests that calmodulin is a target molecule in the root for the toxicity of ophiobolin A.     

Differential trace labeling of calmodulin: investigation of binding sites and conformational states by individual lysine reactivities. Effects of beta-endorphin, trifluoperazine, and ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid

The Ca2+-dependent association of beta-endorphin and trifluoperazine with porcine testis calmodulin, as well as the effects of removing Ca2+ by ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) treatment, were investigated by the procedure of differential kinetic labeling. This technique permitted determination of the relative rates of acylation of each of the epsilon-amino groups of the seven lysyl residues on calmodulin by [3H]acetic anhydride under the different conditions. In all cases, less than 0.52 mol of lysyl residue/mol of calmodulin was modified, thus ensuring that the labeling pattern reflects the microenvironments of these groups in the native protein. Lysines 75 and 94 were found to be the most reactive amino groups in Ca2+-saturated calmodulin. In the presence of Ca2+ and under conditions where beta-endorphin and calmodulin were present at a molar ratio of 2.5:1, the amino groups of lysines 75 and 148 were significantly reduced in reactivity compared to calmodulin alone. At equimolar concentrations of peptide and protein, essentially the same result was obtained except that the magnitudes of the perturbation of these two lysines were less pronounced. With trifluoperazine, at a molar ratio to calmodulin of 2.5:1, significant perturbations of lysines 75 and 148, as well as Lys 77, were also found. These results further substantiate previous observations of a commonality between phenothiazine and peptide binding sites on calmodulin. Lastly, an intriguing difference in Ca2+-mediated reactivities between lysines 75 and 77 of calmodulin is demonstrated. In the Ca2+-saturated form of the protein, both lysines are part of the long connecting helix between the two homologous halves of the protein (Babu, Y. S., Sack, J. S., Greenhough, T. G., Bugg, C. E., Means, A. R., and Cook, W. J. (1985) Nature 315, 37-40). Yet, Lys 75 increases in reactivity some 25-fold, compared to only a 2-fold change for Lys 77, in going from EGTA-treated to Ca2+-saturated calmodulin. Thus, the microenvironment of Lys 75 is markedly altered upon Ca2+ binding, and this linker region between the two globular lobes of the protein appears to be quite important in the interaction of calmodulin with inhibitory molecules and perhaps activatable enzymes.     

Effects of the binding of myosin light chain kinase on the reactivities of calmodulin lysines

The effects of the binding of smooth muscle myosin light chain (MLC) kinase on the microenvironments of different regions of calmodulin (CaM) were investigated by comparing the acylation rate constants of the seven lysine amino groups of free CaM with those of CaM complexed with MLC kinase. Equimolar amounts of CaM and CaM-MLC kinase complex were trace labeled with [3H]acetic anhydride in the presence of phenylalanine as a standard nucleophile. After completion of the reaction, equal amounts of a trace 14C-acetylated CaM sample, together with [14C]acetylphenylalanine, were added to each reaction mixture. The 3H/14C-labeled CaM and acetylphenylalanine were then isolated from each solution. After complete reaction with nonradioactive acetylating reagent, 3H/14C ratios (r) were determined for each epsilon-N-acetyllysine in the two CaM samples. These values were obtained either from isolated peptide fragments containing one lysine or from epsilon-N-acetyl phenylthiohydantoin lysine obtained by Edman degradation of peptide fragments containing two lysines. From the ratios, protection factors (= rfree/rcomplex) were determined as a measure of the perturbation produced by MLC kinase binding. These protection factors were corrected, using the isotope ratios of the internal standard, for differences in the degree of competition for labeling reagent between the two mixtures. In two separate labeling experiments employing different levels of trace labeling, very little change was observed in the reactivities of four lysines on MLC kinase binding (lysines 13, 30, 77, and 94). Small but reproducible decreases (about 2-fold) were observed in the reactivities of lysines 21 and 148, while lysine 75 underwent a major (more then 7-fold) decrease in labeling. In conjunction with previously published data, these results are interpreted as suggesting that the major perturbation in lysine 75 is a direct effect of MLC kinase contact with CaM and that a region in the central helix containing this residue, but not lysine 77, represents or is near the CaM-binding site for MLC kinase. The smaller changes in reactivities at lysines 21 and 148 may reflect a conformational change that occurs in CaM as a result of binding to MLC kinase.     

Differential reactivities of lysines in calmodulin complexed to phosphatase

Calmodulin and calmodulin complexed with calcineurin phosphatase were trace labeled with [3H]acetic anhydride and the incorporation of [3H]acetate into each epsilon-amino lysine of calmodulin was measured. The relative reactivities of calmodulin lysines were higher in the presence of Ca2+ than in the presence of EGTA, and the order was: Lys-75 greater than Lys-94 greater than Lys-148 greater than or equal to Lys-77 greater than Lys-13 greater than or equal to Lys-21 greater than Lys-30. The changes in relative reactivity implied a change in conformation. When calmodulin was complexed with the phosphatase, Lys-21, Lys-77, and Lys-148 were most protected, implying that these residues are at or near the interaction sites or are conformationally perturbed by the interaction. Lys-30 and Lys-75 were slightly protected, lysine 13 showed no change, while lysine 94 significantly increased in reactivity. Comparison with results obtained from myosin light chain kinase using a similar technique (Jackson, A. E., Carraway, K. L., III, Puett, D., and Brew, K. (1986) J. Biol. Chem. 261, 12226-12232) reveals that calmodulin may interact with each of the two enzymes similarly at or near Lys-21, Lys-75, and Lys-148; one difference with phosphatase is that complex formation also involved Lys-77. These findings suggest that calmodulin interacts differently with its target enzymes.     

Human erythrocyte calmodulin. Further chemical characterization and the site of its interaction with the membrane.

Human erythrocyte and bovine brain calmodulins were indistinguishable by tryptic peptide mapping, indicating that the primary sequence of the two proteins is either very similar or identical. Calcium binding determinations of human erythrocyte calmodulin, by equilibrium dialysis and fluorescence titration, were in close agreement with previous studies on other calmodulins. The calcium-activated adenosine triphosphatase which is stimulated by calmodulin was shown to be firmly associated with smooth erythrocyte plasma membranes devoid of spectrin and actin. Kinetic titration demonstrated that there are 4500 calmodulin binding sites per erythrocyte and that the turnover number of this calcium-activated adenosine triphosphatase is 3000 mumol of Pi . (mumol of site)-1 . min-1 which is similar to the turnover numbers of other transport adenosine triphosphatases. Furthermore, calmodulin stimulates calcium-activated adenosine triphosphatase by a simple enzyme-ligand association.     

Calcium effects on calmodulin lysine reactivities

The differential reactivities of individual lysines on porcine testicular calmodulin were determined by trace labeling with high specific activity [3H]acetic anhydride as a function of the molar ratio of Ca2+ to calmodulin. In progressing from the Ca2+-depleted form of the protein to a Ca2+:calmodulin molar ratio of 5:1, six of the seven lysyl residues exhibited a modest 1.5- to 3.0-fold increase in reactivity. Lys 75, in contrast, was enhanced in reactivity greater than 20-fold. When the change in reactivity of each lysine was normalized as a percentage of the maximum change, most of the residues were found to fall into two distinct classes. One class, comprising lysines 94 and 148 from the two carboxy terminal Ca2+-binding domains 3 and 4, respectively, exhibited about 90% of their reactivity change when the Ca2+:calmodulin molar ratio was 2:1, and these residues were perturbed very little upon further addition of Ca2+. The other class, encompassing lysines 13, 21, and 30 from the amino terminal domain 1 and Lys 75 from the extended helix connecting the two globular lobes of calmodulin, underwent most of their overall reactivity change (55-70%) between 2 and 5 equivalents of Ca2+ per mol of calmodulin. Lys 77 was distinct in its pattern of change, undergoing approximately equal changes with each Ca2+ increment. These results are consistent with a model where Ca2+ first binds to the two carboxy terminal sites of calmodulin with no apparent preference, concomitant with minor alterations in the microenvironments of lysines in the unoccupied amino terminal domains. The third and fourth Ca2+ ions then bind to these latter two domains, again with no evidence of preference, with little change in the lysine reactivities at the carboxy terminus of the molecule. The environments of groups in the central helix appear to undergo changes in a manner that reflects their proximity to the amino and carboxy terminal domains. In the course of this work, it was found that Lys 94 in apocalmodulin is specifically perturbed by the addition of EGTA, suggesting that the chelating agent may interact with calmodulin at or near the third Ca2+-binding domain.     

Trimethyllysine and protein function. Effect of methylation and mutagenesis of lysine 115 of calmodulin on NAD kinase activation

Unmethylated calmodulins have been enzymatically methylated at lysine 115, and a direct effect of this methylation on NAD kinase activation has been shown. Similar to naturally occurring calmodulins with trimethyllysine 115, the enzymatically methylated calmodulins activated an NAD kinase preparation to a maximal level that was at least 3-fold lower than the level of activation obtained with the corresponding unmethylated calmodulins. Methylation did not alter the cyclic nucleotide phosphodiesterase activator properties of these calmodulins. A genetically engineered calmodulin containing an arginine at position 115 instead of a lysine was produced by site-specific mutagenesis of a cloned synthetic calmodulin gene. The arginine derivative retained the higher maximal NAD kinase activator properties of the unmethylated calmodulins but was no longer susceptible to the effects of the methyltransferase. The data indicate that the reduction in the level of NAD kinase activation is the direct result of trimethylation of lysine 115 of calmodulin, provide a precedent for a functional effect of trimethyllysine in a protein, and raise the possibility that some of calmodulin's physiological activities may be affected by lysine methylation.     

Affinity selection of chemically modified proteins: role of lysyl residues in the binding of calmodulin to calcineurin

In affinity selection, calcineurin selects from a population of randomly modified calmodulins those species with which it prefers to interact. The method shows that acetylation of lysines affects calmodulin so as to interfere with its ability to interact with calcineurin. Monoacetylation of any lysine of calmodulin reduces its affinity for calcineurin by 5-10-fold. Multiple acetylations amplify the loss of affinity; none of the modifications are imcompatible with activity. The lack of selectivity of calcineurin against any particular modified lysine indicates that the loss of affinity reflects changes induced by the removal of the charged groups and suggests an important role for electrostatic interactions in the cooperative structural transitions which calmodulin undergoes upon binding its target proteins or calcium. In the presence of calcineurin, a large and specific decrease in the rate of acetylation of Lys-75 and -148 of calmodulin is observed. The reactivity of the same residues is greatly increased in the presence of calcium alone [Giedroc, D. P., Sinha, S. K., Brew, K., & Puett, D. (1985) J. Biol. Chem. 260, 13406-13413]. Lys-75, located in the central helix, and the C-terminal Lys-148 [Babu, Y. S., Sacks, J. S., Greenhouse, T. J., Bugg, C. E., Means, A. R., & Cook, W. J. (1985) Nature (London) 315, 37-40] may act as sensors of the calmodulin allosteric transitions. Their reactivity changes in opposite directions in response to calcium-induced or calcineurin-induced structural changes. The reactivity of other residues such as Lys-21, decreased in the presence of calcineurin but not calcium, is also affected by a conformational change which is induced specifically by calcineurin.     

Glycation of calmodulin: chemistry and structural and functional consequences

In the presence of Ca2+ and glucose, calmodulin incorporates 2.5 mol of glucose/mol of protein. In the absence of Ca2+, only 1.5 mol of glucose is incorporated per mole of calmodulin. Glycation of calmodulin is associated with variable reductions in its capacity to activate three Ca2+/calmodulin-dependent brain target enzyme systems, including adenylyl cyclase, phosphodiesterase, and protein kinase. In addition, glycated calmodulin exhibits a 54% reduction in its Ca2+ binding capacity. Isolated CNBr cleavage fragments of glycated calmodulin suggest that glycation follows a nonspecific pattern in that each of seven available lysines is susceptible to modification. A limit observed on the extent of glycation appears related to the accompanying increase in negative charge on the protein. Glycation results in minimal structural rearrangements in calmodulin, and the Ca2+-induced increase in alpha-helix content and radius of gyration is the same for glycated and unmodified calmodulin. Since glycated calmodulin's Ca2+ binding capacity is reduced, this implies that the Ca2+-induced conformational changes in calmodulin do not require all four Ca2+ binding sites to be occupied. Examination of the lysine positions in calmodulin suggests that Ca2+ binding to domains II and IV is sufficient to induce these changes. The functional consequences of calmodulin glycation therefore cannot be attributed to inhibition of these conformational changes. An alternative explanation is that the inhibition arises from interference at the target enzyme binding site by bound glucose. While glycation shows minimal structural effects, a large pH dependence is observed for the alpha-helix content of unmodified calmodulin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Amino Acid sequence of a novel calmodulin from the unicellular alga chlamydomonas

An amino acid sequence for a Chlamydomonas calmodulin has been elucidated with emphasis on the characterization of differences that are unique to Chlamydomonas and Dictyostelium calmodulin. While the concentration of calmodulin required for half-maximal activation of plant NAD kinase varies among vertebrate, higher plant, algal, and slime mold calmodulins, only calmodulins from the unicellular alga Chlamydomonas and the slime mold Dictyostelium show increased maximal activation of NAD kinase (Roberts, Burgess, Watterson 1984 Plant Physiol 75: 796-798; Marshak, Clarke, Roberts, Watterson 1984 Biochemistry 23: 2891-2899). The same preparations of calmodulin do not show major differences in phosphodiesterase or myosin light chain kinase activator activity.

We report here that a Chlamydomonas calmodulin has four primary structural features similar to Dictyostelium that are not found in other calmodulins characterized to date: an altered carboxy terminus including a novel 11-residue extension for Chlamydomonas calmodulin, unique residues at positions 81 and 118, and an unmethylated lysine at position 115. The only amino acid sequence identity unique to Chlamydomonas and Dictyostelium calmodulin is the presence of a lysine at position 115 instead of a trimethyllysine. These studies indicate that the methylation state of lysine 115 may be important in the maximal NAD kinase activator activity of calmodulin and support the concept that calmodulin has multiple functional domains in addition to multiple structural domains.

     

Effects of interaction with calcineurin on the reactivities of calmodulin lysines

Calmodulin was trace labeled by acetylation with [3H]acetic anhydride in the presence and absence of a 30% molar excess of the phosphatase calcineurin; phenylalanine was included in the reaction mixtures as an internal standard. The level of 3H acetylation of each of the 7 lysines was determined and corrected for differences arising from reaction conditions using the labeling of the internal standard, following procedures that are closely similar to those used in a previous study of the interaction of calmodulin with myosin light chain kinase (Jackson, A. E., Carraway, K. L., III, Puett, D., and Brew, K. (1986) J. Biol. Chem. 261, 12226-12232). The interaction with calcineurin was found to produce a 10-fold reduction in the acetylation of lysine 75, with lesser but significant effects on lysines 21 and 148. A small but reproducible perturbation of lysine 77 was also observed. The results are similar to those that are produced by the interaction with myosin light chain kinase. However, when they are compared with two recent reports between which there are major discrepancies (Manalan, A. S., and Klee, C. B. (1987) Biochemistry 26, 1382-1390; Winkler, M. A., Fried, V. A., Merat, D. L., and Cheung, W. Y. (1987) J. Biol. Chem. 262, 15466-15471), our results are in good agreement with those obtained in the former study. From the location of the perturbed groups in the three-dimensional structure of calmodulin, it appears that the interaction site on calmodulin for calcineurin, as well as for myosin light chain kinase, is very extended and may include hydrophobic pockets at homologous sites near the carboxyl-terminal ends of the two halves of the molecule.     

Functional significance of the central helix in calmodulin

The 3-A crystal structure of calmodulin indicates that it has a polarized tertiary arrangement in which calcium binding domains I and II are separated from domains III and IV by a long central helix consisting of residues 65-92. To investigate the functional significance of the central helix, mutated calmodulins were engineered with alterations in this region. Using oligonucleotide-primed site-directed mutagenesis, Thr-79 was converted to Pro-79 to generate CaMPM. CaMPM was further mutated by insertion of Pro-Ser-Thr-Asp between Asp-78 and Pro-79 to yield CaMIM. Calmodulin, CaMPM, and CaMIM were indistinguishable in their ability to activate calcineurin and Ca2+-ATPase. All mutated calmodulins would also maximally activate cGMP-phosphodiesterase and myosin light chain kinase, however, the concentrations of CaMPM and CaMIM necessary for half-maximal activation (Kact) were 2- and 9-fold greater, respectively, than CaM23. Conversion of the 2 Pro residues in CaMIM to amino acids that predict retention of helical secondary structure did not restore normal calmodulin activity. To investigate the nature of the interaction between mutated calmodulins and target enzymes, synthetic peptides modeled after the calmodulin binding region of smooth and skeletal muscle myosin light chain kinase were prepared and used as inhibitors of calmodulin-dependent cGMP-phosphodiesterase. The data suggest that the different kinetics of activation of myosin light chain kinase by CaM23 and CaMIM are not due to differences in the ability of the activators to bind to the calmodulin binding site of this enzyme. These observations are consistent with a model in which the length but not composition of the central helix is more important for the activation of certain enzymes. The data also support the hypothesis that calmodulin contains multiple sites for protein-protein interaction that are differentially recognized by its multiple target proteins.     

Circular dichroism studies on calcium binding to two series of Ca2+ binding site mutants of Drosophila melanogaster calmodulin.

The Ca(2+)-induced structural changes in mutant calmodulins from Drosophila melanogaster have been studied by circular dichroism. The proteins comprise eight site-specific mutants, in which a bidentate glutamic acid (at position 12 in each Ca2+ binding loop) is replaced with either glutamine (BQ series) or lysine (BK series). Previous studies of these proteins indicate that Ca2+ binding at the mutated site is effectively eliminated by each of these substitutions, with additional effects at nonmutated sites. Circular dichroism has now been used to assess Ca(2+)-induced changes in secondary and tertiary structure in these proteins. In the absence of Ca2+, the helical content of these mutant calmodulins is close to that of the wild-type protein. In excess Ca2+, calmodulins with a mutation in the N-terminal sites show Ca(2+)-induced increases in helicity (CD at 222 nm) that are similar to those of the wild-type protein. In contrast, much less additional helix is induced by Ca2+ in calmodulins with mutations in the C-terminal sites, with the two mutations to site IV showing a particularly poor response. Ca(2+)-induced changes to the environment of the single tyrosine of Drosophila calmodulin (Tyr-138 in site IV of the C-terminal domain) have been monitored via CD at 280 nm. The signal from this residue is significantly altered in the Ca(2+)-free form of almost all these mutants, including those in the N-terminal domain. This indicates significant interaction between the N- and C-terminal domains of these mutants.(ABSTRACT TRUNCATED AT 250 WORDS)     

The yeast mitochondrial citrate transport protein: identification of the Lysine residues responsible for inhibition mediated by Pyridoxal 5′-phosphate

The present investigation identifies the molecular basis for the well-documented inhibition of the mitochondrial inner membrane citrate transport protein (CTP) function by the lysine-selective reagent pyridoxal 5′-phosphate. Kinetic analysis indicates that PLP is a linear mixed inhibitor of the Cys-less CTP, with a predominantly competitive component. We have previously concluded that the CTP contains at least two substrate binding sites which are located at increasing depths within the substrate translocation pathway and which contain key lysine residues. In the present investigation, the roles of Lys-83 in substrate binding site one, Lys-37 and Lys-239 in substrate binding site two, and four other off-pathway lysines in conferring PLP-inhibition of transport was determined by functional characterization of seven lysine to cysteine substitution mutants. We observed that replacement of Lys-83 with cysteine resulted in a 78% loss of the PLP-mediated inhibition of CTP function. In contrast, replacement of either Lys-37 or Lys-239 with cysteine caused a modest reduction in the inhibition caused by PLP (i.e., 31% and 20% loss of inhibition, respectively). Interestingly, these losses of PLP-mediated inhibition could be rescued by covalent modification of each cysteine with MTSEA, a reagent that adds a lysine-like moiety (i.e. SCH₂CH₂NH₃ ⁺) to the cysteine sulfhydryl group. Importantly, the replacement of non-binding site lysines (i.e., Lys-45, Lys-48, Lys-134, Lys-141) with cysteine resulted in little change in the PLP inhibition. Based upon these results, we conducted docking calculations with the CTP structural model leading to the development of a physical binding model for PLP. In combination, our data support the conclusion that PLP exerts its main inhibitory effect by binding to residues located within the two substrate binding sites of the CTP, with Lys-83 being the primary determinant of the total PLP effect since the replacement of this single lysine abolishes nearly all of the observed inhibition by PLP. This work was supported by National Institutes of Health Grant GM-054642 to R.S.K.     

Calmodulin Affinity for Brain Coated Vesicle Proteins

A systematic characterization of the affinity of calmodulin for brain coated vesicles was undertaken. Binding of 125I-labeled calmodulin to coated vesicles was saturable and competed with unlabeled calmodulin, but not with troponin-C. Scatchard analysis revealed one high-affinity, low-capacity binding site, KD = 3.9 +/- 0.6 nM, Bmax = 16.3 +/- 2.4 pmol/mg, and one low-affinity, high-capacity binding site, KD = 102 +/- 15.0 nM, Bmax = 151 +/- 23.0 pmol/mg. Radioimmunoassay revealed that coated vesicles contain 1.05 microgram calmodulin/mg protein. Because this value remained constant even after removal of clathrin, the major coat protein, from the coated vesicle, it is apparent that calmodulin is associated with the vesicle per se rather than with its clathrin lattice. When a Triton X-100-treated extract of coated vesicles was passed through a Sepharose 4B-calmodulin affinity column, polypeptides with Mrs (molecular weights) of 100,000, 55,000, and 30,000 bound in a Ca2+-dependent manner. A 30,000 Mr protein doublet purified from coated vesicles was completely eluted by EGTA from the calmodulin affinity column, confirming that this protein doublet represents one of the coated vesicle calmodulin binding sites. Because calmodulin stimulated [Ca2+-Mg2+]-ATPase activity as well as Ca2+ uptake in coated vesicles, it is postulated that the 100,000 and 55,000 Mr calmodulin binding proteins represent the [Ca2+-Mg2+]-ATPase complex, the other coated vesicle calmodulin binding site.