Proline-containing β-turns

The conformations of the dipeptide t-Boc-Pro-d Ala-OH and the tripeptide tBoc-Pro-d Ala-Ala-OH have been determined in the crystalline state by X-ray diffraction and in solution by CD, n.m.r. and i.r. techniques. The unit cell of the dipeptide crystal contains two independent molecules connected by intermolecular hydrogen bonds. The urethane-proline peptide bond is in the cis orientation in both the molecular forms while the peptide bond between Pro and d Ala is in the trans orientation. The single dipeptide molecule exhibits a “bent” structure which approximates to a partial β-turn. The tripeptide adopts the 4 → 1 hydrogen-bonded type II β-turn with all trans peptide bonds. In solution, the CD and i.r. data on the dipeptide indicate an ordered conformation with an intramolecular hydrogen bond. N.m.r. data indicate a significant proportion of the conformer with a trans orientation at the urethane-proline peptide bond. The temperature coefficient of the amide proton of this conformer in DMSO-d₆ points to a 3 → 1 intramolecular hydrogen bond. Taken together, the data on the dipeptide in solution indicate the presence (in addition to the cis conformer) of a C₇ conformation which is absent in the crystalline state. The spectral data on the tripeptide indicate the presence of the type II β-turn in solution in addition to the nonhydrogen-bonded conformer with the cis peptide bond between the urethane and proline residues. The relevance of these data to studies on the substrate specificity of collagen prolylhydroxylase is pointed out.     

CD-n.m.r. study of the solution conformation of bradykinin analogs containing α-aminoisobutyric acid

The conformation in aqueous solution of several α-aminoisobutyric acid (AIB)-containing analogs of bradykinin (BK) has been probed by complementary CD and ¹H n.m.r. measurements. The conclusion reached is that substitution of AIB for Pro² and/or Pro³ in BK stabilizes a degree of β-turn conformation in the N-terminal tetrapeptide moiety of the resulting analogs. Changing the solvent from water to DMSO or TFE further enhances the contribution of particular hydrogen bonded structures to the time-averaged conformation of these peptides. Bradykinin and [AIB⁷]-BK adopt similar hydrogen bonded conformations in TFE, apparently with a contribution from a β-turn involving their common Arg¹-Pro²-Pro³-Gly⁴ moiety. The contrasting biological activities of BK and its AIB-analogs are considered in terms of the conformational analogy between the AIB-residue and cis¹ Pro and the propensity for a β-turn at the N-terminus of the peptide.     

Biologically active conformation of tuftsin

The main features of the assumed biologically active conformation of the tuftsin molecule have been described using the energy calculations as well as the n.m.r. and CD-spectroscopy measurements performed for the conformationally rigid active cycloanalogue, Thr-L-ys-Pro-Arg. The biologically active conformation has been shown to be of BBRB or BLRB backbone type with the trans-conformation of proline residue.     

N-Methyl peptides

The natural occurrence of N-methyl peptides in various plant metabolites has made N-methylation a subtle and attractive possible modification for structure-activity relationship studies of endogeneous peptides. However, little is known about the conformational specificity induced by the N-methylation of a given peptide, and particularly concerning the β-turn conformation. A spectroscopic investigation (i.r., n.m.r., CD) and X-ray diffraction experiments have been carried out on tBuCO-X-Me-Y-NHMe blocked dipeptides (X = Gly, L-Ala, L-Pro, and Y = Gly, and L- or D-Ala, Leu, Phe) with reference to the homologous desmethylated species. The influence of the N-methylation on conformation depends to a large extent on the chirality of the X and Y residues. Homochiral sequences are the most affected, with a strong preference for the βVI-folded conformation containing a middle cis amide bond. Heterochiral sequences are essentially unaffected and retain the βII-folded conformation with a trans middle amide bond. Glycine-containing sequences undergo a more complex perturbation according to the X or Y position of the Gly residue. The available data for larger N-methyl peptides are consistent with our observations, suggesting that these simple dipeptides well reflect the conformational perturbations induced by N-methylation on the β-turn conformation.     

Backbone modifications in cyclic pep tides Conformational analysis of a cyclic pseudopentapeptide containing a thiomethylene ether amide bond replacement

NMR and X-ray crystallographic studies have shown that cyclic pentapeptides of the general structure cyclo(D-Xxx-Pro-Gly-Pro-Gly) possess β- and γ-turn intramolecular hydrogen bonds. As part of our continuing series surveying the compatibility of various amide bond replacements on peptide structure, we have synthesized cyclo(D-Phe-Proψ [CH₂S]Gly-Pro-Gly). The pseudopeptide was prepared by solid phase methods and cleaved from the resin by a new procedure involving phase transfer catalysis using K₂CO₃ and tetrabutylammonium hydrogen sulfate. Cyclization was carried out with the use of DPPA, HOBt, and DMAP to afford the product in 69% yield. The conformational behavior of the pseudopeptide was analyzed by ¹H and ¹³C (1D and 2D) NMR techniques. The backbone modification replaced the amide bond that is involved in a γ-turn intramolecular hydrogen bond in the all-amide structure. In CDCl₃, the pseudopeptide adopted the same all-trans conformation as its parent, although the remaining β-turn hydrogen bond was weaker according to Δδ/ΔT_NH measurements. In DMSO-d₆, the all-trans conformer and a second conformer were observed in a ratio of 55:45. These conformers, which slowly inter converted on the NMR time scale, could be separately assigned; peaks due to chemical exchange were readily distinguishable by the ROESY technique as reported earlier by others. ¹³C and ROESY experiments suggested the minor conformer contained one cis amide bond at the Gly¹-Pro² position. Thus, both the location and type of amide surrogate are important determinants affecting the compatibility of the replacement with a particular conformational feature.     

Conformational analysis of homochiral and heterochiral diprolines as β-turn-forming peptidomimetics: unsubstituted and substituted models

The effect of replacing one of the proline residues in either unsubstituted homochiral or heterochiral diproline segments with either a 2- or a 3-substituted prolyl residue on the allowed conformation of the diproline template has been examined. In heterochiral (l-d ) diprolines, placement of a 2-methyl-d -proline residue in the i+ 2 position and placement of either a cis- or trans-3-methyl-l -proline residue in the i+ 1 position results in substituted diproline peptides that adopt the same type II β-turn conformation as that identified experimentally for the unsubstituted diproline peptides. In contrast, placement of a cis-3-methyl-d -proline residue in the i+ 1 position of a homochiral (d-d ) diproline peptide seems to promote a different conformation than that seen in the unsubstituted case, whereas the trans-3-methyl-d -proline residue seems to provide a stabilizing influence for the predicted type VI'β-turn. The demonstrated ability of certain substituted diproline templates to adopt predictable conformations coupled with the development of asymmetric synthetic routes to both 2- and 3-substituted prolyl residues capable of mimicking a variety of side chains should make these templates useful tools in designing specific turn mimics of biologically active molecules.     

Synthesis and biological activity of tuftsin and rigin derivatives containing monosaccharides or monosaccharide derivatives

Synthesis of some modified rigins is described in which either D-gluconic acid or 2-amino-2-deoxy-β-D-glucopyranose have been linked to the parent molecule through amide bonds involving the α-amino function, α-carboxyl function or the γ-amide function of glutamine in position 2. Glu²-rigin and D-gluconyl-Glu²-rigin have also been synthesized. Binding and phagocytosis assays have been carried out on the rigin derivatives and on some glycosylated tuftsin derivatives as well. Of all the tested peptides only rigin enhanced the phagocytic capacity of mouse peritoneal macrophages to the same extent as tuftsin. The peptides H-Thr-Lys-Pro-Arg-NH-Glc and Nα-gluconyl-Gly-Glu-Pro-Arg-OH slightly enhanced phagocytosis. H-Thr[(α + β)-O-glucosyl]-Lys-Pro-Arg-OH was found to displace ³H-tuftsin even better than tuftsin but lacked the ability to stimulate phagocytosis.     

Synthesis and immunological evaluation of the conjugates composed from a muramyl peptide GMDP and tuftsin

The conjugates of a muramyl dipeptide analog GMDP (N-acetylglucosaminyl β1→4 N-acetylmuramyl-L-alanyl-D-isoglutamine) and tuftsin (Thr-Lys-Pro-Arg) were synthesized from unprotected GMDP by mixed anhydride procedure. The identity of the conjugates was confirmed by high resolution NMR and their immunomodulating properties were determined in various tests. It was found that the conjugate in which the GMDP carboxyl group forms an amide bond with the &-amino group of tuftsin lysyl residue exceeds GMDP in all the activities determined. Synergism of GMDP and tuftsin was found in phagocytosis stimulation assay.     

Motifs and conformational analysis of amino acid residues adjoining β-turns in proteins

Using a data set of 250 non-homologous high-resolution globular proteins, a systematic analysis of the conformations that precede and succeed (positions i and i+3) the various classical β-turn types has been carried out. The collective conformation of a specific β-turn type, including the flanking positions, termed motif, has been studied. In all the four turn types, the majority of examples are preceded and succeeded by extended conformation. Some of the other observations are: (1) In a type I β-turn, Gly at position i+ 3 has a higher favorability to occur with positive ø and does not prefer the major motif βα_R-α_R-β. (2) The left-handed alpha;-helical conformation (alpha;_L) is not preferred at both the flanking positions for type I'and II β-turns, (3) The β–β motif is favourable for all the turn types and the motif β–α_L very highly favourable for type I. © Munksgaard 1996.     

The evaluation of type I and type II β-turn mixtures

Circular dichroism (CD) and¹ H-{¹H}NOE spectra were obtained for Piv-Pro-Ser-NHCH₃(1),[Piv-(CH₃)₃-C-CO], Boc-Pro-Ser-NHCH₃ (2) and Boc-Val-Ser-NHCH₃ (3), to determine the solution conformation of these p-turn models. In the crystal, 1 and 3 adopt an ideal type I β-turn, while 2 is characterized by a semifolded backbone geometry incorporating a cis Boc-Pro tert-amide bond. The predominance of a β-turn conformation in solution was suggested for models 1-3 on the basis of ¹H-{¹H}NOE data. In a nonpolar solvent the prevailing trans rotamer form (>80%) of 2 has a β-turn conformation according to heteronuclear NOE measurement. Positive ¹H-{¹H} NOEs were detected between the H^α(Pro)/NH(Ser), Hα(Ser)/NH(Ser) and NH(NHCH₃3)/HN(Ser) protons in the trans Boc-Pro rotamer form of 2 at -20° in CDCl₃. Similar positive homonuclear NOE enhancements were also observed on the appropriate proton signals in other models, such as Boc-Val-Ser-NHCH₃ (3). Boc-Val-D-Ser-NHCH₃ (4) and Boc-Pro-D-Ser-NHCH₃ (5), in various solvents. The ¹H- {¹H)NOE experiments carried out in CD₃CN clearly showed that besides the type I (or III) β-turn structure, one of the main conformations of models 1-5 is close to the type II β-turn backbone geometry in a nonpolar solvent. Unexpectedly, the conformational mixture of models 1-3 were characterized by class C (helix-like) CD spectra, although class C spectra are generally only correlated with the type I β-turn conformation. These acyclic models are the first carefully investigated examples of -L-L- triamide systems, containing a significant amount of a type II β-turn, as well as the type I p-turn and, however, yielding a class C circular dichroism spectra. The CD spectra recorded for 3 and 4 in acetonitrile were ‘calibrated’ using the ¹H-{¹H}NOE data. Such a “calibration”, as well as the semi-quantitative CD and NMR comprehensive analyses, demonstrated that class C, class B, as well as class C’ CD spectra may be obtained from the linear combination of the same two-component spectra, with different conformational weights. Therefore, it is suggested that the extraction of the conformational components of such models, simply on the basis of their CD spectra, must be made with caution.     

Conformational study on trans- and cis-N-acetyl-N′-methylamides of Pro-Xaa dipeptides

Conformational free energy calculations using an empirical potential ( ECEPP /2) and the hydration shell model were carried out on the N-acetyl-N′-methylamides of Pro-Xaa dipeptides (Xaa = Ala, Leu, Val, Gly, Cys, Met, Phe, Tyr, Asn, Asp, and Ser) with trans and cis peptide bonds preceding proline residue in the unhydrated and hydrated states. As compared with the results obtained by using the earlier version of ECEPP, the values of β-bend probabilities are about doubled. The average calculated population of cis-dipeptide is about 4%, which is close to the abundance obtained from the analysis of X-ray crystal structures of proteins. The β-bends are the most dominant structures of cis-dipeptides. Type I, usually having intramolecular hydrogen bonds, contributes greatly to the β-bend conformations of trans- and cis-dipeptides. However, type I β-bends of cis-dipeptides do not have any hydrogen bonds. By including the hydration, the β-bend probabilities for trans- and cis-dipeptides decreased, indicating that the interactions of water molecules with a backbone or side-chain may force the dipeptides to be more distorted or extended. In particular, type II is found to be a dominant β-bend conformation of trans- and cis-Pro-Gly dipeptides in both the unhydrated and hydrated states. In general, the calculated propensities for Pro-Xaa dipeptides to adopt β-bend conformations are reasonably consistent with available experimental data. From comparing conformations of Pro and Xaa residues in the dipeptides and single residues, we found that inter-residue interactions and hydration are of importance in determining the conformational properties of the Pro-Xaa dipeptide.     

Structure of cyclic peptides: the crystal and solution conformation of cyclo(Phe-Phe-Aib-Leu-Pro)

A solid-state and solution conformation analyses of the cyclopentapeptide cyclo(Phe-Phe-Aib-Leu-Pro) has been carried out by X-ray diffraction and nuclear magnetic resonance techniques. The structure of the hexagonal crystals, grown from a methanol solution [a=b= 16.530(4) Å, c= 21.356(9) Å, space group P6₅, Z = 6], shows the presence of one intramolecular N-H?O=C hydrogen bond with the formation of a γ-turn (C₇). The Aib³ residue, at the center of the γ-turn, presents unexpected values of the torsion angles [φ= 70.5° and ψ= -73.8°], which have been observed only once before for this helicogenic residue. A cis peptide bond occurs between Leu⁴ and Pro⁵; all other peptide bonds are trans. The overall conformation for the cyclopentapeptide with one cis-peptide bond on one side and an intramolecular γ-turn on the opposite side results in an equatorial topology of the side-chains of the Phe¹, Phe² and Leu⁴ residues. Indeed, the C^α-C^βand C^β-C^γ bonds of these residues lie approximately in the mean plane of the cyclic ring system. The structure is compared with data in the literature on cyclic pentapeptides. In addition the Pro-Phe-Phe moiety shows a conformation similar to that observed in other larger cyclic bioactive peptides, which indicates a reduced number of conformations for this sequence. The solution study was carried out in three different solvent systems: chloroform, acetonitrile and methanol in the temperature interval 220–300 K. In all three solvents the room temperature spectra show that the peptide is conformationally nonhomogeneous. In acetonitrile at low temperatures it is possible to reduce the conformational equilibrium to two predominant conformers which differ for the cis-trans isomerism of the Leu⁴-Pro⁵ peptide bond.     

3-Amino-2-piperidinone-6-carboxylic acid

The cis (2a) and trans (2b) isomers of methyl 3-benzamido-2-piperidinone-6-carboxylate (Apca) were prepared and separated by fractional recrystallizations. Proton n.m.r. studies in dimethylsulfoxide solution indicate that the six-membered lactam ring adopts a distorted chair conformation with an equatorially oriented benzamido substituent in both 2a and 2b. The carboxyl function also is equatorially oriented in the trans isomer 2b, but is disposed axially in the cis isomer 2a. In the crystal structure, the six-membered lactam ring of 2a is clearly in a boat conformation with the benzamido and carboxyl functions attached to the two apex carbon atoms equatorially. The trans isomer, 2b, exists as two crystallographically independent, conformationally distinct molecules in one unit cell. The lactam ring in both molecules adopts a distorted chair conformation, as is the case in solution, with both the benazamido and carboxyl functions attached equatorially. The rotameric orientation for the endocyclic lactam differs between the two molecules. Both structures show evidence of C—H.O hydrogen bond formation intermolecularly in the solid state. This ability, along with the distinctive conformational features of Apca, may be exploitable in the design of unique features of polypeptides.     

Determination of structural elements related to the biological activities of a potent decapeptide agonist of human C5a anaphylatoxin

Abstract: The structural features related to the biologic activities of a potent, response-selective decapeptide agonist of human C5a, YSFKPMPLaR (C5a_65–74, Y65, F67, P69, P71, d -Ala73), were identified by NMR analysis in H₂O, DMSO and TFE. This investigation showed that the KPM residues in H₂O and the SFKPM residues in DMSO exhibited an extended backbone conformation, whereas a twisted conformation was found in this region in TFE. In H₂O, the C-terminal region (PLaR) adopted a distorted type II β-turn or a type II/V β-turn. In the type II/V β-turn, Leu72 exhibited a conformation typical of a type II β-turn, whereas d -Ala73 exhibited a conformation characteristic of a type V β-turn. Furthermore, a γ-turn involving residues LaR overlapped with the type II/V β-turn. In DMSO, the C-terminal region had the analogous turn-like motif (type II/V β-turn overlapping with γ-turn) found in H₂O. In TFE, no β-turn motifs were formed by the PLaR residues. These turn-like motifs in the C-terminal region of the peptide in both H₂O and DMSO were in agreement with the biologically important conformations predicted earlier by a structure–function analysis of a related panel of decapeptide analogs. The motifs determined by the NMR analysis of YSFKPMPLaR in H₂O and DMSO may represent structural elements important for C5a agonist activity and thus can be used to design the next generation of C5a agonist, partial agonist and antagonist analogs.     

Stereochemistry of peptides containing 1-aminocycloheptane-1-carboxylic acid (Ac7c)

The crystal structures of four peptides incorporating l-aminocycloheptane-l-carboxylic acid (Ac₇c) are described. Boc-Aib-Ac₇c-NHMe and Boc-Pro-Ac₇c-Ala-OMe adopt β-turn conformations stabilized by an intramolecular 4 × 1 hydrogen bond, the former folding into a type-I/III β-turn and the latter into a type-II β-turn. In the dipeptide esters, Boc-Aib-Ac₇c-OMe and Boc-Pro-Ac₇c-OMe, the Ac₇c and Aib residues adopt helical conformations, while the Pro residue remains semi-extended in both the molecules of Boc-Pro-Ac₇c-OMe found in the asymmetric unit. The cycloheptane ring of Ac₇c residues adopts a twist-chair conformation in all the peptides studied. ¹H-NMR studies in CDCl₃ and (CD₃)₂SO and IR studies in CDCl₃, suggest that Boc-Aib-Ac₇c-NHMe and Boc-Pro-Ac₇c-Ala-OMe maintain the β-turn conformations in solution.     

Structural recognition of an ICAM-1 peptide by its receptor on the surface of T cells: conformational studies of cyclo (1, 12)-Pen-Pro-Arg-Gly-Gly-Ser-Val-Leu-Val-Thr-Gly-Cys-OH

Abstract: The purpose of this study is to elucidate the solution conformation of cyclic peptide 1 (cIBR), cyclo (1, 12)-Pen1-Pro2-Arg3-Gly4-Gly5-Ser6-Val7-Leu8-Val9-Thr10-Gly11-Cys12-OH, using NMR, circular dichroism (CD) and molecular dynamics (MD) simulation experiments. cIBR peptide ( 1 ), which is derived from the sequence of intercellular adhesion molecule-1 (ICAM-1, CD54), inhibits homotypic T-cell adhesion in vitro. The peptide hinders T-cell adhesion by inhibiting the leukocyte function-associated antigen-1 (LFA-1, CD11a/CD18) interaction with ICAM-1. Furthermore, Molt-3 T cells bind and internalize this peptide via cell surface receptors such as LFA-1. Peptide internalization by the LFA-1 receptor is one possible mechanism of inhibition of T-cell adhesion. The recognition of the peptide by LFA-1 is due to its sequence and conformation; therefore, this study can provide a better understanding for the conformational requirement of peptide–receptor interactions. The solution structure of 1 was determined using NMR, CD and MD simulation in aqueous solution. NMR showed a major and a minor conformer due to the presence of cis/trans isomerization at the X-Pro peptide bond. Because the contribution of the minor conformer is very small, this work is focused only on the major conformer. In solution, the major conformer shows a trans-configuration at the Pen1–Pro2 peptide bond as determined by HMQC NMR. The major conformer shows possible β-turns at Pro2-Arg3-Gly4-Gly5, Gly5-Ser6-Val7-Leu8, and Val9-Thr10-Gly11-Cys12. The first β-turn is supported by the ROE connectivities between the NH of Gly4 and the NH of Gly5. The connectivities between the NH of Ser6 and the NH of Val7, followed by the interaction between the amide protons of Val7 and Leu8, support the presence of the second β-turn. Furthermore, the presence of a β-turn at Val9-Thr10-Gly11-Cys12 is supported by the NH–NH connectivities between Thr10 and Gly11 and between Gly11 and Cys12. The propensity to form a type I β-turn structure is also supported by CD spectral analysis. The cIBR peptide ( 1 ) shows structural similarity at residues Pro2 to Val7 with the same sequence in the X-ray structure of D1-domain of ICAM-1. The conformation of Pro2 to Val7 in this peptide may be important for its binding selectivity to the LFA-1 receptor.     

Synthesis and solution conformation of c(D-Trp-D-Cys(SO3-Na+)-Pro-D-Val-Leu), a potent endothelin-A receptor antagonist

The endothelin family of polypeptides are known to exert potent physiological effects which include cardiovascular regulation. The solution conformation and dynamics of c(D-Trp-D-Cys(SO₃-Na⁺)-Pro-D-Val-Leu), a potent endothelin-A receptor-selective antagonist, were characterized in aqueous solution by NMR spectroscopy and molecular modeling. NMR-derived conformational constraints were combined with computer-assisted molecular modeling using distance geometry calculations and energy minimization. The pentapeptide backbone is shown to adopt a single conformation in solution comprising a type II β-turn and an inverse γ-turn, with each residue in the trans conformation. Molecular dynamics were explored using relaxation measurements and low-temperature studies, and indicate that the peptide backbone is highly constrained with little conformational mobility present.     

Immunosuppressive analogues of hexapeptide Tyr-Val-Pro-Leu-Phe-Pro,an immune system stimulant

It was found that substitution of Val² and/or Leu⁴ residue in a hexapeptide Tyr-Val-Pro-Leu-Phe-Pro (I) transforms this peptide immunostimulant into analogues possessing the immunosuppressor activity – Tyr-Gly-Pro-Leu-Phe-Pro (II), Tyr-Val-Pro-Gly-Phe-Pro (III), and Tyr-Gly-Pro-Gly-Phe-Pro (IV). Biological effects of peptides I-IV were studied using PFC (plaque forming cell) test, GvH (graft vs host) reaction in mice, and ARFC (autologous rosette forming cell) test. The strongest immunosuppressor activity was observed for III – in this case the immunosuppressor effect was observed even in PFC test in vitro in which II and IV showed no such activity. These results suggest that simultaneous presence of both Val² and Leu⁴ residues is necessary for the generation of immunostimulation. The CD study of I-IV in methanol solution suggests that the conformational preferences of II-IV change towards stabilization of the β-turn structure, whereas in the case of I the γ-turn on Leu⁴ and cis orientation of the Pro³ carbonyl (distorted β-turn of type I) was found (1) as the preferred conformation. Competition in biological effects observed for I and III in PFC in vitro test suggests that these analogues may interact with the same cellular receptor. Drastic changes in the activity which accompany changes in the sequence are discussed in the terms of our stereochemical hypothesis (1).     

Influence of serine in position i on conformation and dynamics of reverse turns

NMR spectroscopy has been employed for the conformational analysis of the cyclic hexapeptide cycle(-d -Pro¹-Ala²-Ser³(Bzl)-Trp⁴-Orn⁵(Z)-Tyr⁶-) with and without protecting groups on Ser³ and Orn⁵. This peptide sequence was derived from the active loop sequence of the α-amylase inhibitor Tendamistat (HOE 467). The aim was to investigate the role of serine in position i of a standard β-turn on the conformation and stabilization of this turn. Based on distance and torsion constraints from 2D NMR spectroscopic measurements in DMSO-d₆ solution, structure refinement was accomplished by restrained molecular dynamics (MD) simulations in vacuo and in DMSO. The analysis of both structures in solution reveals a considerable effect of the unprotected serine sidechain on the adjacent β-turn conformation. While in the protected peptide with Ser³(Bzl) a βII-turn is observed between Trp⁴ and Orn⁵, the deprotected compound reveals a βI-turn in this region. The βI-turn is stabilized by a backbone-sidechain hydrogen bond from Orn⁵N_αH to Ser³O_γ. Comparisons with other NMR-derived solution structures of cyclic model peptides and in some protein structures from literature reveal a general structural motif in the stabilization of βI-turns by serine in the i position through backbone-sidechain interactions. © Munksgaard 1995.     

Stabilization of β-turn conformations in enkephalins

Stereochemical constraints have been introduced into the enkephalin backbone by substituting α-aminoisobutyryl (Aib) residues at positions 2 and 3, instead of Gly. ¹H n.m.r. studies of Tyr-Aib-Gly-Phe-Met-NH₂, Tyr-Aib-Aib-Phe-Met-NH₂ and Tyr-Gly-Aib-Phe-Met-NH₂ demonstrate the occurrence of folded, intramolecularly hydrogen bonded structures in organic solvents. Similar conformations are also favoured in the corresponding t-butyloxycarbonyl protected tetrapeptides, which lack the Tyr residue. A β-turn centred at positions 2 and 3 is proposed for the Aib²-Gly³analog. In the Gly²-Aib³analog, the β-turn has Aib³-Phe⁴as the corner residues. The Aib²-Aib³analog adopts a consecutive β-turn or 3₁₀ helical conformation. High in vivo biological activity is observed for the Aib²and Aib²-Aib³analogs, while the Aib³peptide is significantly less active.