Structural studies of neuropeptides composed ofl -Asp andd -Glu by13C-NMR spectroscopy

¹³C-NMR spectral data are presented for four neuropeptides composed ofl-Asp, Ac-l-Asp, andd-Glu, which contain and peptide linkages. The data for the various compounds are compared to related dipeptides, one of which is a known neuropeptide, in order to gain structural information about these compounds. Electron-nuclear relaxation rates were used to elucidate the metal-ion binding sites of these species.     

Nuclear magnetic resonance conformational studies on the chemotactic tripeptide formyl-L-methionyl-L-leucyl-L-phenylalanine. A small beta sheet.

Previous work by several groups has shown that the combination of spin--spin coupling constants and spectral density components (derived from spin--lattice relaxation and/or nuclear Overhauser measurements) may aid in the task of conformational determination of peptides in solution. Using the peptide formyl-L-methionyl-L-leucyl-L-phenylalanine, which is a potent specific chemotactic agent for leucocytes, we show the following: (a) that 3JNHCH coupling constants are consistent with a high degree of rigidity in the peptide backbone in solution, (b) that 3H isotopic substitution in combination with relaxation data taken at different Larmor frequencies enables spectral density, and thence conformational, information to be obtained, (c) that side-chain conformations for this molecule mirror, in some aspects, those found in the solid state for other peptides containing the same residues, and (d) that temperature dependence of amide chemical shifts does not have direct implication concerning the existence of intramolecular hydrogen bonds in peptides. We are able to propose a family of conformations which appear to interchange rapidly on the NMR time scale and are characterized by a distribution of side-chain rotamers. The basic backbone conformation is, or closely approximates, a small beta antiparallel pleated sheet and as such suggests a possible mode of receptor--chemotactic peptide interaction.     

Relaxation kinetics of the triple-stranded helix-coil transition at short chain length. A model including the staggering of chains.

The relaxation kinetics of a staggering zipper model are presented, in which the formation of helical nuclei is regarded to be rate-limiting and in which the sliding of strands along the helices is prohibited. Instead a realignment of staggered chains is only possible via complete uncoiling. While maintaining the third order of the initial reaction as in an all-or-none mechanism, the model predicts a large range of relaxation times, which contribute to the mean relaxation time according to the stability of the individual species and which are weakly coupled in the range of small amounts of helical content. The model can easily be compared to experimental results and agrees well with relaxation data obtained from a triple-helical peptide fragment of collagen. It may be readily expanded to other multistranded helix ? coil transitions with steady-state formation of the individual species and it suggests that the fraying of the helix ends is hidden by the fast-relaxation times due to the equilibration of the shortest helical species.     

High-affinity Ca(2+)- and substrate-binding sites on protein kinase C alpha as determined by nuclear magnetic resonance spectroscopy.

Water proton nuclear magnetic resonance (NMR) relaxation rates were used to identify metal sites on protein kinase C (PKC) isozymes alpha and beta using paramagnetic Gd3+ as a probe. The paramagnetic effect of Gd3+ on water proton relaxation was enhanced with PKC isozymes alpha and beta in the presence of diheptanoylphosphatidylcholine/1,2-dioleoyl-sn-glycerol (PC7/DO). The data are consistent with a single class of metal-binding sites on PKC beta and two classes of sites on PKC alpha: a single high-affinity site with a KD for Gd3+ of 0.2 microM and a larger class of sites with a lower affinity for Gd3+. Titration with Ca2+ abolished the observed enhancement of water proton relaxation by the PKC alpha.Gd3+ complex, consistent with displacement of Gd3+ by Ca2+. Titrations of the PKC alpha.Gd3+ complex with Co(NH3)4ATP, a substitution-inert analogue of ATP, caused a substantial decrease in the observed water proton relaxation enhancement, consistent with formation of a ternary enzyme.metal.substrate complex with a KPKC alpha.Gd.[CoATP] of 30-100 nM. Titration of the metal enzyme complex with a model peptide substrate derived from the pseudosubstrate sequence of PKC alpha caused a similar decrease in enhancement at stoichiometric concentrations consistent with the formation of a PKC alpha.Gd3+.peptide complex with a KPKC alpha.Gd.[peptide] of less than or equal to 13 nM. Titrations of the fully formed PKC alpha.Gd3+.peptide complex with Co(NH3)4ATP caused a further decrease in enhancement consistent with formation of a quaternary complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mammalian beta-adrenergic receptors. Structural differences in beta 1 and beta 2 subtypes revealed by peptide maps

Photoaffinity labeling techniques using p-azido-m-[125I]iodobenzylcarazolol have recently demonstrated that both the beta 1- and beta 2-adrenergic receptor-binding subunits from mammalian tissues including heart, lung, and erythrocytes reside on peptides of Mr approximately equal to 62,000-64,000. In this study, a two-dimensional gel electrophoresis method for peptide mapping was used to investigate and compare the structure of beta 1 - and beta 2-adrenergic receptor subtypes. When the photoaffinity labeled Mr approximately equal to 62,000 peptides from the beta 2-adrenergic receptors of rat lung and erythrocyte are subjected to simultaneous proteolysis using Staphylococcus aureus V8 proteinase or papain, exactly the same peptide fragments are generated from each subunit. In contrast, when the Mr approximately equal to 62,000 peptide containing the beta 1-adrenergic receptor-binding subunit derived from the rat heart is proteolyzed simultaneously with the Mr approximately equal to 62,000 peptide containing the beta 2-adrenergic receptors from either lung or erythrocyte, the peptide fragments generated are distinctly different. Peptide maps of beta 1-adrenergic receptors from the myocardial tissue of different species (pig versus rat) yield slightly different maps while the maps derived from the beta 2-adrenergic receptors of hamster lung and rat lung or erythrocytes reveal no interspecies differences. These data suggest: 1) alterations in the primary structure of the beta-adrenergic receptor may be responsible for the pharmacological specificities characteristic of beta 1- and beta 2-adrenergic receptor subtypes; and 2) alterations in the primary structure of similar beta-adrenergic receptor subtypes across different species may relate to the magnitude of their phylogenetic differences.     

Small organic compounds enhance antigen loading of class II major histocompatibility complex proteins by targeting the polymorphic P1 pocket

Major histocompatibility complex (MHC) molecules are a key element of the cellular immune response. Encoded by the MHC they are a family of highly polymorphic peptide receptors presenting peptide antigens for the surveillance by T cells. We have shown that certain organic compounds can amplify immune responses by catalyzing the peptide loading of human class II MHC molecules HLA-DR. Here we show now that they achieve this by interacting with a defined binding site of the HLA-DR peptide receptor. Screening of a compound library revealed a set of adamantane derivatives that strongly accelerated the peptide loading rate. The effect was evident only for an allelic subset and strictly correlated with the presence of glycine at the dimorphic position beta86 of the HLA-DR molecule. The residue forms the floor of the conserved pocket P1, located in the peptide binding site of MHC molecule. Apparently, transient occupation of this pocket by the organic compound stabilizes the peptide-receptive conformation permitting rapid antigen loading. This interaction appeared restricted to the larger Gly(beta86) pocket and allowed striking enhancements of T cell responses for antigens presented by these "adamantyl-susceptible" MHC molecules. As catalysts of antigen loading, compounds targeting P1 may be useful molecular tools to amplify the immune response. The observation, however, that the ligand repertoire can be affected through polymorphic sites form the outside may also imply that environmental factors could induce allergic or autoimmune reactions in an allele-selective manner.     

Differential interaction of synthetic peptides from the carboxyl-terminal regulatory domain of tubulin with microtubule-associated proteins.

In previous studies we have demonstrated that a 4-kd tubulin fragment, including amino acid residues from Phe418 to Glu450 in alpha-subunit and Phe408-Ala445 of the beta-sequence, plays a major role in controlling tubulin interactions leading to microtubule assembly. The 4-kd carboxyl-terminal domain also constitutes an essential domain for the interaction of microtubule-associated proteins (MAPs). Removal of the 4-kd fragment facilitates tubulin self-association and renders the assembly MAP-independent. In order to define the substructure of the tubulin domain for MAP interaction, we have examined the binding of 3H-acetylated C-terminal peptides to MAP-2 and tau. Two synthetic peptides from the low-homology region within the 4-kd domain alpha (430-441) and beta (422-434) and the peptide, alpha (401-410) of the high-homology region adjacent to the 4-kd domain, were analyzed with respect to MAP interaction. The binding data showed a relatively strong interaction of MAP-2 with the beta (422-434) peptide and a weaker interaction of both MAPs components with alpha (430-441) tubulin peptide as analyzed by Airfuge ultracentrifugation and zone filtration chromatography. The homologous alpha (401-410) peptide did not bind to either MAP-2 or tau. Equilibrium dialysis experiments showed a co-operative binding of beta (422-434) peptide to multiple sites in tau. The alpha (430-441) peptide exhibited a stronger interaction for tau as compared with MAP-2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification and characterization of peptide probes directed against PKCalpha conformations.

Phage display is a powerful technology that allows identification of high affinity peptides that bind specifically to a given molecular target. Using a highly complex peptide display library, we have identified separate classes of peptides that bind to protein kinase C alpha (PKCalpha) only under activation conditions. Furthermore, peptide binding was specific to PKCalpha and not to any of the other closely related PKC isoforms. The conformational and isoform specificity of the peptide binding was demonstrated using surface plasmon resonance as well as time-resolved fluorescence assays. Kinase assays showed that these peptides were not direct substrates for PKC nor did they inhibit phosphorylation of PKC substrates. These peptides are most likely directed against protein-protein interaction sites on PKC. The data presented here offers another example of application of phage display technology to identify conformation-dependent peptide probes against therapeutically important drug targets. These peptides are ideally suited to be used as surrogate ligands to identify compounds that bind specifically to PKCalpha, as well as conformational probes to detect activated forms of PKCalpha.     

Thermodynamic and kinetic analysis of a peptide-class I MHC interaction highlights the noncovalent nature and conformational dynamics of the class I heterotrimer

The class I major histocompatibility (MHC) molecule is a heterotrimer composed of a heavy chain, the small subunit beta(2)-microglobulin (beta(2)m), and a peptide. Fluorescence anisotropy has been used to assay the interaction of a labeled peptide with a recombinant, soluble form of the class I MHC HLA-A2. Consistent with earlier work, peptide binding is shown to be a two-step process limited by a conformational rearrangement in the heavy chain/beta(2)m heterodimer. However, we identify two pathways for peptide dissociation from the heterotrimer: (1) initial peptide dissociation leaving a heavy chain/beta(2)m heterodimer and (2) initial dissociation of beta(2)m, followed by peptide dissociation from the heavy chain. Eyring analyses of rate constants measured as a function of temperature permit for the first time a complete thermodynamic characterization of peptide binding. We find that in this case peptide binding is mostly entropically driven, likely reflecting the hydrophobic character of the peptide binding groove and the peptide anchor residues. Thermodynamic and kinetic analyses of peptide-MHC interactions as performed here may be of practical use in the engineering of peptides with desired binding properties and will aid in the interpretation of the effects of MHC and peptide substitutions on peptide binding and T cell reactivity. Finally, our data suggest a role for beta(2)m in dampening conformational dynamics in the heavy chain. Remaining conformational variability in the heavy chain once beta(2)m has bound may be a mechanism to promote promiscuity in peptide binding.     

Structure-function analysis of Arg-Gly-Asp helix motifs in alpha v beta 6 integrin ligands

Data relating to the structural basis of ligand recognition by integrins are limited. Here we describe the physical requirements for high affinity binding of ligands to alpha v beta6. By combining a series of structural analyses with functional testing, we show that 20-mer peptide ligands, derived from high affinity ligands of alpha v beta6 (foot-and-mouth-disease virus, latency associated peptide), have a common structure comprising an Arg-Gly-Asp motif at the tip of a hairpin turn followed immediately by a C-terminal helix. This arrangement allows two conserved Leu/Ile residues at Asp(+1) and Asp(+4) to be presented on the outside face of the helix enabling a potential hydrophobic interaction with the alpha v beta6 integrin, in addition to the Arg-Gly-Asp interaction. The extent of the helix determines peptide affinity for alpha v beta6 and potency as an alpha v beta6 antagonist. A major role of this C-terminal helix is likely to be the correct positioning of the Asp(+1) and Asp(+4) residues. These data suggest an explanation for several biological functions of alpha v beta6 and provide a structural platform for design of alpha v beta6 antagonists.     

Structural analysis of the interaction of apamin with Ia and its recognition by Ad- or Ab-restricted mouse T cells

Apamin is a single-chain, disulfide-bonded, 18-amino acid peptide that elicits mouse T cell responses when presented by cells expressing syngeneic Ad or Ab class II MHC molecules. We previously showed that both the unfolding of this peptide by APC and the integrity of its N terminus segment were required for efficient apamin T cell recognition. To seek further information on the sites through which this peptide interacts with Ia and/or TCR, we used a panel of Ad- or Ab-restricted, apamin-specific THC to probe the antigenicity of a series of synthetic apamin analogs. These included peptides either truncated at the N terminus, or substituted by Ala at position 2, 4, 6, 7, 8, or 10. Analysis of THC responses to apamin analogs and use of the latter in competition assays for peptide presentation revealed the following: 1) optimal apamin T cell recognition critically involved Lys4, Ala5, Pro6, Glu7, and Leu10. The role of these residues in either "Ia or TCR binding regions" was found to depend upon the restricting Ia molecules at play. Thus, Lys4, Glu7, and Leu10 were TCR-binding residues in both Ad- and Ab-apamin complexes, whereas Lys4 participated in apamin/Ab but not, or to a marginal extent, in apamin/Ad interaction. Furthermore, Pro6 was associated either with an Ia contact region or a TCR interaction site when apamin was presented by Ab or Ad molecules, respectively. Unfolded apamin and the unrelated chicken OVA323-339 peptide were found to bind to the same, or closely related site(s) of Ad, as shown by their ability to compete reciprocally for recognition by appropriate Ad-restricted THC. Four distinct TCR V beta genes (V beta 2, V beta 4, V beta 6, and V beta 8) were found to be used in our panel of 16 apamin-specific THC. These data indicate that apamin interacts with Ad or TCR through a motif resembling other beta-sheeted, Ad-binding sequences; however, based on the spacing of the critical residues (i.e., 4, 7, and 10), the possibility exists that apamin processing permits the folding of this sequence into an alpha-helix.     

Aggregation and water-membrane partition as major determinants of the activity of the antibiotic peptide trichogin GA IV

Water-membrane partition and aggregation behavior are fundamental aspects of the biological activity of antibiotic peptides, natural compounds causing the death of pathogenic organisms by perturbing the permeability of their membranes. A synthetic fluorescent analog of the natural lipopeptaibol trichogin GA IV was used to study its interaction with model membranes. Time-resolved fluorescence data show that in water, an equilibrium between monomers and small aggregates is present, the two species having different affinity for membranes. Therefore, association curves are strongly dependent on peptide concentration. A similar heterogeneity is present in the membrane phase, which strongly suggests the occurrence of a monomer-aggregate equilibrium in this case, too. The relative population of each species was determined and a strong correlation between the concentration of membrane-bound aggregates and membrane leakage was found, thereby suggesting that liposome perturbation is due to peptide aggregates only. Light-scattering measurements demonstrate that leakage is not due to liposome micellization. Moreover, experiments with markers of different sizes show that molecules with a diameter of approximately 4 nm are released only to a minor extent. Overall, these results suggest that, within the concentration range explored, pore formation by peptide aggregates is the most likely mechanism of action for trichogin in membranes.     

NMR observation of the interaction of small oligopeptides with phospholipid vesicles

Using proton spin-lattice relaxation times, the interaction of small oligopeptides with sonicated vesicles of synthetic β-γ-dimyristoyl L-α-lecithin has been monitored at 29°C in D₂O. The measured relaxation times for the lecithin choline methyl, alkyl chain, and terminal methyl protons were observed to shorten markedly with increasing concentration of peptide, the relaxation remaining exponential. Noticeable resonance broadening was observed at the highest peptide concentration studied. The data reported are for the effect of the pharmacologically active pentapeptide methionine-enkephalin. Similar results have been observed for the effect of tetraglycine. The relaxation of the observable resonances of the added peptide appear to be unaffected. The results are discussed in terms of peptide-vesicle interactions.     

Structure of the dysprosium-glycocholate complex in submicellar aqueous solution: paramagnetic mapping by proton nuclear magnetic resonance spectroscopy. An approximation for the intrinsic "bound" relaxation rates in the case of nondilute paramagnetic systems

A paramagnetic NMR study of the structure of the calcium-glycocholate complex in submicellar solution, utilizing dysprosium as an isomorphous lanthanide replacement of calcium, is presented. The dysprosium-induced relaxation rate (1/T1) enhancements of certain glycocholate protons have been used to estimate internuclear distances between these protons and the metal ion. An approximation to calculate the intrinsic relaxation rate (1/T1) enhancements for a nondilute paramagnetic solution is given in the Appendix. From these data, and analysis based on conformation averaging and minimum energy conformations, a molecular model of the dysprosium-glycocholate complex in submicellar aqueous solution has been constructed. In this model the metal ion has a unidentate, first-sphere interaction with the proximal oxygen atom of the glycine carboxyl. The metal ion has second-sphere interactions with the peptide bond carbonyl oxygen (3.6 A) and the distal carboxyl oxygen (4.4 A). The metal ion to hydroxyl oxygen distances (8.4-12.4 A) are not compatible with any metal ion to hydroxyl coordination. The side chain appears to exist in one predominant conformation. All six oxygen atoms of glycocholate, the peptide bond carbonyl, the carboxyl group, and the hydroxyl groups are on the alpha face of the bile salt molecule. On the basis of these features we conclude that in the submicellar state the solution structure of the dysprosium-glycocholate complex displays a metal ion enhanced segregation of polar versus nonpolar groups to the two separate faces of the molecule, which may result in a facilitated hydrophobic interaction of different complex units.     

The interaction between the I-II loop and the III-IV loop of Cav2.1 contributes to voltage-dependent inactivation in a beta -dependent manner.

We have investigated the molecular mechanisms whereby the I-II loop controls voltage-dependent inactivation in P/Q calcium channels. We demonstrate that the I-II loop is localized in a central position to control calcium channel activity through the interaction with several cytoplasmic sequences; including the III-IV loop. Several experiments reveal the crucial role of the interaction between the I-II loop and the III-IV loop in channel inactivation. First, point mutations of two amino acid residues of the I-II loop of Ca(v)2.1 (Arg-387 or Glu-388) facilitate voltage-dependent inactivation. Second, overexpression of the III-IV loop, or injection of a peptide derived from this loop, produces a similar inactivation behavior than the mutated channels. Third, the III-IV peptide has no effect on channels mutated in the I-II loop. Thus, both point mutations and overexpression of the III-IV loop appear to act similarly on inactivation, by competing off the native interaction between the I-II and the III-IV loops of Ca(v)2.1. As they are known to affect inactivation, we also analyzed the effects of beta subunits on these interactions. In experiments in which the beta(4) subunit is co-expressed, the III-IV peptide is no longer able to regulate channel inactivation. We conclude that (i) the contribution of the I-II loop to inactivation is partly mediated by an interaction with the III-IV loop and (ii) the beta subunits partially control inactivation by modifying this interaction. These data provide novel insights into the mechanisms whereby the beta subunit, the I-II loop, and the III-IV loop altogether can contribute to regulate inactivation in high voltage-activated calcium channels.     

Chemical shift mapped DNA-binding sites and 15N relaxation analysis of the C-terminal KH domain of heterogeneous nuclear ribonucleoprotein K

The K homology (KH) motif is one of the major classes of nucleic acid binding proteins. Some members of this family have been shown to interact with DNA while others have RNA targets. There have been no reports containing direct experimental evidence regarding the nature of KH module-DNA interaction. In this study, the interaction of the C-terminal KH domain of heterogeneous nuclear ribonucleoprotein K (KH3) with its cognate single-stranded DNA (ssDNA) are investigated. Chemical shift perturbation mapping indicates that the first two helices, the conserved GxxG loop, beta 1, and beta 2, are the primary regions involved in DNA binding for KH3. The nature of the KH3-ssDNA interaction is further illuminated by a comparison of backbone 15N relaxation data for the bound and unbound KH3. Relaxation data are also used to confirm that the backbone of wild-type KH3 is structurally identical to that of the G26R mutant KH3, which was previously published. Amide proton exchange experiments indicate that the two helices involved in DNA binding are less stable than other regions of secondary structure and that a large portion of KH3 backbone amide hydrogens are protected in some manner upon ssDNA binding. The major backbone dynamics features of KH3 are similar to those of the structurally comparable human papillomavirus-31 E2 DNA binding domain. Secondary structure information for ssDNA-bound wild-type KH3 is also presented and shows that binding results in no global changes in the protein fold.     

Peptide and beta 2-microglobulin regulation of cell surface MHC class I conformation and expression.

We have examined the roles of peptide and beta 2-microglobulin (beta 2m) in regulating the conformation and expression level of class I molecules on the cell surface. Using a cell line synthesizing H-2Dd H chain and mouse beta 2m but defective in endogenous peptide loading, we demonstrate the ability of either exogenous peptide or beta 2m alone to increase surface H-2Dd expression at both 25 degrees C and 37 degrees C. Peptide and beta 2m show marked synergy in their abilities to increase surface class I expression, with minimal increases promoted by peptide in the absence of free beta 2m. Low temperature-induced molecules have indistinguishable rates of loss of beta 2m and alpha 1/alpha 2 domain conformational epitopes during culture at 37 degrees C. However, the rate of alpha 3 epitope loss is much slower, indicating a minimum of two steps in class I loss from the cell surface: 1) loss of beta 2m binding to H chain and unfolding of the alpha 1/alpha 2 region; then 2) denaturation, degradation, or internalization of the free H chains possessing alpha 3 epitopes. These data show for the first time that free H chains survive for a finite time on the membrane in a form capable of refolding into alpha 1/alpha 2 epitope positive molecules upon addition of beta 2m and peptide. This refolding in the presence of beta 2m and peptide can explain the reported requirement for both components in sensitizing cells for class I-dependent CTL lysis. It also indicates that such conformational changes in class I molecules are not strictly dependent on either newly synthesized H chains or on intracellular chaperons. The study of H chain-peptide-beta 2m interaction on the cell surface may be relevant to understanding intracellular peptide loading events.     

Small molecule inhibitors of aggregation indicate that amyloid beta oligomerization and fibrillization pathways are independent and distinct

Alzheimer disease is characterized by the abnormal aggregation of amyloid beta peptide into extracellular fibrillar deposits known as amyloid plaques. Soluble oligomers have been observed at early time points preceding fibril formation, and these oligomers have been implicated as the primary pathological species rather than the mature fibrils. A significant issue that remains to be resolved is whether amyloid oligomers are an obligate intermediate on the pathway to fibril formation or represent an alternate assembly pathway that may or may not lead to fiber formation. To determine whether amyloid beta oligomers are obligate intermediates in the fibrillization pathway, we characterized the mechanism of action of amyloid beta aggregation inhibitors in terms of oligomer and fibril formation. Based on their effects, the small molecules segregated into three distinct classes: compounds that inhibit oligomerization but not fibrillization, compounds that inhibit fibrillization but not oligomerization, and compounds that inhibit both. Several compounds selectively inhibited oligomerization at substoichiometric concentrations relative to amyloid beta monomer, with some active in the low nanomolar range. These results indicate that oligomers are not an obligate intermediate in the fibril formation pathway. In addition, these data suggest that small molecule inhibitors are useful for clarifying the mechanisms underlying protein aggregation and may represent potential therapeutic agents that target fundamental disease mechanisms.     

NK and CTL recognition of a single chain H-2Dd molecule: distinct sites of H-2Dd interact with NK and TCR.

We generated transgenic mice expressing a single-chain beta2-microglobulin (beta2m)-H-2Dd. The cell-surface beta2m-H-2Dd molecule was expressed on a beta2m-deficient background and reacted with appropriate mAbs. It was of the expected m.w. and directed the normal development of CD8+ T cells in the thymus of a broad TCR repertoire. It also presented both exogenously provided and endogenous peptide Ags to effector CD8+ T cells. In tests of NK cell education and function, it failed to reveal any interaction with NK cells, suggesting that the site of the interaction of NK receptors with H-2Dd was disrupted. Thus, the sites of TCR and NK receptor interaction with H-2Dd are distinct, an observation consistent with independent modes of TCR and NK receptor evolution and function.     

Calcium-binding properties and molecular organization of bradykinin A solution 1H-NMR study.

The NMR features of bradykinin were investigated in dimethylsulfoxide containing 1% water. The temperature dependence of chemical shifts and ROESY maps were monitored for the major species where all X-Pro bonds are trans. The occurrence of a head-to-tail ionic interaction and intramolecular hydrogen bonds stabilizing a pseudo cyclic arrangement was inferred, a beta turn at the C-terminus being the main feature of the secondary structure. Calcium was shown to bind to the peptide with a dissociation constant Kd = 2.8 + 0.2 mm. 2Pro and 3Pro carbonyls, as well as the 9Arg carboxyl, were assigned as the metal-binding sites. A molecular model of the 1 : 1 metal-complex was obtained. In light of conformational changes experienced by the peptide upon interaction with calcium, a role for the metal was hypothesized in the process of conformational selection from the free to the receptor-bound state of bradykinin.