Three-dimensional structure analysis of mu-agatoxins: further evidence for common motifs among neurotoxins with diverse ion channel specificities.

We report the solution structure of mu-agatoxin-I (mu-Aga-I) and model structures of the closely related mu-agatoxin-IV (mu-Aga-IV) which were isolated from venom of the American funnel web spider, Agelenopsis aperta. These toxins, which modify the kinetics of neuronal voltage-activated sodium channels in insects, are C-terminally amidated peptides composed to 36 amino acids, including four internal disulfide bonds. The structure of mu-Aga-I was determined by NMR and distance geometry/molecular dynamics calculations. Structural calculations were carried out using 256 interresidue NOE-derived distance restraints and 25 angle restraints obtained from vicinal coupling constants. The peptide contains eight cysteines involved in disulfide bonds, the pairings of which were uncertain and had to be determined from preliminary structure calculations. The toxin has an average rmsd of 0.89 A for the backbone atoms among 38 converged conformers. The structure consists of a well-defined triple-stranded beta-sheet involving residues 7-9, 20-24, and 30-34 and four tight turns. A homologous peptide, mu-Aga-IV, exhibited two distinct and equally populated conformations in solution, which complicated spectral analysis. Analysis of sequential NOE's confirmed that the conformers arose from cis and trans peptide bonds involving a proline at position 15. Models were developed for both conformers based on the mu-Aga-I structure. Our structural data show that the mu-agatoxins, although specific modifiers of sodium channels, share common secondary and tertiary structural motifs with phylogenetically diverse peptide toxins targeting a variety of channel types. The mu-agatoxins add voltage-sensitive sodium channel activity to a growing list of neurotoxic effects elicited by peptide toxins which share the same global fold yet differ in their animal origin and ion channel selectivity.

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

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

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

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

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

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