1H NMR study of rabbit skeletal muscle troponin C: Mg2(+)-induced conformational change

Binding of Mg2+ to rabbit skeletal muscle troponin C (TnC) is studied by means of two-dimensional (2D) 1H NMR spectroscopy. Using the sequence-specific resonance assignment method we assign several resonances of TnC in the Mg2(+)-saturated state. Assigned resonances are used as probes of the following titration experiments: (1) Mg2+ titration of apo-TnC, (2) Mg2+ titration of Ca2TnC, and (3) Mg2+ titration of Ca4TnC. In experiment 1, the slow-exchange behavior is observed for resonances of Phe99, Asp107, Gly108, Tyr109, Ile110, Asp111, His125, Gly144, Arg145, Ile146, Asp147, and Phe148 located at the high-affinity Ca2(+)-binding sites in the C-terminal-half domain. In experiments 1 and 2, the fast-exchange behavior is observed for resonances of Gly32, Asp33, Ser35, Gly68, Thr69, and Asp71 located at the low-affinity Ca2(+)-binding sites in the N-terminal-half domain. These results suggest that Mg2+ ions bind to the N domain as well as the C domain. In experiment 3, no spectral change is observed for all above-mentioned residues in the C domain and also for Gly32 and Gly68 in the N domain. It can be concluded that all Ca2(+)-binding sites in both the N and C domains can bind Mg2+ ions. No significant change is observed for resonances of Phe23, Ile34, Val68, and Phe72 in experiments 1 and 2. These results suggest that Mg2+ binding to the N domain does not induce conformational change in the hydrophobic region of the N domain. 2D-NMR spectra and Mg2(+)-titration data suggest that the antiparallel beta-sheet conformation is formed in both the N and C domains when Mg2+ ions bind to the two domains.     

Mastoparan binding induces Ca(2+)-transfer between two globular domains of calmodulin: a 1H NMR study.

The interaction between calmodulin and mastoparan at various concentrations of calcium ions was studied by 1H NMR. It was found that at lower mastoparan concentrations 1 mol of mastoparan binds to both the C-terminal-half and N-terminal-half regions of calcium-saturated calmodulin. The mastoparan affinity is much greater for the C-terminal-half region than for the N-terminal-half region. At higher mastoparan concentrations, a further 1 mol of mastoparan binds to the N-terminal-region of calcium saturated calmodulin. The results can be interpreted in terms of the assumption that the N-terminal-half region of calmodulin with mastoparan has a higher calcium ion affinity than the C-terminal-half region without mastoparan. It is suggested that calcium ions transfer from the C-terminal-half region of calmodulin without mastoparan to the N-terminal-half region of calmodulin with mastoparan. This calcium ion transfer is discussed from the viewpoint of enzyme activation by calmodulin.     

H-NMR study of rabbit skeletal muscle troponin C: Ca(2+)-dependent interaction with mastoparan.

1H-NMR spectroscopy is employed to study the interaction between rabbit skeletal muscle troponin (C (TnC) and wasp venom tetradecapeptide mastoparan. We monitored the spectral change of the following species of TnC as a function of mastoparan concentration: apoTnC, Ca(2+)-saturated TnC (Ca4TnC) and Ca(2+)-half loaded TnC (Ca2TnC). When apo-TnC is titrated with mastoparan, line-broadening is observed for the ring-current shifted resonance of Phe-23, Ile-34, Val-62 and Phe-72 and the downfield-shifted CH alpha-resonances of Asp-33, Thr-69 and Asp-71; these residues are located in the N-domain. When Ca4TnC is titrated with mastoparan, chemical shift change is observed for the ring-current shifted resonances of Phe-99, Ile-110 and Phe-148 and the downfield-shifted CH alpha-resonances of Asn-105, Ala-106, Ile-110 and Ile-146 and aromatic resonance of Tyr-109 and His-125; these residues are located in the C-domain. The resonance of Phe-23, Asp-33, Asp-71, Phe-72, Phe-99, Tyr-109, Ile-146, His-125 and Phe-148 in both N- and C-domains changes when Ca2TnC is titrated with mastoparan. These results suggest that mastoparan binds to the N-domain of apo-TnC, the C-domain of Ca4TnC and the N- and C-domains of Ca2TnC; the hydrophobic cluster in each domain is involved in binding. As mastoparan binds to TnC, the above resonances shift to their normal chemical shift positions. The stability of the cluster and the beta-sheet is reduced by mastoparan-binding. These results suggest that the conformation of the hydrophobic cluster and the neighboring beta-sheet change to a loose form. The stability of the N-domain of Ca2TnC and Ca4TnC increases when these species bind 1 mol of mastoparan at the C-domain. These results suggest a mastoparan-induced interaction between the N- and C-domains of TnC.     

Hydrogen bonding in the carboxyl-terminal half-fragment 78-148 of calmodulin as studied by two-dimensional nuclear magnetic resonance

The C-terminal half-fragment (residues 78-148) of scallop testis calmodulin was investigated by 500-MHz two-dimensional proton NMR in order to clarify the structure and the structural change accompanying Ca2+ binding. The sequential resonance assignment to individual amino acid residues was made in part (27 out of 71 residues) by a combination of correlated spectroscopy and nuclear Overhauser effect spectroscopy of a 90% H2O solution. In the Ca2+-bound state, resonances of backbone amide protons of Gly-98, Gly-134, Ile-100, Asn-137, and Val-136 appear at extremely low fields. These findings suggest that amide protons of these residues are hydrogen bonded. In the Ca2+-free state, the amide resonances of Ile-100 and Gly-134 disappear into the crowded normal shift region. This observation indicates that two hydrogen bonds of Ile-100 and Gly-134 are destroyed (or weakened) as Ca2+ ions are removed from two Ca2+-binding sites. Chemical shifts of amide and alpha-protons of residues located in the Ca2+-binding loop of domain III are similar to those of domain IV. These results suggest that the conformations of the two loops are very similar. The present results can be interpreted in terms of a structure predicted by Kretsinger [Kretsinger, R.H. (1980) Ann. N.Y. Acad. Sci. 356, 14].     

1H NMR study on amide proton exchange of calmodulin-mastoparan complex

Amide proton exchange rates of Ca2(+)-saturated calmodulin and Ca2(+)-saturated calmodulin-mastoparan complex were studied by 1H NMR spectroscopy. Exchange rates of Gly25, Gly61, Gly98, Gly134, Ile27, Ile100, and Asn137 were determined for Ca2(+)-saturated calmodulin and for Ca2(+)-saturated calmodulin-mastoparan complex, and were found to be less than 10(-4)s-1. All these residues of which the amide proton resonances appear at lower fields were considered to form hydrogen bonds, based on the results of X-ray analysis. Exchange rates of Ile27 and Asn137 became an order of magnitude smaller when mastoparan bound to Ca2(+)-saturated calmodulin, while those of the four glycines and Ile100 did not change appreciably. The reduction in accessibility of Asn137 to water cased by mastoparan binding suggests that a part of the mastoparan binding site is probably located in or near the hydrophobic cluster of the C-terminal-half domain. The reduction in accessibility of Ile27 also suggests that another part of the mastoparan binding site is located in or near the hydrophobic cleft of the N-terminal-half domain.     

High-resolution proton nuclear magnetic resonance studies of human gastrin

High-resolution 1H nuclear magnetic resonance (NMR) spectroscopy at 300 MHz has been used to study the behavior of human gastrin in aqueous solution. A large number of resonances have been assigned by analysis of one- and two-dimensional NMR spectra and the effects of pH and by comparison with the spectrum of des-less than Glu1-gastrin. In gastrin, the ratio of cis to trans conformations around the Gly-2 to Pro-3 peptide bond is 3:7. This is reflected in splitting of the resonances of several neighboring residues and of a residue distant in the sequence, Tyr-12. The pKa of Tyr-12 is 10.7. Sulfation of this residue perturbs the resonances of Tyr-12 and Gly-13 but has very little effect on the rest of the spectrum. A study of the temperature dependence shows that several perturbed resonances move toward their expected positions as the temperature is raised but with a linear dependence on temperature, consistent with a redistribution of populations among accessible local conformations rather than a cooperative conformational change. Addition of Na+ or Ca2+ causes only minor changes in the spectrum. The paramagnetic metal ion Co2+ produces a number of spectral changes, reflecting strong binding to at least one site involving the Glu residues and weaker binding to Asp-16.     

The fourth transmembrane domain of the Helicobacter pylori Na+/H+ antiporter NhaA faces a water-filled channel required for ion transport

Cysteine-scanning mutagenesis was performed from Ser-130 to Leu-160 in the fourth transmembrane domain (TM4) of the Na+/H+ antiporter NhaA from Helicobacter pylori to determine the topology of each residue and to identify functionally important residues. All of the mutants were based on cysteine-less NhaA (Cys-less NhaA), which functions very similarly to the wild-type protein, and were expressed at a level similar to Cys-less NhaA. Discontinuity of [14C]N-ethylmaleimide (NEM)-reactive residues suggested that TM4 comprises residues Gly-135 to Val-156. Even within TM4, NEM reactivity was high for I136C, D141C to A143C, L146C, M150C, and G153C to R155C. These residues are thought to be located on one side of the -helical structure of TM4 and to face a putative water-filled channel. Pretreatment of intact cells with membrane-impermeable maleimide did not inhibit [14C]NEM binding to the NEM-reactive residues within TM4, suggesting that the putative channel opens toward the cytoplasm. NEM reactivity of the A143C mutant was significantly inhibited by Li+. The T140C and D141C mutants showed lower affinity for Na+ and Li+ as transport substrates, but their maximal antiporter velocities (Vmax) were relatively unaffected. Whereas the I142C and F144C mutants completely lost their Li+/H+ antiporter activity, I142C had a lower Vmax for the Na+/H+ antiporter. F144C exhibited a markedly lower Vmax and a partially reduced affinity for Na+. These results suggest that Thr-140, Asp-141, and Phe-144 are located in the end portion of a putative water-filled channel and may provide the binding site for Na+, Li+, and/or H+. Furthermore, residues Ile-142 to Phe-144 may be important for the conformational change that accompanies ion transport in NhaA.     

1H NMR studies of mastoparan binding by calmodulin

Association with the cytoactive tetradecapeptide mastoparan perturbs the downfield 1H NMR spectrum of the calmodulin-Ca42+ complex. Changes occur in the resonances assigned to His-107 and Tyr-138. Composite peaks assigned to Phe-16 and Phe-89 and to Phe-68 and Tyr-99 are also affected. Both the upfield and downfield 1H NMR spectra contain evidence for spectroscopically distinct intermediates in Ca2+ binding by the calmodulin-mastoparan complex.     

CrATP-induced Ca2+ occlusion in mutants of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Use of the nonphosphorylating beta,gamma-bidentate chromium(III) complex of ATP to induce a stable Ca(2+)-occluded form of the sarcoplasmic reticulum Ca(2+)-ATPase was combined with molecular sieve high performance liquid chromatography of detergent-solubilized protein to examine the ability of the Ca(2+)-ATPase mutants Gly-233-->Glu, Gly-233-->Val, Glu-309-->Gln, Gly-310-->Pro, Pro-312-->Ala, Ile-315-->Arg, Leu-319-->Arg, Asp-703-->Ala, Gly-770-->Ala, Glu-771-->Gln, Asp-800-->Asn, and Gly-801-->Val to occlude Ca2+. This provided a new approach to identification of amino acid residues involved in Ca2+ binding and in the closure of the gates to the Ca2+ binding pocket of the Ca(2+)-ATPase. The "phosphorylation-negative" mutant Asp-703-->Ala and mutants of ADP-sensitive phosphoenzyme intermediate type were fully capable of occluding Ca2+, as was the mutant Gly-770-->Ala. Mutants in which carboxylic acid-containing residues in the putative transmembrane segments had been substituted ("Ca(2+)-site mutants") and mutant Gly-801-->Val were unable to occlude either of the two calcium ions. In addition, the mutant Gly-310-->Pro, previously classified as ADP-insensitive phosphoenzyme intermediate type (Andersen, J.P., Vilsen, B., and MacLennan, D.H. (1992). J. Biol. Chem. 267, 2767-2774), was unable to occlude Ca2+, even though Ca(2+)-activated phosphorylation from MgATP took place in this mutant.     

Characterization of Calelectrin, a Ca2+-Binding Protein Isolated from the Electric Organ of Torpedo marmorata

We report a fast (less than 1 day) and efficient (2-3 mg protein/100 g tissue) isolation method for calelectrin, a protein of Mr 34,000 in the electric organ of Torpedo marmorata that binds to membranes in the presence of Ca2+. Purified protein was used to investigate the nature of its interaction with membranes and with Ca2+. Calelectrin binds to liposomes composed of total extractable lipids from the electric organ in a Ca2+-dependent and -specific manner with half-maximal binding between 3 and 7 microM free Ca2+. This binding is totally inhibited by 1 mM mercaptoethanol. It is also shown that calelectrin directly binds Ca2+ in solution by two techniques: at 1 and 10 microM Ca2+ it binds 45Ca2+ as measured by gel permeation chromatography, and it contains saturable Tb3+-binding sites that are Ca2+-displaceable. An investigation of the protein's endogenous fluorescence shows that although it contains both tryptophan and tyrosine, there is no change in the apparent quantum yield as a function of Ca2+. Ca2+-dependent hydrophobic affinity chromatography of the total soluble proteins from Torpedo electric organ shows that Torpedo calelectrin, like calmodulin and mammalian calelectrins, is specifically retained in the presence of Ca2+ and eluted by EGTA. Calelectrin also contains high-affinity sites for hydrophobic fluorescence probes such as N-phenyl-1-naphthylamine, 2-CP-toluidinylnaphthalene-6-sulfonic acid, and 1-anilinonaphthalene-8-sulfonic acid, which again unlike calmodulin, show no changes as a function of Ca2+. We conclude that calelectrin is a Ca2+-binding protein whose binding to the lipid moieties of membranes is regulated by physiological change in the Ca2+ concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

The binding of W7, an inhibitor of striated muscle contraction, to cardiac troponin C

W7 is a well-characterized calmodulin antagonist. It decreases the maximal tension and rate of ATP hydrolysis in cardiac muscle fibers. Cardiac troponin C (cTnC) has been previously implicated as the mechanistically significant target for W7 in the myofilament. Two-dimensional NMR spectra ({1H,15N}- and {1H,13C}-HSQCs) were used to monitor the Ca2+-dependent binding of W7 to cTnC. Titration of cTnC x 3Ca2+ with W7 indicated binding to both domains of the protein. We examined the binding of W7 to the separated domains of cTnC to simplify the spectral analysis. In the titration of the C-terminal domain (cCTnC x 2Ca2+), the spectral peaks originating from a subset of residues changed nonuniformly, and could not be well-described as single-site binding. A global fit of the cCTnC x 2Ca2+ titration data to a two-site, sequential binding model (47 residues simultaneously fit) yielded a dissociation constant (Kd1) of 0.85-0.91 mM for the singly bound state, with the second dissociation constant fit to 3.40-3.65 mM (> or = 4 x Kd1). The titration data for the N-terminal domain (cNTnC x Ca2+) was globally fit to single-site binding model with a Kd of 0.15-0.30 mM (41 residues fit). The data are consistent with W7 binding to each domain's major hydrophobic pocket, coordinating side chains responsible for liganding cTnI. When in muscle fibers, W7 may compete with cTnI for target sites on cTnC.     

EPR studies show that all lanthanides do not have the same order of binding to calmodulin

Calmodulin, spin labeled at Tyr-99, has been titrated with the lanthanides La3+, Nd3+, Eu3+, Tb3+, Er3+ and Lu3+ as well as Ca2+ and Cd2+. The titration was monitored by EPR and changes in mobility of the spin label, due to binding into the labeled site and protein conformational change, were observed. Comparison of these titration curves with theoretical binding curves for the various calmodulin-metal species, show that different lanthanides have different high affinity sites. Three basic categories were observed, with Lu3+ and Er3+ behaving like Ca2+, Eu3+ and Tb3+ binding in the opposite order from Ca2+, and La3+ and Nd3+ different from either Ca2+ or Tb3+.     

Calcium binding to the isolated beta-hydroxyaspartic acid-containing epidermal growth factor-like domain of bovine factor X

Coagulation factor X is a vitamin K-dependent protein composed of discrete domains or modules. A proteolytically modified derivative of factor X that lacks the NH2-terminal gamma-carboxyglutamic acid (Gla)-containing region retains one Ca2+ binding site. To localize this Gla-independent Ca2+ binding site and to facilitate future studies aimed at elucidating structure-function relationship in the factor X molecule, we have devised a method to isolate the first beta-hydroxyaspartic acid (Hya)-containing epidermal growth factor (EGF)-like domain from proteolytic digests of bovine factor X performed under strictly controlled conditions. The EGF-like domain, corresponding to residues 45-86 in bovine factor X, was obtained in more than 50% recovery, and was at least 98% homogeneous as judged by NH2-terminal sequence analysis. Ca2+ binding to the isolated EGF-like domain was studied by 1H NMR spectroscopy. On binding of Ca2+ to the domain the resonances from Tyr-68 centered at 6.8 ppm were affected. The Ca2+ concentration dependence of the chemical shift was used to calculate the Ca2+ binding constant, resulting in a K alpha of 4 X 10(3) M-1 at pH 8.5 and 1 X 10(3) M-1 at pH 7.4, the higher value presumably reflecting an increase in negative surface charge due to deprotonation of a histidine residue with a pK alpha of 7.4. The NMR spectra gave no evidence of a conformational change in the EGF-like domain between pH 6 and 8.5.     

Purification, calcium-binding properties, and conformational studies on a 28-kDa cholecalcin-like protein from bovine brain

A large-scale preparation method for bovine brain 28-kDa cholecalcin-like protein is described. Flow dialysis binding studies revealed that the protein binds at least 3 mol of Ca2+/mol of protein. The protein undergoes conformational changes on binding calcium as shown by UV differential absorption spectroscopy, near and far UV circular dichroism, and intrinsic fluorescence. Circular dichroism (CD) studies in the far UV indicate an apparent increase in helical content in the presence of Ca2+. The effect of calcium on the protein structure is nearly maximum for 1 Ca2+ bound/protein molecule. UV differential absorption studies on the binding of the Ca2+ agonist Tb3+ and Tb3+ luminescence induced by energy Trp----Tb3+ transfer indicate that Tb3+ binds to two higher affinity Ca2+-binding sites. These sites are probably very close to the single Trp residue. Analysis of the fluorescence parameters of the single tryptophan residue in the apoprotein and its accessibility to ionic and neutral quenchers suggests that this residue is located in a highly hydrophobic domain on the protein surface.     

Tyrosine-89 is important for enzymatic activity of S. cerevisiae inorganic pyrophosphatase.

7-Chloro-4-nitro-benzofurazan selectively modifies one PPase Tyr residue per subunit and lowers the enzyme activity. Hydrolysis of the modified protein by trypsin and then by chymotrypsin produces the 82-89 peptide which possesses modified Tyr-89. Substrate analog (CaPPi) and the product of the enzyme reaction, MgPi, protect the enzyme against inactivation. Ions of metal-activators (Mg2+, Zn2+) exert no influence on the inactivation rate. On the contrary, the Ca(2+)-inhibitor of the enzyme accelerates the reaction by binding to the high-affinity site, and effectively decreases it when Ca2+ binds to both sites. Mg2+ competes with Ca2+ for one binding site, which is the low affinity site for Mg2+ and the high-affinity site for Ca2+. The Ca2+ saturation of the high-affinity site decreases the pK2 of Tyr-89, probably due to direct coordination between Tyr and Ca2+. The observed properties of Tyr-89 modification enable us to propose that Tyr-89 serves as a proton donor for phosphate releasing during enzymatic hydrolysis of pyrophosphate. The Ca2+ inhibitory effect on the enzyme activity may be due to the existence of a Tyr-89 bond in the Ca2+ pyrophosphatase complex.     

NMR studies of the conformational change in human N-p21ras produced by replacement of bound GDP with the GTP analog GTP gamma S.

1H-Detected 15N-edited NMR in solution was used to study the conformational differences between the GDP- and GTP gamma S-bound forms of human N-p21ras. The amide protons of 15N-labeled glycine and isoleucine were observed. Resonances were assigned to residues of particular interest, glycines-60 and -75 and isoleucines-21 and -36, by incorporating various 13C-labeled amino acids in addition to [15N]glycine and [15N]iosleucine and by replacing Mg2+ by Co2+. When GTP gamma S replaced GDP in the active site of p21ras, only 5 of the 14 glycine amide resonances show major shifts, indicating that the conformational effects are fairly localized. Responsive glycines-10, -12, -13, and -15 are in the active site. Gly-75, located at the far end of a conformationally-active loop and helix, also responds to substitution of GTP gamma S for GDP, while Gly-77 does not, supporting a role for Gly-75 as a swivel point for the conformational change. The amide proton resonances of isoleucines-36 and -21 and a third unidentified isoleucine also undergo major shifts upon replacement of GDP by GTP gamma S. Thus, the effector-binding loop containing Ile-36 is confirmed to be involved in the conformational change, and the alpha-helix containing Ile-21 is also shown to be affected.     

Spectroscopic analysis of a methionine-48 to tyrosine mutant of chicken troponin C.

A mutant (M48Y) of chicken skeletal muscle troponin C was prepared in which Tyr replaced Met-48 of the recombinant protein (rTnC). Since Tyr and Trp are normally absent, spectral properties could be unambiguously assigned to the site of substitution. In the crystal structure, this residue lies at the COOH-terminal end of the B-helix of the N domain in a region postulated to undergo a significant conformational change to a more polar environment upon Ca2+ binding [Herzberg et al. (1986) J. Biol. Chem. 261, 2638-2644]. Comparison of the far-UV CD spectra of M48Y and rTnC in the absence and presence of Ca2+ indicated no overall structural alteration due to the mutation. However, Ca2+ titration of the ellipticity change showed a reduction in Ca2+ affinity and cooperativity of sites I and II. A Ca(2+)-induced increase in the near-UV ellipticity of M48Y at pH 7.12 and a red shift in its UV absorbance spectrum occurred over a range of free [Ca2+] attributable to the N-domain transition only. This was largely abolished at pH 5.3 where Ca2+ no longer binds to sites I and II. That region of the 1H NMR spectrum attributable to Tyr was broadened upon Ca2+ binding. These Ca(2+)-induced changes are consistent with the environment of the Tyr side chain becoming chiral, less polar, and more immobile, all in a direction opposite to that predicted. These observations indicate that while the general features of the postulated model are valid, it is unlikely to be correct in detail.     

Activation of sarcoplasmic reticular Ca2+ transport ATPase by phosphorylation of an associated phosphatidylinositol

Approximately 1 mol phosphatidylinositol phosphate is formed per mol isolated Ca2+ transport ATPase when the enzyme is incubated with ATP/Mg2+. The phosphorylation of this enzyme-associated phosphatidylinositol represents the alkylphosphate formation described earlier. The phosphatidylinositol phosphate has been found in the hydrophobic core of the enzyme. A complex of phosphatidylinositol phosphate with protein can be extracted with acidic chloroform/methanol. The protein behaves like proteolipid during chromatography on Sephadex LH 60 and binds the radioactively labelled phosphatidylinositol phosphate. The phosphorylation of approximately 1 mol phosphatidylinositol per 100,000 g protein correlates with an enhancement of the Ca2+ transport ATPase activity which is due to an approximately 7-fold enhanced affinity for Ca2+ and an approximately 2-fold enhanced maximal turnover.     

Calcium-induced conformational changes of the recombinant CBP3 protein from Dictyostelium discoideum

Calcium-binding proteins play various and significant roles in biological systems. Conformational changes in their structures are closely related to their physiological functions. To understand the role of calcium-binding protein 3 (CBP3) in Dictyostelium discoideum, its recombinant proteins were analyzed using circular dichroism (CD) and fluorescence spectroscopy. Gel mobility shift analysis showed that Ca2+ induced a mobility shift of the recombinant CBP3. Far ultra-violet CD spectra and intrinsic fluorescence spectra on CBP3 and its N- and C-terminal domains exhibited that they underwent a conformational rearrangement depending upon Ca2+ binding. Measurement of Ca2+ dissociation constants demonstrated that CBP3 had high affinity toward Ca2+ in the sub-micromolar range and N-terminal domain had higher affinity than C-terminal domain. The changes of fluorescence spectra by an addition of 8-anilino-1-naphthalene sulfonic acid indicated that the hydrophobic patches of CBP3 and its C-terminal domain are likely to be more exposed in the presence of Ca2+. Since the exposure of hydrophobic patches is thermodynamically unfavorable, Ca2+-bound CBP3 may interact with other proteins in vivo. All these data suggest that Ca2+ induces CBP3 to be more favorable conformation to interact with target proteins.     

Spectroscopic characterization of the EF-hand domain of phospholipase C delta1: identification of a lipid interacting domain

The interaction of the isolated EF-hand domain of phospholipase C delta1 with arachidonic acid (AA) was characterized using circular dichroism (CD) and fluorescence spectroscopy. The far-UV CD spectral changes indicate that AA binds to the EF domain. The near-UV CD spectra suggest that the orientations of aromatic residues in the peptide are affected when AA binds to the protein. The fluorescence of the single intrinsic tryptophan located in EF1 was enhanced by the addition of dodecylmaltoside (DDM) and AA suggesting that this region of the protein is involved in hydrophobic interactions. In the presence of a low concentration of DDM it was found that AA induced a change in fluorescence resonance energy transfer, which is indicative of a conformational change. The lipid induced conformational change may play a role in calcium binding because the isolated EF-hand domain did not bind Ca2+ in the absence of lipids, but Ca2+-dependent changes in the intrinsic tryptophan emission were observed when free fatty acids were present. These studies identify specific EF-hand domains as allosteric regulatory domains that require hydrophobic ligands such as lipids.