Conformational properties of biologically active melanostatin analogs

On the basis of the two-dimensional 1H NMR studies the conformation of melanocyte inhibiting hormone (HCl.Pro-Leu-Gly-NH2, MIF) and its five analogues with p-substituted phenylalanine has been determined. Structure-antidepressant activity relationship (examined by the Porsolt test) of MIF and its analogues has been estimated by means of the multivariate statistical analysis, the vicinal spin coupling constants, which determine phi and chi dihedral angles of the second amino acid and phi and dihedral angle of glycine, being selected as structural parameters. It is shown that a biologically active conformation (10-membered beta-turn II) is realized for the considered peptides.     

Conformational preference of Leu side chain in melanostatin in DMSO

The solution conformation of melanostatin (Pro-Leu-Gly-NH2) in the neutral and protonated forms of DMSO has been monitored by one and two dimensional NMR techniques at 500 MHz. The temperature coefficients of the amide proton chemical shifts in conjunction with the observed NOESY spectra suggest that melanostatin in neutral form in DMSO adopts a backbone conformation such that leucine amide proton is buried by the proline ring and the side chain of leucine. Similar observation is made for protonated form of melanostatin in DMSO. The results of the present study are at variance with the earlier NMR studies which proposed a beta-turn structure for both the forms of melanostatin. There is, however, no evidence for the presence of beta-turn structure for both the forms of melanostatin in DMSO. In CDCl3 also Leu NH appears to be buried as evident from the solvent titration with DMSO and NOESY spectra.     

Conformational energy analysis of retro-all-Dmethionine enkephalin

Empirical conformational energy calculations have been carried out on the molecule retro-all-D -methionine enkephalin. Low-energy conformers were found by energy minimization and conformational search procedures. The lowest energy conformers wee found toi have some stereochemical relationship to the calculated normal met-enkephalin conformers, but they were not retro-all-D -equivalent to the Met-enkephalin structures. The retro-all-D -equivalent conformations were ～10 kcal/mol higher energy than the low-energy conformers found here. A structural comparison between the retro-all-D -conformers and the met-enkephalin conformers shows hat one cannot rely solely on topochemical analysis to predict biological activity for linear retro-all-D -peptides.     

Psychopharmacologic spectrum of melanostatin

Experiments on cats revealed an emotiotropic action of melanostatin on the original spectrum of emotional reactivity, similar to the effects of L-DOPA and amantadin. The drug does not possess an antidepressant action proper but activates the aggressive-defensive behaviour in experimental reserpine depression and reduces the provocation-induced aggressive behaviour in experimental haloperidol depression. In reserpinized mice, it antagonizes reserpine hypothermia, increases muscle tone and eliminates ptosis. It decreases haloperidol-induced catalepsia. Melanostatin increases the brain level of dopamine and its metabolite, homovanilic acid.     

Conformational analysis of endothelin-1: Effects of solvation free energy

In order to investigate conformational preferences of the 21-residue peptide hormone endothelin-1 (ET-1), an extensive conformational search was carried out in vacuo using a combination of high temperature molecular dynamics / annealing and a Monte Carlo / minimization search in torsion angle space. Fully minimized conformations from the search were grouped into families using a clustering technique based on rms fitting over the Cartesian coordinates of the atoms of the peptide backbone of the ring region. A wide range of local energy minima were identified even though two disulfide bridges (Cys¹-Cys¹⁵ and Cys³-Cys¹¹) constrain the structure of the peptide. Low energy conformers of ET-1 as a nonionized species in vacuo arestabilized by intramolecular interaction of the ring region (residues 1-15) with the tail (residues 16–21). Strained conformations for individual residues are observed. Conformational similarity to protein loops is established by matching to protein crystal structures In order to assess the influence of aqueous environment on conformational preference, the electrostatic contribution to the solvation energy was calculated for ET-1 as a fully ionized species (Asp⁸, Lys⁹, Glu¹⁰, Asp¹⁸, N- and C-terminus) using a continuum electrostatics model (DelPhi) for each of the conformed generated in vacuo, and the total solvation free energy was estimated by adding a hydrophobic contribution proportional to solvent accessible surface area. Solvation dramatically alters the relative energetics of ET-1 conformers from that calculated in vacuo. Conformers of ET-1 favored by the electrostatic salvation energy in water include conformers with helical secondary structure in the region of residues 9–15. Perhaps of most importance, it was demonstrated that the contribution tosolvation by an individual charge depends not only on its solvent accessibility but on the proximity of other charges, i.e., it is a cooperative effect. This was shown by the calculation of electrostatic solvation energy as afunction of conformation with individual charges systematically turned “on” and “off”. The cooperative effect of multiple charges on solvation demonstrated in this manner calls into question models that relate solvation energysimply to solvent accessibility by atom or residue alone. © 1995 John Wiley & Sons, Inc.     

Conformational energy analysis of the chemotactic tripeptide formyl-Met-Leu-Phe and three analogs

Conformational energy analyses were carried out on the chemotactic tripeptide fMLF (CHO-Met-Leu-Phe) and three analogs fALF (CHO-Ala-Leu-Phe). fMF (CHO-Met-Phe), and MLF (H-Met-Leu-Phe). A near-folded or puckered conformation predominates in all four peptides. The calculated average end-to-end distance R of each of the peptides is 7.4 A, 7.6 A, 7.0 A, and 7.3 A, respectively (where bends have R less than or equal to 7 A and extended structures have R approximately 10.5 A). The puckered conformation calculated for fMLF is similar to that determined experimentally for fMLF in nonpolar solvents and in the protein receptor. The results suggest that maximum chemotactic activity of the peptides depends on a combination of the chemical structure (the presence of N-formyl-methionine) and backbone conformation (C7conformation of the first amino acid residue).     

Conformational energy analysis of the pentapeptide Ac-Arg-Asn-Cys-Tyr-Asn-NMA from alpha 1-purothionin

Conformational energy analyses were carried out on the pentapeptide RNCYN (Ac-Arg-Asn-Cys-Tyr-Asn-NMA) and on related peptides. RNCYN is a highly conserved amino acid sequence in thionins and viscotoxins. The conformation of the pentapeptide was calculated to be an amphipathic alpha-helix, with the tyrosine and cysteine on the nonpolar side of the helix and the arginine and both asparagines on the polar side. Our results are inconsistent with the conformation determined using the Chou-Fasman prediction method, but are consistent with the conformation determined experimentally (using n.m.r.) for this pentapeptide sequence in alpha 1-purothionin.     

Conformational analysis of phosphatides: Mapping and minimization of the intramolecular energy

Empirical intramolecular energy calculations were carried out on molecular fragments related to phosphatides in order to find the preferred conformations. The energy was mapped as a function of several pairs of torsional angles in progressively larger molecular fragments, with energy minimization being carried out at each map point with respect to other significant variables. The energy mapping results were used as starting points for energy minimization on diheptanoyl L-α-phosphatidic acid-C, which consisted of the named molecule plus a carbon atom attached to one of the phosphate oxygens. It was found that there are 6 pairs of values for 2 of the torsional angles at the 3-way branch point in the glyceryl group which give sterically acceptable conformations; only 4 of these are compatible with lipid bilayer structure in that they can give a parallel arrangement of the acyl chains. The several acceptable conformations of the phosphate and acyl ester groups within each of these conformational classes are enumerated. The results obtained may be used as a guide for further experimental and theoretical work on phosphatide structures.     

Conformational free energy of armadillo metmyoglobin

The conformational free energy of armadillo metmyoglobin was examined over a pH range of 4.4-8.0 and a guanidinium chloride concentration of 0-2.3 M. For isothermal unfolding at 25 degrees essentially the same value was obtained for the conformational free energy from all the data: 27 +/- 2 kJ/mol. These data suggest that the armadillo has the least stable metmyoglobin of any mammal thus far examined. The cooperativity of the unfolding with respect to denaturant is considerably less than for other mammalian myoglobins. On unfolding only three to four side chains with a pKA of 6 in the unfolded protein are protonated instead of the six found for horse and sperm whale myoglobins.     

Conformational energy studies of linear dipeptides H-X-L-Pro-OH

Empirical conformational energy calculations with the use of ECEPP energy functions have been carried out for linear dipeptides H-X-L -Pro-OH, with X = Gly, L -Ala, D -Ala, L -Leu, D -Leu, L -Phe, and D -Phe, in different states of protonation of the end groups. The results of these calculations are compared with the previously reported experimental equilibrium populations for the cis and trans isomers of the X-Pro bond in the different species. For all the protonation states of the seven dipeptides, the calculated nonbonded interactions and the conformational entropy term lead to a preference of the trans forms over the cis isomers by at least 1 kcal/mol. The electrostatic interactions stabilize the cis conformations in all species except the cationic forms of the D ,L -peptides, and it could further be shown that only the carbonyl group of X and the two end groups contribute significantly to the total electrostatic energy. One of the principal results of the experimental studies, i.e., the occurrence of 5–15% cis-proline in all the peptides with an uncharged C-terminus, was corroborated by our investigation of the cationic species. A detailed assessment of the electrostatic contribution to the total energy of the different conformations of H-Gly-L -Pro-OH indicates that the standard ECEPP parameters tend to overestimate the electrostatic interactions in aqueous solutions of the X-Pro dipeptides.     

Conformational analysis of xyloglucans

Xyloglucan isolated from the elongating regions of pea stems was examined using X-ray diffraction and energy calculations. The X-ray fibre pattern suggested that the backbone (1----4)-beta-D-glucan takes an extended two-fold helix similar to common cellulose. In order to study side chains (xylosyl or fucosyl-galactosyl-xylosyl residues) of the polysaccharide, energetically preferable conformations were searched by calculation of interactions between non-bonded atom pairs. A stepwise calculation for the conformation of fucosyl-galactosyl-xylosyl residue gave 10 allowed area (phi-psi) maps which are useful to deduce xyloglucan conformations of both monocotyledons and dicotyledons in the walls of growing plant cells.     

Conformational analysis of poly-N-methyl-L-alanine

Sterically allowed forms of the poly-N-methyl-L -alanine chain were found by calculation of conformational energies as a function of the rotation angles of its chain bonds. The lowest energy form seems to be a right-handed, approximately threefold helix.     

Conformational energy calculations on alginic acid. II. Conformational statistics of the copolymers

Conformational energy maps have been calculated for α-D -mannuronic acid (1–4) α-L -guluronic acid and for α-L -guluronic acid (1–4) β-D -mannuronic acid. These have been used, together with maps previously calculated for the homomonomeric dimers, to estimate the characteristic ratios and Kuhn lengths of the alternating copolymer and of a stochastic copolymer similar in composition to that extracted from L. digitata.The results show that the alternating copolymer is less extended than either homopolymer. Kuhn lengths calculated for the stochastic copolymer agree well with experimental results on high ionic strength solutions of alginate isolated from L digitata.     

Conformational energy refinement of horse-heart ferricytochrome c.

The reported X-ray structure of horse-heart ferricytochrome c has been refined by conformational energy calculations, using a three-stage computational procedure. In stage I, the atomic positions are adjusted to conform to idealized bond lengths and bond angles characteristic of small amino acid derivatives, while yet remaining as close as possible to the X-ray coordinates. In stage II, atomic overlaps are eliminated by adjusting the backbone and side-chain dihedral angles to minimize the nonbonded energy, hydrogen-bonded energy, and rotational energy contributions. In the final stage of refinement, the electrostatic energy and a more accurate hydrogen-bonded energy treatment are considered, in addition to the energy contributions of stage II. A "fitting potential" of gradually decreasing strength is imposed in both stages II and III, in order to keep the computed structure as similar to the x-ray structure as is consistent with a low-energy conformation. The final computed structure of cytochrome c exhibits a very low conformational energy (-504 kcal/mol) and also closely resembles the X-ray structure (RMS deviation = 0.77 A for all atoms). However, a special treatment was required in order to alter the location of the phenyl ring of phenylalanine-82. In contrast to the originally published X-ray structure, which shows the phenyl ring pointing away from the heme, the phenyl ring in the computed structure is tucked into the heme crevice, in a position similar to that observed in the reduced form of tuna cytochrome c, in the oxidized form of Rhodospirillum rubrum cytochrome c2, and also in the recently determined structure of oxidized tuna cytochrome c.