Activation of 3',5'-cyclic adenosine monophosphate phosphodiesterase by calcium ion and a protein activator.

3',5'-CAMP phosphodiesterase was partially purified from bovine cerebral cortex. A heat-stable activating factor was separated from the enzyme by chromatography on DEAE-cellulose. The enzyme in crude ammonium sulfate fractions was stimulated by 5 mM CaCl2. This stimulation was reversed by the calcium chelator EGTA. The main phosphodiesterase peak obtained by DEAE-cellulose chromatography was not stimulated by Ca2+. Upon addition of column effluent containing a heat stable factor, Ca2+ activation was restored. Protein activator was inactive when endogenous contaminating Ca2+ was complexed with EGTA. It was concluded that activation of phosphodiesterase requires the presence of both activator and Ca1+. From an analysis of activation of cGMP hydrolysis a kinetic model for the interaction of Ca2+ and protein activator with the phosphodiesterase was developed. Heterotropic cooperativity between the binding of Ca2+ and protein activator to the phosphodiesterase was observed, i.e., Ca1+ decreased the apparent dissociation constant for protein activator and protein activator decreased the apparent dissociation constant for Ca2+.     

Chemical modification studies on the Ca2+-dependent protein modulator: the role of methionine residues in the activation of cyclic nucleotide phosphodiesterase.

Methionine residues have been implicated in the activation of cyclic nucleotide phosphodiesterase by the Ca2+-dependent protein modulator [Walsh, M., & Stevens, F.C. (1977) Biochemistry 16,2742-2749]. Treatment of the modulator with N-chlorosuccinimide in the presence of Ca2+ resulted in selective oxidation of methionine residues at positions 71,72, 76, and, possibly, 109 in the modulator sequence. These residues lie on the surface of the molecule exposed to solvent. This modification has several effects on the modulator protein: (1) the Ca2+-binding properties of the oxidized modulator are changed with apparent loss of high-affinity binding sites, (2) the oxidized protein no longer interacts with phosphodiesterase, and (3) troponin C like activities, viz., Ca2+-dependent change in mobility on urea-polyacrylamide gel electrophoresis and formation of a urea-stable complex with troponin I, are lost upon oxidation of the modulator. The phosphodiesterase binding domain of the modulator protein appears to be located between the second and third Ca2+-binding loops, a region of the molecule known from previous partial proteolysis studies [Walsh, M., Stevens, F.C., Kuznicki, J., & Drabikowski, W.(1977), J. Biol. Chem. 252, 7440-7443] to be exposed in the presence of Ca2+.     

Metal binding and metal-induced conformational change of frog bone gamma-carboxyglutamic acid-containing protein

Ca2+ or Cd2+ binding and the conformational change induced by the metal binding in two frog bone Gla-proteins (BGP, termed BGP-1 and BGP-2) were studied by equilibrium dialysis and CD measurement. By CD measurement in the far-ultraviolet region, the alpha-helix content of both apoBGPs was found to be 8%. Binding of both Ca2+ and Cd2+ was accompanied with a change in the CD spectrum, and the alpha-helix content increased to 15 and 25% for BGP-1 and BGP-2, respectively. CD measurement in the near-ultraviolet region indicated that the environment of aromatic amino acid residues in the protein molecule was changed by metal binding. Equilibrium dialysis experiments indicated that each of these two protein binds specifically 2 mol of Ca2+, and nonspecifically an additional 3-4 mol of Ca2+ in 0.02 M Tris-HCl/0.15 M NaCl (pH 7.4), at 4 degrees C. According to the two separate binding sites model, BGP-1 has 1 high-affinity Ca2+ binding site (Kd1 = 0.17 mM) and 1 low-affinity site (Kd2 = 0.29 mM), and BGP-2 contains 1 high-affinity site (Kd1 = 0.14 mM) and 1 low-affinity site (Kd2 = 0.67 mM). In addition, 2 Cd2+ bound to a high-affinity binding site on BGP-1 with Kd1 of 10.4 microM, and 1 Cd2+ bound to a low-affinity binding site with Kd2 of 41.5 microM. On the other hand, BGP-2 had three classes of binding sites and 1 Cd2+ bound to each binding site with Kd1 = 3.6 microM, Kd2 = 16.3 microM, Kd3 = 51.7 microM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of gamma-carboxyglutamyl residues in the positive cooperative binding of Ca2+ to blood coagulation factor X

1. The calcium binding properties of factor X and its analogous decarboxyprotein have been compared with the aid of flow rate dialysis and ultraviolet difference spectroscopy. 2. Factor X binds approx. 20 mol of calcium per mol of protein. The first four sites exhibit positive cooperativity. 3. Changes in the ultraviolet difference spectrum when Ca2+ is bound suggest a conformational change. 4. In decarboxyfactor X low affinity of Ca2+ and no ligand-induced conformational change was observed. It is concluded that the presence of gamma-carboxyglutamate residues is a prerequisite for positive cooperative Ca2+ binding.     

Calcium-dependent alpha-helical structure in osteocalcin

Osteocalcin is an abundant Ca2+-binding protein of bone containing three residues of vitamin K dependent gamma-carboxyglutamic acid (Gla) among its 49 (human, monkey, cow) or 50 (chicken) amino acids. Gla side chains participate directly in the binding of Ca2+ ions and the adsorption of osteocalcin to hydroxylapatite (HA) surfaces in vivo and in vitro. Osteocalcin exhibits a major conformational change when Ca2+ is bound. Metal-free chicken osteocalcin is a random coil with only 8% of its residues in the alpha helix as revealed by circular dichroism. In the presence of physiological levels of Ca2+, 38% of the protein adopts the alpha-helical conformation with a transition midpoint at 0.75 mM Ca2+ in a rapid, reversible fashion which (1) requires an intact disulfide bridge, (2) is proportionally diminished when Gla residues are decarboxylated to Glu, (3) is insensitive to 1.5 m NaCl, and (4) can be mimicked by other cations. Tyr fluorescence, UV difference spectra, and Tyr reactivity to tetranitromethane corroborate the conformational change. Homologous monkey osteocalcin also exhibits Ca2+-dependent structure. Integration of predictive calculations from osteocalcin sequence has yielded a structural model for the protein, the dominant features of which include two opposing alpha-helical domains of 9-12 residues each, connected by a bea turn and stabilized by the Cys23-Cys29 disulfide bond. Cation binding permits realization of the full alph a-helical potential by partial neutralization of high anionic charge in the helical domains. Periodic Gla occurrence at positions 17, 21, and 24 has been strongly conserved throughout evolution and places all Gla side chains on the same face of one alpha helix spaced at intervals of approximately 5.4 A, closely paralleling the interatomic separation of Ca2+ in the HA lattice. Helical osteocalcin has greatly increased affinity for HA; thus, the Ca2+-induced structural transition may perform an informational role related to bone metabolism.     

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)     

Purification and characterization of a Ca2+-binding protein in Lumbricus terrestris.

A Ca2+-binding protein which is capable of activating mammalian Ca2+-activatable cyclic nucleotide phosphodiesterase has been purified from Lumbricus terrestris and characterized. This protein and the Ca2+-dependent protein modulator from bovine tissues have many similar properties. Both proteins have molecular weights of approximately 18,000, isoelectric points of about pH 4, similar and characteristic ultraviolet spectra, and similar amino acid compositions. Both proteins bind calcium ions with high affinity. However, the protein from Lumbricus terrestris binds 2 mol of calcium ions with equal affinity, Kdiss = 6 X 10(-6) M, whereas the Ca2+-dependent protein modulator from bovine tissues binds 4 mol of calcium ions with differing affinities. Although the Ca2+-binding protein of Lumbricus terrestris activates the Ca2+-activatable cyclic nucleotide phosphodiesterase from mammalian tissues, we have failed to detect the existence of a Ca2+-activatable phosphodiesterase activity in Lumbricus terrestris. The activation of phosphodiesterase by the Ca2+-binding protein from Lumbricus terrestris is inhibited by the recently discovered bovine brain modulator binding protein (Wang, J. H., and Desai, R. (1977) J. Biol. Chem. 252, 4175-4184). Since the modulator binding protein has been shown to associate with the mammalian protein modulator to result in phosphodiesterase inhibition, it can be concluded that the Lumbricus terrestris Ca2+-binding protein also associates with the bovine brain modulator binding protein. Attempts to demonstrate the existence of a similar modulator binding protein in Lumbricus terrestris have been unsuccessful.     

Circular dichroism studies of native and chemically modified Ca2+-dependent protein modulator.

The structural features of the native Ca2+-dependent protein modulator and two chemically modified derivatives, namely, nitrotyrosyl modulator and alkylated modulator, were examined by circular dichroism. The binding of Ca2+ to the native molecule was accompanied by an increase in helical content from 40 to 49%, with little effect on the local environments of aromatic residues in the modulator. The Mg2+ and Mn2+ do not elicit the conformational change induced by the binding of Ca2+, which also stabilizes the modulator against urea denaturation. The overall secondary structure of nitrotyrosyl modulator is indistinguishable from that of the native protein and undergoes a similar conformational change upon binding Ca2+. These observations are in agreement with the fact that nitration has no effect on modulator functions. Furthermore, nitrotyrosyl modulator interacts with troponin I only in the presence of Ca2+, as detected by circular dichroism (cd). On the other hand, alkylation of five methionine residues on the modulator with benzyl bromide affects protein conformation, as evidenced by a reduced helical content of only 35%. Alkylated modulator retains the ability of the native protein to bind Ca2+ although the affinity of this derivative for Ca2+ is reduced some three orders of magnitude relative to the native protein, with Kd = 3.2 X 10(-4) M. The results with the alkylated modulator, in conjunction with previous cd studies on N-chlorosuccinimide oxidized modulator are utilized to advance a model for the Ca2+ activation of modulator protein, based on three conformational states of the molecule.     

Physicochemical properties of a novel Mr-21 000 Ca2+-binding protein of bovine brain.

The physicochemical properties of a novel Mr-21 000 Ca2+-binding protein isolated from bovine brain were investigated. The protein exhibited a partial specific volume of 0.724 ml/g, a degree of hydration of 0.47 g of water/g of protein and a mean residue weight of 119. Sedimentation equilibrium analysis revealed Mr = 22 600 in the absence of Ca2+; Ca2+ binding appeared to induce dimerization of the molecule. Size-exclusion chromatography indicated a compacting of the molecule on binding of Ca2+: the Stokes radius decreased from 2.75 nm in the absence of Ca2+ to 2.56 nm in its presence. Far-u.v.c.d. spectroscopy showed the apoprotein to be composed of 44% alpha-helix, 18% beta-pleated sheet and 38% random coil. Addition of either KCl (0.1 M) plus Mg2+ (1 mM), or Ca2+ (2 mM), changed the conformation to 49% alpha-helix, 18% beta-pleated sheet and 33% random coil. Near-u.v.c.d. and u.v. difference spectroscopy both indicated perturbations in the environments of all three types of aromatic amino acids on binding of Ca2+. Ca2+ binding also resulted in a 30% enhancement in the tryptophan fluorescence emission intensity. Ca2+ titration of the far-u.v.c.d. and fluorescence enhancement provided KD values of 9.91 microM and 4.68 microM respectively. Finally, the protein was shown to bind Zn2+ with KD = 1.44 microM (no Mg2+) and 1.82 microM (+ Mg2+). These observations strongly support the possibility that this novel Ca2+-binding protein resembles calmodulin and related Ca2+-binding proteins and undergoes a conformational change on binding of Ca2+ which reflects a physiological role in Ca2+-mediated regulation of brain function.     

Cyclic 3':5'-nucleotide phosphodiesterase. Ca2+ confers more helical conformation to the protein activator.

The ultraviolet spectrum of a protein activator of cyclic nucleotide phosphodiesterase and adenylate cyclase purified to homogeneity from bovine brain displayed absorption peaks at 252, 259, 265, 269, and 277 nm. The activator contained no phosphate and did not serve as a substrate for cyclic adenosine 3':5'-monophosphate- or cyclic guanosine 3':5'-monophosphate-dependent protein kinases. The activator binds Ca2+, and the active form appears to be a Ca2+ activator complex (Lin, Y.M., Liu, Y.P., and Cheung, W.Y. (1974) J. Biol. Chem. 249, 4943-4954). Optical rotatory dispersion measurement showed that the Ca2+-free activator exhibited a reduced mean residue rotation ([m']231) of -5700, corresponding to 39% of helical content. In the presence of Ca2+, the [m']231 was increased to -7500, corresponding to 57% of helical content. The Ca2+ -induced conformational change was corroborated by a chemical method. In the presence of Ca2+, the activator was more resistant to trypsin inactivation, presumably because proteins with more helical structures are more resistant to tryptic attack. The activator is rich in aspartate and glutamate. Chemical block of some of the carboxyl groups with glycine ethyl ester or methoxyamine diminished the [m']231 of the activator and its activity, suggesting that blockade of some of the carboxyl groups in the activator unfolded the molecule, leading to a loss of activity. We conclude that Ca2+, which confers more helical structure to the activator, converts the inactive, less helical structure to the active, more helical structure, and that chemical modification of the activator leading to unfolding of the molecule abolishes its biological activity.     

4Ca2+.troponin C forms dimers in solution at neutral pH that dissociate upon binding various peptides: small-angle X-ray scattering studies of peptide-induced structural changes.

Small-angle X-ray scattering data have been measured for rabbit skeletal muscle troponin C and its complexes with the venom peptides melittin and mastoparan as well as synthetic peptides based on regions of the troponin I sequence implicated in troponin C binding. At the neutral pH used in this study (pH 6.8), troponin C shows a tendency to form dimers in the presence of 4 mol equiv of Ca2+, but is monomeric in solution when 2 or less mol equiv of Ca2+ is present. The 4Ca2+.troponin C dimers dissociate upon binding melittin, mastoparan, and peptides based on residues 96-115, 1-30, and 1-40 in the troponin I sequence. This result suggests that the peptide-binding sites overlap with the regions of contact between troponin C molecules forming a dimer. Like the structurally homologous calcium-binding protein calmodulin, troponin C shows conformational flexibility upon binding different peptides. Upon binding melittin, troponin C contracts in a similar manner to calmodulin when it binds peptides known to form amphiphilic helices (e.g., melittin, mastoparan, or MLCK-I). In contrast, mastoparan binding to troponin C does not result in a contracted structure. The scattering data indicate troponin C also remains in an extended structure upon binding the inhibitory peptides having the same sequence as residues 96-115 in troponin I.     

Purification and characterization of a novel 12,000-Da calcium binding protein from smooth muscle.

A new low molecular weight calcium binding protein, designated 12-kDa CaBP, has been isolated from chicken gizzard using a phenyl-Sepharose affinity column followed by ion-exchange and gel filtration chromatographies. The isolated protein was homogeneous and has a molecular weight of 12,000 based on sodium dodecyl sulfate-gel electrophoresis. The amino acid composition of this protein is similar to but distinct from other known low molecular weight Ca2+ binding proteins. Ca2+ binding assays using Arsenazo III (Sigma) indicated that the protein binds 1 mol of Ca2+/mol of protein. The 12-kDa CaBP underwent a conformational change upon binding Ca2+, as revealed by uv difference spectroscopy and circular dichroism studies in the aromatic and far-ultraviolet range. Addition of Ca2+ to the 12-kDa CaBP labeled with 2-p-toluidinylnaphthalene-6-sulfonate (TNS) resulted in a sevenfold increase in fluorescence intensity, accompanied by a blue shift of the emission maximum from 463 to 445 nm. Hence, the probe in the presence of Ca2+ moves to a more nonpolar microenvironment. Like calmodulin and other related Ca2+ binding proteins, this protein also exposes a hydrophobic site upon binding calcium. Fluorescence titration with Ca2+ using TNS-labeled protein revealed the presence of a single high affinity calcium binding site (kd approximately 1 x 10(-6) M).     

Expression of calreticulin in Escherichia coli and identification of its Ca2+ binding domains

Recombinant calreticulin and discrete domains of calreticulin were expressed in Escherichia coli, using the glutathione S-transferase fusion protein system, and their Ca2+ binding properties were determined. Native calreticulin bound 1 mol of Ca2+/mol of protein with high affinity, and also bound approximately 20 mol of Ca2+/mol of protein with low affinity. Both Ca2+ binding sites were present in the recombinant calreticulin indicating that proper folding of the protein was achieved using this system. Calreticulin is structurally divided into three distinct domains: the N-domain encompassing the first 200 residues; the P-domain which is enriched in proline residues (residue 187-317); and the C-domain which covers the carboxyl-terminal quarter of the protein (residues 310-401), and contains a high concentration of acidic residues. These domains were expressed in E. coli, isolated, and purified, and their Ca2+ binding properties were analyzed. The C-domain bound approximately 18 mol of Ca2+/mol of protein with a dissociation constant of approximately 2 mM. The P-domain bound approximately 0.6-1 mol of Ca2+/mol of protein with a dissociation constant of approximately 10 microM. The P-domain and the C-domain, when expressed together as the P+C-domain, bound Ca2+ with both high affinity and low affinity, reminiscent of both full length recombinant calreticulin and native calreticulin. In contrast the N-domain, did not bind any detectable amount of 45Ca2+. We conclude that calreticulin has two quite distinct types of Ca2+ binding sites, and that these sites are in different structural regions of the molecule. The P-domain binds Ca2+ with high affinity and low capacity, whereas the C-domain binds Ca2+ with low affinity and high capacity.     

Identification of an activator protein for myosin light chain kinase as the Ca2+-dependent modulator protein

Myosin light chain kinase which phosphorylates g2 light chain of skeletal muscle myosin requires an activator for the activity (Yazawa, M., and Yagi, K (1977) J. Biochem. (Tokyo) 82, 287-289). This activator has now been identified as the modulator protein known to be a Ca2+-dependent regulator for phosphodiesterase, adenylate cyclase, and ATPases. The identification is based on the quantitative cross-reactivity of muscle activator protein and brain modulator protein in activating myosin light chain kinase and brain phosphodiesterase and identical properties of both proteins in regard to sensitivities to Ca2+, UV absorption spectra, UV absorption difference spectra with or without Ca2+, and mobilities upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In the presence of modulator protein, the activity of myosin light chain kinase was reversibly controlled by the physiological concentration of Ca2+. We suggest that two Ca2+-receptive proteins, i.e. modulator protein and troponin-C, may play roles in the contraction-relaxation cycle of skeletal muscle.     

Using protein design to dissect the effect of charged residues on metal binding and protein stability

Ca2+ controls biological processes by interacting with proteins with different affinities, which are largely influenced by the electrostatic interaction from the local negatively charged ligand residues in the coordination sphere. We have developed a general strategy for rationally designing stable Ca2+- and Ln3+-binding proteins that retain the native folding of the host protein. Domain 1 of cluster differentiation 2 (CD2) is the host for the two designed proteins in this study. We investigate the effect of local charge on Ca2+-binding affinity based on the folding properties and metal-binding affinities of the two proteins that have similarly located Ca2+-binding sites with two shared ligand positions. While mutation and Ca2+ binding do not alter the native structure of the protein, Ca2+ binding specifically induced changes around the designed Ca2+-binding site. The designed protein with a -5 charge at the binding sphere displays a 14-, 20-, and 12-fold increase in the binding affinity for Ca2+, Tb3+, and La3+, respectively, compared to the designed protein with a -3 charge, which suggests that higher local charges are preferred for both Ca2+ and Ln3+ binding. The localized charged residues significantly decrease the thermal stability of the designed protein with a -5 charge, which has a T(m) of 41 degrees C. Wild-type CD2 has a T(m) of 61 degrees C, which is similar to the designed protein with a -3 charge. This decrease is partially restored by Ca2+ binding. The effect on the protein stability is modulated by the environment and the secondary structure locations of the charged mutations. Our study demonstrates the capability and power of protein design in unveiling key determinants to Ca2+-binding affinity without the complexities of the global conformational changes, cooperativity, and multibinding process found in most natural Ca2+-binding proteins.     

Thermodynamic changes in the binding of Ca2+ to a mutant human lysozyme (D86/92). Enthalpy-entropy compensation observed upon Ca2+ binding to proteins.

The thermodynamic change in the binding of Ca2+ to a mutant human lysozyme having an engineered Ca2+ binding site (Kuroki, R., Taniyama, Y., Seko, C., Nakamura, H., Kikuchi, M., and Ikehara, M. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 6903-6907) was analyzed by calorimetry and interpreted in terms of structural information obtained from x-ray crystallography. It was found that the enthalpic contribution for the Ca2+ binding reaction was small, driven primarily by entropy release (10 kcal/mol). This release of entropy was also observed in some organic chelators. Moreover, through the information of the tertiary structures of the apo- and holomutant lysozyme, it was confirmed that the entropy release (10 kcal/mol) upon the binding of Ca2+ arises primarily from the release of bound water molecules hydrating the free Ca2+. Previous studies of Ca2+ binding to proteins have involved significant changes in protein conformation. They can now be reevaluated to determine the contribution of conformational changes to Ca2+ binding. After removing the thermodynamic contribution of Ca2+ binding itself, it is found that upon the binding of Ca2+ the enthalpy change is negative but is almost compensated by the negative entropy change. The negative change in both enthalpy and entropy is characteristic of values seen in the thermodynamic change upon the folding of proteins.     

Calcium-induced conformational changes in Leishmania infantum kinetoplastid membrane protein-11

Total-reflection X-ray fluorescence has been used to study whether the Leishmania infantum kinetoplastid membrane protein-11 is a Ca2+-binding protein. The 108 amino acid helix-loop-helix protein has the loop region located between residues 45 and 57, having similarity to the EF-hand motifs. In particular, the sequence alignment of the putative motif revealed the existence of 67% similarity and 33% identity with the EF-hand of the plasmodia-specific 40-kDa protein from Physarum polycephalum. To address the type of conformational changes induced by Ca2+ binding, circular dichroism and fluorescence spectroscopy were used. The data showed that Ca2+ induces changes in both the secondary and tertiary structure of the protein in a temperature- and pH-dependent way. It also induces the precipitation of the protein at pH 7.5, in contrast with what occurs at pH 5.0, and the precipitation process can be reverted by addition of EGTA. At acidic pH values the complex EGTA-Ca2+ causes drastic structural changes, forcing the protein to adopt a structure close to that of a random coil. Because, at acidic pH values, protein:Ca2+:EGTA ternary complexes may be formed, the drastic change may be attributed to the presence of a high density of EGTA negative charges in the neighborhood of the alpha-helices.     

Purification of cyclic 3',5'-nucleotide phosphodiesterase inhibitory protein by affinity chromatography on activator protein coupled to Sepharose.

The Ca2+-dependent, reversible, interaction of cyclic adenosine 3',5'-monophosphate (cAMP) phosphodiesterase with its activator has been used to purify the enzyme by affinity chromatography. Activator-dependent cAMP phosphodiesterase is only a minor component of the proteins specifically adsorbed in the presence of Ca2+ by the Ca2+-dependent activator protein coupled to Sepharose and subsequently released by [ethylenebis(oxyethylenenitrilo)]tetraacetic acid. The major protein component can be partially resolved from the enzyme by gel filtration on Sephadex G-200. This protein has been purified to apparent homogeneity and shown to be composed of two polypeptide chains with molecular weights of 61,000 and 15,000 respectively. This protein is, by itself, devoid of phosphodiesterase activity and inhibits the activation of cAMP phosphodiesterase by its activator without affecting the basal activity. Thus, activation of cAMP phosphodiesteriase by the Ca2+-dependent activator protein may be controlled by interactions with yet a third component of the enzyme complex.     

Rational design of a conformation-switchable Ca2+- and Tb3+-binding protein without the use of multiple coupled metal-binding sites

Ca2+, as a messenger of signal transduction, regulates numerous target molecules via Ca2+-induced conformational changes. Investigation into the determinants for Ca2+-induced conformational change is often impeded by cooperativity between multiple metal-binding sites or protein oligomerization in naturally occurring proteins. To dissect the relative contributions of key determinants for Ca2+-dependent conformational changes, we report the design of a single-site Ca2+-binding protein (CD2.trigger) created by altering charged residues at an electrostatically sensitive location on the surface of the host protein rat Cluster of Differentiation 2 (CD2).CD2.trigger binds to Tb3+ and Ca2+ with dissociation constants of 0.3 +/- 0.1 and 90 +/- 25 microM, respectively. This protein is largely unfolded in the absence of metal ions at physiological pH, but Tb3+ or Ca2+ binding results in folding of the native-like conformation. Neutralization of the charged coordination residues, either by mutation or protonation, similarly induces folding of the protein. The control of a major conformational change by a single Ca2+ ion, achieved on a protein designed without reliance on sequence similarity to known Ca2+-dependent proteins and coupled metal-binding sites, represents an important step in the design of trigger proteins.     

Characterization of fodrin phosphorylation by spleen protein tyrosine kinase

Fodrin, an actin and calmodulin binding and spectrin-like protein present in many nonerythrocyte tissues, could be phosphorylated up to more than 1.5 mol of phosphate/mol of protein by a highly purified non-receptor-associated protein tyrosine kinase from bovine spleen. The protein phosphorylation was not affected by Ca2+/calmodulin or by F-actin. Km and Vmax values of the reaction were 91 nM and 0.35 nmol of P2 min-1 (mg of kinase)-1, respectively. Both subunits A and B of fodrin were phosphorylated, with the rate of subunit A phosphorylation much greater than that of subunit B phosphorylation. Tryptic phosphopeptide mapping of the phosphorylated subunits suggested that there were three major phosphorylation sites in subunit A and one in subunit B. Phosphotyrosylfodrin could be dephosphorylated by the calmodulin-stimulated phosphatase (calcineurin) in the presence of activating metal ions; Ni2+ was a much more effective activator than Mn2+ for this reaction. Fodrin phosphorylation by the spleen protein tyrosine kinase did not appear to alter the actin and calmodulin binding properties of the protein. On the other hand, the calmodulin-dependent stimulation of smooth muscle actomyosin Mg2+-ATPase by fodrin was enhanced by 101% +/- 3% (n = 3) upon fodrin phosphorylation. Ni2+-calcineurin, which was shown to effectively dephosphorylate the phosphotyrosyl residues on fodrin, could reverse the phosphorylation-enhanced Mg2+-ATPase stimulatory activity of fodrin.