Refined solution structure of the DNA-binding domain of GAL4 and use of 3J(113Cd,1H) in structure determination.

We have refined the solution structure of cadmium-bound GAL4 and present its 15N and 1H NMR assignments. The root-mean-square (rms) deviation to the average structure was 0.4 +/- 0.05 A for backbone atoms, and 0.9 +/- 0.1 A for all heavy atoms. The three-bond heteronuclear 3J(113Cd,1H) coupling constants were found to disobey a Karplus-type relationship, which was attributable to the unusual constraints imposed by the bimetal-thiolate cluster in GAL4. We conclude that the structural parameters that correlate to 3J(113Cd,1H) are complex.

Nuclear magnetic resonance solution structure of the growth factor receptor-bound protein 2 Src homology 2 domain.

A family of NMR solution structures of the growth factor receptor-bound protein 2 (Grb2) SH2 domain has been determined by heteronuclear multidimensional NMR. Proton, nitrogen, and carbon chemical shift assignments have been made for the SH2 domain of Grb2. Assignments were made from a combination of homonuclear two-dimensional and 15N- and 13C-edited three-dimensional spectra at pH 6.2 and 298 K. Structure-induced proton and carbon secondary shifts were calculated and used to facilitate the spectral assignment process. NOE, scalar coupling, secondary chemical shift, and amide proton exchange data were used to characterize the secondary structural elements and hydrogen-bonding network in the Grb2 SH2 domain. The three-dimensional structure of the Grb2 SH2 domain was calculated using 1112 restraints obtained from NOE, coupling constant, and amide proton exchange data. The rmsd for the 24 calculated structures to the mean structure of the Grb2 SH2 domain was 0.75 A for backbone and 1.28 A for all heavy atoms. The three-dimensional fold of the Grb2 SH2 domain is similar to that observed for other SH2 domains and consists of two alpha-helical segments and eight beta-strands, six strands that make up two contiguous antiparallel beta-sheets, and two strands that form two short parallel beta-sheets. The structure of the phosphotyrosine binding pocket of Grb2 is similar to that observed for other SH2 domains. The hydrophobic binding pocket of Grb2 is similar to that observed for Src with the exception that tryptophan 121 of Grb2 occupies part of the pY+3 binding pocket. Structural implications for the Grb2 SH2 domain selectivity at the pY+2 and pY+3 sites are discussed.

The solution structure of omega-Aga-IVB, a P-type calcium channel antagonist from venom of the funnel web spider, Agelenopsis aperta.

The 48 amino acid peptides omega-Aga-IVA and omega-Aga-IVB are the first agents known to specifically block P-type calcium channels in mammalian brain, thus complementing the existing suite of pharmacological tools used for characterizing calcium channels. These peptides provide a new set of probes for studies aimed at elucidating the structural basis underlying the subtype specificity of calcium channel antagonists. We used 288 NMR-derived constraints in a protocol combining distance geometry and molecular dynamics employing the program DGII, followed by energy minimization with Discover to derive the three-dimensional structure of omega-Aga-IVB. The toxin consists of a well-defined core region, comprising seven solvent-shielded residues and a well-defined triple-stranded beta-sheet. Four loop regions have average backbone rms deviations between 0.38 and 1.31 A, two of which are well-defined type-II beta-turns. Other structural features include disordered C- and N-termini and several conserved basic amino acids that are clustered on one face of the molecule. The reported structure suggests a possible surface for interaction with the channel. This surface contains amino acids that are identical to those of another known P-type calcium channel antagonist, omega-Aga-IVA, and is rich in basic residues that may have a role in binding to the anionic sites in the extracellular regions of the calcium channel.

Design and structure-activity relationships of C-terminal cyclic neurotensin fragment analogues.

Neurotensin (NT) is a linear tridecapeptide with a broad range of central and peripheral pharmacological effects. The C-terminal hexapeptide of NT (NT8-13) has been shown to possess similar properties to NT itself, and in fact, an analogue of NT8-13 (N alpha MeArg8-Lys-Pro-Trp-Tle-Leu13, Tle = tert-leucine) has been reported to possess central activity after peripheral administration. Cyclic derivatives of this hexapeptide were synthesized by a combination of solution and solid-phase peptide synthetic methodologies, and several analogues had low nanomolar binding affinity for the NT receptor. In particular, cyclo[Arg-Lys-Pro-Trp-Glu]-Leu (cyclized between the alpha amine of Arg and the gamma carboxylate of Glu) possessed 16 nM NT receptor affinity and was determined to be an agonist in vitro. 1H-NMR and 13C-edited 1H-NMR spectroscopy were performed on this and related cyclic analogues to help identify structural properties which may be important for receptor recognition. These cyclic peptides represent novel molecular probes to further investigate NT receptor pharmacology, as well as to advance our understanding of the structure-conformation relationships of NT and to help establish a working basis for additional pharmacophore mapping studies.

The 13C chemical shifts of amino acids in aqueous solution containing organic solvents: application to the secondary structure characterization of peptides in aqueous trifluoroethanol solution.

The 13C chemical shifts for all of the protonated carbons of the 20 common amino acid residues in the protected linear pentapeptide Gly-Gly-X-Gly-Gly have been obtained in water at low pH as well as in aqueous solution containing 10, 20 and 30% acetonitrile or trifluoroethanol. Dioxane was used as an internal reference and its carbon chemical shift value was found to be 66.6 ppm relative to external TMS in water. Comparison of the different referencing methods for 13C chemical shifts in organic cosolvent mixtures showed that an external standard (either TMS or TSP capillary) was the most appropriate. In the present study, external TSP was chosen to define the 0 ppm of the 13C chemical shift scale. When the difference in referencing the dioxane carbon resonance is taken into account, the carbon chemical shift values of the amino acids in aqueous solution are similar to those previously reported (Richarz and Wüthrich (1978) Biopolymers, 17, 2133-2141; Howarth and Lilley (1979) Prog. NMR Spectrose., 12, 1-40). The pentapeptides studied were assumed to be in a random coil conformation and the measured 13C chemical shifts were used as reference values to correlate carbon chemical shifts with the secondary structure of two well-characterized peptides, bombesin and the 1-29 amino acid fragment of Nle27 human growth hormone-releasing factor. In both cases, the C alpha chemical shifts exhibited a characteristic positive deviation from the random coil values, which indicates the presence of alpha-helices.

Structure and properties of omega-agatoxin IVB, a new antagonist of P-type calcium channels.

A new peptide antagonist of voltage-activated calcium channels was purified from venom of the funnel web spider, Agelenopsis aperta. This 48-amino acid peptide, omega-agatoxin (omega-Aga)-IVB, was found to be a potent (Kd, approximately 3 nM) blocker of P-type calcium channels in rat cerebellar Purkinje neurons but had no activity against T-type, L-type, or N-type calcium channels in a variety of neurons. The calcium channel-blocking properties of omega-Aga-IVB were similar to those of another toxin, omega-Aga-IVA, which has 71% amino acid identity with omega-Aga-IVB. The 10-fold greater abundance of omega-Aga-IVB in venom allowed structural studies using NMR spectroscopy. The three-dimensional structure derived from NMR data resulted in a proposed disulfide bond configuration for the peptide. Although omega-Aga-IVB has fewer basic and more acidic residues than does omega-Aga-IVA, the two toxins show conservation of positively charged residues in a mid-peptide region that is predicted to form one face of the omega-Aga-IVB molecule. This region may be crucial for high affinity binding to the P-type calcium channel. In contrast, the amino termini of the two toxins have different charges and seem unlikely to be involved in binding to the channel.

Secondary structure and backbone resonance assignments of the periplasmic cyclophilin type peptidyl-prolyl isomerase from Escherichia coli.

Proton, carbon-13, and nitrogen-15 sequence-specific backbone assignments have been obtained for the periplasmic cyclophilin type cis-trans peptidyl-prolyl isomerase from Escherichia coli (167 residues, M(r) = 18,244). Assignments were obtained using both 1H, 13C, and 15N triple-resonance and 1H and 15N double-resonance three-dimensional (3D) NMR spectroscopy at pH 6.2, 25 degrees C. Complete or partial residue-specific assignments have been obtained for 165 of the 167 residues. The secondary structure has been characterized using long- and medium-range NOEs. The protein consists of an eight-stranded anti-parallel beta-sheet and two helices. The overall topology of E. coli cyclophilin is similar to that of human T-cell cyclophilin. Sequence alignment with human T-cell cyclophilin based on secondary structure homology implicates several residues in E. coli cyclophilin that may be crucial for binding the peptide substrate AC-A-A-P-A-AMC and the immunosuppressive drug cyclosporin A.

Design, synthesis and solution structure of a renin inhibitor. Structural constraints from NOE, and homonuclear and heteronuclear coupling constants combined with distance geometry calculations.

A macrocyclic renin inhibitor was designed using molecular modeling and a model of human renin. The synthesized molecular displayed poor binding affinity. To investigate the reasons for the observed inactivity, the structure of the compound has been studied by NMR spectroscopy and distance geometry. Structural constraints for distance geometry calculations were derived from nuclear Overhauser effects and homonuclear and heteronuclear three bond coupling constants. Homonuclear coupling constants were measured directly from the resolution-enhanced proton spectra and heteronuclear coupling constants were measured from the natural abundance 15N- and 13C-edited TOCSY experiments. One phi angle was determined uniquely by this method and two were reduced to two possible values each. By using a statistical analysis of 400 structures generated with distance geometry, two families of structures were found to be consistent with the NMR data. The solution structures so derived were different from the originally designed structure, including an internal hydrogen bond. This provides a possible explanation for the lack of effectiveness of this compound.

NMR studies of structure and dynamics of isotope enriched proteins.

Structural studies of globular proteins by nmr can be enhanced by the use of isotope enrichment. We have been working with proteins enriched with 15N, and with both 15N and 13C. Due to the isotope enrichment we could assign several large proteins with up to 186 residues and could address structural questions. Furthermore, we can accurately measure heteronuclear and homonuclear vicinal coupling constants. This involves in part multidimensional multiple resonance experiments. This is important for characterization of minor conformational changes caused by mutations. We have also made use of isotope enrichment to study the internal mobility of proteins. We also have developed novel methods for measuring accurately 15N relaxation parameters, in particular transverse relaxation rates. This has led us toward a method for directly mapping spectral density functions of the rotational motions of N-H bond vectors in proteins. The protein systems that are discussed include the unlabeled proteins kistrin and cytochrome c551, and the labeled proteins eglin c, a flavodoxin, and human dihydrofolate reductase.

The solution structure of a cyclic endothelin antagonist, BQ-123, based on 1H-1H and 13C-1H three bond coupling constants.

A cyclic pentapeptide endothelin antagonist, cyclo(dTrp-dAsp-Pro-dVal-Leu), recently reported (K. Ishikawa et al., 13th Am. Pept. Symp., Cambridge MA, 1991) has been studied by NMR spectroscopy and molecular modeling. A stable structure has been determined without the use of nuclear Overhauser effects and is based primarily on homonuclear and heteronuclear three bond coupling constants. The 13C-edited TOCSY experiment is demonstrated at natural abundance and approximately 30 mM peptide concentrations. Three bond 13C-1H coupling constants obtained by this method are shown to reduce the ambiguity in phi angle determination which exists when only interproton coupling constants are used. Three out of four phi angles were determined uniquely by this method and the fourth was reduced to two possible values. The proline phi angle was determined to be -78 degrees based on the 3JH alpha, H beta and 3JH alpha, H beta coupling constants. Comparison of amide proton temperature dependence, chemical shifts and vicinal proton coupling constants in a 20% acetonitrile/80% water solvent mixture and in (CD3)2SO indicates that the structure is similar in both solvents.

A new 3D HN(CA)HA experiment for obtaining fingerprint HN-Halpha peaks in 15N- and 13C-labeled proteins.

A new 3D 1H-15N-13C triple resonance experiment is presented that provides in-phase absorptive cross peaks between amide protons and alpha-protons of the same and the sequentially preceding residue. The experiment yields similar connectivities as those described previously by Montelione and Wagner (1990a) (J. Magn. Reson., 87, 183-188) and Kay et al. (1991) (J. Magn. Reson., 91, 84-92). However, the pulse sequence was designed to minimize the time that transverse coherence of the 13Calpha nucleus is present, since this nucleus has the shortest transverse relaxation time of all the nuclei involved in these experiments. This is achieved by using a coherence transfer pathway from 1HN to 15N, 13Calpha, 1Halpha and back to the 1HN. In the sequence described, transverse 13Calpha coherence is present only for a length of ca. 1/1J(Calpha-Halpha). This reduces loss of signal due to transverse relaxation. We tested the technique on uniformly 15N- and 13C-enriched T4 lysozyme.

Solution structure of Fe(II) cytochrome c551 from Pseudomonas aeruginosa as determined by two-dimensional 1H NMR.

The solution structure of Fe(II) cytochrome c551 from Pseudomonas aeruginosa based on 2D 1H NMR data is reported. Two sets of structure calculations were completed with a combination of simulated annealing and distance geometry calculations: one set of 20 structures included the heme-peptide covalent linkages, and one set of 10 structures excluded them. The main-chain atoms were well constrained within the two structural ensembles (1.30 and 1.35 A average RMSD, respectively) except for two regions spanning residues 30-40 and 60-70. The results were essentially the same when global fold comparisons were made between the ensembles with an average RMSD of 1.33 A. In total, 556 constraints were used, including 479 NOEs, 53 volume constraints, and 24 other distances. This report represents the first solution structure determination of a heme protein by 2D 1H NMR and should provide a basis for the application of these techniques to other proteins containing large prosthetic groups or cofactors.

1H and 15N resonance assignments of oxidized flavodoxin from Anacystis nidulans with 3D NMR.

Proton and nitrogen-15 sequence-specific nuclear magnetic resonance assignments have been determined for recombinant oxidized flavodoxin from Anacystis nidulans (169 residues, Mr 19,048). Assignments were obtained by using 15N-1H heteronuclear three-dimensional (3D) NMR spectroscopy on a uniformly nitrogen-15 enriched sample of the protein, pH 6.6, at 30 degrees C. For 165 residues, the backbone and a large fraction of the side-chain proton resonances have been assigned. Medium- and long-range NOE's have been used to characterize the secondary structure. In solution, flavodoxin consists of a five-stranded parallel beta sheet involving residues 3-9, 31-37, 49-56, 81-89, 114-117, and 141-144. Medium-range NOE's indicate the presence of several helices. Several 15N and 1H resonances of the flavin mononucleotide (FMN) prosthetic group have been assigned. The FMN-binding site has been investigated by using polypeptide-FMN NOE's.

Sequential 1H NMR assignments of iron(II) cytochrome c551 from Pseudomonas aeruginosa.

Sequence-specific 1H NMR resonance assignments for all but the C-terminal Lys 82 are reported for iron(II) cytochrome c551 from Pseudomonas aeruginosa at 25 degrees C and pH = 6.8. Spin systems were identified by using TOCSY and DQF-COSY spectra in 2H2O and 1H2O. Sequential assignments were made by using NOESY connectivities between adjacent amide, alpha, and beta protons. Resonances from several amino acids including His 16, Gly 24, Ile 48, and Met 61 experience strong ring-current shifts due to their placement near the heme. All heme protons, including the previously unassigned propionates, have been identified. Preliminary analysis of sequential and medium-range NOEs provides evidence for substantial amounts of helix in the solution structure. Long-range NOEs indicate that the folds in solution and crystal structures are similar. For one aromatic side chain (Tyr 27) that is close to the heme group we found a transition from hindered ring rotation at low temperature to rapid rotation at high temperature.

A nuclear Overhauser effect investigation of the molecular and electronic structure of the heme crevice in lactoperoxidase.

The proton homonuclear nuclear Overhauser effect, NOE, in conjunction with paramagnetic-induced dipolar relaxation, is utilized to assign resonances and to probe the molecular and electronic structures of the heme cavity in the low-spin cyanide complex of resting-state bovine lactoperoxidase, LPO-CN. Predominantly primary NOEs were detected in spite of the large molecular weight (approximately 78 x 10(3)) of the enzyme, which demonstrates again the advantage of paramagnetism suppressing spin diffusion in large proteins. Both of the nonlabile ring protons of a coordinated histidine are located at resonance positions consistent with a deprotonated imidazole. Several methylene proton pairs are identified, of which the most strongly hyperfine-shifted pair is assigned to the unusual chemically functionalized 8-(mercaptomethylene) group of the prosthetic group [Nichol, A. W., Angel, L. A., Moon, T., & Clezy, P. S. (1987) Biochem. J. 247, 147-150]. The large 8-(mercaptomethylene) proton contact shifts relative to that of the only resolved heme methyl signal are rationalized by the additive perturbations on the rhombic asymmetry of the functionalization of the 8-position and the alignment of the axial histidyl imidazole projection along a vector passing through pyrrole A and C of the prosthetic group. Such a stereochemistry is consistent with the resolution of only a single heme methyl group, 3-CH3, as observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Deuterium NMR study of structural and dynamic properties of horseradish peroxidase.

High field deuterium NMR spectra have been recorded for various horseradish peroxidase complexes reconstituted with hemins possessing specific 2H labels. The line width of the 2H NMR signals of deuteroheme reconstituted-horseradish peroxidase (HRP) and its cyano complex for the immobilized skeletal 2-2H and 4-2H labels yield the overall protein rotational correlation time (22 ms at 55 degrees C), which is consistent with expectations based on molecular weight. Meso-2H4 labels yield broad (1.3 kHz) signals just upfield from the diamagnetic protein envelope for HRP, and in the central portion of the protein envelope for the CN- ligated resting state HRP. Meso-2H4-labeled mesohemin-reconstituted HRP exhibits a similar signal but shifted further upfield by approximately 10 ppm. The net upfield meso-H hyperfine shifts confirm a five-coordinate structure for resting state HRP. 2Ha resonances for essentially rotationally immobile vinyl groups were detected in both resting state HRP and CN- ligated resting state HRP. Heme methyl-2H-labeling yields relatively narrow lines (approximately 80 Hz) indicative of effective averaging of the quadrupolar relaxation by rapid methyl rotation. Thus the 2H line width of rapidly rotating methyls in hemoproteins can be used effectively to determine the overall protein tumbling rate. Preliminary 2H experiments in meso-2H4-labeled compound I do not support large pi spin density at these positions on the porphyrin cation radical, and argue for a a1u rather than a a2u orbital ground state.

A nuclear Overhauser effect study of the heme crevice in the resting state and compound I of horseradish peroxidase: evidence for cation radical delocalization to the proximal histidine.

The assignment of resolved hyperfine-shifted resonances in high-spin resting state horseradish peroxidase (HRP) and its double-oxidized reactive form, compound I (HRP-I), has been carried out by using the nuclear Overhauser effect (NOE) starting with the known heme methyl assignments in each species. In spite of the efficient spin-lattice relaxation and very broad resonances, significant NOEs were observed for all neighboring pyrrole substituents, which allowed the assignment of the elusive propionate alpha-methylene protons. In the resting state HRP, this leads directly to the identity of the proximal His-170 H beta peaks. The determination that one of the most strongly contact-shifted single proton resonances in HRP-I does not arise from the porphyrin dictates that the cation radical must be delocalized to some amino acid residue. The relaxation properties of the non-heme contact-shifted signal in HRP-I support the identity of this contributing residue as the proximal His-170. Detailed analysis of changes in both contact shift pattern and NOEs indicates that compound I formation is accompanied by a approximately 5 degree rotation of the 6-propionate group. The implication of a porphyrin cation radical delocalized over the proximal histidine for the proposed location of the solely amino acid centered radical in compound I of related cytochrome c peroxidase is discussed.

1H-NMR heme resonance assignments by selective deuteration in low-spin complexes of ferric hemoglobin A.

The heme methyl and vinyl alpha-proton signals have been assigned in low-spin ferric cyanide and azide ligated derivatives of the intact tetramer of hemoglobin A, as well as the isolated chains, by reconstituting the proteins with selectively deuterated hemins. For the hemoglobin cyanide tetramer, assignment to individual subunits was effected by forming hybrid hemoglobins possessing isotope-labeled hemins in only one type of subunit. The heme methyl contact shift pattern has 1-methyl and 5-methyl shifts furthest downfield in both chains and the individual subunits of the intact hemoglobin in both the cyanide- and azide-ligated species, which is consistent with a dominant rhombic perturbation due to the proximal His-F8 imidazole pi bonding in the known structure for human adult hemoglobin. The individual chain and subunit assignments confirm that the detailed electronic/magnetic properties of the heme pocket are essentially unaltered upon assembling the R-state tetramer from the isolated subunits.

NMR study of the molecular and electronic structure of the heme cavity of Aplysia metmyoglobin. Resonance assignments based on isotope labeling and proton nuclear Overhauser effect measurements.

The 1H NMR characteristics of the high-spin metmyoglobin from the mollusc Aplysia limacina have been investigated and compared with those of the myoglobin (Mb) from sperm whale. Aplysia metMb exhibits a normal acid----alkaline transition with pK approximately 7.8. In the acidic form, the heme methyl and meso proton resonances have been assigned by 1H NMR using samples reconstituted with selectively deuterated hemins and in the latter case by 2H NMR as well. On the basis of the methyl peak intensities and shift pattern, heme rotational disorder could be established in Aplysia Mb; approximately 20% of the protein exhibits a reversed heme orientation compared to that found in single crystals. Three meso proton resonances have been detected in the upfield region between -16 and -35 ppm, showing that the chemical shift of such protons can serve as a diagnostic probe for a pentacoordinated active site in hemoproteins, as previously shown to be the case in model compounds. The temperature dependence of the chemical shift of the meso proton signals deviates strongly from the T-1 Curie behavior, reflecting the presence of a thermally accessible Kramers doublet with significant S = 3/2 character. Nuclear Overhauser effect, NOE, measurements on Aplysia metMb have provided the assignment of individual heme alpha-propionate resonances and were used to infer spatial proximity among heme side chains. The hyperfine shift values for assigned resonances, the NOE connectivities, and the NOE magnitudes were combined to reach a qualitative picture of the rotational mobility and the orientation of the vinyl and propionate side chains of Aplysia metMb relative to sperm whale MbH2O.(ABSTRACT TRUNCATED AT 250 WORDS)