Influence of local interactions on protein structure. III. Conformational energy studies of N-acety-N′-methylamides of Gly-X and X-Gly dipeptides

Conformational energy calculations using an empirical conformational energy program for peptides (ECEPP) were carried out on 20 N-acetyl- N′-methylamides of Gly-X and X-Gly depeptides, where X = Ala, Asn, Asp, Gly, Phe, Ser, Thr, Tyr, Val, and Pro, and also of Leu-Gly. Each depeptde was found to have 25 or more low-energy minima, except Gly-Thr, which had only 11 low-energy minima because of the stable side chian-backbone hydrogen present in all low-energy conformation. As a group, the stble chain-backbone hydrogen bonds present in all low-energy conformations. As a group, the Gly-containing dipeptides were calculated in all low-energy prpensity for formation of bends than the Ala-containing depeptides. The X- Gly dipeptides were calculated to favor bends more than the Gly-X dipeptides, primarlly because of the high stability of the type II bend in X-Gly dipeptides. These results are in agreement with obseved occurrences of bends in the x-ray structures of globular proteins. The calculated conformation properties were found to be in good agreement with experimental results.     

Influence of local interactions on protein structure. II. Conformational energy studies of N-acetyl-N′-methylamides of Ala-X and X-Ala dipeptides

Conformational energy calculations using an empirical conformational energy program for peptides (ECEPP) were carried out on 17 N-acetyl-N′-methylamides of Ala-X and X-Ala dipeptides, Where X = Ala, Asn, Asp, Gly, Phe, Ser, Tyr, Val, and Pro. Each dipeptide was found to have many low-energly minima, some of which corresponded to bend structures. The stability of bends was found to depend on the amino acid composition and sequence, with the Ala-X dipeptide generally favoring bends more than the X-Ala dipeptide for a particular X. In bends and nonbends alike, intraresidue interactions dominate over interresidue interactions in determining conformational propeties. The calcutions were shown to be in good agreement with available experimental data.     

Influence of local interactions on protein structure. IV. Conformational energy studies of N-acetyl-N′-mehylamides of Ser-X- and X-Ser dipeptides

Conformational energy calculations using an empirical conformatinol energy program for peptides (ECEPP) werer carried out on 16 N-acetyl-N′-methylamides of Ser-X and X- Ser dipeptides, where X = Ala, Asn, Asn, Asp, Gly, Phe, Ser, Thr, and Val, and on Pro-Ser. As with the other dipeptides studied in this serites, intraresidue interactions found to dominate over interresidue interactions in determining conformational properties. The Ser-containing dipeptides (except for those with a pro or Gly residue) were found to have unusually low calculated bend probailities, in disagreement observations on proteins; this discrepancy probably arises becuse of sovent effects (not included in the computations). The Ser-X dipeptides were calculated to have a lower preference for bends than the X-Ser dipeptides.     

Conformational preferences of amino acid side chains in collagen

Conformational energy computations were carried out on collagenlike triple-stranded conformations of several poly(tripeptide)s with the general structure CH₃CO? (Gly? X? Y)₃? NHCH₃. The sequences considered had various amino acid residues in position X or Y of the central tripeptide, with either Pro or Ala as a neighbor, i.e., Gly-X-Pro, Gly-X-Ala, Gly-Pro-Y, and Gly-Ala-Y. Minimum-energy conformations were computed for the side chains, and their distributions were compared for the four sequences. The residues used were Abu (= α-aminobutyric acid), Leu, Phe, Ser, Asp, Asn, Val, Ile, and Thr. The conformational energy of a ? Ch₂? CH₃ side chain in Abu was mapped as a function of the dihedral angle χ¹. Intrastrand interactions with neighboring residues do not affect the conformations of a side chain in position Y, and they have a minor effect on it in the X-Ala sequence, but they strongly restrict the conformational freedom of the side chain in the X-Pro sequence. Conversely, interstrand interactions do not affect side chains in position X, but they strongly restrict the conformational freedom of a side chain in position Y if there is a nearby Pro residue in a neighboring strand. Hydrogen bonds with the backbone can be formed in some conformations of long polar side chains, such as Asp, Asn, or Gln. All amino acid residues can be accommodated in collagen. Because of the interactions mentioned above, steric and energetic constraints can be correlated with observed preferences of certain amino acids for positions X or Y in collagen. Hence, these preferences may be explained, in part, in terms of differences in the conformational freedom of the side chains in the triple-stranded structure.     

Influence of hydration on the conformational stability and formation of bends in terminally blocked dipeptides

The conformations of 23 terminally blocked dipeptide sequences were examined by conformational energy calculations that included the effects of the aqueous solvent. Starting structures were derived from combinations of minimum-energy conformations of hydrated single residues. Their conformational energies were then minimized using the ECEPP potential (Empirical Conformational Energy Program for Peptides) with hydration included. Short-range interactions dominate in stabilizing the conformations of the hydrated dipeptides. Differences between conformational stabilities of hydrated and unhydrated dipeptides in many cases are due to the competition of solute–water and intramolecular hydrogen bonds. In other cases, perturbation of the hydration shell of the solute by close approach of solute atoms alters conformational preferences. Probabilities of formation of bends were calculated and compared to the corresponding quantities for unhydrated dipeptides and to those calculated from x-ray structures. For bends in dipeptides containing two nonpolar amino acids, computations omitting hydration yield better results. However, better agreement with experimental (x-ray) bend probabilities for dipeptides containing glycine or polar amino acids is obtained only in some sequences when hydration is included. The results are rationalized by the observation that, in proteins, bends containing nonpolar sequences occur on the inside, shielded from the solvent. Bends containing glycine or polar amino acids occur frequently on the surface of the protein, but they are not completely hydrated.     

Conformational studies on beta-bend containing a cis peptide unit.

Conformational studies have been carried out on the X-cis-Pro tripeptide system (a system of three linked peptide units, in the trans-cis-trans configuration) using energy minimization techniques. For X, residues Gly, L-Ala, D-Ala and L-Pro have been used. The energy minima have been classified into different groups based upon the conformational similarity. There are 15, 20, 18 and 6 minima that are possible for the four cases respectively and these fall into 11 different groups. A study of these minima shows that, (i) some minima contain hydrogen bonds--either 4-->1 or 1-->2 type, (ii) the low energy minima qualify themselves as bend conformations, (iii) cis' and trans' conformations are possible for the prolyl residue as also the C gamma-endo and C gamma-exo puckerings, and (iv) for Pro-cis-Pro, cis' at the first prolyl residue is ruled out, due to the high energy. The available crystal structure data on proteins and peptides, containing cis-Pro segment have been examined with a view to find the minima that occur in solid state. The data from protein show that they fall under two groups. The conformation at X in X-cis-Pro is near extended when it is a non-glycyl residue. In both peptides and proteins there exists a preference for trans' conformation at prolyl residue over cis' when X is a non-glycyl residue. The minima obtained can be useful in modelling studies.     

Dipeptide backbone conformation and antibody recognition of a viral octapeptide epitope.

The peptide YKGTMDSG (Tyr-Lys-Gly-Thr-Met-Asp-Ser-Gly) represents an important antigenic determinant from the glycoprotein G2 of the pathogenic Rift Valley fever virus. By preparing a series of single-residue substitution peptides, the importance to antigenicity of individual residues within this octapeptide has been determined. Here, we investigated a simple and rapid computational analysis to test for correlations between the observed antigenicity of the substitution analogue peptides and the calculated conformational preferences in local regions of the peptides. Conformational energy analyses were carried out on all dipeptide combinations represented in the wild-type octapeptide and in the single-residue substitution analogue peptides. Conformational similarities and differences between wild-type and substitution dipeptide pairs were determined. The results of these computational analyses were then compared with the data on the relative antigenicity of the wild-type octapeptide and the substitution analogues. This comparison revealed a positive correlation. Substitution peptides showing changes in antigenicity possessed significant changes in the calculated backbone conformation relative to wild type in the dipeptides encompassing the residue substitution. Substitution peptides showing no change in antigenicity similarly showed no significant changes in dipeptide conformation. The potential utility of dipeptide conformational energy analyses and this preliminary structure-activity correlation are discussed.     

Conformational energy calculations of enzyme-substrate complexes of lysozyme. I. Energy minimization of monosaccharide and oligosaccharide inhibitors and substrates of lysozyme

Conformational energy calculations were performed on monosaccharide and oligosaccharide inhibitors and substrates of lysozyme to examine the preferred conformations of these molecules. A grid-search method was used to locate all of the low-energy conformational regions for N-acetyl-β-D -glycosamine (NAG), and energy minimization was then carried out in each of these regions. Three stable positions for the N-acetyl group have ben located, in two of which the plane of the amide unit is normal to the mean plane of the pyranosyl ring. Nine local energy minima were located for the —CH₂OH group. The positions of the two vicinal cis —OH groups are determined predominantly by interactions with either the —CH₂OH or the N-acetyl group. The most stable conformations of β-N-acetylmuramic acid (NAM) were determined from the study of the low-energy conformations of NAG. In the two stable orientations for the D -lactic acid side chain, the O—C—C′ plane (C′ being the carbon atom of the terminal carboxyl group) was found to be normal to the mean plane of the pyranosyl ring. The low-energy positions for the COOH group of NAM are determined mainly by interactions with neighboring groups. The conformational preferences of the α-anomers of NAG and NAM were also explored. The calculated conformation of the N-acetyl group for α-NAG was quite close to that determined by X-ray analysis. Two of the three lowest energy conformations of α-NAM are similar to the corresponding conformations of the β-anomer. A third low-energy structure, which has a hydrogen bond from the NH of the N-acetyl group to the C?O of the lactic acid group, corresponds very closely to the X-ray structure of this molecule. The preferred conformations of the disaccharides NAG–NAG, NAM–NAG and NAG–NAM were also investigated. Two preferred orientations of the reducing pyranosyl ring relative to the nonreducing ring were found for all of these disaccharides, both of which are close to the extended conformation. In one of these conformations, a hydrogen bond can form between the OH group attached to C₃ of the reducing sugar and the ring oxygen of the preceding residue. Each conformation can be stabilized further by a hydrogen bond between the CH₂OH (donor) of residue i + 1 and the C?O of residue i (acceptor). The interactions that determine conformations for all oligosaccharides containing both NAG and NAM are shown to be exclusively intraresidue and nearest neighbor interactions, so that it is possible to predict all stable conformations of oligosaccharides containing NAG and NAM in any sequence.     

Conformation analysis of the N-glycosylation site Asn-X-Thr/Ser in glycoproteins

Theoretical conformational analysis of oligopeptides CH3CO-Asn-X-Thr-NHCH3 (X = Gly, Ala, Pro), modelling N-glycosylation site, and their glycosylated derivatives CH3CO-(GlcNAc beta 1-4GlcNAc beta 1) Asn-X-Thr-NHCH3 has been carried out. Active conformations of the site are found, corresponding to structural prerequisities of N-glycosylation: Asn residue's position in beta-turn and hydrogen bond formation between side chains of Asn and Thr/Ser residues. In this case the L conformation of the central residue X is most probable. Since Pro residue does not possess this conformation, sequences with X = Pro are not glycosylated. It is shown that glycosylation of the above-mentioned sites is accompanied by reorientation of the Asn residue's side chains.     

Conformational analysis of cysteine-containing peptides and prospects of their application to 213Bi chelating in antitumor therapy

The method of conformational analysis was applied to the spatial structures of peptide analogues of phytochelatins and some fragments of metallothioneins: (Cys-Gly)₃, (Cys-Gly)₃-Asp, (Cys-Gly)₃-Glu, (Cys-βAla)₃, (Cys-γGlu)₃, and (Cys-Gly-Gly)₃. All the possible low-energy conformations of the molecules were revealed and the role of intra-and interresidual interactions in the formation of their spatial structures was determined. A different tendency of the molecules under study for acceptance of conformations favorable for binding bismuth ions was shown. Low-energy structures providing an optimum binding of bismuth ion were shown to be most frequent for (Cys-βAla)₃ peptide. Among the analogues of peptide fragments of the metallothioneins, lacking in natural peptides, low-energy pentapeptide CCXXC fragments (where X = Gln, Asn, Phe, Tyr, or Gly) were revealed. In the α-helical conformations of these pentapeptides, the distance between the sulfur atoms corresponds to that in Bi₂S₃.     

Stress and strain in staphylococcal nuclease.

Protein molecules generally adopt a tertiary structure in which all backbone and side chain conformations are arranged in local energy minima; however, in several well-refined protein structures examples of locally strained geometries, such as cis peptide bonds, have been observed. Staphylococcal nuclease A contains a single cis peptide bond between residues Lys 116 and Pro 117 within a type VIa beta-turn. Alternative native folded forms of nuclease A have been detected by NMR spectroscopy and attributed to a mixture of cis and trans isomers at the Lys 116-Pro 117 peptide bond. Analyses of nuclease variants K116G and K116A by NMR spectroscopy and X-ray crystallography are reported herein. The structure of K116A is indistinguishable from that of nuclease A, including a cis 116-117 peptide bond (92% populated in solution). The overall fold of K116G is also indistinguishable from nuclease A except in the region of the substitution (residues 112-117), which contains a predominantly trans Gly 116-Pro 117 peptide bond (80% populated in solution). Both Lys and Ala would be prohibited from adopting the backbone conformation of Gly 116 due to steric clashes between the beta-carbon and the surrounding residues. One explanation for these results is that the position of the ends of the residue 112-117 loop only allow trans conformations where the local backbone interactions associated with the phi and psi torsion angles are strained. When the 116-117 peptide bond is cis, less strained backbone conformations are available. Thus the relaxation of the backbone strain intrinsic to the trans conformation compensates for the energetically unfavorable cis X-Pro peptide bond. With the removal of the side chain from residue 116 (K116G), the backbone strain of the trans conformation is reduced to the point that the conformation associated with the cis peptide bond is no longer favorable.     

Conformational energy studies on N-methylated analogs of thyrotropin releasing hormone, enkephalin, and luteinizing hormone-releasing hormone

Empirical conformational energy calculations have been carried out for N-methyl derivatives of alanine and phenylalanine dipeptide models and N-methyl-substituted active analogs of three biologically active peptides, namely thyrotropin-releasing hormone (TRH), enkephalin (ENK), and luteinizing hormone-releasing hormone (LHRH). The isoenergetic contour maps and the local dipeptide minima obtained, when the peptide bond (ω) preceding the N-methylated residue is in the trans configuration show that (1) N-methylation constricts the conformational freedom of both the ith and (i + 1)th residues; (2), the lowest energy position for both residues occurs around ? = ?135° ± 5° and ψ = 75° ± 5°, and (3) the α_L conformational state is the second lowest energy state for the (i + 1)th residue, whereas for the ith residue the C₅ (extended) conformation is second lowest in energy. When the peptide bond (ω_i) is in the cis configuration the ith residue is energetically forbidden in the range ? = 0° to 180° and ψ = ?180° to +180°. Conformations of low energy for ω_i = 0° are found to be similar to those obtained for the trans peptide bond. In all the model systems (irrespective of cis or trans), the α_R conformational state is energetically very high. Significant deviations from planarity are found for the peptide bond when the amide hydrogen is replaced by a methyl group. Two low-energy conformers are found for [(N-Me)His²]TRH. These conformers differ only in the ? and ψ values at the (N-Me)His² residue. Among the different low-energy conformers found for each of the ENK analogs [D -Ala²,(N-Me)Phe⁴, Met⁵]ENK amide and [D -Ala²,(N-Me)Met⁵]ENK amide, one low-energy conformer was found to be common for both analogs with respect to the side-chain orientations. The stability of the low-energy structures is discussed in the light of the activity of other analogs. Two low-energy conformers were found for [(N-Me)Leu⁷]LHRH. These conformations differ in the types of bend around the positions 6 and 7 of LHRH. One bend type is eliminated when the active analog [D -Ala⁶,(M-Me)Leu⁷]LHRH is considered.     

Analgesic dipeptide derivatives. II. Synthetic dipeptides containing a C-terminal 2-(2-nitrophenylsulfenyl) tryptophan residue

The syntheses of dipeptide derivatives of the general formula X-Trp(Nps)-OR (R = H or Me; X = Lys, Gly, Ala, Leu, Ser, Glu, His, Arg, Orn, Dpr, Gpr and Har) are described. The analgesic activities of Gpr- and Har-containing dipeptides have been evaluated and, in the light of these results, the influence of the side chain length of the basic amino acid on the analgesic effect is studied.     

Synthesis,conformational study,and spectroscopic characterization of the cyclic Cα,α‐disubstituted glycine 9‐amino‐9‐fluorenecarboxylic acid

A series of terminally blocked peptides (to the pentamer level) from l ‐Ala and the cyclic C^α,α‐disubstituted Gly residue Afc and one Gly/Afc dipeptide have been synthesized by solution method and fully characterized. The molecular structure of the amino acid derivative Boc‐Afc‐OMe and the dipeptide Boc‐Afc‐Gly‐OMe were determined in the crystal state by X‐ray diffraction. In addition, the preferred conformation of all of the model peptides was assessed in deuterochloroform solution by FT‐IR absorption and ¹H‐NMR. The experimental data favour the conclusion that the Afc residue tends to adopt either the fully‐extended (C₅) or a folded/helical structure. In particular, the former conformation is highly populated in solution and is also that found in the crystal state in the two compounds investigated. A comparison with the structural propensities of the strictly related C^α,α‐disubstituted Gly residues Ac₅c and Dϕg is made and the implications for the use of the Afc residue in conformationally constrained analogues of bioactive peptides are briefly examined. A spectroscopic (UV absorption, fluorescence, CD) characterization of this novel aromatic C^α,α‐disubstituted Gly residue is also reported. Copyright © 1999 European Peptide Society and John Wiley & Sons, Ltd.     

Conformational features responsible for the binding of cyclic analogues of enkephalin to opioid receptors. II. Models of mu- and delta-receptor-bound structures for analogues containing Phe4

Models of mu- and delta-receptor-bound backbone conformations of enkephalin cyclic analogues containing Phe4 were determined by comparing geometrical similarity among the previously found low-energy backbone structures of [D-Cys2,Cys5]-enkephalinamide, [D-Cys2,D-Cys5]-enkephalinamide, [D-Pen2,L-Pen5]-enkephalin and [D-Pen2,D-Pen5]-enkephalin. The present mu-receptor-bound conformation resembles a beta-I bend in the peptide backbone centred on the Gly3-Phe4 region. Two slightly different models were found for the delta-receptor-bound conformation; both of them are more extended than the mu-receptor-bound conformation and include a gamma-turn (or a gamma-like turn) on the Gly3 residue. Energetically favourable rotamers of Tyr and Phe side chains were also determined for the mu- and delta-conformations. The present models of mu- and delta-conformations share geometrical similarity with the low-energy structures of Leu-enkephalin and the Tyr-D-Lys-Gly-Phe-analogue.     

Influence of substituents on conformational preferences of helix foldamers of γ‐dipeptides

Conformational preferences of 9‐ and 14‐helix foldamers have been studied for γ‐dipeptides of 2‐aminocyclohexylacetic acid (γAc₆a) residues such as Ac‐(γAc₆a)₂‐NHMe ( 1 ), Ac‐(C^α‐Et‐γAc₆a)₂‐NHMe ( 2 ), Ac‐(γAc₆a)₂‐NHBn ( 3 ), and Ac‐(C^α‐Et‐γAc₆a)₂‐NHBn ( 4 ) at the M06‐2X/cc‐pVTZ//M06‐2X/6‐31 + G(d) level of theory to explore the influence of substituents on their conformational preferences. In the gas phase, the 9‐helix foldamer H9 and 14‐helix foldamer H14‐z are found to be most preferred for dipeptides 2 and 4 , respectively, as for dipeptides 1 and 3 , which indicates no remarkable influence of the C^α‐ethyl substitution on conformational preferences. The benzyl substitution at the C‐terminal end lead H14‐z to be the most preferred conformer for dipeptides 3 and 4 , whereas it is H9 for dipeptides 1 and 2 , which can be ascribed to the favored C? H···π interactions between the cyclohexyl group of the first residue and the C‐terminal benzyl group. There are only marginal changes in backbone structures and the distances and angles of H‐bonds for all local minima by C^α‐ethyl and/or benzyl substitutions. Although vibrational frequencies and intensities of the dipeptide 4 calculated at both M06‐2X/6‐31 + G(d) and M05‐2X/6‐31 + G(d) levels of theory are consistent with observed results in the gas phase, H14‐z is predicted to be most preferred by ΔG only at the former level of theory. Hydration did not bring the significant changes in backbone structures of helix foldamers for both dipeptide 1 and 4 . It is expected that the different substitutions at the C‐terminal end lead to the different helix foldamers, which may increase the resistance of helical structures to proteolysis and provide the more surface to the helical structures suitable for molecular recognition. © 2014 Wiley Periodicals, Inc. Biopolymers 101: 1077–1087, 2014.     

Preferred conformations of cyclic Ac-Cys-Pro-Xaa-Cys-NHMe peptides: a model for chain reversal and active site of disulfide oxidoreductase

The conformational study on cyclic Ac-Cys-Pro-Xaa-Cys-NHMe (Ac-CPXC-NHMe; X=Ala, Val, Leu, Aib, Gly, His, Phe, Tyr, Asn and Ser) peptides has been carried out using the Empirical Conformational Energy Program for Peptides, version 3 (ECEPP/3) force field and the hydration shell model in the unhydrated and hydrated states. This work has been undertaken to investigate structural implications of the CPXC sequence as the chain reversal for the initiation of protein folding and as the motif for active site of disulfide oxidoreductases. The backbone conformation DAAA is commonly the most feasible for cyclic CPXC peptides in the hydrated state, which has a type I beta-turn at the Pro-Xaa sequence. The proline residue and the hydrogen bond between backbones of two cystines as well as the formation of disulfide bond appear to play a role in stabilizing this preferred conformation of cyclic CPXC peptides. However, the distributions of backbone conformations and beta-turns may indicate that the cyclic CPXC peptide seems to exist as an ensemble of beta-turns and coiled conformations in aqueous solution. The intrinsic stability of the cyclic CPXC motif itself for the active conformation seems to play a role in determining electrochemical properties of disulfide oxidoreductases.     

Ramachandran analysis of conserved glycyl residues in homologous proteins of known structure

High conservation of glycyl residues in homologous proteins is fairly frequent. It is commonly understood that glycine tends to be highly conserved either because of its unique Ramachandran angles or to avoid steric clash that would arise with a larger side chain. Using a database of aligned 3D structures of homologous proteins we identified conserved Gly in 288 alignment positions from 85 families. Ninety‐six of these alignment positions correspond to conserved Gly residue with (φ, ψ) values allowed for non‐glycyl residues. Reasons for this observation were investigated by in‐silico mutation of these glycyl residues to Ala. We found in 94% of the cases a short contact exists between the C^β atom of the introduced Ala with the atoms which are often distant in the primary structure. This suggests the lack of space even for a short side chain thereby explaining high conservation of glycyl residues even when they adopt (φ, ψ) values allowed for Ala. In 189 alignment positions, the conserved glycyl residues adopt (φ, ψ) values which are disallowed for Ala. In‐silico mutation of these Gly residues to Ala almost always results in steric hindrance involving C^β atom of Ala as one would expect by comparing Ramachandran maps for Ala and Gly. Rare occurrence of the disallowed glycyl conformations even in ultrahigh resolution protein structures are accompanied by short contacts in the crystal structures and such disallowed conformations are not conserved in the homologues. These observations raise the doubt on the accuracy of such glycyl conformations in proteins.     

Comparison by 1H-nmr spectroscopy of the conformation of the 2600 dalton antifreeze glycopeptide of polar cod with that of the high molecular weight antifreeze glycoprotein

The antifreeze glycopeptide (AFGP-8) from polar cod, B. saida, is a 14-amino acid polypeptide having alternating glycotripeptide sequences of Ala-[Gal(β1 → 3)GalNAc(β1 → O)]-Thr-Pro and Ala-[Gal(β1 → 3)GalNAc(β1 → O)]-Thr-Ala, with alanyl residues at amino and carboxy terminals. Conformational studies of AFGP-8 have been carried out by ¹H-nmr and empirical energy calculations to investigate the difference in its antifreeze behavior from that of the more active high-molecular weight AFGP 1-4 of P. borchgrevinki. The ¹H-nmr spectra, including the resonances of the exchangeable amide protons, were assigned by two-dimensional correlated spectroscopy (COSY), one-dimensional difference decoupling, and nuclear Overhauser effect (NOE) measurements. For the four threonyl residues, the amide proton coupling constants and the small coupling constants between H^α and H^β indicate similar conformations, despite significant chemical shift differences. The strong NOE between the α protons and the amide protons of the residue following together with large temperature coefficients of chemical shifts, indicate an extended conformation not consisting of α-helix, turns or bends. Energy computations indicate several low-energy conformations consistent with the observed coupling constants for ?. Among these, a left-handed helical conformation with three repeating residues per turn has been proposed, which is in accordance with the observed NOE between the methyl group of the α-GalNAc and Ala H^βs. While the observed Overhauser effects in the threonyl side chain suggest a certain amount of conformational averaging, the effect involving the acetmido methyl of α-GalNAc and H^βs of Ala indicate that it as is a major conformer. In view of the close similarity between the conformations of AFGP-8 and the more active antifreeze polymer, AFGP 1-4, we propose that the difference in their activities is due to the length of the regular repeating structure with glycosylation at every third amino acid residue, and not due to any fundamental difference in their conformations.     

Conformational study of peptides containing dehydrophenylalanine: helical structures without hydrogen bond

The conformational behaviour of deltaZPhe has been investigated in the model dipeptide Ac-deltaZPhe-NHMe and in the model tripeptides Ac-X-deltaZPhe-NHMe with X=Gly,Ala,Val,Leu,Abu,Aib and Phe and is found to be quite different. In the model tripeptides with X=Ala,Val,Leu,Abu,Phe the most stable structure corresponds to phi1=-30 degrees, psi1=120 degrees and phi2=psi2=30 degrees. This structure is stabilized by the hydrogen bond formation between C=O of acetyl group and the NH of the amide group, resulting in the formation of a 10-membered ring but not a 3(10) helical structure. In the peptides Ac-Aib-deltaZPhe-NHMe and Ac-(Aib-deltaZPhe)3-NHMe, the helical conformers with phi = +/-30 degrees, psi = +/-60 degrees for Aib residue and phi=psi= +/-30 degrees for deltaZPhe are predicted to be most stable. The computational studies for the positional preferences of deltaZPhe residue in the peptide containing one deltaZPhe and nine Ala residues reveal the formation of a 3(10) helical structure in all the cases with terminal preferences for deltaZPhe. The conformational behaviour of Ac-(deltaZPhe)n-NHMe with n< or =4 is predicted to be very labile. With n > 4, degenerate conformational states with phi,psi values of 0 degrees +/- 90 degrees adopt helical structures which are stabilized by carbonyl-carbonyl interactions and the N-H-pi interactions between the amino group of every deltaZPhe residue with one C-C edge of its own phenyl ring. The results are in agreement with the experimental finding that screw sense of helix for peptides containing deltaZPhe residues is ambiguous in solution. The helical structures stabilized by hydrogen bond formation are found to be at least 3kCalmol(-1) less stable. Conformational studies have also been carried out for the peptide Ac-(deltaEPhe)6-NHMe and the peptide Ac-deltaAla-(deltaZPhe)6-NHMe containing deltaAla residue at the N-terminal. The N-H-pi interactions are absent in peptide Ac-(deltaEPhe)6-NHMe.