Delta-selective opioid peptides containing a single aromatic residue in the message domain: an NMR conformational analysis

Tailoring the nuclear Overhauser effect for the study of small and medium-sized molecules by solvent viscosity manipulation

The nuclear Overhauser effect (NOE) is a consequence of cross-relaxation between nuclear spins mediated by dipolar coupling. Its sensitivity to internuclear distances has made it an increasingly important tool for the determination of through-space atom proximity relationships within molecules of sizes ranging from the smallest systems to large biopolymers. With the support of sophisticated FT-NMR techniques, the NOE plays an essential role in structure elucidation, conformational and dynamic investigations in liquid-state NMR. The efficiency of magnetization transfer by the NOE depends on the molecular rotational correlation time, whose value depends on solution viscosity. The magnitude of the NOE between ¹H nuclei varies from +50% when molecular tumbling is fast to -100% when it is slow, the latter case corresponding to the spin diffusion limit. In an intermediate tumbling regime, the NOE may be vanishingly small. Increasing the viscosity of the solution increases the motional correlation time, and as a result, otherwise unobservable NOEs may be revealed and brought close to the spin diffusion limit. The goal of this review is to report the resolution of structural problems that benefited from the manipulation of the negative NOE by means of viscous solvents, including examples of molecular structure determination, conformation elucidation and mixture analysis (the ViscY method).

The conformation of enkephalin bound to its receptor: an "elusive goal" becoming reality

The availability of solid state structures of opioid receptors has prompted us to reconsider a crucial question concerning bioactive peptides: can their conformation be studied without any knowledge of the structure of their receptors? The possibility of giving a meaningful answer to this query rests ultimately on the ease of dealing with the flexibility of bioactive peptides, and amongst them one of the most flexible bioactive peptides, enkephalin. All solution studies of enkephalin hint at an inextricable mixture of quasi isoenergetic conformers. In this study we refer to the only NMR work that yielded inter-residue NOEs, performed at very low temperature. In the present work, we have used the simplest possible docking methods to check the consistency of the main conformers of enkephalin with the steric requirements of the active site of the receptor, as provided by the crystal structure of its complex with naltrindole, a rigid antagonist. We show that the conformers found in the equilibrium mixture at low temperature are indeed compatible with a good fit to the receptor active site. The possible uncertainties linked to the different behavior of agonists and antagonists do not diminish the relevance of the finding.

Exploring deltorphin II binding to the third extracellular loop of the delta-opioid receptor

The third extracellular loop of the human delta-opioid receptor (hDOR) is known to play an important role in the binding of delta-selective ligands. In particular, mutation of three amino acids (Trp(284), Val(296), and Val(297)) to alanine significantly diminished delta-opioid receptor affinity for delta-selective ligands. To assess the changes in conformation accompanying binding of the endogenous opioid peptide deltorphin II to the delta-opioid receptor at both the receptor and ligand levels as well as to determine points of contact between the two, an in-depth spectroscopic study that addressed these points was initiated. Fragments of the delta-opioid receptor of variable length and containing residues in the third extracellular loop were synthesized and studied by NMR and CD spectroscopy in a membrane-mimetic milieu. The receptor peptides examined included hDOR-(279-299), hDOR-(283-299), hDOR-(281-297), and hDOR-(283-297). A helical conformation was observed for the longest receptor fragment between Val(283) and Arg(291), whereas a nascent helix occurred in a similar region for hDOR-(281-297). Further removal of N-terminal residues Val(281) and Ile(282) abolished helical conformation completely. Binding of the delta-selective ligand deltorphin II to hDOR-(279-299) destabilized the helix at the receptor peptide N terminus. Dramatic changes in the alpha-proton chemical shifts for Trp(284) and Leu(286) in hDOR-(279-299) also accompanied this loss of helical conformation. Large upfield displacement of alpha-proton chemical shifts was observed for Leu(295), Val(296), and Val(297) in hDOR-(279-299) following its interaction with deltorphin II, thus identifying a gain in beta-conformation at the receptor peptide C terminus. Similar changes did not occur for the shorter peptide hDOR(281-297). A hypothesis describing the conformational events accompanying selective deltorphin II binding to the delta-opioid receptor is presented.

pKa and volume of residue one influence delta/mu opioid binding: QSAR analysis of tyrosine replacement in a nonselective deltorphin analogue

[Gly(4)]deltorphin (Tyr-D-Ala-Phe-Gly-Val-Val-Gly-NH(2)) is a nonselective analogue of the opioid heptapeptides isolated from Phyllomedusa amphibian skin. Its nonselective nature allows for simultaneous characterization of the effects of sequence modification on both delta (delta) and mu (mu) receptor binding. The N-terminal regions of opioid peptides are considered to be responsible for receptor recognition, and the tyrosine at position one is relatively intolerant to alteration. In order to further investigate the role of the phenolic hydroxyl group in receptor interaction, a series of peptides was synthesized in which the position-one tyrosine residue was replaced with analogues of varying electronic, steric, and acid/base character, including ring-substituted tyrosines, para-substituted phenylalanines, and other nonaromatic and heterocyclic amino acids. The effects of these replacements on delta and mu receptor affinities were measured and then analyzed through quantitative structure-activity relationship (QSAR) calculations. Results support a dual hydrogen bond donor/acceptor role for the Tyr(1) hydroxyl moiety, with less acidic hydroxyl groups exhibiting stronger binding to opioid receptors. In addition, steric bulk in the Tyr(1) position independently strengthens mu and possibly delta binding, presumably by either a ligand conformational effect or enhanced van der Waals interactions with a 'loose' receptor site. The pK(a) effect is stronger on delta than on mu binding, generating an increase in delta selectivity with increasing residue-one pK(a).

Control of peptide conformation by the Thorpe-Ingold effect (C alpha-tetrasubstitution)

The preferred conformations of peptides heavily based on the currently extensively exploited achiral and chiral alpha-amino acids with a quaternary alpha-carbon atom, as determined by conformational energy computations, crystal-state (x-ray diffraction) analyses, and solution ((1)H-NMR and spectroscopic) investigations, are reviewed. It is concluded that 3(10)/alpha-helical structures and the fully extended (C(5)) conformation are preferentially adopted by peptide sequences characterized by this family of amino acids, depending upon overall bulkiness and nature (e.g., whether acyclic or C(alpha) (i) <--> C(alpha) (i) cyclized) of their side chains. The intriguing relationship between alpha-carbon chirality and bend/helix handedness is also illustrated. gamma-Bends and semiextended conformations are rarely observed. Formation of beta-sheet structures is prevented.

Probing structural requirements of fMLP receptor: on the size of the hydrophobic pocket corresponding to residue 2 of the tripeptide

The conformationally constrained f-L-Met-Ac(n)c-L-Phe-OMe (n = 4,9-12) tripeptides, analogues of the chemoattractant f-L-Met-L-Leu-L-Phe-OH, were synthesized in solution by classical methods and fully characterized. These compounds and the published f-L-Met-Xxx-L-Phe-OMe (Xxx = Aib and Ac(n)c where n = 3, 5-8) analogues were compared to determine the combined effect of backbone preferred conformation and side-chain bulkiness at position 2 on the relation of 3D-structure to biological activity. A conformational study of all the analogues was performed in solution by FT-IR absorption and 1H-NMR techniques. In parallel, each peptide was tested for its ability to induce chemotaxis, superoxide anion production and lysozyme secretion from human neutrophils. The biological and conformational data are discussed in relation to the proposed model of the chemotactic receptor on neutrophils, in particular of the hydrophobic pocket accommodating residue 2 of the tripeptide.

Pharmacology of amphibian opiate peptides

In 1980 the skin of certain frogs belonging to the genus Phyllomedusinae was found to contain two new peptides that proved to be selective mu-opioid agonists, and named dermorphins. Since 1987 deltorphins, a family of highly selective delta-opioid peptides were identified either by cloning of the cDNA from frog skins or isolation of the peptides. The distinctive feature of opioid peptides is the presence of a naturally occurring D-enantiomer at the second position in their common N-terminal sequence, Tyr-D-Xaa-Phe. The discovery of the amphibian opiate peptides, provided new insights into the functional role of the mu- and delta-opiate systems. It also provided models for novel analgesics with enhanced therapeutic benefits and reduced toxicity.

Solution conformation of a potent cyclic analogue of tuftsin: low- temperature nuclear magnetic resonance study in a cryoprotective mixture

Tuftsin, a linear tetrapeptide (Thr-Lys-Pro-Arg), corresponding to the sequence 289-292 of the heavy chain of leukokinin, has been the object of intensive SAR studies during the past 30 years, owing to its numerous biological activities and to the possibility of generating a novel anticancer drug. A cyclic tuftsin analogue, c-[T-K-P-R-G], has biological activity 50 times higher than that of the parent linear peptide. Here we present a conformational study of c-[T-K-P-R-G] based on NMR data in a cryoprotective DMSO/water mixture. The preferred conformation is a type VIa turn centered on the K-P residues. The orientation of the side chains of the two basic residues (K and R) may represent the essential feature of the bioactive conformation of tuftsin. A possible role of tuftsin as a DNA binding motif is suggested by the similarity of the bioactive conformation of c-[T-K-P-R-G] and of the beta-turn conformation proposed by Suzuki for the [T,S]-P-K-R motif.

What peptides these deltorphins be

The deltorphins are a class of highly selective delta-opioid heptapeptides from the skin of the Amazonian frogs Phyllomedusa sauvagei and P. bicolor. The first of these fascinating peptides came to light in 1987 by cloning of the cDNA of from frog skins, while the other members of this family were identified either by cDNA or isolation of the peptides. The distinctive feature of deltorphins is the presence of a naturally occurring D-enantiomer at the second position in their common N-terminal sequence, Tyr-D-Xaa-Phe, comparable to dermorphin, which is the prototype of a group of mu-selective opioids from the same source. The D-amino acid and the anionic residues, either Glu or Asp, as well as their unique amino acid compositions are responsible for the remarkable biostability, high delta-receptor affinity, bioactivity and peptide conformation. This review summarizes a decade of research from many laboratories that defined which residues and substituents in the deltorphins interact with the delta-receptor and characterized pharmacological and physiological activities in vitro and in vivo. It begins with a historical description of the topic and presents general schema for the synthesis of peptide analogues of deltorphins A, B and C as a means to document the methods employed in producing a myriad of analogues. Structure activity studies of the peptides and their pharmacological activities in vitro are detailed in abundantly tabulated data. A brief compendium of the current level of knowledge of the delta-receptor assists the reader to appreciate the rationale for the design of these analogues. Discussion of the conformation of these peptides addresses how structure leads to further hypotheses regarding ligand receptor interaction. The review ends with a broad discussion of the potential applications of these peptides in clinical and therapeutic settings.

Conformational sampling of bioactive conformers: a low-temperature NMR study of 15N-Leu-enkephalin

Conformational studies of enkephalins are hampered by their high flexibility which leads to mixtures of quasi-isoenergetic conformers in solution and makes NOEs very difficult to detect in NMR spectra. In order to improve the quality of the NMR data, Leu-enkephalin was synthesized with 15N-labelled uniformly on all amide nitrogens and examined in a viscous solvent medium at low temperature. HMQC NOESY spectra of the labelled Leu-enkephalin in a DMSOd6/H2O) mixture at 275 K do show numerous NOEs, but these are not consistent with a single conformer and are only sufficient to describe the conformational state as a mixture of several conformers. Here a different approach to the structure-activity relationships of enkephalins is presented: it is possible to analyse the NMR data in terms of limiting canonical structures (i.e. beta- and gamma-turns) and finally to select only those consistent with the requirements of delta selective agonists and antagonists. This strategy results in the prediction of a family of conformers that may be useful in the design of new delta selective opioid peptides.