The calmodulin-binding site of the plasma membrane Ca2+ pump interacts with the transduction domain of the enzyme.

Calpain proteolysis of the plasma membrane Ca2+ pump removes a C-terminal 14-kDa portion which includes the calmodulin-binding domain. This produces a fully activated 124-kDa fragment, which can be inhibited by synthetic versions of the calmodulin-binding domain. The inhibition is strongest when Trp-8 in the latter domain is replaced by a Tyr residue (Falchetto, R., Vorherr, T., Brunner, J., & Carafoli, E., 1991, J. Biol. Chem. 266, 2930-2936). In the present study, the N-terminus of the 28-residue synthetic calmodulin-binding domain was acetylated with 3H-acetic anhydride, and Phe in position 25 was replaced by a phenylalanine derivatized with a diazirine-based, photoactivatable carbene precursor. This peptide (C28WC*) inhibited the fully active 124-kDa fragment of the pump and became cross-linked to it upon photolysis. After proteolysis of the fragment with Asp-N or Staphylococcus aureus V8 (Glu-C) protease, labeled peptides were isolated by reversed-phase high-performance liquid chromatography and subjected to Edman sequence analysis. The peptides originated from a region of the pump located within the unit protruding into the cytoplasm between transmembrane domain two and three. This unit has been proposed to be the site of the energy transduction domain, which would couple the ATP hydrolysis to Ca2+ translocation.     

The calmodulin-binding domain mediates the self-association of the plasma membrane Ca2+ pump.

Dimerization (oligomerization) of the plasma membrane Ca2+ pump increases its activity (Kosk-Kosicka, D., Bzdega, T., and Wawrzynow, A. (1989) J. Biol. Chem. 264, 19495-19499). Fluorescence titration on preparations of the purified eosin-labeled human erythrocyte ATPase has been used to monitor the oligomerization process. Calmodulin inhibits oligomerization, although it can bind to the oligomerized enzyme. Synthetic peptides corresponding to the calmodulin-binding domain of the pump stimulate its ATPase activity, indicating the formation of heterooligomers of the peptides with the pump. The oligomerization is prevented by the preincubation of the ATPase with calmodulin. Polyclonal antibodies against the synthetic calmodulin-binding domain inhibit its basal and its calmodulin-stimulated ATPase activity and prevent the formation of the oligomers. ATPase preparations truncated at the COOH terminus with calpain to a fragment of 124 kDa which does not contain the calmodulin-binding domain fail to oligomerize with the intact ATPase. The results show that the calmodulin-binding domain mediates the oligomerization of the Ca2+ pump.     

Functional domains of chicken gizzard myosin light chain kinase

The proteolytic susceptibility of chicken gizzard myosin light chain kinase, a calmodulin-dependent enzyme, has been utilized to define the relative location of the catalytic and regulatory domains of the enzyme. Myosin light chain kinase isolated from this source exhibits a Mr of 130,000 and is extremely sensitive to trypsin at 24 degrees C; however, the molecule is divided into susceptible and resistant domains such that proteolysis proceeds rapidly and at multiple sites in the sensitive regions even at 4 degrees C while the rest of the molecule remains relatively resistant to digestion. One of these sensitive areas is the calmodulin-binding domain. On the other hand, Staphylococcus aureus V8 protease digestion generates a calmodulin-binding fragment (Mr = 70,000) that retains Ca2+/calmodulin-dependent enzymatic activity and both of the phosphorylation sites recognized by cAMP-dependent protein kinase. In contrast, treatment with chymotrypsin produces a 95,000 Mr calmodulin-binding fragment that contains only the calmodulin-modulated phosphorylation site. Sequential proteolytic digestion studies demonstrated that the chymotryptic cleavage site responsible for the generation of this 95,000 Mr peptide is within 3,000 Mr of the V8 protease site which produces the 70,000 Mr fragment. Moreover, the non-calmodulin-modulated phosphorylation site must exist in this 3,000 Mr region. A calmodulin-Sepharose affinity adsorption protocol was developed for the digestion and used to isolate both the 70,000 and 95,000 Mr fragments for further study. Taken together, our results are compatible with a model for chicken gizzard myosin light chain kinase in which there is no overlap between the active site, the calmodulin-binding region, and the two sites phosphorylated by cAMP-dependent protein kinase with regard to their relative position in the primary sequence of the molecule.     

The calmodulin binding domain of the plasma membrane Ca2+ pump interacts both with calmodulin and with another part of the pump

Synthetic peptides corresponding to the calmodulin-binding domain of the human erythrocyte Ca2+ pump were prepared representing residues 2-29 (C28W), 2-21 (C20W), 2-16 (C15W), and 16-29 (C14) of the sequence (James, P., Maeda, M., Fisher, R., Verma, A. K., Krebs, J., Penniston, J. T., and Carafoli, E. (1988) J. Biol. Chem. 263, 2905-2910). Peptides C28W, C20W, and C15W bound to calmodulin with an apparent 1:1 stoichiometry in the presence of Ca2+ and inhibited the activation of the Ca2+ pump by calmodulin, while C14 was ineffective. Substituting tyrosine (C28Y) or alanine (C28A) for the tryptophan residue lowered the affinity for calmodulin. The estimated Kd values for the calmodulin-peptide complexes were 0.1 nM for C28W, 5-15 nM for C20W, C28Y, and C28A, and 700-1700 nM for C15W. The Ca2+ pump in inside-out erythrocyte membrane vesicles was activated by proteolytic removal of the endogenous calmodulin-binding domain. Addition of C20W or C28W then inhibited calmodulin-independent Ca2+ transport, while a calmodulin-binding peptide from another enzyme had no effect. The inhibition of the pump by C20W was purely competitive with Ca2+, while C28W decreased the Vmax and increased the K1/2 for Ca2+, restoring the pump activity nearly to its low basal level. The results suggest that a calmodulin-binding peptide from any enzyme has two kinds of specificity: it shares with peptides from other enzymes the ability to bind to calmodulin, but only it has the specificity to interact with its own (proteolytically activated) enzyme.     

Protein kinase C phosphorylates the carboxyl terminus of the plasma membrane Ca(2+)-ATPase from human erythrocytes.

Purified Ca(2+)-stimulated, Mg(2+)-dependent ATPase (Ca(2+)-ATPase) from human erythrocytes was phosphorylated with a stoichiometry of about 1 mol of phosphate/mol of ATPase at both threonine and serine residues by purified rat brain type III protein kinase C. In the presence of calmodulin, the phosphorylation was markedly reduced. Labeled phosphate from [gamma-32P]ATP was retained on an 86-kDa calmodulin-binding tryptic fragment of Ca(2+)-ATPase but not on 82- and 77-kDa non-calmodulin-binding fragments. Similarly, fragmentation of the phosphorylated Ca(2+)-ATPase by calpain I revealed that calmodulin-binding fragments (127 and 125 kDa) retained phosphate label whereas a non-calmodulin-binding fragment (124 kDa) did not. The calmodulin-binding domain, located about 12 kDa from the carboxyl terminus of the Ca(2+)-ATPase, was thus located as a site of protein kinase C phosphorylation. A synthetic peptide corresponding to a segment of the calmodulin-binding domain (H2 N-R-G-L-N-R-I-Q-T-Q-I-K-V-V-N-COOH) was indeed phosphorylated at the single threonine residue within this sequence. The additional serine phosphorylation site was carboxyl terminal to the calmodulin domain. Phosphorylation by purified type III protein kinase C (canine heart) antagonized the calmodulin activation of the Ca(2+)-ATPase, particularly at lower Ca2+ concentrations (0.2-1.0 microM). By contrast, a purified but unresolved protein kinase C isoenzyme mixture from rat brain stimulated the activity of Ca(2+)-ATPase prepared in asolectin, but not glycerol, by more than 2-fold in the presence of the ionophore A23187, without increasing its Ca2+ sensitivity. The results clearly indicate that human erythrocyte Ca(2+)-ATPase is a substrate of protein kinase C, but the effect of phosphorylation on the activity of the enzyme depends on the isoenzyme form of protein kinase C used and on the lipid associated with the Ca(2+)-ATPase.     

Calmodulin-binding domains from isozymes of the plasma membrane Ca2+ pump have different regulatory properties.

Peptides C28R2 and C28R1A, representing the two main alternative classes of calmodulin-binding domains from the plasma membrane Ca2+ pump, were tested for their calmodulin-binding properties and for their capacity to interact with pump from which the calmodulin-binding domain had been removed by chymotryptic proteolysis. Peptide C28R2 was more effective in both capacities. Binding of peptide to calmodulin was measured by competition experiments. Such experiments indicated that Ki for C28R2 as an inhibitor of the pump-calmodulin interaction was 0.1 nM, whereas C28R1A had a Ki of 1 nM. Interaction of peptide with chymotryptically activated Ca2+ pump was measured by observing the inhibition by peptide of active Ca2+ transport into inside-out membrane vesicles at low Ca2+. Those experiments showed that C28R2 interacted relatively strongly (an IC50 of 1 microM), whereas C28R1A had an IC50 of 15 microM. The calmodulin-binding peptides had effects on both the K1/2 for Ca2+ and the Vmax of the proteolyzed pump. The effects on the K1/2 for Ca2+ were related to the net plus charge on the peptide, with the most positive peptides being most effective in competing with Ca2+. The substantial differences between C28R2 and C28R1A suggest that Ca2+ pumps containing calmodulin-binding domains like C28R1A have lower calmodulin affinities and higher activities in the absence of activator.     

Small-angle X-ray scattering study of calmodulin bound to two peptides corresponding to parts of the calmodulin-binding domain of the plasma membrane Ca2+ pump.

The interaction between calmodulin (CaM) and two synthetic peptides, C20W and C24W, corresponding to parts of the calmodulin-binding domain of the Ca2+ pump of human erythrocytes, has been studied by using small-angle X-ray scattering (SAXS). The total length of the CaM-binding domain of the enzyme is estimated to be 28 amino acids. C20W contains the 20 N-terminal amino acids of this domain, C24W the 24 C-terminal amino acids. The experiments have shown that the binding of either peptide results in a complex with a radius of gyration (Rg) smaller than that of CaM. The complex between CaM and C20W revealed an interatomic length distribution function, P(r), similar to that of calmodulin alone, indicating that the complex retains an extended, dumbbell-shaped structure. By contrast, the binding of C24W resulted in the formation of a globular structure similar to those observed with many other CaM-binding peptides.     

Photoaffinity labeling study of the interaction of calmodulin with the plasma membrane Ca2+ pump.

Bovine brain calmodulin was labeled with synthetic peptides corresponding to the calmodulin-binding domain of the erythrocyte plasma membrane Ca(2+)-ATPase. One 20-amino acid peptide and two 28-amino acid peptides were used, carrying L-4'-(1-azi-2,2,2-trifluoroethyl)phenylalanine residues in position 9 (peptides C20W* and C28W*) and position 25 (peptide C28WC*), respectively. The localization of the contact regions between calmodulin and the N- and C-terminal portions of the peptides was the aim of this study. The three peptides were N-terminally blocked with a 3H-labeled acetyl group to facilitate the identification of labeled fragments after isolation and digestion. The binding site for phenylalanine 25 was identified in the N-terminal domain of calmodulin while the phenylalanine derivative in position 9 labeled the C-terminal domain. Fluorescence studies using the dansylated N- and C-terminal halves of calmodulin and peptide C20W corresponding to the first 20 amino acids of the calmodulin-binding domain showed that only the C-terminal lobe of calmodulin had high affinity for the peptide (KD in the nanomolar range).     

Calmodulin-binding sites on adenylyl cyclase type VIII

Ca2+ stimulation of adenylyl cyclase type VIII (ACVIII) occurs through loosely bound calmodulin. However, where calmodulin binds in ACVIII and how the binding activates this cyclase have not yet been investigated. We have located two putative calmodulin-binding sites in ACVIII. One site is located at the N terminus as revealed by overlay assays; the other is located at the C terminus, as indicated by mutagenesis studies. Both of these calmodulin-binding sites were confirmed by synthetic peptide studies. The N-terminal site has the typical motif of a Ca2+-dependent calmodulin-binding domain, which is defined by a characteristic pattern of hydrophobic amino acids, basic and aromatic amino acids, and a tendency to form amphipathic alpha-helix structures. Functional, mutagenesis studies suggest that this binding makes a minor contribution to the Ca2+ stimulation of ACVIII activity, although it might be involved in calmodulin trapping by ACVIII. The primary structure of the C-terminal site resembles another calmodulin-binding motif, the so-called IQ motif, which is commonly Ca2+-independent. Mutagenesis and functional assays indicate that this latter site is a calcium-dependent calmodulin-binding site, which is largely responsible for the Ca2+ stimulation of ACVIII. Removal of this latter calmodulin-binding region from ACVIII results in a hyperactivated enzyme state and a loss of Ca2+ sensitivity. Thus, Ca2+/calmodulin regulation of ACVIII may be through a disinhibitory mechanism, as is the case for a number of other targets of Ca2+/calmodulin.     

Identification of two domains which mediate the binding of activating phospholipids to the plasma-membrane Ca2+ pump.

The stimulation of the purified human erythrocyte calcium pump by acidic phospholipids was investigated using synthetic peptides corresponding to a putative phospholipid-responsive domain [Zvaritch, E., James, P., Vorherr, T., Falchetto, R., Modyanov, N. & Carafoli, E. (1990) Biochemistry 29, 8070-8076] and to the calmodulin-binding domain of the pump. The peptides interfered with the activation of the enzyme by phosphatidylserine and phosphatidic acid in competition assays. The peptide corresponding to the calmodulin-binding domain was found to be the most efficient antagonist. Direct binding measurements using fluorescent derivatives of the peptides confirmed the interaction between the acidic phospholipids and the peptides, and fluorescence titrations of dansylated calmodulin with the purified ATPase showed a direct effect of acidic phospholipids on calmodulin binding. A proteolyzed preparation of the Ca(2+)-ATPase lacking the calmodulin-binding domain confirmed that the phospholipid-induced stimulation is mediated by two sites, one located in the C-terminal portion of the previously identified 44-amino-acid phospholipid-responsive domain, the other in the calmodulin-binding domain.     

A model for the activation of plasma membrane calcium pump isoform 4b by calmodulin

Overexpression of the plasma membrane calcium pump (PMCA) isoform 4b by means of the baculovirus system enabled us, for the first time, to study the kinetics of calmodulin binding to this pump. This was done by stopped-flow fluorescence measurements using 2-chloro-(amino-Lys(75))-[6-[4-(N,N-diethylamino)phenyl]-1,3,5-triazin-4-yl]calmodulin (TA-calmodulin). Upon mixing with PMCA, the fluorescence of TA-calmodulin changed along a biphasic curve: a rapid and small increase in fluorescence was followed by a slow and large decrease that lasted about 100 s. The experiment was done at several PMCA concentrations. Global fitting nonlinear regression analysis of these results led to a model in which PMCA is present in two forms: a closed conformation and an open conformation. Calmodulin reacts with both conformations but reacts faster and with higher affinity for the open conformation. Measurements of the ATPase activity of PMCA under similar conditions revealed that the open form has higher ATPase activity than the closed one. Contrasting with the reaction with the whole pump, TA-calmodulin reacted rapidly (in about 2 s) with a calmodulin-binding peptide made after the sequence of the calmodulin-binding domain of PMCA (C28). Results of TA-calmodulin binding to C28 are explained by a simpler model, in which only an open conformation exists.     

The calmodulin-binding domain as an endogenous inhibitor of the p-nitrophenylphosphatase activity of the Ca2+ pump from human red cells.

Digestion of red cell membranes with chymotrypsin elicited p-nitrophenylphosphatase activity. During digestion, the p-nitrophenylphosphatase appeared in parallel with the activation of the Ca(2+)-ATPase (in the absence of calmodulin). The chymotrypsin-activated p-nitrophenylphosphatase was inhibited by C20W, a 20 amino acid peptide modelled after the sequence of the calmodulin-binding site of the red cell Ca2+ pump (Vorherr et al. (1990) Biochemistry 29, 355-365). On the contrary, the (ATP + Ca(2+)-dependent p-nitrophenylphosphatase activity of intact red cell membranes was not affected by C20W. Ca2+ inhibited the chymotrypsin-induced p-nitrophenylphosphatase (Ki for Ca2+ = 2 microM). In the absence of ATP, C20W and Ca2+ did not interact in apparent affinity as inhibitors of this activity. On the other hand, in the presence of 2 mM ATP, Ca2+ antagonized the inhibition produced by C20W. The results are consistent with the idea that the calmodulin-binding site is an 'autoinhibitory domain' of the Ca2+ pump, and that removal of this domain by proteolysis, or its modification by calmodulin binding is the reason for the activation of both the ATPase and the p-nitrophenylphosphatase activity of the pump. The results presented in this paper give new information about the mechanism of the two kinds of p-nitrophenylphosphatase and about the nature of the apparent competition between C20W and Ca2+.     

Phosphorylation-regulated calmodulin binding to a prominent cellular substrate for protein kinase C

We have evaluated the possibility that a major, abundant cellular substrate for protein kinase C might be a calmodulin-binding protein. We have recently labeled this protein, which migrates on sodium dodecyl sulfate-gel electrophoresis with an apparent Mr of 60,000 from chicken and 80,000-87,000 from bovine cells and tissues, the myristoylated alanine-rich C kinase substrate (MARCKS). The MARCKS proteins from both species could be cross-linked to 125I-calmodulin in a Ca2+-dependent manner. Phosphorylation of either protein by protein kinase C prevented 125I-calmodulin binding and cross-linking, suggesting that the calmodulin-binding domain might be located at or near the sites of protein kinase C phosphorylation. Both bovine and chicken MARCKS proteins contain an identical 25-amino acid domain that contains all 4 of the serine residues phosphorylated by protein kinase C in vitro. In addition, this domain is similar in sequence and structure to previously described calmodulin-binding domains. A synthetic peptide corresponding to this domain inhibited calmodulin binding to the MARCKS protein and also could be cross-linked to 125I-calmodulin in a calcium-dependent manner. In addition, protein kinase C-dependent phosphorylation of the synthetic peptide inhibited its binding and cross-linking to 125I-calmodulin. The peptide bound to fluorescently labeled 5-dimethylaminonaphthalene-1-sulfonyl-calmodulin with a dissociation constant of 2.8 nM, and inhibited the calmodulin-dependent activation of cyclic nucleotide phosphodiesterase with an IC50 of 4.8 nM. Thus, the peptide mimics the calmodulin-binding properties of the MARCKS protein and probably represents its calmodulin-binding domain. Phosphorylation of these abundant, high affinity calmodulin-binding proteins by protein kinase C in intact cells could cause displacement of bound calmodulin, perhaps leading to activation of Ca2+-calmodulin-dependent processes.     

Identification of contacts between topoisomerase I and its target DNA by site-specific photocrosslinking.

Vaccinia DNA topoisomerase, a eukaryotic type I enzyme, binds and cleaves duplex DNA at sites containing the sequence 5''-(T/C)CCTT. We report the identification of Tyr70 as the site of contact between the enzyme and the +4C base of its target site. This was accomplished by UV-crosslinking topoisomerase to bromocytosine-substituted DNA, followed by isolation and sequencing of peptide-DNA photoadducts. A model for the topoisomerase-DNA interface is proposed, based on the crystal structure of a 9 kDa N-terminal tryptic fragment. The protein domain fits into the DNA major groove such that Tyr70 is positioned close to the +4C base and Tyr72 is situated near the +3C base. Mutational analysis indicates that Tyr70 and Tyr72 contribute to site recognition during covalent catalysis. We propose, based on this and other studies of the vaccinia protein, that DNA backbone recognition and reaction chemistry are performed by a relatively well-conserved 20 kDa C-terminal portion of the vaccinia enzyme, whereas discrimination of the DNA sequence at the cleavage site is accomplished by a separate N-terminal domain, which is less conserved between viral and cellular proteins. Division of function among distinct structural modules may explain the different site specificities of the eukaryotic type I topoisomerases.     

Protein kinase cθ c2 domain is a phosphotyrosine binding module that plays a key role in its activation

Protein kinase Cθ (PKCθ) is a novel PKC that plays a key role in T lymphocyte activation. To understand how PKCθ is regulated in T cells, we investigated the properties of its N-terminal C2 domain that functions as an autoinhibitory domain. Our measurements show that a Tyr(P)-containing peptide derived from CDCP1 binds the C2 domain of PKCθ with high affinity and activates the enzyme activity of the intact protein. The Tyr(P) peptide also binds the C2 domain of PKCδ tightly, but no enzyme activation was observed with PKCδ. Mutations of PKCθ-C2 residues involved in Tyr(P) binding abrogated the enzyme activation and association of PKCθ with Tyr-phosphorylated full-length CDCP1 and severely inhibited the T cell receptor/CD28-mediated activation of a PKCθ-dependent reporter gene in T cells. Collectively, these studies establish the C2 domain of PKCθ as a Tyr(P)-binding domain and suggest that the domain may play a major role in PKCθ activation via its Tyr(P) binding.     

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

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

Regulation of the calcium ion pump of sarcoplasmic reticulum: reversible inhibition by phospholamban and by the calmodulin binding domain of the plasma membrane calcium ion pump.

A 45 amino acid peptide (A45) corresponding to the phospholamban (PLN) binding domain of the sarcoplasmic reticulum (SR) ATPase was synthesized. Circular dichroism experiments have shown that the peptide had a predominantly random-coil conformation but adopted a higher proportion of secondary structure in the presence of a synthetic 32 amino acid peptide corresponding to the hydrophilic portion of PLN. A similar conformational change was induced by the synthetic calmodulin binding domain of the plasma membrane Ca2+ pump (peptide C28W), which acts as an endogenous inhibitor of the pump and is homologous to PLN. Cross-linking experiments have shown that peptide C28W interacted with peptide A45. The Ca(2+)-pumping activity of cardiac SR, which contains endogenous PLN, was stimulated about 30% by peptide A45. The stimulation was maximal at submicromolar Ca2+ levels and tended to disappear at higher Ca2+ concentrations. By contrast, the Ca(2+)-pumping activity of skeletal muscle SR, which lacks endogenous PLN, was unaffected. Peptide C28W strongly inhibited the pumping activity of skeletal muscle SR, and peptide A45 reversed the inhibition. The results suggest that peptide A45 competed with the ATPase for phospholamban or for peptide C28W, removing the inhibition of the pump. Thus, the exogenous inhibitor of the SR Ca(2+)-ATPase, PLN, and the internal inhibitor of the plasma membrane Ca(2+)-ATPase, peptide C28W, are functionally analogous.     

Regulation of endothelial nitric oxide synthase by protein kinase C

Endothelial nitric oxide synthase (eNOS) is a key enzyme in nitric oxide-mediated signal transduction in mammalian cells. Its catalytic activity is regulated both by regulatory proteins, such as calmodulin and caveolin, and by a variety of post-translational modifications including phosphorylation and acylation. We have previously shown that the calmodulin-binding domain peptide is a good substrate for protein kinase C [Matsubara, M., Titani, K., and Taniguchi, H. (1996) Biochemistry 35, 14651-14658]. Here we report that bovine eNOS protein is phosphorylated at Thr497 in the calmodulin-binding domain by PKC both in vitro and in vivo, and that the phosphorylation negatively regulates eNOS activity. A specific antibody that recognizes only the phosphorylated form of the enzyme was raised against a synthetic phosphopeptide corresponding to the phosphorylated domain. The antibody recognized eNOS immunoprecipitated with anti-eNOS antibody from the soluble fraction of bovine aortic endothelial cells, and the immunoreactivity increased markedly when the cells were treated with phorbol 12-myristate 13-acetate. PKC phosphorylated eNOS specifically at Thr497 with a concomitant decrease in the NOS activity. Furthermore, the phosphorylated eNOS showed reduced affinity to calmodulin. Therefore, PKC regulates eNOS activity by changing the binding of calmodulin, an eNOS activator, to the enzyme.     

Low affinity Ca2+-binding sites of calcineurin B mediate conformational changes in calcineurin A

Limited proteolysis of calcineurin in the presence of Ca(2+) suggested that its calmodulin-binding domain, readily degraded by proteases, was unfolded while calcineurin B was compactly folded [Hubbard, M. J., and Klee, C. B. (1989) Biochemistry 28, 1868-1874]. Moreover, in the crystal structure of calcineurin, with the four Ca(2+) sites of calcineurin B occupied, the calmodulin-binding domain is not visible in the electron density map [Kissinger, C. R., et al. (1995) Nature 378, 641-644]. Limited proteolysis of calcineurin in the presence of EGTA, shows that, when the low affinity sites of calcineurin B are not occupied, the calmodulin-binding domain is completely protected against proteolytic attack. Slow cleavages are, however, detected in the linker region between the calmodulin-binding and the autoinhibitory domains of calcineurin A. Upon prolonged exposure to the protease, selective cleavages in carboxyl-terminal end of the first helix and the central helix linker of calcineurin B and the calcineurin B-binding helix of calcineurin A are also detected. Thus, Ca(2+) binding to the low-affinity sites of calcineurin B affects the conformation of calcineurin B and induces a conformational change of the regulatory domain of calcineurin A, resulting in the exposure of the calmodulin-binding domain. This conformational change is needed for the partial activation of the enzyme in the absence of calmodulin and its full activation by calmodulin. A synthetic peptide corresponding to the calmodulin-binding domain is shown to interact with a peptide corresponding to the calcineurin B-binding domain, and this interaction is prevented by calcineurin B in the presence but not the absence of Ca(2+). These observations provide a mechanism to explain the dependence on Ca(2+) binding to calcineurin B for calmodulin activation and for the 10-20-fold increase in affinity of calcineurin for Ca(2+) upon removal of the regulatory domain by limited proteolysis [Stemmer, P. M., and Klee, C. B. (1994) Biochemistry 33, 6859-6866].     

Evidence for domain organization within the 61-kDa calmodulin-dependent cyclic nucleotide phosphodiesterase from bovine brain.

The complete amino acid sequence of the 61-kDa calmodulin-dependent, cyclic nucleotide phosphodiesterase (CaM-PDE) from bovine brain has been determined. The native protein is a homodimer of N alpha-acetylated, 529-residue polypeptide chains, each of which has a calculated molecular weight of 60,755. The structural organization of this CaM-PDE has been investigated with use of limited proteolysis and synthetic peptide analogues. A site capable of interacting with CaM has been identified, and the position of the catalytic domain has been mapped. A fully active, CaM-independent fragment (Mr = 36,000), produced by limited tryptic cleavage in the absence of CaM, represents a functional catalytic domain. N-Terminal sequence and size indicate that this 36-kDa fragment is comprised of residues 136 to approximately 450 of the CaM-PDE. This catalytic domain encompasses a approximately 250 residue sequence that is conserved among PDE isozymes of diverse size, phylogeny, and function. CaM-PDE and its PDE homologues comprise a unique family of proteins, each having a catalytic domain that evolved from a common progenitor. A search of the sequence for potential CaM-binding sites revealed only one 15-residue segment with both a net positive charge and the ability to form an amphiphilic alpha-helix. Peptide analogues that include this amphiphilic segment were synthesized. Each was found to inhibit the CaM-dependent activation of the enzyme and to bind directly to CaM with high affinity in a calcium-dependent manner. This site is among the sequences cleaved from a 45-kDa chymotryptic fragment that has the complete catalytic domain but no longer binds CaM. These results indicate that residues located between position 23 and 41 of the native enzyme contribute significantly to the binding of CaM although the involvement of residues from additional sites is not excluded.