Threonine6-bradykinin: Conformational study of a flexible peptide in dimethyl sulfoxide by NMR and ensemble calculations

In silico folding of hydrophobic peptides that form β-hairpin structures in solution

Peptides designed with residues that have a high propensity to occur in β-turns form β-hairpin structures in apolar as well as in polar organic solvents such as dimethyl sulfoxide (DMSO). Due to limited solubility, their conformations have not been investigated experimentally in water. We have examined the conformations of four of such designed peptides that fold into well-defined β-hairpin structures facilitated by β-turns, in the crystalline state and in solution, by molecular dynamics simulations (MDS). The peptides folded into β-hairpin structures in water, starting from the fully extended conformation. However, in DMSO, neither folding nor unfolding was observed during MDS, when the starting structures were unfolded and folded, respectively. The lack of folding in DMSO was investigated by constructing folding free energy landscapes by umbrella sampling. The folding free energy landscape is smooth in water while in DMSO folded and unfolded structures are separated by high-energy barriers. The folding free energy is less in DMSO compared to water due to a more stable unfolded structure in DMSO compared to water, which in turn is due to stabilization of the unfolded state by hydrophobic interactions in DMSO. This finding will be helpful to researchers to accurately model and/or design small peptide structures in water and organic solvents.

Structural diversity of angiotensin-converting enzyme

The crystal structure of a Drosophila angiotensin-converting enzyme (ANCE) has recently been solved, revealing features important for the binding of ACE inhibitors and allowing molecular comparisons with the structure of human testicular angiotensin-converting enzyme (tACE). ACER is a second Drosophila ACE that displays both common and distinctive properties. Here we report further functional differences between ANCE and ACER and have constructed a homology model of ACER to help explain these. The model predicts a lack of the Cl(-)-binding sites, and therefore the strong activation of ACER activity towards enkephalinamide peptides by NaCl suggests alternative sites for Cl(-) binding. There is a marked difference in the electrostatic charge of the substrate channel between ANCE and ACER, which may explain why the electropositive peptide, MKRSRGPSPRR, is cleaved efficiently by ANCE with a low K(m), but does not bind to ACER. Bradykinin (BK) peptides are excellent ANCE substrates. Models of BK docked in the substrate channel suggest that the peptide adopts an N-terminal beta-turn, permitting a tight fit of the peptide in the substrate channel. This, together with ionic interactions between the guanidino group of Arg9 of BK and the side chains of Asp360 and Glu150 in the S(2)' pocket, are possible reasons for the high-affinity binding of BK. The replacement of Asp360 with a histidine in ACER would explain the higher K(m) recorded for the hydrolysis of BK peptides by this enzyme. Other differences in the S(2)' site of ANCE and ACER also explain the selectivity of RXPA380, a selective inhibitor of human C-domain ACE, which also preferentially inhibits ACER. These structural and enzymatic studies provide insight into the molecular basis for the distinctive enzymatic features of ANCE and ACER.

Structural characterization of cyclic kallidin analogues in DMSO by nuclear magnetic resonance and molecular dynamics

The conformational properties in DMSO of two head-to-tail cyclic analogues of kallidin ([Lys(0)]-bradykinin, KL) as well as those of the corresponding linear peptides were studied by NMR and molecular dynamics (MD) simulations. The modifications in the sequence were introduced at position 6, resulting in the four peptides, [Tyr(6)]-KL (YKL), [Trp(6)]-KL (WKL), cyclo-([Tyr(6)]-KL) (YCKL) and cyclo-([Trp(6)]-KL) (WCKL). The linear WKL analogue was significantly more potent than kallidin on rat duodenum preparations, whereas YKL was significantly less potent. Both cyclic peptides, YCKL and WCKL displayed similar activity, lower than that of the linear analogues and also of cyclo-KL. The two linear analogues display high conformational flexibility in DMSO. In the predominant conformer, for both peptides, all three X-Pro bonds adopt a trans configuration. Three out of four conformers present in YCKL and WCKL were completely assigned. The configurations at the X-Pro bonds are the same for the two analogues. All cyclic conformers show a cis configuration in at least one X-Pro bond and always opposite configuration for the two consecutive X-Pro bonds. The NOE-restrained MD calculations resulted in the detection of several elements of secondary structure in each of the conformers. Such elements are described and their possible relevance to biological activity is discussed.

Extracellular domains of the neurokinin-1 receptor: structural characterization and interactions with substance P

The technical difficulties associated with the structure determination of membrane proteins have limited the structural information available for the ligand binding to G-protein coupled receptors (GPCRs). Here, we describe a reductionist approach to GPCR structure determination in which the extracellular domains of the receptor are examined by high-resolution NMR in the presence of a membrane mimetic. The resulting structural features are then incorporated into a molecular model of the receptor, utilizing the x-ray structure of rhodopsin to generate the topological orientation of the transmembrane helices. The results of our study of the neurokinin-1 receptor (NK-1R) and its interactions with substance P (SP) are detailed here. The structure of the N-terminus, NK-1R(1-39), and of the third extracellular loop, NK-1R(264-290), in the presence of dodecylphosphocholine micelles is described. Our findings provide a structural basis for the interpretation of the results from other methods including mutagenesis, fluorescence, and photoaffinity labeling experiments, resulting in an experimentally based, high-resolution model of SP binding to NK-1R.

Cannabinoid receptor-G protein interactions: G(alphai1)-bound structures of IC3 and a mutant with altered G protein specificity

The structure of the C-terminal region of the third cytoplasmic loop (IC3) of the cannabinoid receptor one (CB1) bound to G(alphai1) has been determined using transferred nuclear Overhauser effects (NOEs). The wild-type IC3 sequence is helical when associated with G(alphai1). In contrast, a peptide containing the amino-acid inversion, Ala(341)-Leu(342) adopts a single turn. These findings correlate with the attenuated G(i) association of CB1 with the Ala(341)-Leu(342) mutation previously observed in vivo and the diminished stimulation of G(alphai1) GTPase activity by the corresponding peptide demonstrated in vitro here. These results, the first to report the structure of a GPCR domain while associated with G protein, imply the C-terminus of CB1 IC3, a region with high-sequence conservation among G-protein coupled receptors, must be helical for efficient coupling and activation of the G(i) protein.

Synthesis, conformation and biological activity of linear and cyclic Thr6-bradykinin analogues containing N-benzylglycine in place of phenylalanine

Three linear Thr6-bradykinin analogues in which either one or both the two phenylalanine residues in the peptide sequence have been substituted by N-benzylglycine (BzlGly) and their head-to-tail cyclic analogues were synthesized and tested on an isolated rat duodenum preparation. The linear (BzlGly5,Thr6-BK, BzlGly8,Thr6-BK and BzlGly(5,8),Thr6-BK) and the cyclic (cyclo BzlGly5,Thr6-BK, cyclo BzlGly8,Thr6-BK and cyclo BzlGly(5,8),Thr6-BK) peptoid-like analogues were characterized by amino acid analysis, optical rotation, analytical HPLC and MALDI-TOF mass spectroscopy. The conformational features of both the linear and cyclic derivatives were investigated by FT-IR and CD measurements. Preliminary molecular mechanics calculations were also performed on some synthetic peptides. Pharmacological screening using the relaxation of the isolated rat duodenum preparation showed that incorporation of N-benzylglycine at positions 5 and/or 8 in the linear Thr6-BK causes a substantial decrease in potency. Comparable incorporation in cyclo Thr6-BK, at position 8, or 5 and 8, resulted in nearly inactive analogues. However, cyclo BzlGly5,Thr6-BK showed a potency which is of the same order of magnitude as for cyclo-BK and cyclo Thr6-BK.

Structural characterization of lipopeptide agonists for the bradykinin B2 receptor

The conformational features of Pam-Lys(0)-Arg(1)-Pro(2)-Pro(3)-Gly(4)-Phe(5)-Ser(6)-Pro(7)-Phe(8)-Arg(9)-OH (PKD) and Pam-Gly(-1)-Lys(0)-Arg(1)-Pro(2)-Pro(3)-Gly(4)-Phe(5)-Ser(6)-Pro(7)-Phe(8)-Arg(9)-OH (PGKD), the Pam-Lys and Pam-Gly-Lys analogues of bradykinin, have been determined by high-resolution NMR in a zwitterionic lipoid environment. Radical-induced relaxation of the (1)H NMR signals was used to probe the topological orientation of the peptides with respect to the zwitterionic lipid interface. The radical-induced relaxation and molecular dynamics (MD) data indicated that the palmitic acid and N-terminal amino acid residues embed into the micelles, while the rest of the polypeptide chain is closely associated with the water-micelle interface. Throughout the entire nuclear Overhauser effect restrained MD simulation, a nonideal type I beta-turn was observed in the C-terminus of PKD between residues 6 and 9, and a gamma-turn was observed in the C-terminus of PGKD between residues 6 and 7. Therefore, the additional glycine has a dramatic effect on the structural preferences of the biologically important C-terminus, an effect brought about by the interaction with the lipid environment. These structural features are correlated to the biological activity at the bradykinin B2 receptor.

Structural characterization of peptide hormone/receptor interactions by NMR spectroscopy

The structural characterization of peptide hormones and their interaction with G-protein (guanine nucleotide-binding regulatory protein) coupled receptors by high-resolution nmr is described. The general approaches utilized can be categorized into three different classes based on their target: the ligand, the receptor, and the ligand/receptor complex. Examples of these different approaches, aimed at facilitating the rational design of peptides and peptidomimetics with improved pharmacological profiles, based on work carried out in our own laboratory, are given. In the ligand-based approach, the high-resolution structures of bradykinin analogues allowing for the development of a structure-activity relationship for activation of the B1 receptor are described. Studies targeting the receptor are to a large extent theoretical, based on computational molecular modeling. However, experimentally based structural features provided by high-resolution nmr can be used to great advantage, providing insight into the mechanism of receptor function, as illustrated here with results from parathyroid hormone. A similar combination of theoretical methods, supplemented by high-resolution structures from nmr has been utilized to probe the formation and stabilization of the ligand/receptor complex both for parathyroid hormone and cholecystokinin. In each of these three approaches, the importance of well-designed peptide mimetics and accurate structural analysis by high-resolution nmr, will be highlighted.

New insights into the conformational requirements of B2 bradykinin antagonism

The conformational profiles of a selected group of a new series of small linear and cyclic penta- and hexapeptides, inspired on the C-terminal segment of second-generation bradykinin (BK) antagonists, were independently computed in order to assess the chemical and geometrical requirements necessary for BK antagonism. Specifically, four cyclic peptides: cyclo-(Gly-Thi-D-Tic-Oic-Arg), cyclo-(Gly-Ala-D-Tic-Oic-Arg), cyclo-(Abu-Ala-Ser-D-Tic-Oic-Arg), cyclo-(Abu-D-Phe-Ala-D-Tic-Oic-Arg), and a linear peptide: Thi-Ser-D-Tic-Oic-Arg were selected for the present study. The first three BK analogs are capable to antagonize kinin-induced rabbit jugular vein and rabbit aorta smooth muscle contraction, while last two show no detectable affinity for the BK B2 receptor. The conformational space of the five peptides was thoroughly explored using simulated annealing (SA) in an iterative fashion as sampling technique. The bioactive conformation was assessed by pairwise cross comparisons between each of the unique low energy conformations found for each of the different peptides studied within a 5 kcal/mol threshold in respect to the global minimum. The conformational profile of the highly potent BK antagonist HOE-140, computed in an independent study, was also used in conjunction with the bioactive form assessed in the present study, to propose a pharmacophore that includes the stereochemical requirements for B2 BK antagonism.

NMR determination of the major solution conformation of a peptoid pentamer with chiral side chains

Polymers of N-substituted glycines ("peptoids") containing chiral centers at the alpha position of their side chains can form stable structures in solution. We studied a prototypical peptoid, consisting of five para-substituted (S)-N-(1-phenylethyl)glycine residues, by NMR spectroscopy. Multiple configurational isomers were observed, but because of extensive signal overlap, only the major isomer containing all cis-amide bonds was examined in detail. The NMR data for this molecule, in conjunction with previous CD spectroscopic results, indicate that the major species in methanol is a right-handed helix with cis-amide bonds. The periodicity of the helix is three residues per turn, with a pitch of approximately 6 A. This conformation is similar to that anticipated by computational studies of a chiral peptoid octamer. The helical repeat orients the amide bond chromophores in a manner consistent with the intensity of the CD signal exhibited by this molecule. Many other chiral polypeptoids have similar CD spectra, suggesting that a whole family of peptoids containing chiral side chains is capable of adopting this secondary structure motif. Taken together, our experimental and theoretical studies of the structural properties of chiral peptoids lay the groundwork for the rational design of more complex polypeptoid molecules, with a variety of applications, ranging from nanostructures to nonviral gene delivery systems.