Proton nuclear magnetic resonance assignments

Structure and lipid interactions of an anti-inflammatory and anti-atherogenic 10-residue class G(*) apolipoprotein J peptide using solution NMR

The surprising observation that a 10-residue class G(⁎) peptide from apolipoprotein J, [113-122]apoJ, possesses anti-inflammatory and anti-atherogenic properties prompted us to delineate its structural characteristics in the presence of normal and oxidized lipid. Towards this, we have determined high-resolution structure of [113-122]apoJ in solution using nuclear magnetic resonance (NMR) spectroscopy and studied its interaction with lipids, including oxidized lipids, using a number of biophysical methods. Circular dichroism and NMR studies established that in the presence of dodecylphosphocholine (DPC) micelle, this peptide adopts amphipathic α-helical structure. The observed Nuclear Overhauser effects indicate that the amphipathic helical structure of the peptide is stabilized by the N-terminal acetyl and C-terminal amide blocking groups. We used isothermal titration calorimetry to measure binding enthalpy of the peptide with DPC micelle, an oxidized lipid, 1-(palmitoyl)-2-(5-keto-6-octene-dioyl) phosphatidylcholine (KOdiA-PC), and the mixture of these two lipids (5mol% KOdiA-PC in DPC micelle). We find that the peptide binding with DPC micelle is associated with an enthalpy change (-16.75±0.16 Kcal/mol) much larger than that resulting from the binding with KodiA-PC (-3.67±0.13 Kcal/mol). Incorporation of a small amount of KOdiA-PC (5mol%) in DPC micelle also results in the lowering of peptide binding enthalpy (-13.43±0.18 Kcal/mol). These results are consistent with overall negative charge and altered conformational properties of oxidized sn-2 chain of KOdiA-PC. Our results have unambiguously established the amphipathic α-helical structure of [113-122]apoJ peptide in the presence of DPC micelle as well as its ability to bind oxidized lipid. These in vitro results help explain the previously observed anti-inflammatory and anti-atherosclerotic properties of this peptide.

Effect of leucine to phenylalanine substitution on the nonpolar face of a class A amphipathic helical peptide on its interaction with lipid: high resolution solution NMR studies of 4F-dimyristoylphosphatidylcholine discoidal complex

Model class A amphipathic helical peptides mimic several properties of apolipoprotein A-I (apoA-I), the major protein component of high density lipoproteins. Previously, we reported the NMR structures of Ac-18A-NH(2) (renamed as 2F because of two phenylalanines), the base-line model class A amphipathic helical peptide in the presence of lipid ( Mishra, V. K., Anantharamaiah, G. M., Segrest, J. P., Palgunachari, M. N., Chaddha, M., Simon Sham, S. W., and Krishna, N. R. (2006) J Biol. Chem. 281, 6511-6519 ). Substitution of two Leu residues on the nonpolar face (Leu(3) and Leu(14)) with Phe residues produced the peptide 4F (so named because of four phenylalanines), which has been extensively studied for its anti-inflammatory and antiatherogenic properties. Like 2F, 4F also forms discoidal nascent high density lipoprotein-like particles with 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC). Since subtle structural changes in the peptide-lipid complexes have been shown to be responsible for their antiatherogenic properties, we undertook high resolution NMR studies to deduce detailed structure of 4F in 4F.DMPC discs. Like 2F, 4F adopts a well defined amphipathic alpha-helical structure in association with the lipid at a 1:1 peptide/lipid weight ratio. Nuclear Overhauser effect (NOE) spectroscopy revealed a number of intermolecular close contacts between the aromatic residues in the hydrophobic face of the helix and the lipid acyl chain protons. Similar to 2F, the pattern of observed peptide-lipid NOEs is consistent with a parallel orientation of the amphipathic alpha helix, with respect to the plane of the lipid bilayer, on the edge of the disc (the belt model). However, in contrast to 2F in 2F.DMPC, 4F in the 4F.DMPC complex is located closer to the lipid headgroup as evidenced by a number of NOEs between 4F and DMPC headgroup protons. These NOEs are absent in the 2F.DMPC complex. In addition, the conformation of the DMPC sn-3 chain in 4F.DMPC complex is different than in the 2F.DMPC complex as evidenced by the NOE between lipid 2.CH and betaCH(2) protons in 4F.DMPC, but not in 2F.DMPC, complex. Based on the results of this study, we infer that the antiatherogenic properties of 4F may result from its preferential interaction with lipid headgroups.

Association of a Model Class A (Apolipoprotein) Amphipathic α Helical Peptide with Lipid

Class A amphipathic helical peptides have been shown to mimic apolipoprotein A-I, the major protein component of high density lipoproteins and have been shown to inhibit atherosclerosis in several dyslipidemic mouse models. Previously we reported the NMR structure of Ac-18A-NH2, the base-line model class A amphipathic helical peptide in a 50% (v/v) trifluoroethanol-d3/water mixture, a membrane-mimic environment (Mishra, V. K., Palgunachari, M. N., Anantharamaiah, G. M., Jones, M. K., Segrest, J. P., and Krishna, N. R. (2001) Peptides 22, 567-573). The peptide Ac-18A-NH2 forms discoidal nascent high density lipoprotein-like particles with 1,2-dimyristoyl-sn-glycero-3-phosphocholine. Because subtle structural changes in the peptide.lipid complexes have been shown to be responsible for their antiatherogenic properties, we undertook high resolution NMR studies to deduce detailed structure of recombinant peptide.1,2-dimyristoyl-sn-glycero-3-phosphocholine complexes. The peptide adopts a well defined amphipathic alpha helical structure in association with the lipid at a 1:1 peptide:lipid weight ratio. Nuclear Overhauser effect spectroscopy revealed a number of intermolecular close contacts between the aromatic residues in the hydrophobic face of the helix and the lipid acyl chain protons. The pattern of observed peptide-lipid nuclear Overhauser effects is consistent with a parallel orientation of the amphipathic alpha helix, with respect to the plane of the lipid bilayer, on the edge of the disc (the belt model). Based on the results of chemical cross-linking and molecular modeling, we propose that peptide helices are arranged in a head to tail fashion to cover the edge of the disc. This arrangement of peptides is also consistent with the pKa values of the Lys residues determined previously. Taken together, these results provide for the first time a high resolution structural view of the peptide.lipid discoidal complexes formed by a class A amphipathic alpha helical peptide.

The nisin-lipid II complex reveals a pyrophosphate cage that provides a blueprint for novel antibiotics

The emerging antibiotics-resistance problem has underlined the urgent need for novel antimicrobial agents. Lantibiotics (lanthionine-containing antibiotics) are promising candidates to alleviate this problem. Nisin, a member of this family, has a unique pore-forming activity against bacteria. It binds to lipid II, the essential precursor of cell wall synthesis. As a result, the membrane permeabilization activity of nisin is increased by three orders of magnitude. Here we report the solution structure of the complex of nisin and lipid II. The structure shows a novel lipid II-binding motif in which the pyrophosphate moiety of lipid II is primarily coordinated by the N-terminal backbone amides of nisin via intermolecular hydrogen bonds. This cage structure provides a rationale for the conservation of the lanthionine rings among several lipid II-binding lantibiotics. The structure of the pyrophosphate cage offers a template for structure-based design of novel antibiotics.

NMR structure of the thromboxane A2 receptor ligand recognition pocket

To overcome the difficulty of characterizing the structures of the extracellular loops (eLPs) of G protein-coupled receptors (GPCRs) other than rhodopsin, we have explored a strategy to generate a three-dimensional structural model for a GPCR, the thromboxane A(2) receptor. This three-dimensional structure was completed by the assembly of the NMR structures of the computation-guided constrained peptides that mimicked the extracellular loops and connected to the conserved seven transmembrane domains. The NMR structure-based model reveals the structural features of the eLPs, in which the second extracellular loop (eLP(2)) and the disulfide bond between the first extracellular loop (eLP(1)) and eLP(2) play a major role in forming the ligand recognition pocket. The eLP(2) conformation is dynamic and regulated by the oxidation and reduction of the disulfide bond, which affects ligand docking in the initial recognition. The reduced form of the thromboxane A(2) receptor experienced a decrease in ligand binding activity due to the rearrangement of the eLP(2) conformation. The ligand-bound receptor was, however, resistant to the reduction inactivation because the ligand covered the disulfide bond and stabilized the eLP(2) conformation. This molecular mechanism of ligand recognition is the first that may be applied to other prostanoid receptors and other GPCRs.

Conformational constraints of tyrosine in protein tyrosine kinase substrates: Information about preferred bioactive side-chain orientation

The side-chain orientation of a tyrosine residue located in a peptide, which is an excellent substrate of Syk tyrosine kinase (A. M. Brunati, A. Donella-Deana, M. Ruzzene, O. Marin, L. A. Pinna, FEBS Letters, 1995, Vol. 367, pp. 149-152), was fixed in the gauche (+) or gauche (-) conformation by using the 7-hydroxy-1,2,3,4-tetrahydro isoquinoline-3-carboxylic (Htc) structure. The tyrosine trans conformation was blocked by using an aminobenzazepine-type (Hba) structure. The proposed side-chain orientations were confirmed by the analysis of the (1)H-NMR parameters: chemical shifts, coupling constants, and nuclear Overhauser effects to the tyrosine constraints in the different analogs. This "rotamer scan" of the phosphorylatable residue allowed us to generate optimal substrates in terms of both phosphorylation efficiency and selectivity for Syk tyrosine kinase. In contrast, these conformationally restricted tyrosine analogs were not tolerated by the Src-related tyrosine kinases Lyn and c-Fgr.

Evidence of the residues involved in ligand recognition in the second extracellular loop of the prostacyclin receptor characterized by high resolution 2D NMR techniques

In previous studies, we have determined the solution structure of the second extracellular loop (eLP(2)) of the human thromboxane A(2) receptor (TP) and identified the residues in the eLP(2) domain involved in ligand recognition, by using a combination of approaches including a constrained synthetic peptide, 2D NMR spectroscopy, and recombinant proteins. These findings led us to hypothesize that the specific ligand recognition sites may be localized in the eLP(2) for all the prostanoid receptors. To test this hypothesis, we have investigated the ligand recognition site for another prostanoid receptor, the prostacyclin receptor (IP), which mediates an opposite biological function compared to that of the TP receptor. The identification of the interaction between the IP receptor and its agonist, iloprost, was achieved with a constrained synthetic peptide mimicking the eLP(2) region of the receptor. The IP eLP(2) segment was designed and synthesized to form a constrained loop, using a homocysteine disulfide bond connecting the ends of the peptide, based on the distance predicted from the IP receptor model created by homology modeling using the crystal structure of bovine rhodopsin as a template. The evidence of the constrained IP eLP(2) interaction with iloprost was found by the identification of the conformational changes of the eLP(2) induced by iloprost using fluorescence spectroscopy, and was further confirmed by 1D and 2D 1H NMR experiments. In addition, the IP eLP(2)-induced structure of iloprost in solution was elucidated through a complete assignment of the 2D 1H NMR spectra for iloprost in the presence of the IP eLP(2) segment. In contrast, no ordered structure was observed in the 2D 1H NMR experiments for iloprost alone in solution. These studies not only identified that the eLP(2) segment of the IP receptor is involved in ligand recognition, but also solved the 3D solution structure of the bound-form of iloprost, which could be used to study the receptor-ligand interaction in structural terms.

NMR study of mersacidin and lipid II interaction in dodecylphosphocholine micelles. Conformational changes are a key to antimicrobial activity

Mersacidin belongs to the type B lantibiotics (lanthionine-containing antibiotics) that contain post-translationally modified amino acids and cyclic ring structures. It targets the cell wall precursor lipid II and thereby inhibits cell wall synthesis. In light of the emerging antibiotics resistance problem, the understanding of the antibacterial activity on a structural basis provides a key to circumvent this issue. Here we present solution NMR studies of mersacidin-lipid II interaction in dodecylphosphocholine (DPC) micelles. Distinct solution structures of mersacidin were determined in three different states: in water/methanol solution and in DPC micelles with and without lipid II. The structures in various sample conditions reveal remarkable conformational changes in which the junction between Ala-12 and Abu-13 (where Abu is aminobutyric acid) effectively serves as the hinge for the opening and closure of the ring structures. The DPC micelle-bound form resembles the previously determined NMR and x-ray crystal structures of mersacidin in pure methanol but substantially deviates from the other two states in our current report. The structural changes delineate the large chemical shift perturbations observed during the course of a two-step (15)N-(1)H heteronuclear single quantum coherence titration. They also modulate the surface charge distribution of mersacidin suggesting that electrostatics play a central role in the mersacidin-lipid II interaction. The observed conformational adaptability of mersacidin might be a general feature of lipid II-interacting antibiotics/peptides.

Protein structure determination by non-parametric regression and knowledge-based constraints

We have devised a non-parametric regression-based approach for the estimation of small- and medium-range inter-residual three-dimensional (3d) distances in a protein using only the primary sequence as input. A multivariate analysis of variance technique is used to identify the attributes of the primary sequence that is most effective in determining the tertiary structure. Certain compactness and hydrophobic core building heuristics are used along with the estimated distances in a distance geometry program to predict the 3d-structure (tertiary fold). Our method is found to predict correctly the native topologies of small proteins having up to 150 residues. The sensitivity of the structures to long-range distance constraints is studied by incorporating a small number of NMR distance restraints. In terms of modularity, precision, accuracy and computational efficiency our method is found to be better in comparison with current computational methods like X-PLOR and DRAGON on the sample that was reported in the literature for the comparison of these two methods.

Solution NMR structure of a model class A (apolipoprotein) amphipathic alpha helical peptide

To better understand the structural determinants of the physical-chemical and the biological properties of Ac-18A-NH(2) (acetyl-AspTrpLeuLysAlaPheTyrAspLysValAlaGluLysLeuLysGluAlaPhe-amide), we have determined its structure in 50% (v/v) trifluroethanol (TFE-d(3))/water mixture (5 mM potassium phosphate, pH 5.5, 310K) using two-dimensional proton NMR spectroscopy. Stereospecific assignments have been made for C(beta)H protons (all the residues except Ala and Val) and gammaCH(3) (Val) groups. Nuclear Overhauser effects are observed between the nonpolar side chains spaced at (i) and (i + 4) position in the primary sequence, e.g., Trp2 and Phe6, and Phe6 and Val10. This suggests that in addition to N-terminal acetyl and C-terminal amide groups, the amphipathic alpha helical structure of Ac-18A-NH(2) is further stabilized by interactions between the hydrophobic residues on the nonpolar face of the helix.

Identification of the substrate interaction site in the N-terminal membrane anchor segment of thromboxane A2 synthase by determination of its substrate analog conformational changes using high resolution NMR technique

The present studies describe an investigation for the interaction of N-terminal membrane anchor domain of thromboxane A(2) synthase (TXAS) with its substrate analog in a membrane-bound environment using the two-dimensional NMR technique. TXAS and prostaglandin I(2) synthase (PGIS), respectively, convert the same substrate, prostaglandin H(2) (PGH(2)), to thromboxane A(2) and prostaglandin I(2), which have opposite biological functions. Our topology studies have indicated that the N-terminal region of TXAS has a longer N-terminal endoplasmic reticulum (ER) membrane anchor region compared with the same segment proposed for PGIS. The differences in their interaction with the ER membrane may have an important impact to facilitate their common substrate, PGH(2), across the membrane into their active sites from the luminal to the cytoplasmic side of the ER. To test this hypothesis, we first investigated the interaction of the TXAS N-terminal membrane anchor domain with its substrate analog. A synthetic peptide corresponding to the N-terminal membrane anchor domain (residues 1-35) of TXAS, which adopted a stable helical structure and exhibited a membrane anchor function in the membrane-bound environment, was used to interact with a stable PGH(2) analog,. High resolution two-dimensional NMR experiments, NOESY and TOCSY, were performed to solve the solution structures of in a membrane-mimicking environment using dodecylphosphocholine micelles. Different conformations were clearly observed in the presence and absence of the TXAS N-terminal membrane anchor domain. Through combination of the two-dimensional NMR experiments, completed (1)H NMR assignments of were obtained, and the data were used to construct three-dimensional structures of in H(2)O and dodecylphosphocholine micelles, showing the detailed conformation change upon the interaction with the membrane anchor domain. The observation supported the presence of a substrate interaction site in the N-terminal region. The combination of the structural information of and was able to simulate a solution structure of the unstable TXAS and PGIS substrate, PGH(2).

Characterization of substance P-membrane interaction by transferred nuclear Overhauser effect

Substance P, one of the mammalian tachykinins, is known to interact strongly with lipid bilayers and this interaction may play a role in the receptor-peptide recognition process. The conformation of substance P bound to vesicles consisting of perdeuterated phosphatidylcholine has been investigated by means of two-dimensional transferred nuclear Overhauser (trNOE) spectroscopy. Nuclear magnetic resonance data analysis resulted in a unique conformational family characterized by a well-defined conformation of the last seven C-terminal amino acids, which consists of a sequence of nonstandard turns following each other in a helix-like manner. The absence of short- or medium-range trNOE in the N-terminal part indicates its structural flexibility.

The solution structure of Rhodobacter sphaeroides LH1beta reveals two helical domains separated by a more flexible region: structural consequences for the LH1 complex

Here, the solution structure of the Rhodobacter sphaeroides core light-harvesting complex beta polypeptide solubilised in chloroform:methanol is presented. The structure, determined by homonuclear NMR spectroscopy and distance geometry, comprises two alpha helical regions (residue -34 to -15 and -11 to +6, using the numbering system in which the conserved histidine residue is numbered zero) joined by a more flexible four amino acid residue linker. The C-terminal helix forms the membrane spanning region in the intact LH1 complex, whilst the N-terminal helix must lie in the lipid head groups or in the cytoplasm, and form the basis of interaction with the alpha polypeptide. The structure of a mutant beta polypeptide W(+9)F was also determined. This mutant, which is deficient in a hydrogen bond donor to the bacteriochlorophyll, showed an identical structure to the wild-type, implying that observed differences in interaction with other LH1 polypeptides must arise from cofactor binding. Using these structures we propose a modification to existing models of the intact LH1 complex by replacing the continuous helix of the beta polypeptide with two helices, one of which lies at an acute angle to the membrane plane. We suggest that a key difference between LH1 and LH2 is that the beta subunit is more bent in LH1. This modification puts the N terminus of LH1beta close to the reaction centre H subunit, and provides a rationale for the different ring sizes of LH1 and LH2 complexes.

NMR solution structure of domain 1 of human annexin I shows an autonomous folding unit

Annexins are excellent models for studying the folding mechanisms of multidomain proteins because they have four-eight homologous helical domains with low identity in sequence but high similarity in folding. The structure of an isolated domain 1 of human annexin I has been determined by NMR spectroscopy. The sequential assignments of the 1H, 13C, and 15N resonances of the isolated domain 1 were established by multinuclear, multidimensional NMR spectroscopy. The solution structure of the isolated domain 1 was derived from 1,099 experimental NMR restraints using a hybrid distance geometry-simulated annealing protocol. The root mean square deviation of the ensemble of 20 refined conformers that represent the structure from the mean coordinate set derived from them was 0. 57 +/- 0.14 A and 1.11 +/- 0.19 A for the backbone atoms and all heavy atoms, respectively. The NMR structure of the isolated domain 1 could be superimposed with a root mean square deviation of 1.36 A for all backbone atoms with the corresponding part of the crystal structure of a truncated human annexin I containing all four domains, indicating that the structure of the isolated domain 1 is highly similar to that when it folded together with the other three domains. The result suggests that in contrast to isolated domain 2, which is largely unfolded in solution, isolated domain 1 constitutes an autonomous folding unit and interdomain interactions may play critical roles in the folding of annexin I.

Solution structure of a beta-neurotoxin from the New World scorpion Centruroides sculpturatus Ewing

We report the detailed solution structure of the 7.2 kDa protein CsE-I, a beta-neurotoxin from the New World scorpion Centruroides sculpturatus Ewing. This toxin binds to sodium channels, but unlike the alpha-neurotoxins, shifts the voltage of activation toward more negative potentials causing the membrane to fire spontaneously. Sequence-specific proton NMR assignments were made using 600 MHz 2D-NMR data. Distance geometry and dynamical simulated annealing refinements were performed using experimental distance and torsion angle constraints from NOESY and pH-COSY data. A family of 40 structures without constraint violations was generated, and an energy-minimized average structure was computed. The backbone conformation of the CsE-I toxin shows similar secondary structural features as the prototypical alpha-neurotoxin, CsE-v3, and is characterized by a short 2(1/2)-turn alpha-helix and a 3-strand antiparallel beta-sheet, both held together by disulfide bridges. The RMSD for the backbone atoms between CsE-I and CsE-v3 is 1.48 A. Despite this similarity in the overall backbone folding, the these two proteins show some important differences in the primary structure (sequence) and electrostatic potential surfaces. Our studies provide a basis for unravelling the role of these differences in relation to the known differences in the receptor sites on the voltage sensitive sodium channel for the alpha- and beta-neurotoxins.

Structure of the fifth EGF-like domain of thrombomodulin: An EGF-like domain with a novel disulfide-bonding pattern

The structure of the fifth EGF-like domain (residues Q387 to E426) of thrombomodulin (TMEGF5) has been determined by two-dimensional NMR. TMEGF5 binds to thrombin with a Ki of 1.9 microM and has been shown to have a novel disulfide bonding pattern in a fully active fragment of TM. In EGF, the disulfide bonding pattern is (1-3,2-4, 5-6), while TMEGF5 has an uncrossed (1-2,3-4,5-6) pattern. The structure of this novel domain, determined from 483 NOE-derived distance restraints, appears to have diverged from the common EGF-like structure. Superposition of the 14 lowest-energy structures of TMEGF5 gives an overall r.m.s.d. of 1.09 A for the backbone atoms. The central two-stranded beta-sheet common to all EGF-like domains is not present in TMEGF5. The A loop, residues C390 to C395, is twisted away from interacting with the B loop, residues C399 to C407, as in EGF, and is close to the C loop, residues C409 to C421. This twist causes the N and C termini to be closer together in TMEGF5 than in EGF. Most of the residues that are important for activity lie on one face of the molecule, which is likely to be the thrombin-binding surface of the domain. The structure of the C loop within the domain, which is a beta-hairpin similar to EGF, is similar to the structure of a synthetic version of the loop bound to thrombin as determined by transferred NOE experiments. Despite the similarity in the structures of the loops, the residues immediately following C421 are in different positions in the two structures suggesting that these "tail" residues may change conformation upon thrombin binding.

The three-dimensional solution structure of the lantibiotic murein-biosynthesis-inhibitor actagardine determined by NMR

The three-dimensional solution structure of the lantibiotic actagardine was determined at high resolution by homonuclear and heteronuclear two-dimensional and three-dimensional NMR spectroscopy in [2H3]acetonitrile/H2O (7:3). 133 non-trivial distance and 22 torsional-angle constraints were derived from the NMR data. An ensemble of 15 low-energy structures was calculated by distance geometry followed by an iterative relaxation-matrix-refinement procedure. The rmsd of the backbone coordinates with respect to the average structure was 17 pm. The two distinct thioether ring systems 1-6 and 7-19 were even better defined, with backbone rmsd of 10 pm and 14 pm, respectively. Actagardine shows a rigid compact globular shape based on the constraining bridging pattern, which is composed of an N-terminal lanthionine ring from residues 1-6 and three intertwined C-terminal methyllanthionine rings comprising residues 7-12, 9-17 and 14-19. In addition, this C-terminal ring system is stabilised by a short antiparallel beta sheet. A feature of the actagardine structure is the presence of two putative binding pockets. A pocket is generated by the covalent constraints of the C-terminal thioether ring system. The rim of this pocket is built up by a loop structure comprising residues 12-19, whose backbone amide protons are all directed to the centre of the pocket. The second pocket is formed by an L-shaped orientation of the N-terminal and C-terminal thioether ring systems. The only two hydrophilic amino acid residues of actagardine, Glu11 and Ser2, are directed to this pocket. A region of high sequence similarity with the related lantibiotic mersacidin is located exactly at the position of the second pocket (residues 3-12). This suggests that the second pocket is responsible for the antibiotic mode of action of actagardine and mersacidin as inhibitors of the murein biosynthesis of gram-positive bacteria.

Solution structures of a highly insecticidal recombinant scorpion alpha-toxin and a mutant with increased activity

The solution structure of a recombinant active alpha-neurotoxin from Leiurus quinquestriatus hebraeus, Lqh(alpha)IT, was determined by proton two-dimensional nuclear magnetic resonance spectroscopy (2D NMR). This toxin is the most insecticidal among scorpion alpha-neurotoxins and, therefore, serves as a model for clarifying the structural basis for their biological activity and selective toxicity. A set of 29 structures was generated without constraint violations exceeding 0.4 A. These structures had root mean square deviations of 0.49 and 1.00 A with respect to the average structure for backbone atoms and all heavy atoms, respectively. Similarly to other scorpion toxins, the structure of Lqh(alpha)IT consists of an alpha-helix, a three-strand antiparallel beta-sheet, three type I tight turns, a five-residue turn, and a hydrophobic patch that includes tyrosine and tryptophan rings in a "herringbone" arrangement. Positive phi angles were found for Ala50 and Asn11, suggesting their proximity to functionally important regions of the molecule. The sample exhibited conformational heterogeneity over a wide range of experimental conditions, and two conformations were observed for the majority of protein residues. The ratio between these conformations was temperature-dependent, and the rate of their interconversions was estimated to be on the order of 1-5 s(-1) at 308 K. The conformation of the polypeptide backbone of Lqh(alpha)IT is very similar to that of the most active antimammalian scorpion alpha-toxin, AaHII, from Androctonus australis Hector (60% amino acid sequence homology). Yet, several important differences were observed at the 5-residue turn comprising residues Lys8-Cys12, the C-terminal segment, and the mutual disposition of these two regions. 2D NMR studies of the R64H mutant, which is 3 times more toxic than the unmodified Lqh(alpha)IT, demonstrated the importance of the spatial orientation of the last residue side chain for toxicity of Lqh(alpha)IT.

Polyamine spider toxins and mammalian N-methyl-D-aspartate receptors. Structural basis for channel blocking and binding of argiotoxin636

Recombinant N-methyl-D-aspartate receptors composed of NR1/NR2A subunits were expressed in Xenopus oocytes to analyse the voltage-dependent and use-dependent channel blocking activity of argiotoxin636. Functional assays demonstrate that the toxin competes with other open channel blockers such as Mg2+ and MK-801. Direct binding or competition assays using radiolabeled ligands and isolated rat brain membranes, in contrast, reveal no specific binding or yield binding constants which differ by orders of magnitude from the IC50 values of the functional assays. One explanation is that argiotoxin636 does not bind with high affinity to the inhibitory site in the N-methyl-D-aspartate-receptor channel under in vitro conditions when membranes are depolarised. The structure of argiotoxin636 was investigated by NMR spectroscopy. In solution the positively charged argiotoxin636 acquires an extended conformation and its dimensions might allow permeation deep into the channel. In the absence of direct structural information on the channel protein, the detailed analysis of blockade in conjunction with structural information, as provided here, may be of aid in the deduction of structural features of glutamate-receptor channel ion pores.

Solution conformations of proline rings in proteins studied by NMR spectroscopy

Three different conformations of proline rings in a protein in solution, Up, Down and Twist, have been distinguished, and stereospecific assignments of the pyrrolidine beta-, gamma- and delta-hydrogens have been made on the basis of 1H-1H vicinal coupling constant patterns and intraresidue NOEs. For all three conformations, interhydrogen distances in the pairs alpha-beta 3, beta 3-gamma 3, beta 2-gamma 2, gamma 2-delta 2, and gamma 3-delta 3 (2.3 A) are shorter than those in the pairs alpha-beta 2, beta 2-gamma 3, beta 3-gamma 2, gamma 2-delta 3, and gamma 3-delta 2 (2.7-3.0 A), resulting in stronger NOESY cross peaks. For the Up conformation, the beta 3-gamma 2 and gamma 2-delta 3 spin-spin coupling constants are small (< 3 Hz), and weak cross peaks are obtained in a short-mixing-time (10 ms) TOCSY spectrum; all other vicinal coupling constants are in the range 5-12 Hz, and result in medium to strong TOCSY cross peaks. For the Down form, the alpha-beta 2, beta 2-gamma 3, and gamma 3-delta 2 vicinal coupling constants are small, leading to weak TOCSY cross peaks; all other couplings again are in the range 5-12 Hz, and result in medium to strong TOCSY cross peaks. In the case of a Twist conformation, dynamically averaged coupling constants are anticipated. The procedure has been applied to bovine pancreatic trypsin inhibitor and Cucurbita maxima trypsin inhibitor-V, and ring conformations of all prolines in the two proteins have been determined.

Solution structure of omega-conotoxin MVIIA using 2D NMR spectroscopy

The solution structure of omega-conotoxin MVIIA (SNX-111), a peptide toxin from the fish hunting cone snail Conus magus and a high-affinity blocker of N-type calcium channels, was determined by 2D NMR spectroscopy. The backbones of the best 44 structures match with an average pairwise RMSD of 0.59 angstroms. The structures contain a short segment of triple-stranded beta-sheet involving residues 6-8, 20-21, and 24-25. The structure of this toxin is very similar to that of omega-conotoxin GVIA with which is has only 40% sequence homology, but very similar calcium channel binding affinity and selectivity.

Synthesis, molecular modelling, and NMR structure determination of four cyclic peptide antagonists of endothelin

A combined distance geometry and molecular mechanics/dynamics (MM/MD) protocol was unable to predict the active conformation of the cyclic pentapeptide inhibitor of endothelin-1 receptor, BQ-123, and two analogues. However, the MM/MD method alone is sufficient to predict the solution conformation of a third analogue. In that one case, the combination of proline at residue 3 and an N alpha-methyl substitution at residue 5 provides enough internal constraints to eliminate conformational flexibility seen in the other three analogues. For this constrained analogue, the 50 lowest energy conformations (out of a set of 500 DGEOM-generated, MM/MD minimized conformations) differ by no more than 3.9 kcal/mol. Thirty three of these 50 conformations have backbone atom RMSDs of less than 0.33 A, relative to the lowest energy conformation. The accuracy of this MM/MD model is verified by determining the solution structure of each of the four analogues with 2D NMR techniques. Each of the cyclic pentapeptides has a well defined solution conformation where a proline residue is clearly in a gamma-turn, leaving the remaining residues in a loose beta-turn. All four experimental NMR conformations agree closely with the MM/MD model.

Phosphophoryn, a biomineralization template protein: pH-dependent protein folding experiments

The protein folding behavior of a polyelectrolyte protein, bovine dentine phosphophoryn (BDPP), in the pH range of 1.82-11.0 has been investigated. One- and two-dimensional nmr spectroscopy has been utilized to obtain proton spin assignments for amino acid residues in D2O and in H2O. One-dimensional 31P-nmr experiments verify the existence of three separate classes of O-phosphoserine (PSer) resonances in BDPP (alpha, beta, chi), representing three distinct PSer residue populations at pH 6.94. By means of pH titration and 1H-nmr, five populations of Asp residues can be identified. Three of these populations exhibit secondary inflection points on their pH titration curves that correspond to an observed pKa of 6.17-6.95. The presence or absence of secondary inflection points for Asp populations and the 31P-nmr chemical shift dispersion for the three PSer residue populations indicate that BDPP may be comprised of homologous (Asp-Asp)n. (PSer-PSer)n, and heterologous (PSer-Asp)n sequences arranged into polyelectrolyte cluster regions. The pH titration also revealed that certain populations of Ser, Gly, and Pro residues in BDPP exhibit pH-dependent resonance frequency shifts. The "apparent" pKa for the transition points of these frequency shifts corresponds to either the pK1a of Pser monophosphate ester and/or the pKa of Asp COOH group of BDPP polyelectrolyte regions. On the basis of these transition points, we can assign four types of Ser, Gly, or Pro-containing "intervening" regions in BDPP, based on their sensitivity to protonation and deprotonation events occurring at (Asp)n, (PSer)n, or (PSer-Asp)n anionic cluster regions that flank the intervening regions. Our 1H-nmr experiments also reveal that BDPP assumes a folded conformation at low pH. As the pH increases, this conformation undergoes several unfolding transitions as the BDPP molecule assumes more open conformations in response to increased electrostatic repulsion between polyelectrolyte anionic regions in the protein. These folding-unfolding transitions are mediated by the intervening regions, which act as "hinges" to allow the polyelectrolyte regions to fold relative to one another.

Conformational analysis of CCK-B agonists using 1H-NMR and restrained molecular dynamics: comparison of biologically active Boc-Trp-(N-Me) Nle-Asp-Phe-NH2 and inactive Boc-Trp-(N-Me)Phe-Asp-Phe-NH2

The tetrapeptide Boc-Trp-(N-Me)Nle-Asp-Phe-NH2 is a potent CCK-B agonist. Replacement in this analogue of the norleucine residue by a phenylalanine, to yield Boc-Trp-(N-Me) Phe-Asp-Phe-NH2, led to a 740-fold decrease in affinity whereas the same decrease in affinity was not observed in their nonmethylated counterparts. In order to ascertain the conformational preferences of these two N-methylated tetrapeptides, a study by two-dimensional (2D) nmr spectroscopy and molecular modeling was undertaken. The solution conformation of the two peptides was examined by 1H-nmr in a d6-DMSO/H2O (80:20) mixture. A cis-trans equilibrium, induced by N-methylation, was observed for both analogues, and the proton spectra of the two rotamers were fully characterized in each case. 1H-1H distance constraints, derived from 2D nuclear Overhauser effect spectroscopy and rotating frame nuclear Overhauser effect spectroscopy experiments, were used as inputs for subsequent restrained molecular dynamics simulations. Comparisons of the nmr and molecular modeling data point toward distinct conformational preferences for these two peptides with an opposite spatial orientation of the Trp residue, and could explain the large difference in their biological activities. Furthermore, the tridimensional structure of Boc-Trp-(N-Me)Nle-Asp-Phe-NH2 could serve as a model for the design of nonpeptide CCK-B agonists.

Solution structure of RP 71955, a new 21 amino acid tricyclic peptide active against HIV-1 virus

The structure of RP 71955, a new tricyclic 21 amino acid peptide active against human immunodeficiency virus 1, was determined. Its amino acid composition was inferred from the results of fast atom bombardment mass spectrometry, nuclear magnetic resonance, Raman spectroscopy, and amino acid analysis. Its sequence could not be determined classically, using Edman degradation, given the lack of a free terminal NH2. It was deduced from the interpretation of interresidue nuclear Overhauser effects and confirmed by the sequencing of peptides obtained by limited chemical hydrolysis. It was found to be CLGIGSCNDFAGCGYAVVCFW. An internal amide bond between the NH2 of C1 and the gamma-COOH of D9 was observed, as well as two disulfide bridges, one between C1 and C13 and one between C7 and C19. The three-dimensional structure of RP 71955 was determined from nuclear magnetic resonance derived constraints using distance geometry, restrained molecular dynamics, nuclear Overhauser effect back calculation, and an iterative refinement using a full relaxation matrix approach. Analogies between the structure of RP 71955 and some functional domains of gp41, the transmembrane protein of human immunodeficiency virus 1, suggest hypotheses concerning the mode of action of RP 71955.

The solution structure of the histidine-containing protein (HPr) from Staphylococcus aureus as determined by two-dimensional 1H-NMR spectroscopy

The three-dimensional solution structure of the heat-stable phosphocarrier protein HPr from Staphylococcus aureus was determined from two-dimensional NMR data by restrained molecular dynamics. It consists of a large twisted antiparallel beta-pleated sheet with four strands A, B, C, and D of amino acids 2-7, 34-37, 40-42 and 60-65. Three right-handed helices A, B, C (amino acids 18-27, 47-53 and 71-85) are positioned on top of this sheet. The aromatic ring of His15 is located in a cleft formed by amino acids 12-17 and 55-58, only the nitrogen (N delta 1) atom which can be phosphorylated by enzyme I is exposed to the water. The side chains of Thr12 and Arg17 are located close to the histidine ring. The regulatory serine residue (Ser46) is located in a hydrophobic patch, its hydroxyl group is water-accessible but forms hydrogen bonds with the amide groups of the backbone. The general features of the three-dimensional structure are similar to those found in HPr proteins from different microorganisms such as Escherichia coli, Bacillus subtilis and Streptococcus faecalis.

Solution structure by 2D 1H-NMR of a chimeric peptide recognized by galanin and neuropeptide Y receptors

The 25 amino acid residue chimeric peptide M32, galanin(1-13)-neuropeptide Y(25-36)-amide, was synthesized. The peptide was found to be recognized by both galanin and NPY receptors. The solution structure in 30% (v/v) 1,1,1,3,3,3-hexafluoro-2-propanol was examined by 2-D 1H-NMR and by CD. Proton resonance assignments were made, and structures were calculated using DIANA and refined by restrained energy minimization and molecular dynamics. The obtained structures contain an alpha-helical part in the NPY portion of the peptide including residues 13-20, and in some structures it continues to the C-terminal Tyr25. The more flexible N-terminal portion of the peptide has the freedom to approach the C-terminal alpha-helix, via a reverse turn or a nascent alpha-helix, which permits the N-terminus with Trp2 to come into close contact with the C-terminus with Tyr25. Among the ten NMR structures with lowest energy, there are structures reminiscent of the horseshoe shape of aPP, a close relative of NPY with known crystal structure. It appears that the strong alpha-helical character of the NPY (25-36) amide fragment of M32 helps to stabilize structural features in the galanin-derived part of the peptide. It is noteworthy that this rigid NPY portion of M32 does not prevent the recognition of the peptide by galanin receptors; rather, the peptide has unusually high affinity: IC50 = 0.1 nM at galanin receptors. The chimeric peptide M32 is also recognized by NPY receptors with submicromolar affinity (IC50 = 0.25 microM). The availability of a solution structure for peptide M32, which is recognized by two peptide receptors that are both members of the family of G-protein-coupled receptors, may be useful in understanding peptide receptor-ligand interactions and in designing new galanin and NPY receptor ligands.

A comparative study of the solution structures of tachyplesin I and a novel anti-HIV synthetic peptide, T22 ([Tyr5,12, Lys7]-polyphemusin II), determined by nuclear magnetic resonance

The solution structure of tachyplesin I, which was isolated from membrane acid extracts of the hemocytes from the Japanese horseshoe crab (Tachypleus tridentatus), was determined by nuclear magnetic resonance (NMR) and distance geometry calculation. Tachyplesin I takes an antiparallel beta-sheet structure with a type-II beta-turn. Recently, among more than 20 synthetic peptides associated with tachyplesin and its isopeptide (polyphemusin), we found that a novel compound, which we designated as T22 ([Tyr5,12, Lys7]-polyphemusin II), strongly inhibited the human immunodeficiency virus (HIV)-1-induced cytopathic effect and viral antigen expression. The solution structure of T22 was investigated using NMR, and its secondary structure was confirmed to be similar to that of tachyplesin I. The anti-parallel beta-sheet structure and the several amino-acid side chains on the plane of the beta-sheet of T22 are thought to be associated with the expression of anti-HIV activity.

Solution structures of nisin A and its two major degradation products determined by n.m.r

The conformations of nisin and two major degradation products, nisin-(1-32)-peptide (nisin1-32) and des-delta Ala5-nisin1-32 (where delta Ala is alpha beta-didehydroalanine), in aqueous solution have been determined from n.m.r. data. Sequential assignments of the peptides using correlation spectroscopy ('COSY'), homonuclear Hartmann-Hahn spectroscopy ('HOHAHA'), nuclear Overhauser enhancement spectroscopy (NOESY), relayed NOESY and rotating-frame nuclear Overhauser spectroscopy (ROESY) experiments are presented, including stereospecific assignments of beta-methylene protons of the lanthionine residues. ROESY experiments are also used to detect flexible regions in the polypeptide chain. A dynamic-stimulated-annealing approach is used for structural determination. It can be concluded that all these peptides are flexible in aqueous solution, with no experimental evidence of preferred overall conformations; the only defined conformational features are imposed by the presence of the lanthionine residues. Low-temperature studies also reveal that des-delta Ala5-nisin1-32 adopts conformations similar to those when the ring is intact, suggesting that the loss of activity of this degradation product is due to the absence of the delta Ala5 residue rather than to the conformational consequences of ring-opening.

Conformation of [8-arginine]vasopressin and V1 antagonists in dimethyl sulfoxide solution derived from two-dimensional NMR spectroscopy and molecular dynamics simulation

Structural and dynamic properties of [8-arginine]vasopressin and a class of highly potent vasopressin V1 antagonists which contain 3-mercapto-3,3-cyclopentamethylene propionic acid (Mca) in position 1 of the vasopressin sequence have been determined. On the basis of two-dimensional NMR experiments in dimethyl sulfoxide solution, interproton distances were derived according to which model conformations were built and refined using molecular dynamics simulations. The conformation of vasopressin and the V1 antagonists differ mainly in the region of the mutated residue. The antagonistic property was found to be related to an inversed chirality of the disulfide bridge. In all investigated molecules, characteristic beta-turn structure elements were found for the backbone conformation of the endocyclic residues Tyr2-Asn5. For this portion of the peptide sequence, various conformational equilibria were detected which matched different time scales. For [Arg8]vasopressin, averaged NMR parameters were obtained which could be explained by rapid interconversion between different beta-turn geometries, whereas multiple slowly exchanging conformations were observed for the V1 antagonists. V1 antagonists containing sarcosine in position 7 exhibited multiple spectral patterns for the exocyclic part attributed to cis/trans isomerization. The X-ray structure of deamino-oxytocin [Wood, S. P., Tickle, I. J., Treharne, A. M., Pitts, J. E., Mascarenhas, Y., Li, J. Y., Husain, J., Cooper, S., Blundell, T. L., Hruby, V. J., Buku, A., Fischman, A. J. & Wyssbrod, H. R. (1986) Science 232, 633-636] was found to represent one sample of the conformational space covered by the multiple conformations found for [Mca1, Arg8]vasopressin.

Solution structure of mu-conotoxin GIIIA analysed by 2D-NMR and distance geometry calculations

We have investigated the structure of mu-conotoxin GIIIA by 2D-NMR methods. The assignment of 1H NMR spectra and a quantitative analysis of NOE and J-coupling data are presented. These results were used for the calculation of secondary structure elements of mu-conotoxin GIIIA. Distance geometry calculations were carried out to define the global folding of the peptide.

Structural studies of cytochrome b5: complete sequence-specific resonance assignments for the trypsin-solubilized microsomal ferrocytochrome b5 obtained from pig and calf

We report complete sequence-specific proton resonance assignments for the trypsin-solubilized microsomal ferrocytochrome b5 obtained from calf liver. In addition, sequence-specific resonance assignments for the main-chain amino acid protons (i.e., C alpha, C beta, and amide protons) are also reported for the porcine cytochrome b5. Assignment of the majority of the main-chain resonances was rapidly accomplished by automated procedures that used COSY and HOHAHA peak coordinates as input. Long side chain amino acid spin system identification was facilitated by long-range coherence-transfer experiments (HOHAHA). Problems with resonance overlap were resolved by examining differences between the two-dimensional 500-MHz NMR spectra of rabbit, pig, and calf proteins and by examining the temperature-dependent variation of amide proton resonances. Calculations of the aromatic ring-current shifts for protons that the X-ray crystal structure indicated were proximal to aromatic residues were found to be useful in corroborating assignments, especially those due to the large shifts induced by the heme. Assignment of NOESY cross peaks was greatly facilitated by a prediction of intensities using a complete relaxation matrix analysis based on the crystal structure. These results suggest that the single-crystal X-ray structure closely resembles that of the solution structure although there is evidence that the solution structure has a more dynamic character.