Nuclear magnetic resonance studies of the internal dynamics in Apo, (Cd2+)1 and (Ca2+)2 calbindin D9k. The rates of amide proton exchange with solvent.

The backbone dynamics of the EF-hand Ca(2+)-binding protein, calbindin D9k, has been investigated in the apo, (Cd2+)1 and (Ca2+)2 states by measuring the rate constants for amide proton exchange with solvent. 15N-1H correlation spectroscopy was utilized to follow direct 1H-->2H exchange of the slowly exchanging amide protons and to follow indirect proton exchange via saturation transfer from water to the rapidly exchanging amide protons. Plots of experimental rate constants versus intrinsic rate constants have been analyzed to give qualitative insight into the opening modes of the protein that lead to exchange. These results have been interpreted within the context of a progressive unfolding model, wherein hydrophobic interactions and metal chelation serve to anchor portions of the protein, thereby damping fluctuations and retarding amide proton exchange. The addition of Ca2+ or Cd2+ was found to retard the exchange of many amide protons observed to be in hydrogen-bonding environments in the crystal structure of the (Ca2+)2 state, but not of those amide protons that were not involved in hydrogen bonds. The largest changes in rate constant occur for residues in the ion-binding loops, with substantial effects also found for the adjacent residues in helices I, II and III, but not helix IV. The results are consistent with a reorganization of the hydrogen-bonding networks in the metal ion-binding loops, accompanied by a change in the conformation of helix IV, as metal ions are chelated. Further analysis of the results obtained for the three states of metal occupancy provides insight into the nature of the changes in conformational fluctuations induced by ion binding.     

Interaction of cardiac troponin C with Ca(2+) sensitizer EMD 57033 and cardiac troponin I inhibitory peptide

The binding of Ca(2+) to cardiac troponin C (cTnC) triggers contraction in cardiac muscle. In diseased heart, the myocardium is often desensitized to Ca(2+), leading to weak cardiac contractility. Compounds that can sensitize cardiac muscle to Ca(2+) would have potential therapeutic value in treating heart failure. The thiadiazinone derivative EMD 57033 is an identified 'Ca(2+) sensitizer', and cTnC is a potential target of the drug. In this work, we used 2D ?(1)H, (15)N?-HSQC NMR spectroscopy to monitor the binding of EMD 57033 to cTnC in the Ca(2+)-saturated state. By mapping the chemical shift changes to the structure of cTnC, EMD 57033 is found to bind to the C-domain of cTnC. To test whether EMD 57033 competes with cardiac TnI (cTnI) for cTnC and interferes with the inhibitory function, we examined the interaction of cTnC with an inhibitory cTnI peptide (residues 128-147, cIp) in the absence and presence of EMD 57033, respectively. cTnC was also titrated with EMD 57033 in the presence of cIp. The results show that although both the drug and cIp interact with the C-domain of cTnC, they do not displace each other, suggesting noncompetitive binding sites for the two targets. Detailed chemical shift mapping of the binding sites reveals that the regions encompassing helix G-loop IV-helix H are more affected by EMD 57033, while residues located on helix E-loop III-helix F and the linker between sites III and IV are more affected by cIp. In both cases, the binding stoichiometry is 1:1. The binding affinities for the drug are 8.0 +/- 1.8 and 7.4 +/- 4.8 microM in the absence and presence of cIp, respectively, while those for the peptide are 78.2 +/- 10.3 and 99.2 +/- 30.0 microM in the absence and presence of EMD 57033, respectively. These findings suggest that EMD 57033 may exert its positive inotropic effect by not directly enhancing Ca(2+) binding to the Ca(2+) regulatory site of cTnC, but by binding to the structural domain of cTnC, modulating the interaction between cTnC and other thin filament proteins, and increasing the apparent Ca(2+) sensitivity of the contractile system.     

Conformational dynamics of yeast calmodulin in the Ca(2+)-bound state probed using NMR relaxation dispersion

Most calmodulin (CaM) in apo and Ca(2+)-bound states show a dumb-bell-like structure, involving the N- and C-terminal domains, connected with a flexible linker. However, Ca(2+)-bound yeast calmodulin (yCaM) takes on a unique globular structure; the target-binding site of this protein is autoinhibited. We applied NMR relaxation dispersion experiments to yCaM in the Ca(2+)-bound state. The amide (15)N and (1)H(N) relaxation dispersion profiles indicated the presence of conformational dynamics for specific residues at the interface between the N- and C-terminal domains. We conclude that these conformational dynamics were derived from the mobility of the C-terminal domain.     

Location of the Zn(2+)-binding site on S100B as determined by NMR spectroscopy and site-directed mutagenesis

In addition to binding Ca(2+), the S100 protein S100B binds Zn(2+) with relatively high affinity as confirmed using isothermal titration calorimetry (ITC; K(d) = 94 +/- 17 nM). The Zn(2+)-binding site on Ca(2+)-bound S100B was examined further using NMR spectroscopy and site-directed mutagenesis. Specifically, ITC measurements of S100B mutants (helix 1, H15A and H25A; helix 4, C84A, H85A, and H90A) were found to bind Zn(2+) with lower affinity than wild-type S100B (from 2- to >25-fold). Thus, His-15, His-25, Cys-84, His-85, and perhaps His-90 of S100B are involved in coordinating Zn(2+), which was confirmed by NMR spectroscopy. Previous studies indicate that the binding of Zn(2+) enhances calcium and target protein-binding affinities, which may contribute to its biological function. Thus, chemical shift perturbations observed here for residues in both EF-hand domains of S100B during Zn(2+) titrations could be detecting structural changes in the Ca(2+)-binding domains of S100B that are pertinent to its increase in Ca(2+)-binding affinity in the presence of Zn(2+). Furthermore, Zn(2+) binding causes helix 4 to extend by one full turn when compared to Ca(2+)-bound S100B. This change in secondary structure likely contributes to the increased binding affinity that S100B has for target peptides (i.e., TRTK peptide) in the presence of Zn(2+).     

Fe(2+)-catalyzed oxidation and cleavage of sarcoplasmic reticulum ATPase reveals Mg(2+) and Mg(2+)-ATP sites

Fe(2+) can substitute for Mg(2+) in activation of the sarcoplasmic reticulum (SR) ATPase, permitting approximately 25% activity in the presence of Ca(2+). Therefore, we used Fe(2+) to obtain information on the binding sites for Mg(2+) and the Mg(2+)-ATP complex within the enzyme structure. When the ATPase is incubated with Fe(2+) in the presence of H(2)O(2) and/or ascorbate, specific patterns of Fe(2+)-catalyzed oxidation and cleavage are observed in the SR ATPase, depending on its Ca(2+)-bound (E1-Ca(2)) or Ca(2+)-free conformation (E2-TG), as well as on the presence of ATP. The ATPase protein in the E1-Ca(2) state is cleaved efficiently by Fe(2+) with H(2)O(2) and ascorbate assistance, yielding a 70-75 kDa carboxyl end fragment. Cleavage of the ATPase protein in the E2-TG state occurs within the same region, but with a more diffuse pattern, yielding multiple fragments within the 65-85 kDa range. When Fe(2+) catalysis is assisted by ascorbate only (in the absence of H(2)O(2)), cleavage at the same protein site occurs much more slowly, and is facilitated by ATP (or AMP-PNP) and Ca(2+). Amino acid sequencing indicates that protein cleavage occurs at and near Ser346, and is attributed to Fe(2+) bound to a primary Mg(2+) site near Ser346 and neighboring Glu696. In addition, incubation with Fe(2+) and ascorbate produces Ca(2+)- and ATP-dependent oxidation of the Thr441 side chain, as demonstrated by NaB(3)H(4) incorporation and analysis of fragments obtained by extensive trypsin digestion. This oxidation is attributed to bound Fe(2+)-ATP complex, as shown by structural modeling of the Mg(2+)-ATP complex at the substrate site.     

Dopamine receptor-mediated Ca(2+) signaling in striatal medium spiny neurons

Inositol 1,4,5-trisphosphate (InsP(3)) and cAMP are the two second messengers that play an important role in neuronal signaling. Here, we investigated the interactions of InsP(3)- and cAMP-mediated signaling pathways activated by dopamine in striatal medium spiny neurons (MSN). We found that in approximately 40% of the MSN, application of dopamine elicited robust repetitive Ca(2+) transients (oscillations). In pharmacological experiments with specific agonists and antagonists, we found that the observed Ca(2+) oscillations were triggered by activation of D1 class dopamine receptors (DARs). We further demonstrated that activation of phospholipase C was required for induction of dopamine-induced Ca(2+) oscillations and that maintenance of dopamine-evoked Ca(2+) oscillations required both Ca(2+) influx and Ca(2+) mobilization from internal Ca(2+) stores. In "priming" experiments with a type 2 5-hydroxytryptamine receptor agonist, we have shown a likely role for calcyon in coupling D1 class DARs with Ca(2+) oscillations in MSN. In experiments with the DAR-specific agonist SKF83959, we discovered that phospholipase C activation alone could not account for dopamine-induced Ca(2+) oscillations. We further demonstrated that direct activation of protein kinase A by 8-bromo-cAMP or inhibition of protein phosphatase-1 (PP1) or calcineurin (PP2B) resulted in elevation of basal Ca(2+) levels in MSN, but not in Ca(2+) oscillations. In experiments with competitive peptides, we have shown an importance of type 1 InsP(3) receptor association with PP1alpha and with AKAP9.protein kinase A for dopamine-induced Ca(2+) oscillations. In experiments with MSN from DARPP-32 knock-out mice, we demonstrated a regulatory role of DARPP-32 in dopamine-induced Ca(2+) oscillations. Our results indicate that, following D1 class DAR activation, InsP(3) and cAMP signaling pathways converge on the type 1 InsP(3) receptor, resulting in Ca(2+) oscillations in MSN.     

Ca(2+)- and H(+)-dependent conformational changes of calbindin D(28k)

Calbindin D(28k) is a member of a large family of intracellular Ca(2+) binding proteins characterized by EF-hand structural motifs. Some of these proteins are classified as Ca(2+)-sensor proteins, since they are involved in transducing intracellular Ca(2+) signals by exposing a hydrophobic patch on the protein surface in response to Ca(2+) binding. The hydrophobic patch serves as an interaction site for target enzymes. Other members of this group are classified as Ca(2+)-buffering proteins, because they remain closed after Ca(2+) binding and participate in Ca(2+) buffering and transport functions. ANS (8-anilinonaphthalene-1-sulfonic acid) binding and affinity chromatography on a hydrophobic column suggested that both the Ca(2+)-free and Ca(2+)-loaded form of calbindin D(28k) have exposed hydrophobic surfaces. Since exposure of hydrophobic surface is unfavorable in the aqueous intracellular milieu, calbindin D(28k) most likely interacts with other cellular components in vivo. A Ca(2+)-induced conformational change was readily detected by several optical spectroscopic methods. Thus, calbindin D(28k) shares some of the properties of Ca(2+)-sensor proteins. However, the Ca(2+)-induced change in exposed hydrophobic surface was considerably less pronounced than that in calmodulin. The data also shows that calbindin D(28k) undergoes a rapid and reversible conformational change in response to a H(+) concentration increase within the physiological pH range. The pH-dependent conformational change was shown to reside mainly in EF-hands 1-3. Urea-induced unfolding of the protein at pH 6, 7, and 8 showed that the stability of calbindin D(28k) was increased in response to H(+) in the range examined. The results suggest that calbindin D(28k) may interact with targets in a Ca(2+)- and H(+)-dependent manner.     

The second Ca(2+)-binding domain of NCX1 binds Mg2+ with high affinity

We report the effects of binding of Mg(2+) to the second Ca(2+)-binding domain (CBD2) of the sodium-calcium exchanger. CBD2 is known to bind two Ca(2+) ions using its Ca(2+)-binding sites I and II. Here, we show by nuclear magnetic resonance (NMR), circular dichroism, isothermal titration calorimetry, and mutagenesis that CBD2 also binds Mg(2+) at both sites, but with significantly different affinities. The results from Mg(2+)-Ca(2+) competition experiments show that Ca(2+) can replace Mg(2+) from site I, but not site II, and that Mg(2+) binding affects the affinity for Ca(2+). Furthermore, thermal unfolding circular dichroism data demonstrate that Mg(2+) binding stabilizes the domain. NMR chemical shift perturbations and (15)N relaxation data reveal that Mg(2+)-bound CBD2 adopts a state intermediate between the apo and fully Ca(2+)-loaded forms. Together, the data show that at physiological Mg(2+) concentrations CBD2 is loaded with Mg(2+) preferentially at site II, thereby stabilizing and structuring the domain and altering its affinity for Ca(2+).     

Paramagnetic NMR study of Cu(2+)-IDA complex localization on a protein surface and its application to elucidate long distance information

The paramagnetic metal chelate complex Cu(2+)-iminodiacetic acid (Cu(2+)-IDA) was mixed with ubiquitin, a small globular protein. Quantitative analyses of (1)H and (15)N chemical shift changes and line broadenings induced by the paramagnetic effects indicated that Cu(2+)-IDA was localized to a histidine residue (His68) on the ubiquitin surface. The distances between the backbone amide proton and the Cu(2+) relaxation center were evaluated from the proton transverse relaxation rates enhanced by the paramagnetic effect. These correlated well with the distances calculated from the crystal structure up to 20 A. Here, we show that a Cu(2+)-IDA is the first paramagnetic reagent that specifically localizes to a histidine residue on the protein surface and gives the long-range distance information.     

Expression of doubly labeled Saccharomyces cerevisiae iso-1 ferricytochrome c and (1)H, (13)C and (15)N chemical shift assignments by multidimensional NMR

We have expressed [U-(13)C,(15)N]-labeled Saccharomyces cerevisiae iso-1 cytochrome c C102T;K72A in Escherichia coli with a yield of 11 mg/l of growth medium. Nuclear magnetic resonance (NMR) studies were conducted on the Fe(3+) form of the protein. We report herein chemical shift assignments for amide (1)H and (15)N, (13)C(omicron), (13)C(alpha), (13)C(beta), (1)H(alpha) and (1)H(beta) resonances based upon a series of three-dimensional NMR experiments: HNCA, HN(CO)CA, HNCO, HN(CA)CO, HNCACB, HCA(CO)N, HCCH-TOCSY and HBHA(CBCA)NH. An investigation of the chemical shifts of the threonine residues was also made by using density functional theory in order to help solve discrepancies between (15)N chemical shift assignments reported in this study and those reported previously.     

Triple-resonance multidimensional NMR study of calmodulin complexed with the binding domain of skeletal muscle myosin light-chain kinase: indication of a conformational change in the central helix

Heteronuclear 3D and 4D NMR experiments have been used to obtain 1H, 13C, and 15N backbone chemical shift assignments in Ca(2+)-loaded calmodulin complexed with a 26-residue synthetic peptide (M13) corresponding to the calmodulin-binding domain (residues 577-602) of rabbit skeletal muscle myosin light-chain kinase. Comparison of the chemical shift values with those observed in peptide-free calmodulin [Ikura, M., Kay, L. E., & Bax, A. (1990) Biochemistry 29, 4659-4667] shows that binding of M13 peptide induces substantial chemical shift changes that are not localized in one particular region of the protein. The largest changes are found in the first helix of the Ca(2+)-binding site I (E11-E14), the N-terminal portion of the central helix (M72-D78), and the second helix of the Ca(2+)-binding site IV (F141-M145). Analysis of backbone NOE connectivities indicates a change from alpha-helical to an extended conformation for residues 75-77 upon complexation with M13. This conformational change is supported by upfield changes in the C alpha and carbonyl chemical shifts of these residues relative to M13-free calmodulin and by hydrogen-exchange experiments that indicate that the amide protons of residues 75-82 are in fast exchange (kexch greater than 10 s-1 at pH 7, 35 degrees C) with the solvent. No changes in secondary structure are observed for the first helix of site I or the C-terminal helix of site IV. Upon complexation with M13, a significant decrease in the amide exchange rate is observed for residues T110, L112, G113, and E114 at the end of the second helix of site III.     

Solution studies of staphylococcal nuclease H124L. 2. 1H, 13C, and 15N chemical shift assignments for the unligated enzyme and analysis of chemical shift changes that accompany formation of the nuclease-thymidine 3',5'-bisphosphate-calcium ternary complex.

Accurate 1H, 15N, and 13C chemical shift assignments were determined for staphylococcal nuclease H124L (in the absence of inhibitor or activator ion). Backbone 1H and 15N assignments, obtained by analysis of three-dimensional 1H-15N HMQC-NOESY data [Wang, J., Mooberry, E.S., Walkenhorst, W.F., & Markley, J. L. (1992) Biochemistry (preceding paper in this issue)], were refined and extended by a combination of homo- and heteronuclear two-dimensional NMR experiments. Staphylococcal nuclease H124L samples used in the homonuclear 1H NMR studies were at natural isotopic abundance or labeled randomly with 2H (to an isotope level of 50%); nuclease H124L samples used for heteronuclear NMR experiments were labeled uniformly with 15N (to an isotope level greater than 95%) or uniformly with 13C (to an isotope level of 26%). Additional nuclease H124L samples were labeled selectively by incorporating single 15N- or 13C-labeled amino acids. The chemical shifts of uncomplexed enzyme were then compared with those determined previously for the nuclease H124L.pdTp.Ca2+ ternary complex [Wang, J., LeMaster, D. M., & Markley, J.L. (1990) Biochemistry 29, 88-101; Wang, J., Hinck, A.P., Loh, S. N., & Markley, J.L. (1990) Biochemistry 29, 102-113; Wang, J., Hinck, A.P., Loh, S.N., & Markley, J.L. (1990) Biochemistry 29, 4242-4253]. The results reveal that the binding of pdTp and Ca2+ induces large shifts in the resonances of several amino acid segments. These chemical shift changes are interpreted in terms of changes in backbone torsion angles that accompany the binding of pdTp and Ca2+; changes at the binding site appear to be transmitted to other regions of the molecule through networks of hydrogen bonds.     

Two-and three-dimensional HCN experiments for correlating base and sugar resonances in 15N, 13C-labeled RNA oligonucleotides

Summary New 2D and 3D ¹H-¹³C-¹⁵N triple resonance experiments are presented which allow unambiguous assignments of intranucleotide H1'-H8(H6) connectivities in ¹³C-and ¹⁵N-labeled RNA oligonucleotides. Two slightly different experiments employing double INEPT forward and back coherence transfers are optimized to obtain the H1'-C1'-N9/N1 and H8/H6-C8/C6-N9/N1 connectivities, respectively. The correlation of H1' protons to glycosidic nitrogens N9/N1 is obtained in a nonselective fashion. To correlate H8/H6 with their respective glycosidic nitrogens, selective ¹³C-refocusing and ¹⁵N-inversion pulses are applied to optimize the magnetization transfers along the desired pathway. The approach employs the heteronuclear one-bond spin-spin interactions and allows the 2D ¹H-¹⁵N and 3D¹H-¹³C-¹⁵N chemical shift correlation of nuclei along and adjacent to the glycosidic bond. Since the intranucleotide correlations obtained are based exclusively on through-bond scalar interactions, these experiments resolve the ambiguity of intra-and internucleotide H1'-H8(H6) assignments obtained from the 2D NOESY spectra. These experiments are applied to a 30-base RNA oligonucleotide which contains the binding site for Rev protein from HIV.     

(H)N(COCA)NH and HN(COCA)NH experiments for 1H-15N backbone assignments in 13C/15N-labeled proteins

Triple resonance HN(COCA)NH pulse sequences for correlating 1H(i), 15N(i),1H(i-1), and 15N(i-1) spins that utilize overlapping coherence transfer periods provide increased sensitivityrelative to pulse sequences that utilize sequential coherence transfer periods. Although theoverlapping sequence elements reduce the overall duration of the pulse sequences, theprincipal benefit derives from a reduction in the number of 180° pulses. Two versions of thetechnique are presented: a 3D (H)N(COCA)NH experiment that correlates 15N(i),1H(i-1), and 15N(i-1) spins, and a 3D HN(COCA)NH experiment that correlates 1H(i), 15N(i),1H(i-1), and 15N(i-1) spins by simultaneously encoding the 1H(i) and 15N(i) chemical shiftsduring the t1 evolution period. The methods are demonstrated on a 13C/15N-enriched sampleof the protein ubiquitin and are easily adapted for application to 2H/13C/15N-enrichedproteins.     

Solution structure and fluctuation of the Mg(2+)-bound form of calmodulin C-terminal domain

Calmodulin (CaM) is a Ca(2+)-binding protein that functions as a ubiquitous Ca(2+)-signaling molecule, through conformational changes from the "closed" apo conformation to the "open" Ca(2+)-bound conformation. Mg(2+) also binds to CaM and stabilizes its folded structure, but the NMR signals are broadened by slow conformational fluctuations. Using the E104D/E140D mutant, designed to decrease the signal broadening in the presence of Mg(2+) with minimal perturbations of the overall structure, the solution structure of the Mg(2+)-bound form of the CaM C-terminal domain was determined by multidimensional NMR spectroscopy. The Mg(2+)-induced conformational change mainly occurred in EF hand IV, while EF-hand III retained the apo structure. The helix G and helix H sides of the binding sequence undergo conformational changes needed for the Mg(2+) coordination, and thus the helices tilt slightly. The aromatic rings on helix H move to form a new cluster of aromatic rings in the hydrophobic core. Although helix G tilts slightly to the open orientation, the closed conformation is maintained. The fact that the Mg(2+)-induced conformational changes in EF-hand IV and the hydrophobic core are also seen upon Ca(2+) binding suggests that the Ca(2+)-induced conformational changes can be divided into two categories, those specific to Ca(2+) and those common to Ca(2+) and Mg(2+).     

The carcinogen Cd(2+) activates InsP(3)-mediated Ca(2+) release through a specific metal ion receptor in Xenopus oocyte

The effects of the carcinogen Cd(2+) on Xenopus oocyte were evaluated by Inositol (1,4,5)-trisphosphate (InsP(3)) assays and electrophysiological experiments. The stimulation of the Ca(2+)-dependent Cl(-) current by Cd(2+) is clearly linked to InsP(3) formation since the effects of the metal are antagonized by neomycin, heparin and caffeine. A similar inhibition of the Cd(2+) effects is observed when the oocytes are pretreated with thapsigargin. Moreover, the use of sulfhydryl groups reductors such as 2-mercaptoethanol or N-ethylmaleimide strongly suggests that the Cd(2+) response is mediated by an extracellular receptor. Finally, measurements of InsP(3) production demonstrate that Cd(2+) superfusion actually leads to a PIP(2) breakdown. We conclude that extracellular Cd(2+) evokes an increase in [Ca(2+)](i) by stimulating the emptying of the InsP(3)-sensitive Ca(2+) stores, and that it may do so by interacting with a specific cell-surface ion receptor. This putative ion receptor may be important in allowing oocytes to respond to heavy metals.     

Ca(2+)-binding site in Rhodobacter sphaeroides cytochrome C oxidase

Cytochrome c oxidase (COX) from R. sphaeroides contains one Ca(2+) ion per enzyme that is not removed by dialysis versus EGTA. This is similar to COX from Paracoccus denitrificans [Pfitzner, U., Kirichenko, A., Konstantinov, A. A., Mertens, M., Wittershagen, A., Kolbesen, B. O., Steffens, G. C. M., Harrenga, A., Michel, H., and Ludwig, B. (1999) FEBS Lett. 456, 365-369] and is in contrast to the bovine oxidase, which binds Ca(2+) reversibly. A series of R. sphaeroides mutants with replacements of the E54, Q61, and D485 residues, which form the Ca(2+) coordination sphere in subunit I, has been generated. The substitutions for the E54 residue do not assemble normally. Mutants with the Q61 replacements are active and retain the tightly bound Ca(2+); their spectra are not perturbed by added Ca(2+) or EGTA. The D485A mutant is active, binds to Ca(2+) reversibly, like the mitochondrial oxidase, and exhibits the red shift in the heme a absorption spectrum upon Ca(2+) binding for both reduced and oxidized states of heme a. The K(d) value of 6 nM determined by equilibrium titrations is much lower than that reported for the homologous D477A mutant of Paracoccus denitrificans or for bovine COX (K(d) = 1-3 microM). The rate of Ca(2+) binding with the D485A oxidase (k(on) = 5 x 10(3) M(-1) s(-1)) is comparable to that observed earlier for bovine COX, but the off-rate is extremely slow (approximately 10(-3) s(-1)) and highly temperature-dependent. The k(off) /k(on) ratio (190 nM) is about 30-fold higher than the equilibrium K(d) of 6 nM, indicating that formation of the Ca(2+)-adduct may involve more than one step. Sodium ions reverse the Ca(2+)-induced red shift of heme a and dramatically decrease the rate of Ca(2+) binding to the D485A mutant COX. With the D485A mutant, 1 Ca(2+) competes with 1 Na(+) for the binding site, whereas 2 Na(+) compete with 1 Ca(2+) for binding to the bovine oxidase. This finding indicates that the aspartic residue D442 (a homologue of R. sphaeroides D485) may be the second Na(+) binding site in bovine COX. No effect of Ca(2+) binding to the D485A mutant is evident on either the steady-state enzymatic activity or several time-resolved partial steps of the catalytic cycle. It is proposed that the tightly bound Ca(2+) plays a structural role in the bacterial oxidases while the reversible binding with the mammalian enzyme may be involved in the regulation of mitochondrial function.     

1H, 13C, and 15N backbone assignment and secondary structure of the receptor-binding domain of vascular endothelial growth factor.

Nearly complete sequence-specific 1H, 13C, and 15N resonance assignments are reported for the backbone atoms of the receptor-binding domain of vascular endothelial growth factor (VEGF), a 23-kDa homodimeric protein that is a major regulator of both normal and pathological angiogenesis. The assignment strategy relied on the use of seven 3D triple-resonance experiments [HN(CO)CA, HNCA, HNCO, (HCA)CONH, HN(COCA)HA, HN(CA)HA, and CBCA-(CO)NH] and a 3D 15N-TOCSY-HSQC experiment recorded on a 0.5 mM (12 mg/mL) sample at 500 MHz, pH 7.0, 45 degrees C. Under these conditions, 15N relaxation data show that the protein has a rotational correlation time of 15.0 ns. Despite this unusually long correlation time, assignments were obtained for 94 of the 99 residues; 8 residues lack amide 1H and 15N assignments, presumably due to rapid exchange of the amide 1H with solvent under the experimental conditions used. The secondary structure of the protein was deduced from the chemical shift indices of the 1H alpha, 13C alpha, 13C beta, and 13CO nuclei, and from analysis of backbone NOEs observed in a 3D 15N-NOESY-HSQC spectrum. Two helices and a significant amount of beta-sheet structure were identified, in general agreement with the secondary structure found in a recently determined crystal structure of a similar VEGF construct [Muller YA et al., 1997, Proc Natl Acad Sci USA 94:7192-7197].     

Measurement of 15N relaxation in deuterated amide groups in proteins using direct nitrogen detection

15N chemical shielding tensors contain useful structural information, and their knowledge is essential for accurate analysis of protein backbone dynamics. The anisotropic component (CSA) of 15N chemical shielding can be obtained from 15N relaxation measurements in solution. However, the predominant contribution to nitrogen relaxation from 15N-(1)H dipolar coupling in amide groups limits the sensitivity of these measurements to the actual CSA values. Here we present nitrogen-detected NMR experiments for measuring 15N relaxation in deuterated amide groups in proteins, where the dipolar contribution to 15N relaxation is significantly reduced by the deuteration. Under these conditions nitrogen spin relaxation becomes a sensitive probe for variations in 15N chemical shielding tensors. Using the nitrogen direct-detection experiments we measured the rates of longitudinal and transverse 15N relaxation for backbone amides in protein G in D(2)O at 11.7 T. The measured relaxation rates are validated by comparing the overall rotational diffusion tensor obtained from these data with that from the conventional 15N relaxation measurements in H(2)O. This analysis revealed a 17-24 degree angle between the NH-bond and the unique axis of the 15N chemical shielding tensor.