An Intragenic Suppressor of a Calmodulin Mutation in Paramecium: Genetic and Biochemical Characterization

We describe a suppressor of the calmodulin mutant cam1 in Paramecium tetraurelia. The cam1 mutant, which has a SER----PHE change at residue 101 of the third calcium-binding domain, inhibits the activity of the Ca(2+)-dependent K+ current and causes exaggerated behavioral responses to most stimuli. An enrichment scheme, based on an increased sensitivity to Ba2+ in cam1 cells, was used to isolate suppressors. One such suppressor, designated cam101, restores both the activity of the Ca(2+)-dependent K+ current and behavioral responses of the cells. We show that the cam101 mutant is an intragenic suppressor of cam1, based on genetic and microinjection data. The cam101 calmodulin is shown to be similar to wild-type calmodulin in terms of its ability to stimulate calmodulin-dependent phosphodiesterase at low concentrations of free calcium. However, the cam101 calmodulin has a reduced affinity for a monoclonal antibody to wild-type Paramecium calmodulin, as does the parental cam1 calmodulin, and a different mobility on acid-urea gels relative to both wild-type and cam1 calmodulin. We have been able to demonstrate that the isolation of intragenic suppressors of a calmodulin mutation is possible, which allows for the further genetic analysis of structure-function relationships in the calmodulin molecule.     

Amino acid sequence of a novel calmodulin from Paramecium tetraurelia that contains dimethyllysine in the first domain

A class of Paramecium behavioral mutants called pantophobiacs have a deficiency in calcium-dependent potassium efflux, and this deficiency can be corrected by the microinjection of wild-type Paramecium calmodulin (Hinrichsen, R. D., Burgess-Cassler, A., Soltvelt, B. C., Hennessey, T., and Kung, C. (1986) Science 232, 503-506). As a starting point in investigations of which features allow wild-type Paramecium calmodulin to fully restore this behavior while other calmodulins are inactive or poorly effective, we elucidated the amino acid sequence of the wild-type calmodulin. We utilized an approach that combined Edman chemistry with mass spectrometry. This approach resulted in the identification of a new post-translational modification in calmodulin: N epsilon,N epsilon-dimethyllysine at residue 13. This particular modification has not been described for calmodulins studied previously. The only other first-domain modification that has been described for any calmodulin is acetylation of the amino terminus (Watterson, D. M., Sharief, F., and Vanaman, T. C. (1980) J. Biol. Chem. 255, 962-975). These results along with analyses of pantophobiac calmodulin and calmodulin binding proteins will provide insight into calmodulin's role in a well-defined behavioral mutant.     

Primary mutations in calmodulin prevent activation of the Ca(++)-dependent Na+ channel in Paramecium.

Paramecium tetraurelia behavioral mutant cam12 displays a "fast-2" behavioral phenotype: it fails to respond to Na+ stimuli. Electrophysiologically, it lacks a Ca(++)-dependent Na+ current. Genetics and DNA sequencing showed the primary defect of cam12 to be in the calmodulin gene (Kink et al., 1990). To correlate calmodulin structure and function in Paramecium, we elucidated the primary structure of cam12 calmodulin. Peptide sequencing confirmed the two point mutations predicted by the DNA sequence: a glycine-to-glutamate substitution at position 40 and an aspartate-to-asparagine substitution at position 50. Our results further showed that lysine 13 and lysine 115 were methylated normally in cam12. It is likely that the electrophysiological abnormalities of cam12 are a direct reflection of the amino-acid substitutions, as opposed to improper posttranslational modification.     

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.     

Calmodulin from neurospora crassa. General properties and conformational changes

Calmodulin from Neurospora crassa has been purified to electrophoretic homogeneity. Equilibrium gel filtration experiments suggest that its Ca-binding properties are indistinguishable from those of vertebrate calmodulins. The isoelectric point of 4.04 and electrophoretic behavior under nondenaturing conditions indicate that N. crassa calmodulin is slightly less acidic than its vertebrate counterpart. The amino acid composition is typical of plant calmodulins with the exception that trimethyllysine is absent and that the content of Ser is unusually high. The tryptic peptide map of N. crassa calmodulin reveals an important number of point mutations as compared to vertebrate calmodulin. Differences in primary structure may explain why N. crassa calmodulin is less potent in the activation of myosin light chain kinase than calmodulins from higher organisms. The far UV circular dichroic spectra of the Ca-, Mg-, and metal-free forms of N. crassa calmodulin are similar to those of vertebrate calmodulin; in contrast, the near UV circular dichroic spectra are very different, apparently due to the differences in Tyr content. The single Tyr residue of N. crassa calmodulin, presumably located in position 138, undergoes an inversion of optical chirality upon addition of Ca2+, but not of Mg2+, to the metal-free protein.     

Further Characterization of Calmodulin from the Monocotyledon Barley (Hordeum vulgare)

We report here that calmodulin isolated from the monocotyledon barley is indistinguishable by a variety of criteria from calmodulin isolated from the dicotyledon spinach. In contrast to previous reports, we find that barley (Hordeum vulgare) calmodulin has an amino acid composition similar to that of vertebrate and spinach calmodulins, including the presence of a single trimethyllysinyl residue, and that barley calmodulin quantitatively activates cyclic nucleotide phosphodiesterase. Furthermore, spinach and barley calmodulins are similar in terms of tryptic peptide maps and immunoreactivity with various antisera that differ in their molecular specificities for calmodulins. Limited amino acid sequence analysis demonstrates that the region around the single histidinyl and trimethyllysinyl residues is identical among barley, spinach, and vertebrate calmodulins and that barley calmodulin, like spinach calmodulin, has a novel glutamine residue at position 96. We conclude that calmodulin is highly conserved among higher plants and that detailed sequence analysis is required before significant differences, if any, can be assigned to barley or other higher plant calmodulins. These studies suggest that calmodulin's fundamental importance to the eukaryotic cell may have been established prior to the evolutionary emergence of higher plants.     

Calmodulin is essential for assembling links necessary for exocytotic membrane fusion in Paramecium.

Calmodulin has long been suspected to be involved in calcium-regulated exocytosis but its precise site(s) of action has not yet been identified. In Paramecium, a genetic approach to the problem is possible as in vivo-selected mutations in the calmodulin gene that prevent the activation of some channels have been characterized. Three of these calmodulin mutants were examined for exocytotic capacity and the mutant cam1 was found to be defective for exocytosis at 35 degrees C. The loss of exocytotic capacity in cam1 cells can be restored by transformation with the wild-type calmodulin gene, demonstrating that its exocytotic lesion is indeed due to the mutation in the calmodulin gene. The cam1 mutant displays abnormal exocytotic sites at the non-permissive temperature: it lacks the links ('rosettes' of intramembranous particles in the plasma membrane and the fibrous 'connecting material') which normally connect plasma and trichocyst membranes. Upon shift of cam1 cells from the permissive to a non-permissive temperature, performed sites remain functional. These results demonstrate that calmodulin is necessary for the assembly of these links at the exocytotic site. These results do not, however, exclude the possibility of calmodulin also being involved in Ca(2+)-dependent steps of the stimulus-exocytosis coupling.     

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.     

Genetic dissection of Ca2(+)-dependent ion channel function in Paramecium.

The ciliated protozoan, Paramecium, broadcasts the activity of its individual ion channel classes through its swimming behaviour. This fact has made it possible to isolate mutants with defective ion currents, simply by selecting individuals with abnormal swimming patterns. At least four of Paramecium's ion currents are activated by rising intracellular calcium concentration, including two K+ currents and a Na+ current. A variety of cell lines with defects in these Ca2(+)-dependent currents have been isolated: in several cases, the defects have been traced to mutations in the structural gene for calmodulin. Sequence analysis of calmodulins from these and other Ca2(+)-dependent ion-current mutants may enable a detailed mapping of putative channel interaction domains on the surface of the calmodulin molecule.     

Isolation and characterization of calmodulin from the motile green alga Chlamydomonas reinhardtii

Calmodulin, a calcium-binding protein with no known enzymatic activity but multiple, in vitro effector activities, has been purified to apparent homogeneity from the unicellular green alga Chlamydomonas reinhardtii and compared to calmodulin from vertebrates and higher plants. Chlamydomonas calmodulin was characterized in terms of electrophoretic mobility, amino acid composition, limited amino acid sequence analysis, immunoreactivity, and phosphodiesterase activation. Chlamydomonas calmodulin has two histidine residues similar to calmodulin from the protozoan Tetrahymena. However, unlike the protozoan calmodulin, only one of the histidinyl residues of Chlamydomonas calmodulin is found in the COOH-terminal third of the molecule. Chlamydomonas calmodulin lacks trimethyllysine but does have a lysine residue at the amino acid sequence position corresponding to the trimethyllysine residue in bovine brain and spinach calmodulins. The lack of this post-translational modification does not prevent Chlamydomonas calmodulin from quantitatively activating bovine brain phosphodiesterase. These studies also demonstrate that this unique calmodulin from a phylogenetically earlier eukaryote may be as similar to vertebrate calmodulin as it is to higher plant calmodulins, and suggest that Chlamydomonas calmodulin may more closely approximate the characteristics of a putative precursor of the calmodulin family than any calmodulin characterized to date.     

Comparison of the NAD Kinase and Myosin Light Chain Kinase Activator Properties of Vertebrate, Higher Plant, and Algal Calmodulins

In the preceding paper (Lukas, Iverson, Schleicher, Watterson 1984 Plant Physiol 75: 788-795), we reported that the amino acid sequence of spinach calmodulin has at least 13 amino acid sequence differences from vertebrate calmodulin. In the present study, we investigated the effect of these amino acid sequence substitutions on the enzyme activator properties of vertebrate and plant calmodulins. Calmodulins from spinach and the green alga Chlamydomonas reinhardtii activate chicken gizzard myosin light chain kinase in a manner similar but not identical to chicken calmodulin. In contrast, these calmodulins have very different NAD kinase activator properties. The concentration required for half-maximal activation of pea seedling NAD kinase by spinach calmodulin (3-4 nanomolar) is lower than the corresponding concentrations of chicken (20 nanomolar) and Chlamydomonas (40 nanomolar) calmodulins. However, the maximum level of activation obtained with Chlamydomonas calmodulin is 4- to 6-fold higher than spinach or chicken calmodulin. These data indicate that the limited structural heterogeneity among calmodulins have differential effects on their biochemical activities.     

Biochemical characterization of a genetically altered calmodulin in Paramecium

Recent evidence proposes that the calcium-binding protein, calmodulin, plays a crucial role in the regulation or modulation of the calcium-dependent potassium conductance in Paramecium tetraurelia (Hinrichsen, R.D., Burgess-Cassler, A., Soltvedt, B.C., Hennessey, T. and Kung, C. (1986) Science 323, 503-506). We purified the calmodulins from both the wild type and pantophobiac A (a mutant lacking the above-mentioned conductance and whose phenotypic defect is traceable to its calmodulin) by hydrophobic interaction and immunoaffinity chromatographies, and examined them biochemically. In this paper we address the preliminary characterization of the two calmodulins and discuss the consequences of the genetic alteration. The differences described here are in their electrophoretic mobilities in polyacrylamide gel electrophoresis and in their binding characteristics to monoclonal antibodies raised against calmodulin from wild-type paramecia. Also, we present data which indicate a difference in the stimulation of the calmodulin-dependent enzyme bovine brain phosphodiesterase under certain conditions.     

A site-directed mutagenesis study of yeast calmodulin

A site-directed mutagenesis study was carried out in order to understand the regulatory mechanism of calmodulin. We started from the yeast (Saccharomyces cerevisiae) calmodulin gene since it has many differences in amino acid sequence and inferior functional properties compared with the vertebrate calmodulin. Recombinant yeast calmodulins were generated in Escherichia coli transformed by constructed expression plasmids. Three recombinant calmodulins were obtained. The first two were YCM61G, in which the Ca2(+)-binding site 2 (the four Ca2(+)-binding EF-hand structures in calmodulin were numbered from the N-terminus) was converted to the same as that in vertebrate calmodulin, and YCM delta 132-148, in which the C-terminal half sequence of site 4 was deleted. These two recombinant calmodulins had the same maximum Ca2+ binding (3 mol/mol) as yeast calmodulin, which indicates that site 4 of yeast calmodulin was the one losing Ca2+ binding capacity. YCM delta 132-148 could not activate target enzymes, whereas its Ca2+ binding profile was similar to those of yeast calmodulin and YCM61G. Therefore, the structure in site 4 which cannot bind Ca2+ is indispensable for the regulatory function of yeast calmodulin. The complete regulatory function of vertebrate calmodulin can be attained by the combination of 4 Ca2+ binding structures. The negative charge cluster in the central alpha-helix region is suggested to stabilize the active conformation of calmodulin, since the third yeast calmodulin mutant, YCM83E, which had the negative charge cluster, increased the maximum activation of myosin light chain kinase.     

Characterization and purification of a soluble protein controlling Ca-channel activity in paramecium

The analysis of the voltage-sensitive Ca++ channel of the unicellular eucaryote, Paramecium has been extended to a biochemical level based on recent observations that the transfer of cytoplasm from wild-type cells into mutants lacking Ca++-channel function ("pawn" in P. tetraurelia and "CNR" in P. caudatum) causes mutant cells to regain Ca++-channel function. We have microinjected various cytoplasmic fractions into mutant cells and measured the restored Ca++-channel function using a convenient behavioral assay. Following the "curing" activity, we characterized and purified the component from wild-type cytoplasm that can restore the function missing in cells carrying mutations in the cnrC gene. The curing factor is not an RNA, but a heat-labile, -SH-containing protein that appears to affect existing mutant channels on the ciliary membrane. We have purified this factor over 500-fold from the soluble cytoplasm using conventional techniques. The protein is of low apparent molecular weight (less than 30,000 daltons), acidic, soluble, and does not have the properties of calmodulin.     

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)     

Isolation and purification of calmodulin from the shrimp, Crangon crangon.

Calmodulin was isolated and purified from shrimp abdominal muscle by heat precipitation, ion exchange and hydrophobic interaction chromatography. The purified calmodulin was homogeneous when evaluated by polyacrylamide gel electrophoresis. A still remaining contaminant was eliminated by high performance liquid chromatography on a phenyl column. The biological and physicochemical properties of shrimp calmodulin such as amino acid composition, molecular weight and the ability to activate calmodulin-deficient bovine heart phosphodiesterase were compared to those of other invertebrate calmodulins.     

A single point mutation has pleiotropic effects on pp60v-src function.

The Rous sarcoma virus mutant tsLA29 encodes a pp60v-src molecule that is temperature sensitive for both tyrosine kinase activity and its ability to locate at the cell periphery. The defect in localization appears to be due to a perturbation in events following complex dissociation, since the mutant enzyme shows a rapidly reversible association with the cytoskeleton when shifted between permissive and restrictive temperatures. Although tsLA29 pp60v-src differs from the wild type at three amino acid residues, studies with chimeric proteins show that only one of the mutations, an alanine-for-proline substitution at residue 507, accounts for all the temperature-sensitive characteristics. Moreover, a single second site mutation, at residue 427, can restore the wild phenotype. Cells infected with a chimeric virus encoding only the alanine substitution at position 507 have a conspicuously fusiform morphology, suggesting that this mutation also has subtle effects on pp60v-src function that are apparently compensated for by the other mutations in native tsLA29.     

Cyclic AMP may not be involved in catabolite repression in Saccharomyes cerevisiae: evidence from mutants capable of utilizing it as an adenine source.

Mutants able to utilize 5'-AMP or cyclic AMP as the adenine source were isolated from an ade6 ade10 double mutant by ethyl methane sulfonate mutagenesis. A single amp1 mutation, primarily selected on 5'-AMP medium, confers the phenotype for utilization of exogenous 5'-AMP as the adenine source. From the ade6 ade10 amp1 triple mutant, a mutant able to utilize cyclic AMP was isolated, and the mutant phenotype was proven to be due to the simultaneous occurrence of triple mutations designated as cam1, cam2, and cam3. The cam3 mutation, but not cam1 or cam2, also confers the phenotype for utilizing 5'-AMP, the same phenotype as the amp1 mutation. All of these mutations are recessive to the respective wild-type counterparts. Cells having the ade6 ade10 amp1 cam1 cam2 cam3 genotype showed significant ability to take up exogenous cyclic AMP, whereas no differences were observed in cyclic AMP phosphodiesterase activity in comparison with that of the original strains used in the mutant isolation. Since glucose severely repressed galactokinase synthesis in the constitutive GAL81 mutant having the ade6 ade10 amp1 cam1 cam2 cam3 genotype, irrespective of the presence or absence of cyclic AMP in the medium, it was suggested that cyclic AMP is not involved in the mechanism of catabolite repression in Saccharomyces cerevisiae. It does, however, have a stimulative effect on the galactokinase synthesis in the GAL81 mutant in the absence of glucose.     

Purification and biochemical properties of calmodulin from Saccharomyces cerevisiae

Calmodulin from the yeast Saccharomyces cerevisiae was purified to complete homogeneity by hydrophobic interaction chromatography and HPLC gel filtration. The biochemical properties of the purified protein as calmodulin were examined under various criteria and its similarity and dissimilarity to other calmodulins have been described. Like other calmodulins, yeast calmodulin activated bovine phosphodiesterase and pea NAD kinase in a Ca2+-dependent manner, but its concentration for half-maximal activation was 8-10 times that of bovine calmodulin. The amino acid composition of yeast calmodulin was different from those of calmodulins from other lower eukaryotes in that it contained no tyrosine, but more leucine and had a high ratio of serine to threonine. Yeast calmodulin did not contain tryptophanyl or tyrosyl residues, so its ultraviolet spectrum reflected the absorbance of phenylalanyl residues, and had a molar absorption coefficient at 259 nm of 1900 M-1 cm-1. Ca2+ ions changed the secondary structure of yeast calmodulin, causing a 3% decrease in the alpha-helical content, unlike its effect on other calmodulins. Antibody against yeast calmodulin did not cross-react with bovine calmodulin, and antibody against bovine calmodulin did not cross-react with yeast calmodulin, presumably due to differences in the amino acid sequences of the antigenic sites. It is concluded that the molecular structure of yeast calmodulin differs from those of calmodulins from other sources, but that its Ca2+-dependent regulatory functions are highly conserved and essentially similar to those of calmodulins of higher eukaryotes.     

Plant and fungus calmodulins are polyubiquitinated at a single site in a Ca2(+)-dependent manner

In plants Ca2+ plays a crucial role as second messenger. Thus calmodulin is one of the most important signal transducing molecules for metabolic regulation in plants. Previously we showed that bovine testis calmodulin can be covalently coupled at one site to ubiquitin in a Ca2(+)-dependent manner in the presence of ATP/Mg2+ by ubiquityl-calmodulin synthetase. Since calmodulin from spinach has 13 amino acid sequence differences to bovine calmodulin - two of them in Ca2(+)-binding loops - it was unclear, whether a conjugation of ubiquitin to this molecule would be possible. In this paper it is shown that calmodulin from spinach and a similar calmodulin from the mold Neurospora crassa can be covalently conjugated to ubiquitin in a Ca2(+)-dependent manner. It is shown that higher molecular mass conjugates containing up to three ubiquitin molecules per calmodulin are obtained. Experiments with methylated ubiquitin demonstrate that, as with vertebrate calmodulins, only one lysine residue is linked to ubiquitin and that the incorporation of additional ubiquitin molecules leads to a polyubiquitin chain.