Drug-protein interactions: binding of chlorpromazine to calmodulin, calmodulin fragments, and related calcium binding proteins

The quantitative binding of a phenothiazine drug to calmodulin, calmodulin fragments, and structurally related calcium binding proteins was measured under conditions of thermodynamic equilibrium by using a gel filtration method. Plant and animal calmodulins, troponin C, S100 alpha, and S100 beta bind chlorpromazine in a calcium-dependent manner with different stoichiometries and affinities for the drug. The interaction between calmodulin and chlorpromazine appears to be a complex, calcium-dependent phenomenon. Bovine brain calmodulin bound approximately 5 mol of drug per mol of protein with apparent half-maximal binding at 17 microM drug. Large fragments of calmodulin had limited ability to bind chlorpromazine. The largest fragment, containing residues 1-90, retained only 5% of the drug binding activity of the intact protein. A reinvestigation of the chlorpromazine inhibition of calmodulin stimulation of cyclic nucleotide phosphodiesterase further indicated a complex, multiple equilibrium among the reaction components and demonstrated that the order of addition of components to the reaction altered the drug concentration required for half-maximal inhibition of the activity over a 10-fold range. These results confirm previous observations using immobilized phenothiazines [Marshak, D.R., Watterson, D.M., & Van Eldik, L.J. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 6793-6797] that indicated a subclass of calcium-modulated proteins bound phenothiazines in a calcium-dependent manner, demonstrate that the interaction between phenothiazines and calmodulin is more complex than previously assumed, and suggest that extended regions of the calmodulin molecule capable of forming the appropriate conformation are required for specific, high-affinity, calcium-dependent drug binding activity.

Immunoreactive levels of myosin light-chain kinase in normal and virus-transformed chicken embryo fibroblasts

Calmodulin, a calcium-modulated effector protein, is an important mediator of the intracellular actions of calcium through its interaction with calmodulin-binding proteins. We report here that the immunoreactive levels of a calmodulin-binding protein, myosin light-chain kinase, are decreased in transformed chicken embryo fibroblasts.

Identification of calmodulin-binding proteins in chicken embryo fibroblasts

We recently reported the detection of multiple classes of calmodulin-binding proteins in subcellular fractions of chicken embryo fibroblasts by using a gel binding procedure (Van Eldik, L.J., and W.H. Burgess, 1983, J. Biol. Chem., 258:4539-4547). In this report we identify many of these calmodulin-binding proteins and provide further evidence for the existence of multiple classes of calmodulin-binding proteins based on the interaction of these proteins with calmodulin and other calcium-modulated proteins. The fact that, in some cases, the same calmodulin-binding protein can bind troponin C and S100 alpha suggests that similar functional domains may be present in these distinct calcium-modulated proteins. We also have used protocols based on purification steps for calmodulin-binding proteins and calmodulin-regulated activities from other systems, in conjunction with enzymatic assays and various immunological methods, to identify many of the calmodulin-binding proteins in chicken embryo fibroblasts. The identities of these proteins suggest in vivo roles for calmodulin in the regulation of cell shape and motility, cyclic nucleotide metabolism, and possibly nucleic acid and protein turnover in fibroblasts.

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.

Structural characterization of a higher plant calmodulin : spinacia oleracea

Calmodulin is a eukaryotic calcium binding protein which has several calcium-dependent in vitro activities. Presented in this report is a structural characterization of calmodulin from spinach leaves (Spinacia oleracea). Spinach calmodulin may be representative of higher plant calmodulins in general since calmodulin from the monocotyledon barley (Hordeum vulgare) is indistinguishable by a variety of physical, chemical, and functional criteria (Schleicher, Lukas, Watterson 1983 Plant Physiol 73: 666-670). Spinach calmodulin is homologous to bovine brain calmodulin with only 13 identified amino acid sequence differences, excluding a blocked NH(2)-terminal tripeptide whose sequence has not been elucidated. Two extended regions of sequence identity are in the NH(2)-terminal half of the molecule, while nine of the 13 identified differences are in the COOH-terminal half of the molecule. Two of the changes, a cysteine at residue 26 and a glutamine at residue 96, require a minimum of two base changes in the nucleotide codons. Both of these changes occur in the proposed calcium binding loops of the molecule. Five additional amino acid differences found in spinach calmodulin had not been observed previously in a calmodulin. As described in an accompanying report (Roberts, Burgess, Watterson 1984 Plant Physiol 75: 796-798), these limited number of amino acid sequence variations appear to result in differential effects on the activation of calmodulin-dependent enzymes by plant and vertebrate calmodulins.

Structural and functional properties of calmodulin from the eukaryotic microorganism Dictyostelium discoideum

Calmodulin was purified from the eukaryotic microorganism Dictyostelium discoideum and characterized in terms of its nearly complete primary structure and quantitative activator activity. The strategy for amino acid sequence analysis took advantage of the highly conserved structure of calmodulin and employed a new procedure for limited cleavage of calmodulin that uses a protease from mouse submaxillary gland. Fourteen amino acid sequence differences between Dictyostelium and bovine calmodulin were identified unequivocally, as well as an unmethylated lysine at residue 115 instead of N epsilon, N epsilon, N epsilon-trimethyllysine. Seven of the amino acid substitutions in Dictyostelium calmodulin are novel in that the residues at these positions are invariant in all calmodulin sequences previously examined, most notably an additional residue at the carboxy terminus. Comparison of the Dictyostelium calmodulin sequence with other calmodulin sequences shows that the region with the greatest extended sequence identity includes parts of the first and second structural domains and the interdomain region between domains 1 and 2. Dictyostelium calmodulin activated bovine brain cyclic nucleotide phosphodiesterase in a manner indistinguishable from that of bovine brain calmodulin. However, Dictyostelium calmodulin activated pea NAD kinase to a maximal level 4.6-fold greater than that produced by bovine brain calmodulin. This functional difference demonstrates the potential biological importance of the limited number of amino acid sequence differences between Dictyostelium calmodulin and other calmodulins and provides further insight into the structure, function, and evolution of the calmodulin family of proteins.

Biosynthesis of calmodulin in normal and virus-transformed chicken embryo fibroblasts

We report here that the higher levels of calmodulin in transformed chicken embryo fibroblasts are due to an increase in the rate of synthesis of calmodulin that results from an increased amount of calmodulin-specific mRNA in transformed cells. Transformation of several types of eucaryotic cells by oncogenic viruses results in a two- to threefold increase in the intracellular levels of calmodulin. We used the normal chicken embryo fibroblast and its Rous sarcoma virus-transformed counterpart to examine the biosynthesis of calmodulin. We show that the higher levels of calmodulin found in transformed fibroblasts appear to be the consequence of a selective increase in the rate of synthesis of calmodulin above that of total soluble or total cellular protein. A significant difference in the rate of degradation of calmodulin or total protein between transformed and normal cells was not detected. We also examined the mechanism of the increased synthesis rate of calmodulin and show that the levels of calmodulin mRNA are increased in transformed fibroblasts as measured by both translational activity and hybridization to a calmodulin cDNA probe. It is suggested by these data that the higher levels of calmodulin in transformed cells may result from a specific increase in the rate of either calmodulin gene transcription or mRNA processing.

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.

Elucidation of a minimal immunoreactive site of vertebrate calmodulin

The heptapeptide Asn-Tyr-Glu-Glu-Phe-Val-Gln-NH2 corresponding to residues 137-143 of vertebrate calmodulin is as immunoreactive as the entire 148-residue protein. A reproducible and rapid procedure for producing antisera against vertebrate calmodulin has been previously described (L. J. Van Eldik and D. M. Watterson (1981) J. Biol. Chem. 256, 4205-4210). Most of the antisera elicited by this method react with a major immunoreactive region (residues 127-144) in the COOH-terminal domain of vertebrate calmodulin. In this report, the minimum segment of calmodulin required for reactivity with an antiserum that readily distinguishes various types of calmodulins is defined. These studies demonstrate that a linear segment of seven amino acid residues shows a competition curve in radioimmunoassay resembling the competition curve of intact calmodulin. This heptapeptide is the smallest calmodulin segment and the only seven-residue segment in the 135-145 region that shows quantitative immunoreactivity with the anti-calmodulin serum. These data demonstrate that this heptapeptide is a major immunoreactive site of calmodulin. However, when this immunoreactive site heptapeptide is conjugated to a carrier and injected into rabbits, it does not elicit antisera that react with the native protein. These studies demonstrate that quantitative immunoreactivity of antisera produced in animals can be found in small peptide segments and that, for calmodulin, the requirements for production of anti-peptide antibodies that react with the native protein molecule are not as simple as surface exposure of the peptide region.

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.

Engineering of site-directed antisera against vertebrate calmodulin by using synthetic peptide immunogens containing an immunoreactive site

Site-directed antisera against vertebrate calmodulin were elicited in rabbits by injection of a synthetic immunogen containing the pentadecapeptide Gly-Gln-Val-Asn-Tyr-Glu-Glu-Phe-Val-Gln-Met-Met-Thr-Ala-Lys-OH, which corresponds to residues 134-148 of vertebrate calmodulin. A major immunoreactive region (residues 127-144) of calmodulin is found in the COOH-terminal structural domain and an immunoreactive site for one antiserum is contained in the heptapeptide Asn-Tyr-Glu-Glu-Phe-Val-Gln-NH2, which corresponds to residues 137-143 of vertebrate calmodulin. This immunoreactive heptapeptide was conjugated to a carrier protein by adding a cysteine residue to the NH2 terminus of the peptide and coupling the Cys-heptapeptide to the carrier through the thiol group of the cysteine residue. Injection of this Cys-heptapeptide-protein conjugate into rabbits yielded antisera that react with the heptapeptide but not with native calmodulin. Thus, the immunoreactive heptapeptide that is exposed on the surface of calmodulin is immunogenic, but it is not sufficient to elicit antibodies that react with native calmodulin. However, when the Cys-pentadecapeptide corresponding to residues 134-148 and containing the immunoreactive heptapeptide sequence was conjugated to a carrier protein and injected into rabbits, antisera were elicited that react with the intact calmodulin molecule. The affinities and specificities of these antisera for calmodulin are similar to those of antisera elicited by injection of the intact protein and are sufficient for their use in radioimmunoassays. These results indicate that the successful engineering of site-directed antisera against proteins by using synthetic peptide immunogens may require an appropriate intramolecular environment that allows the peptide region to closely approximate the spatial orientation it adopts in the intact protein.

Analysis of suborganellar fractions from spinach and pea chloroplasts for calmodulin-binding proteins

Purified chloroplasts from spinach and pea leaves were subfractionated into envelope, thylakoid, and stroma fractions and were analyzed for calmodulin-binding proteins using a 125I-calmodulin gel overlay assay. Calmodulin binding was primarily associated with a major polypeptide (Mr 33,000) in the envelope membrane fraction. In contrast, major calmodulin-binding proteins were not detected in the thylakoid or stroma fractions. Our results provide the first evidence of calmodulin-binding proteins in the chloroplast envelope, and raise the possibility that calmodulin may contribute to the regulation of chloroplast function through its interaction with calmodulin-binding proteins in the chloroplast envelope. In addition, our results combined with those of other investigators support the proposal that subcellular organelles may be a primary site of calmodulin action.

Analysis of differences between coomassie blue stain and silver stain procedures in polyacrylamide gels: conditions for the detection of calmodulin and troponin C

It is reported that the conditions used in some silver stain procedures can fail to detect calmodulin, troponin C, and other proteins with similar physical properties. Conditions are described that allow the reproducible detection of these proteins. Two phenomena are described: (1) lack of protein staining when treatment with glutaraldehyde is omitted from the protocol, and (2) loss of small proteins from the gel matrix during prolonged washing procedures. These data directly demonstrate that the use of some silver staining protocols can result in misleading data in biological studies and provide an explanation for at least one class of proteins of how silver staining and Coomassie blue staining of gels can give different results.

Calcium-dependent interaction of S100b, troponin C, and calmodulin with an immobilized phenothiazine

We have purified the brain-specific protein S100b by affinity-based adsorption chromatography on phenothiazine-Sepharose conjugates and studied the interaction of this and other calcium-modulated proteins with the immobilized antipsychotic drug. Bovine brain calmodulin, rabbit skeletal muscle troponin C, and bovine brain S100b bind to phenothiazine-Sepharose in a calcium-dependent manner. These three proteins competitively inhibit the calcium-dependent binding of 125I-labeled chicken gizzard calmodulin to the immobilized drug. However, carp parvalbumin and chicken intestinal vitamin D-dependent calcium binding protein do not inhibit the phenothiazine--calmodulin interaction. These results suggest that the known amino acid sequence homology among calmodulin, troponin C, and S100b may be reflected in a similar functional domain present in these proteins but absent in parvalbumin and vitamin D-dependent protein.

Reproducible production of antiserum against vertebrate calmodulin and determination of the immunoreactive site

Calmodulin is a small, acidic, calcium-binding protein that exhibits multiple in vitro biochemical activities. Although calmodulin has no known enzymatic activity, it stimulates several enzyme activities in calcium-dependent manner. Because of its ubiquitous distribution and highly conserved structure, it has been difficult to elicit anti-calmodulin sera of useful titer. We describe here a reproducible and rapid method for producing anti-calmodulin sera. This method requires the injection of performic acid-oxidized calmodulin, but the antisera react equally well with unoxidized calmodulin. A response was elicited in 11 out of 11 rabbits using three variations of this method. Antisera titers were high enough to enable development of a quantitative radioimmunoassay using dilutions of whole sera, immunoglobulin fractions, or immunoglobulin fractions purified on calmodulin-Sepharose conjugates. For the majority of the antisera, the immunoreactive site is contained in a unique region of the calmodulin molecule. Based on the quantitative reactivity of overlapping tryptic and cyanogen bromide peptides, we propose that a major immunoreactive site is fund within an 18-residue region in the COOH-terminal domain of calmodulin.

Spinach calmodulin: isolation, characterization, and comparison with vertebrate calmodulins

Calmodulin is the name proposed for a multifunctional, calcium binding protein whose presence has been detected in a number of eukaryotic cells. In the studies summarized here, calmodulin has been isolated from spinach leaves (Spinacea oleracea), characterized, and compared to vertebrate calmodulins. Quantitative recovery data for a rapid-isolation protocol demonstrate that calmodulin is a major constituent of spinach leaves. Spinach calmodulin is indistinguishable from vertebrate calmodulins in phosphodiesterase activator activity using vertebrate brain phosphodiesterase and in quantitative immunoreactivity using antiserum made against vertebrate calmodulin. However, spinach calmodulin is really distinguished from vertebrate and invertebrate calmodulins in electrophoretic mobility and in amino acid composition. Spinach calmodulin, like vertebrate calmodulins, lacks tryptophan and contains 1 mol each of N epsilon-trimethyllysine and histidine per 17000 g of protein. In contrast to vertebrate calmodulins, spinach calmodulin has only one tyrosinyl residue and has a threonine/serine ratio of 1.3. While amino acid compositions indicate differences between spinach and vertebrate calmodulins, isolation and characterization of tryptic peptides containing the single histidinyl and N epsilon-trimethyllysyl residues and both prolinyl residues indicate that these regions in spinach calmodulin are similar to the corresponding regions in vertebrate calmodulin. These studies more fully define the general and specific characteristics of calmodulins and indicate that calmodulin structure is not as highly conserved among all eukaryotes as it is among vertebrates and invertebrates.

Similarities and dissimilarities between calmodulin and a Chlamydomonas flagellar protein

A protein that resembles vertebrate calmodulins and troponin C has been isolated from Chlamydomonas flagella by using a calmodulin purification protocol that included calcium-dependent affinity-based adsorption chromatography on phenothiazine-Sepharose conjugates. The flagellar protein resembled calmodulin in elution from reverse-phase columns, had a peptide map similar to that of calmodulin, and competed with vertebrate calmodulin in a radioimmunoassay using antisera against vertebrate calmodulin. However, this flagellar protein did not activate phosphodiesterase, lacked N epsilon-trimethyllysine, and had an isoelectric point approximately 0.3 pH unit higher than that of vertebrate calmodulin. When analyzed by polyacrylamide gel electrophoresis under various conditions, the Chlamydomonas protein migrated between vertebrate calmodulins and rabbit skeletal muscle troponin C and did not manifest a large calcium-dependent mobility shift. This calmodulin-like protein was identified as one of the approximately 200 35S-labeled components in Chlamydomonas flagella resolved by two-dimensional gel electrophoresis. These studies indicate that calmodulin and a structurally and functionally homologous protein are present in the same cell. These studies also demonstrate that caution is necessary: (i) in identifying a protein as a calmodulin, (ii) in using phenothiazines or antisera directed against vertebrate calmodulins as specific probes for calmodulin, and (iii) in the interpretation of experiments on biological systems in which calmodulin is substituted for the homologous calmodulin-like protein.

Comparison of calcium-modulated proteins from vertebrate brains

Calmodulins have been purified from porcine, rabbit, rat, and chicken brains and their structural and functional properties compared to those of the bovine brain protein whose complete amino acid sequence has been elucidated. No major differences were detected in the amino acid compositions and tryptic peptide maps of these five proteins. All calmodulins lacked tryptophan and cysteine and contained 1 mol of N epsilon-trimethyllysine and histidine per mol of protein. Bovine, porcine, rabbit, rat, and chicken brain calmodulins comigrated on polyacrylamide gels run under a variety of conditions in the presence and absence of denaturants. All brain calmodulins gave identical profiles for the calcium-dependent activation of "activatable" bovine brain 3',5'-cyclic nucleotide phosphodiesterase. In addition, they formed calcium-dependent complexes with rabbit skeletal muscle troponin I and the electrophoretic mobilities of the complexes were identical with one another and similar to the corresponding complex between troponin I and troponin C. These studies more fully define what is a calmodulin, demonstrate that calmodulin is a relatively invariant constituent of vertebrate brain, and indicate that calmodulin structure and function have been highly conserved throughout vertebrate evolution.

Studies on functional domains of the regulatory subunit of bovine heart adenosine 3':5'-monophosphate-dependent protein kinase

The functional domains of the regulatory subunit of isozyme II of cAMP-dependent protein kinase were studied. It was shown using Edman degradation that the regulatory subunit contained a phosphorylated residue which was very close in primary sequence to the site most sensitive to hydrolysis by low trypsin concentrations as postulated previously (Corbin, J.D., Sugden, P.H., West, L., Flockhart, D.A., Lincoln, T.M., and McCarthy, D. (1978) J. Biol. Chem. 253, 3997-4003). Catalytic subunit incorporated 0.9 mol of 32P from [gamma-32P]ATP into a preparation of regulatory subunit that contained 1.1 mol of endogenous phosphate. After phosphorylation by the catalytic subunit, the regulatory subunit contained 2.2 mol of chemical phosphate. The effects of heat denaturation upon the rate and extent of phosphorylation of the regulatory subunit were compared with the effects of these treatments upon the cAMP binding and inhibitory domains. These data suggested that the regulatory subunit required factors in addition to an intact phosphorylatable primary sequence in order for inhibitory activity to be expressed. Such factors might be part of the secondary or tertiary structure of the protein. These studies are discussed with respect to the mechanism of inhibition of catalytic activity, and a model of the regulatory subunit structure is proposed.

Rapid separation and quantitation of 3',5'-cyclic nucleotides and 5'-nucleotides in phosphodiesterase reaction mixtures using high-performance liquid chromatography

A simple, rapid high-performance liquid-chromatography system for the fractionation and direct quantitation of substrates and products in crude phosphodiesterase reaction mixtures is described. Phosphate buffers and a pellicular anion exchange resin are used at ambient temperature. The method is sensitive, measuring picomoles of products with ultraviolet detection and femtomoles with isotopic measurement, and offers several advantages over the more popular batch sorption and manual methods for measuring phosphodiesterase activity. The time required for analysis, less than 8 min for single substrate reaction mixtures, is a fraction of that required with other chromatographic systems, and precision is +/- 5%. Results of studies with an activatable form of phosphodiesterase demonstrate the accuracy, precision and utility of the procedure for biochemical analyses.