Differential scanning calorimetry studies of NaCl effect on the inverse temperature transition of some elastin-based polytetra-, polypenta-, and polynonapeptides

Differential scanning calorimetry studies of the effect of NaCl on protein-based polymer self-assembly has been carried out on six elastin-based synthetic sequential polypeptides- i.e., the polypentapeptide (L -Val¹-L -Pro²-Gly³-L -Val⁴-Gly⁵)_n and its more hydrophobic analogues (L -Leu¹-L -Pro²-Gly³-L -Val⁴-Gly⁵)_n and (L -Val¹-L -Pro²-L -Ala³-L -Val⁴-Gly⁵)_n; the polytetrapeptide (L -Val¹-L -Pro²-Gly³-Gly⁴)_n and its more hydrophobic analogue (L -IIe¹-L -Pro²-Gly³-Gly⁴)_n; and the polynonapeptide (a pentatetra hybrid), (L -Val¹-L -Pro²-Gly³-L -Val⁴-Gly⁵-L -Val⁶-L -Pro⁷-Gly⁸-Gly⁹)_n. Previous physical characterizations of the polypentapeptides have demonstrated the occurrence of an inverse temperature transition since increase in order of the polypentapeptide, as the temperature is raised from below to above that of the transition, has been repeatedly observed using different physical characterizations. In the present experiments, it is observed that the transition temperatures of the polypeptides studied are linearly dependent on NaCl concentration. The molar effectiveness of NaCl in shifting the transition temperature ΔT_m/[N], is about 14°C/[N], with the dependence on peptide hydrophobicity being fairly small. Interestingly, however, the δΔQ/ [N] does depend on the hydrophobicity of a polypeptide.     

Phase-structure transitions of the elastin polypentapeptide-water system within the framework of composition-temperature studies

The temperature dependence of the composition of coacervate and equilibrium phases is examined for the polypentapeptide of elastin (L -Val¹-L -Pro²-Gly³-L -Val⁴-Gly⁵)_n in water. This provides for the development of a phase diagram. CD data is presented that provides information on associated polypeptide structure changes that, when added to previous CD, nmr, and dielectric relaxation data at lower water composition, allow construction of a phase-structure diagram of the polypentapeptide–water system. The molecular-weight dependence of phase change (coacervation) is included. The volume–composition studies as a function of temperature also provide temperature coefficients of expansion and of composition important in analyzing the mechanism of elasticity.     

Carbon-13 magnetic resonance spectra of aortic alpha-elastin in solution, coacervate and fibrous states.

Carbon-13 magnetic resonance spectra are reported for aortic α-elastin in solution, coacervate and fibrous states. The observation of spectra for the coacervate and fibrous states indicates retention of some chain mobility in these condensed phases and qualitative comparisons demonstrate selected and identifiable losses of resonance intensity on progressing from the solution state to the coacervate and fibrous states. Comparison of the carbonyl regions of α-elastin and the polypentapeptide, HCO-(Val₁-Pro₂-Gly₃-Val₄-Gly₅)_n-Val-OMe, spectra suggests that the polypentapeptide is a good model for the observable carbonyls of α-elastin. With the polypenta-peptide model, certain resonances of elastin in each of the three states can be assigned and related to previously defined features of sequence and of conformation. This approach will ultimately lead to substantial and detailed information on the structure and dynamics of fibrous elastin.     

Nuclear overhauser enhancement demonstration of the type II β-turn in repeat peptides of tropoelastin

Nuclear Overhauser enhancement (NOE) experiments have been performed with the elastin peptides, namely; HCO-Val₁-Pro₂-Gly₃-Gly₄-OMe, t-Boc-Val₁-Pro₂-Gly₃-Val₄-Gly₅-OMe and t-Boc-Val₆-Ala₁-Pro₂-Gly₃-Val₄-Gly₅-OMe in DMSO-d₆. An NOE of approximately 10% was observed between the αCH of Pro₂ and the NH of Gly₃ involved in the β-turn of all three peptides. This finding shows the close proximity of two aforementioned protons and thus shows the occurrence of Type II β-turn in the repeat elastin peptides. The intermolecular distances are calculated and compared with the distances obtained from other model systems.     

Nmr and computer-aided studies of the three interchanging stereoisomers of the cyclic hexapeptide cyclo[-Pro1-Gly2-Glu3(OBzl)-Pro4-Phe5-Leu6-]: Unexpected observation of a cis isomer of a secondary amide peptide bond in the presence of two trans proline peptide bonds

The cyclic hexapeptide cyclo[-Pro¹-Gly²-Glu³(OBzl)-Pro⁴-Phe⁵-Leu⁶-] ( 1 ; OBzl: benzyl ester) was modeled and synthesized to be used as a chiral site for the separation of enantiomers. Total correlation spectroscopy and nuclear Ovehauser effect spectroscopy spectra of the peptide in CDCl₃ showed the presence of three stereoisomers. The two dominant stereoisomers 1a and 1b exchanged chemically with each other, while the minor stereoisomer 1c exchanged exclusively with the stereoisomer 1b . Stereoisomer 1a had two cis proline peptide bonds while stereoisomer 1b had all-trans peptide bonds. The stereoisomer 1c had, for nonstrained peptides, an unusual cis phenylalanine peptide bond while both proline peptide bonds were trans. © 1993 John Wiley & Sons, Inc.     

Conformational Studies of Two Bradykinin Antagonists by Using Two-dimensional NMR Techniques and Molecular Dynamics Simulations

Abstract

The solution conformations of two potent antagonists of bradykinin (Arg¹-Pro²-Pro³-Gly⁴- Phe⁵-Ser⁶-Pro⁷-Phe⁸-Arg⁹), [Aca-¹, DArg⁰, Hyp³, Thi⁵, DPhe⁷,(N-Bzl)Gly⁸]BK (1) and [Aaa- ¹, DArg⁰, Hyp³, Thi⁵,(2-DNal)⁷, Thi⁸]BK (2), were studied by using 2D NMR spectroscopy in DMSO-dg and molecular dynamics simulations. The NMR spectra of peptide 1 reveals the existence of at least two isomers arising from isomerization across the DPhe⁷-(N-Bzl)Gly⁸peptide bond. The more populated isomer possesses the cis peptide bond at this position. The ratio of cis/trans isomers amounted to 7:3. With both antagonists, the NMR data indicate a β-turn structure for the Hyp³-Gly⁴ residues. In addition, for peptide 2, position 2,3 is likely to be occupied by turn-like structures. The cis peptide bond between DPhe⁷ and (N- Bzl)Gly⁸ in analogue 1 suggests type VI β-turn at position 7,8. The molecular dynamics runs were performed on both peptides in DMSO solution. The results indicate that the structure of peptide 1 is characterized by type VIb β-turn comprising residues Ser-Arg⁹ and the βI or βII-turn involving the Pro²-Thi⁵ fragment, whereas peptide 2 shows the tendency towards the formation of type I β-turn at position 2,3. The structures of both antagonists are stabilized by a salt bridge between the guanidine moiety of Arg¹ and the carboxyl group of Arg⁹. Moreover, the side chain of DArg⁰ is apart of the rest of molecule and is not involved in structural elements except for a few calculated structures.     

A proton magnetic resonance study of two synthetic agonist–antagonist pairs of bradykinin analogues

The conformation of two agonist–antagonist pairs of bradykinin (Arg¹-Pro²-Pro³-Gly⁴-Phe⁵-Ser⁶-Pro⁷-Phe⁸-Arg⁹) analogues were studied in CD₃OH/H₂O solution by ¹H-nmr techniques. The first agonist peptide studied, D -Arg⁰-Arg¹-Pro²-Hyp³-Gly⁴-Thi⁵-Ser⁶-Pro⁷-Thi⁸-Arg⁹, differs from the bradykinin sequence by the addition of D -Arg⁰, the replacement of the Phe moieties in positions 5 and 8 by Thi (Thi = β-(2-thienyl)-L -alanine), and Hyp³ (Hyp = L -4-hydroxy-L -proline) in position 3. In the corresponding antagonist sequence, Pro⁷ is replaced by D -Phe⁷. The second agonist–antagonist pair studied does not contain the D -Arg⁰ residue, which is present only to slow down the rate of metabolism. Based on complete resonance assignments from two-dimensional total correlation spectroscopy and rotating frame nuclear Overhauser effect spectroscopy spectra at 500 MHz, the peptides were analyzed in terms of intraresidue, sequential, and medium-range nuclear Overhauser effects, amide proton temperature coefficients, and vicinal coupling constants. Both agonist peptides show clear evidence for the existence of a type I β-turn comprising the C-terminal residues Ser⁶-Pro⁷-Thi⁸-Arg⁹ in fast conformational equilibrium with extended structures throughout. Although the conformational space is dominated by extended structures, the presence of the β-turn is spectroscopically clearly discernible. The two antagonist peptides, on the other hand, do not show evidence of turn formation but rather the presence of an extended conformation with some irregularities in the N-terminal region of the peptide. While the existence of a turn at the C-terminal end of bradykinin and its analogues with agonist activity has been predicted by empirical calculations and measurements in very apolar solvents, this study, for the first time, provides evidence based on physical data in a polar solvent environment that the turn is present, that it is type I and that it is essential for agonist activity. In the particular solvent used in these studies, the Pro⁷ to D -Phe⁷ substitution precluded the formation of the turn for the C-terminal residues of the antagonist. © 1993 John Wiley & Sons, Inc.     

Proton and carbon magnetic resonance studies of the synthetic polypentapeptide of elastin.

Proton and ¹³C magnetic resonance studies are reported on the synthetic polypentapeptide of elastin, HCO-(Val₍₁₎-Pro₍₂₎-Gly₍₃₎-Val₍₄₎-Gly₍₅₎)_n-Val-OMe, where n ∼- 18. Temperature and solvent dependence of peptide N$\text{H}$ chemical shift and solvent dependence of peptide carbonyl chemical shift were used to delineate these moieties preliminary to identification of secondary structure.Based on these studies it is proposed, for the organic solvents of dimethyl sulfoxide, methanol, and low-temperature trifluoroethanol, that dynamic hydrogen bonds form in order of decreasing frequency of occurrence between the Val₍₁₎$\text{C}$O and the Val₍₄₎ N$\text{H}$ (a β-turn), between the Gly₍₃₎ N$\text{H}$ and the Gly₍₅₎$\text{C}$O (an 11-atom, hydrogen-bonded ring), and a more limited interaction between the Gly₍₃₎$\text{C}$O and the Gly₍₅₎ N$\text{H}$ (a γ-turn).Arguments are presented that relate the conformational features proposed above to the coacervate, which is a filamentous state.     

Nmr and molecular modeling investigations of the neuropeptide bradykinin in three different solvent systems: DMSO, 9 : 1 dioxane/water,and in the presence of 7.4 mM lyso phosphatidylcholine micelles

The linear nonapeptide hormone bradykinin (Arg¹-Pro²-Pro³-Gly⁴-Phe⁵-Ser⁶-Pro⁷-Phe⁸-Arg⁹) is involved, either directly or indirectly, in a wide variety of physiological processes, particularly pain and hyperanalgesia. Additional evidence suggests that bradykinin also plays a major role in inflammatory response, asthma, sepsis, and symptoms associated with the rhinoviral infection. It has long been speculated that a β-turn at the C-terminus of bradykinin plays a major role in the biological activity of the neuropeptide. The β-turn forming potential of bradykinin in three vastly different local chemical environments, DMSO, 9 : 1 dioxane/water, and in the presence of 7.4 mM lyso phosphatidylcholine micelles, was investigated using two-dimensional homonuclear nmr experiments coupled with simulated annealing calculations. The results of these investigations show that in all three systems residues 6–9 of the C-terminus adopt very similar β-turn like structures. These results suggest that the β-turn at the C-terminus of bradykinin is an important secondary structural feature for receptor recognition and binding. © 1994 John Wiley & Sons, Inc.     

Temperature-correlated force and structure development in elastomeric polypeptides: the Ile1 analog of the polypentapeptide of elastin

The Ile¹ analog of the polypentapeptide of elastin, (L · Ile¹-L · Pro²-Gly³-L · Val⁴-Gly⁵)_n, abbreviated as Ile¹-PPP, was synthesized with n > 100 to determine the effect of the increased hydrophobicity of the pentamer resulting from Val¹ replacement by Ile¹ on the previously characterized inverse temperature transition of the polypentapeptide of elastin (PPP). Ile¹-PPP, dissolved in water at 4°C, was found to aggregate, forming a viscoelastic coacervate on raising the temperature. The onset of aggregation was 8°C for Ile¹-PPP, as compared to 24°C for PPP. Characterization by CD demonstrated an increase in intramolecular order on raising the temperature from 8°C to 25°C, and demonstrated similar conformations for PPP and Ile¹-PPP before and after their respective transitions. The CD-characterized transition also occurred at a temperature some 15°C lower than that of PPP. By means of 20-Mrad γ-irradiation cross-linking of the Ile¹-PPP coacervate, an elastomeric matrix was formed with an elastic modulus, similar to that of 20-Mrad cross-linked PPP. The temperature dependence of elastomeric force of cross-linked Ile¹-PPP showed an abrupt increase from essentially zero at 8°C to three-quarters of full force at 10°C and essentially full force by 20–25°C. This development of elastomeric force for the more hydrophobic Ile¹-PPP matrix, which parallels the increase in intramolecular order characterized by the CD studies, also occurs at a temperature some 15°C lower than that for the PPP matrix. Thus, in these elastomeric polypeptides, development of elastomeric force is coupled to an inverse temperature transition, the temperature of which depends inversely on the hydrophobicity of the constituent pentamer. It appears that a series of elastomeric polypeptide biomaterials are possible in which the temperature over which elastomeric force develops can be varied.     

Solution conformational preferences of a peptidic analogue of a natural macrolide

The conformational behavior in solution of a cyclic peptide with sequence cyclo-(Pro¹-Pro²-Dab³ (cHexA)ψ[N⁷HCO]-Leu⁴ψ[NHCO]-Suc⁵-Gly⁶-) has been throughly investigated with the combined use of nmr and molecular dynamic techniques. The compound, which has been modeled to mimic the FK506 macrolide bound to the FK506 binding protein structure, can be considered as a peptidic analogue of the FK506 system. The synthesis was carried out on a phenylacetoamidomethyl resin using an appropriate protocol for the peptide chain elongation. The conformational properties of the cyclic hexapeptide were studied in DMSO and water. The nmr data in DMSO and restrained molecular dynamics simulations show the presence of two contiguous cis peptide bonds involving the -Gly-Pro-Pro- segment. This segment in water exhibits conformational heterogeneity presenting at least two distinct conformational families, characterized the first by cis-cis and the second by a trans-cis Gly-Pro-Pro configuration; the trans-cis isomer was fully characterized. © 1997 John Wiley & Sons, Inc. Biopoly 42: 349–361, 1997     

Proton magnetic resonance studies of bradykinin antagonists

Bradykinin (BK) is a peptide hormone with sequence Arg¹-Pro²-Pro³-Gly⁴-Phe⁵-Ser⁶-Pro⁷-Phe⁸-Arg⁹ and has been implicated in a multitude of pathophysiological processes such as the ability to lower systemic blood pressure and stimulate pain. BK analogues having bulky, β-branched D -aliphatic residues at position 7 combined with bulky L -aliphatic residues at position 8 have now been observed to be strong antagonists. Conformational studies based on two-dimensional nmr experiments in methanol/water (80/20 v/v) were carried out on several such active antagonists in a polar solvent. Included in this study were the very active antagonists, [D -Arg⁰, Hyp³, Thi⁵, D -Cpg⁷, Cpg⁸]-BK [Cpg: α-cyclo-pentyl-glycine; Hyp: trans-4-hydroxy-L -proline; Thi: β-(2-thienyl)-L -alanine] ( I ), [D -Arg⁰, Hyp³, D -Cpg⁷, Cpg⁸] -BK ( II ), as well as its variant with D -Cpg⁷ replaced by Cpg⁷, namely [D -Arg⁰, Hyp³, Cpg⁷, Cpg⁸]-BK ( III ). A turn-like structure, which coexists with the extended conformation, was observed between residues 2 and 5 for the most active antagonists I and II , in direct correlation with the peptide activities. No turn-like structure was found for residues 6–9. In peptide III , a turn-like structure was not identified. The existence of a turn at the C-terminal end of bradykinin and its analogues has been predicted by empirical calculations and supported by nmr measurements. But the present nmr study on the most active antagonists ( I , II ) does not support this hypothesis. Instead, the data suggest that a turn-like structure between residues 2 and 5 could be important for antagonist activity. Finally, one weak inhibitor [D -Cpg⁷]-BK ( IV ) showed no defined secondary structure. © 1993 John Wiley & Sons, Inc.     

Prediction of the native conformation of a polypeptide by a statistical-mechanical procedure. III. Probable and average conformations of enkephalin

The program SMAPPS (Statistical-Mechanical Algorithm for Predicting Protein Structure) was originally designed to determine the probable and average backbone (?, ψ) conformations of a polypeptide by the application of equilibrium statistical mechanics in conjunction with an adaptive importance sampling Monte Carlo procedure. In the present paper, the algorithm has been extended to include the variation of all side-chain (χ) and peptide-bond (ω) dihedral angles of a polypeptide during the Monte Carlo search of the conformational space. To test the effectiveness of the generalized algorithm, SMAPPS was used to calculate the probable and average conformations of Met-enkephalin for which all dihedral angles of the pentapeptide were allowed to vary. The total conformational energy for each randomly generated structure of Met-enkephalin was obtained by summing over the interaction energies of all pairs of nonbonded atoms of the whole molecule. The interaction energies were computed by the program ECEPP /2 (Empirical Conformational Energy Program for Peptides). Solvent effects were not included in the computation. The results of the Monte Carlo calculation of the structure of Met-enkephalin indicate that the thermodynamically preferred conformation of the pentapeptide contains a γ-turn involving the three residues Gly²-Gly³-Phe⁴. The γ-turn conformation, however, does not correspond to the structure of lowest conformational energy. Rather, the global minimum-energy conformation, recently determined by a new optimization technique developed in this laboratory, contains a type II′ β-bend that is formed by the interaction of the four residues Gly²-Gly³-Phe⁴-Met⁵. A similar minimum-energy conformation is found by the SMAPPS procedure. The thermodynamically preferred γ-turn structure has a conformational energy of 4.93 kcal/mole higher than the β-bend structure of lowest energy but, because of the inclusion of entropy in the SMAPPS procedure, it is estimated to be ～ 9 kcal/mole lower in free energy. The calculation of the average conformation of Met-enkephalin was repeated until a total of ten independent average conformations were established. As far as the phenylalanine residue of the pentapeptide is concerned, the results of the ten independent average conformations were all found to lie in the region of conformational space corresponding to the γ-turn. These results further support the conclusion that the γturn conformation is thermodynamically favored.     

Entropic elastic processes in protein mechanisms. II. Simple (passive) and coupled (active) development of elastic forces

The first part of this review on entropic elastic processes in protein mechanisms (Urry, 1988) demonstrated with the polypentapeptide of elastin (Val¹-Pro²-Gly³-Val⁴-Gly⁵)_n that elastic structure develops as the result of an inverse temperature transition and that entropic elasticity is due to internal chain dynamics in a regular nonrandom structure. This demonstration is contrary to the pervasive perspective of entropic protein elasticity of the past three decades wherein a network of random chains has been considered the necessary structural consequence of the occurrence of dominantly entropic elastomeric force. That this is not the case provides a new opportunity for understanding the occurrence and role of entropic elastic processes in protein mechanisms. Entropic elastic processes are considered in two classes: passive and active. The development of elastomeric force on deformation is class I (passive) and the development of elastomeric force as the result of a chemical process shifting the temperature of a transition is class II (active). Examples of class I are elastin, the elastic filament of muscle, elastic force changes in enzyme catalysis resulting from binding processes and resulting in the straining of a scissile bond, and in the turning on and off of channels due to changes in transmembrane potential. Demonstration of the consequences of elastomeric force developing as the result of an inverse temperature transition are seen in elastin, where elastic recoil is lost on oxidation, i.e., on decreasing the hydrophobicity of the chain and shifting the temperature for the development of elastomeric force to temperatures greater than physiological. This is relevant in general to loss of elasticity on aging and more specifically to the development of pulmonary emphysema. Since random chain networks are not the products of inverse temperature transitions and the temperature at which an inverse temperature transition occurs depends on the hydrophobicity of the polypeptide chain, it now becomes possible to consider chemical processes for turning elastomeric force on and off by reversibly changing the hydrophobicity of the polypeptide chain. This is herein called mechanochemical coupling of the first kind; this is the chemical modulation of the temperature for the transition from a less-ordered less elastic state to a more-ordered more elastic state. In the usual considerations to date, development of elastomeric force is the result of a standard transition from a more-ordered less elastic state to a less-ordered more elastic state. When this is chemically modulated, it is herein called mechanochemical coupling of the second kind. For elastin and the polypentapeptide of elastin, since entropic elastomeric force results on formation of a regular nonrandom structure and thermal randomization of chains results in loss of elastic modulus to levels of limited use in protein mechanisms, consideration of regular spiral-like structures rather than ramdom chain networks or random coils are proposed for mechanochemical coupling of the second kind. Chemical processes to effect mechanochemical coupling in biological systems are most obviously phosphorylation-dephosphorylation and changes in calcium ion activity but also changes in pH. These issues are considered in the events attending parturition in muscle contraction and in cell motility.     

Unexpected aspartimide formation during coupling reactions using Asp(OAl) in solid-phase peptide synthesis

Summary Succinimide ring closure is a well-documented side reaction in the synthesis of certain Asp-containing peptides. This side reaction is typically acid-or base-catalyzed, and its occurrence during coupling reactions has not been previously noted. This unforeseen manifestation of aspartimide formation was detected while exploring a new strategy for side-chain to side-chain lactam formation on a solid support to synthesizecyclo[D-Asp², Dap⁵]dynorphin A-(1-11) amide. The availability of allyl protecting groups, which provide an additional level of orthogonality in solid-phase peptide synthesis, was very appealing for use in preparing this conformationally constrained analogue. We found that the allyl ester (OAl) was not sufficient protection from this side reaction in this susceptible D-Asp²-Gly³ sequence. Remarkably, the aspartimide formation appeared to occur during the coupling reaction in the absence of base if excess coupling reagent was present.     

Unusual conformational preferences of β-alanine containing cyclic peptides. VII

In the present paper we describe the synthesis, purification, and single crystal x-ray analysis of the cyclic pentapeptide cyclo-(Pro-Phe-Phe-β-Ala-β-Ala). This compound crystallizes in the orthorhombic space group P2₁2₁2₁ from methanol and adopts in the solid state an unusual conformation characterized by a cis β-Ala⁵-Pro¹ peptide bond and by an intramolecular hydrogen bond stabilizing a C₁₁- and a C₁₂-ring structure. The C₁₁, structure contains the Phe³ and the β-Ala⁴ at the corner position of the turn; it is the first observation of a type II β-turn enlargement due to the insertion of an extra methylene group of the β-alanine residue. The rest of the molecule participates in a newly characterized C₁₂-ring structure, which incorporates a β-Ala residue at position i of the turn. © 1996 John Wiley & Sons, Inc.     

Nmr and computer-aided modeling studies of the interactions between a cyclic hexapeptide and the two enantiomers of some Boc- and Fmoc-amino acids

The cyclic hexapeptide cyclo[-Pro¹-Gly²-Glu³(OBzl) -Pro⁴-Phes⁵-Leu⁶-] ( 1 ) was modeled and synthesized to be used for chiral discrimination studies. Total correlated spectroscopy and nuclear Overhauser effect spectroscopy spectra of the cyclic hexapeptide 1 in CDCl₃ showed the presence of three stereoisomers: two dominant stereoisomers 1a and 1b that exchanged chemically with each other, and a minor stereoisomer 1c (4%) that exchanged exclusively with the stereoisomer 1b . Of the two dominant stereoisomers, only 1a interacted specifically with t-butyloxycarbonyl (Boc-) and 9-flourenylmethyloxycarbonyl (Fmoc-) amino acids in CDCl₃. The interaction site of la when complexing with the derivatized amino acids was the chain segment Phe⁵-Leu⁶. The Phe⁵ NH and Leu⁶ NH protons are contiguous and solvent exposed. Their nmr signals shifted strongly downfield with the addition of Boc- or Fmoc- amino acids to the peptide solution. Thus, both NH protons hydrogen bond to the amino acids, forming a two-point hydrogen-bonding complex. The peptide stereoisomer 1b did not interact specifically with the Boc- and Fmoc-amino acids because of the lack of two contiguous and solvent-exposed peptidic NH protons that seem to be needed for specific interactions of the cyclic hexapeptide 1 with the Boc- and Fmoc-amino acids. A clear difference in the interaction of 1a with D - and L -enantiomers of BocTrp and Fmoc-Trp was observed with nmr spectroscopy. Docking models and molecular mechanics calculations together with nmr observations showed that the NH proton of the indole ring of the Boc-L -Trp and the Fmoc-L- Trp hydrogen bonded to the Pro¹ carbonyl group. In this three-point hydrogen-bonding complex, the indole ring becomes locked underneath the Leu residue. The nmr signals of all the Leu⁶ protons (except for Leu NH) shifted strongly upfield owing to the shielding effect of the indole aromatic ring currents. The indole NH of the D -enantiomer did not hydrogen bond to the Pro¹ carbonyl group because the formation of such a three-point hydrogen-bonding complex was thermodynamically unfavorable. © 1993 John Wiley & Sons, Inc.     

A CD and an nmr study of multiple bradykinin conformations in aqueous trifluoroethanol solutions

CD and nmr studies have been carried out on aqueous trifluoroethanol (TFE) solutions of bradykinin (BK) and a bradykinin antagonist. The CD results exhibit a striking effect of TFE on the spectra of BK, with sequence Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg, and the BK antagonist, with sequence D -Arg-Arg-Pro-Hyp-Gly-Thi-D -Ser-D -Cpg-Cpg-Arg [where Hyp is 4-hydroxy-L -proline; Thi refers to β-(2-thienyl)-L -alanine and Cpg refers to α-cyclopentylglycine]. The effect of increasing concentration of TFE in water on the difference ellipticity at 222 nm was examined and showed that BK may be a mixture of at least two different conformers, one of which largely forms when the TFE concentration is increased beyond 80%. The linear extrapolation of 100% of the difference ellipticity of BK at low TFE concentrations yields a value in agreement with that shown by the BK antagonist, indicating that the conformation of BK at the lower TFE concentrations is similar to that of the BK antagonist. The conformational analysis was carried out using both one-dimensional and two-dimensional ¹H-nmr techniques. The total correlation spectroscopy (TOCSY) spectrum of BK in a 60/40% (v/v) TFE/H₂O solution at 10°C and a nuclear Overhauser effect spectroscopy (NOESY) spectrum that shows only sequential H_α(i) – NH(i + 1) or the H_α(i) – H_δδ′(i + 1) NOEs indicate that the majority of the molecules adopt an all-trans extended conformation. The TOCSY for BK in the 95/5% (v/v) TFE/H₂O solution shows that there are two major conformations in the solution with about equal population. The NOESY experiment shows two new important cross peaks for one conformation, namely Pro²(α)-Pro³ (α) and the Pro²(α)-Gly⁴(NH), indicating a cis Pro²-Pro³ bond and a type VI β-turn between residues Arg¹ and Gly⁴ involving cis proline at position 3, respectively. The low temperature coefficient of Gly⁴ for this conformation suggests the presence of an intramolecular hydrogen bond, therefore a type VIa β-turn is present. The other conformation is all trans and extended. The BK antafonist shows difference CD spectra in TFE solutions referred to H₂O that are superficially indicative of a β-bend. However, nmr speaks against this possibility, as only one set of peaks were observed in the TOCSY and NOESY experiments, indicating an all-trans extended confirmation over the range of TFE concentrations. The BK-antagonist CD data suggest that solvent perturbation of the CD of an extended confirmation perturbation of the optical activity of the thienyl moiety of the peptide since the CD spectrum of N-acetyl-β-thienyl-L -alanine N-methylamide is strongly perturbed by TFE. The present results again demonstrate the complementary relationship between CD and nmr. © 1994 John Wiley & Sons, Inc.     

Formation of several stable complexes between the minor components of the cyclic tetrapeptide cyclo-(-Pro1-Ala2-D-Phe3-Leu4-) and some specific Boc-amino acids

The cyclic tetrapeptide cyclo(-Pro¹-Ala²-D -Phe³-Leu⁴-) was modeled and synthesized to be used for molecular interactions and chiral discrimination studies in CDCl₃. Total correlation spectroscopy and nuclear Overhauser effect spectroscopy spectra of the cyclic tetrapeptide showed the presence of one dominant stereoisomer— 1 —and three minor ones— 2a , 2b , and 2c —in a relationship of 92:6:1:1. They formed three- to five-hydrogen bond complexes with Boc-D -Ser, Boc-L -Ser and Boc-L -Thr (Boc: t-butyloxylcarbonyl). These three Boc-amino acids interact more strongly with 2a , 2b , and 2c than with 1 , altering their relative concentrations to 48:40:6:6. In the complex between the cyclic tetrapeptide and Boc-D -Ser, the stereoisomer 2a exchanged chemically with 1 , 2b , and 2c , while 1 did not exchange with either 2b or 2c . This chemical exchange is due to cis-trans isomerization of the peptide bonds. The chiral discrimination of 2a , 2b , and 2c was stronger than that of 1 . No complexation occurred with Boc-L -Ala or Boc-L -Trp. © 1993 John Wiley & Sons, Inc.     

Effect of naloxone and D-Met2-Pro5-enkephalinamide treatment on the DNA synthesis in the developing rat brain

Effects of a single dose of naloxone and of D-Met²-Pro⁵-enkephalinamide on the DNA synthesis in the forebrain, hypothalamus and cerebellum of 11 day old female rats were studied. As an index of DNA synthesis the rate of incorporation of ³H-thymidine into DNA was measured 30 min after a sc. injection of 40 μCi/100 g b.w.. A time dependent effect of naloxone administration on cerebral DNA synthesis was observed. In the forebrain at 1 and 3 hrs after naloxone injection an increased rate of ³H-thy-midine incorporation into DNA was found followed by a marked decrease at 9 and 12 hrs. The effect in the hypothalamus was similar but the initial increase at 1 hr was absent. On cerebellar DNA synthesis naloxone had no effect. The administration of D-Met²-Pro⁵-enkephalinamide resulted in a marked reduction in the labelling of cerebral and hypothalamic DNA between 1 to 12 hrs. Except a decrease at 1 hr no effect was found in the cerebellum.