Synthesis of sequential oligopeptides and polypeptide having the sequence of L-alanyl-L-leucylglycine

A series of sequential oligopeptides having simple nonpolar side chains, Nps-(L -Ala-L -Leu-Gly)_n- OEt has been prepared by a stepwise fragment-condensation method using Nps-L -alanyl-L -leucylglycine N-hydroxysuccinimide ester, which was prepared by the Nps-N-carboxy α-amino-acid-anhydride method. The success of the synthesis of the peptide having a high-molecular weight, such as octadecapeptide, results from the highest solubility of the tripeptide unit, L -alanyl-L -leucylglycine. The sequential polypeptide having the same tripeptide sequence was also prepared by polycondensation of the tripeptide N-hydroxy-succinimide ester.     

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.     

Synthesis and conformational study of sequential polypeptides, (L-ala-L-val-gly)n and (L-val-L-ala-gly)n.

As an approach for elucidating the role of sequences of amino acids in protein structures, model polypeptides having the same composition but different sequences of amino acids, (L -Ala-L -Val-Gly)_n and (L -Val-L -Ala-Gly)_n, have been prepared by the method involving facile monomer synthesis using N-carboxy α-amino acid anhydrides and N-hydroxysuccinimide esters. The yields and the molecular weights of the polypeptides formed by polycondensation do not depend on the monomer concentrations, but on the sequences of the amino acids in the monomers. Infrared spectra in the solid state showed that (L -Ala-L -Val-Gly)_n can take the α-helical conformation but (L -Val-L -Ala-Gly)_n cannot. The results suggest that the conformations of polypeptides are influenced by the sequences of the amino acids in the polypeptides.     

Nearest-neighbor and next-nearest-neighbor effects in the proton NMR spectra of the oligoribonucleotides ApXpG,CpXpG, CpApXpUpG,ApGpXpC, and ApGpXpCpU

The proton nmr spectra of the oligoribonucleotides in the series CpXpG, ApXpG, CpApXpUpG, and ApGpXpC (X = A, G, C, and U), together with the reference compounds CpG, ApG, CpApUpG, and ApGpC, have been measured. A complete analysis of all the nonexchangeable base protons and the ribose H-1′ protons was made. The insertion of a nucleotide X into a oligoribonucleotide led to shift changes at both nearest-neighbor and next-nearest-neighbor positions, which were rationalized in terms of the shielding abilities of the various bases. The derived shielding trends in the ApGpXpC series of compounds were successfully used to predict the chemical shifts of resonances in the related ApGpXpCpU series.     

The X-Pro peptide bond as an nmr probe for conformational studies of flexible linear peptides

The equilibrium between the cis and trans forms of X-Pro peptide bonds can readily be measured in the ¹³C nmr spectra. In the present paper we investigate how observation of this equilibrium could be used as an nmr probe for conformational studies of flexible polypeptide chains. The experiments include studies by ¹³C nmr of a series of linear oligopeptides containing different X-L -Pro peptide bonds, with X = Gly, L -Ala, L -Leu, L -Phe, D -Ala, D -Leu, and D -Phe. Overall the study confirms that X-Pro peptide bonds can generally be useful as ¹³C nmr probes reporting the formation of nonrandom conformation in flexible polypeptide chains. It was found that the cis–trans equilibrium of X-Pro is greatly affected by the side chain of X and the configuration of the α-carbon atom of X. On the basis of these observations some general rules are suggested for a practical applications of the X-Pro nmr probes in conformational studies of polypeptide chains.     

Far-infrared spectra of sequential copolymers of amino acids with alkyl group side chains

Far-infrared spectra were measured for the sequential copolymers of amino acids with alkyl group side chains. The analysis of the spectra showed that (L -Ala-L -Ala-Gly)_n, (L -Ala-Gly)_n, (L -Ala-Gly-Gly)_n, (L -Val-L -Ala-L -Ala)_n, and (L -Val-L -Ala)_n, have the antiparallel pleated sheet structures and that the backbone conformations of (L -Val-L -Val-L -Ala)_n and (L -Val-L -Val-Gly)_n are the same as that of poly-L -valine. The far-infrared bands characteristic of the antiparallel pleated sheet structure were assigned on the basis of the result of the normal coordinate analysis of poly-L -alanine with this structure. The intersheet and interchain spacings of the sequential copolymers with the antiparallel pleated sheet structure were determined from the x-ray powder-diffraction patterns of these samples.     

Comparative analysis of the sequences of the three collagen chains α1(I), α2 and α1(III): Functional and genetic aspects

The amino acid sequences of type I collagen containing α1(I) and α2 chains at a ratio of 2:1, and of type III collagen consisting of α1 (III) chains are known. A statistical analysis of the sequences of these α chains is presented. The inter-chain comparison showed a high level of homology between the three α chains. The interactive amino acids, such as the polar charged and part of the hydrophobic residues responsible for the assembly of the molecules, are strongly conserved. The intra-chain analysis revealed that the α chains are divided into four related D units, each with a length of 234 residues. Between the D units within a chain the polar residues show a higher variability than the hydrophobic amino acids.Besides the D units, other periodicities such as $\text{D}\text{3}$ (78 residues), $\text{D}\text{6}$ (39 residues), $\text{solD}\text{11}$ (21 residues) and $\text{solD}\text{13}$ (18 residues) were observed, particularly in α1 (I) and α1 (III). The D unit is a functional repeat that is formed by the interactive polar charged and hydrophobic residues and which determines the aggregation of the molecules. The $\text{solD}\text{3}$ unit is mainly pronounced by the non-interactive residues such as proline and alanine and appears to be a reminiscence of a primordial gene. The smaller periodic repeating units may be considered as additional genetic units or as structural units, which determine the triplehelical pitch and thus the lateral aggregation of the molecules.In contrast to α1 (I) and α1 (III), the α2 chain shows less regularity in its internal structure.     

Nearest-neighbor and next-nearest-neighbor effects in the proton NMR spectra of the oligoribonucleotides ApGpX and CpApX

The variable-temperature proton nmr spectra of the oligoribonucleotides in the series CpApX and the series ApGpX, X = A, G, C, U, together with the parent dimers CpA and ApG have been measured. A complete analysis of all the nonexchangeable base proton resonances and ribose H-1′ proton resonances was made. The presence of trends in the shielding abilities of the various bases at both the nearest-neighbor and next-nearest-neighbor positions were identified. The observed shieldings could be used to predict the chemical shifts of protons in related systems. Based on the empirical results from ribodinucleoside monophosphates, the temperature-dependent behavior of the J_1′2′ coupling constants of the triribonucleotides suggested that the compounds in the CpApX series stacked from the 5′-end to the 3′-end, while those in the ApGpX series stacked from the 3′-end to the 5′-end.     

Proton magnetic resonance studies on conformation and association of oligo-γ-benzyl-L-glutamates in solution

The proton magnetic resonance spectra of o-nitrophenylthio-tetra- and hexa-γ-benzyl-L -glutamate ethylamides have been measured at different concentrations in CDCl₃ and CD₂₂C1. The NH and α-CH resonances of the tetrapeptide show downfield shifts with increasing concentration, accompanying disappearance of their fine structure and line broadening. The apparent feature of chemical shifts against concentration is sigmoidal, and it can be interpreted by assuming the presence of a step or more of association–dissociation equilibria of tetrapeptide. With increasing concentration, small aggregates are formed by intermolecular hydrogen bonding, the size of which is not sufficiently large to exhibit critical micelle concentrations. In contrast to the tetrapeptide, the hexapeptide has constant chemical shifts of the NH and α-CH resonances, independent of concentration, which implies that only the unassociated molecules show observable sharp resonances. In the hexapeptide, the phenyl CH and benzyl CH₂ groups of the side chains exhibit new resonances above certain critical concentrations, indicating the restriction of rotational freedom of the side chains in the aggregated states.     

Studies of peptide conformation: Backbone folding of tetrapeptide derivatives in methanol and water

Derivatives of tetrapeptide sequences considered likely to form β-turns were investigated by the study of their proton magnetic resonances in methanol and in water. Differential broadening of N—H resonances by an added nitroxyl was used to indicate the presence of the sequestered N—H proton expected in β-turn conformations. Transfer of magnetic saturation from solvent water protons to N—H protons was also examined. The evidence is consistent with significant contributions by β-turn-like backbones to the conformational averages in methanol of the sequences Gly-L -Pro-D -Val-Gly, D (or L )-Val-L -Pro-Gly-Gly, and Gly-L -Pro-L -Asn-Gly, but not the sequence Gly-D -Ala-L -Val-Gly. It is suggested that a Type I turn, Likely in Gly-L -Pro-L -Asn-Gly derivatives, is characterized by sequestered N—H protons of both the third and fourth residues. For all of the peptide derivatives, save possibly Ac-L -Val-L -Pro-Gly-Gly-NHNH₂, contributions from folded structures in water are not detectable by line-broadening experiments. However, the transfer of saturation experiments may be interpreted as indicating some degree of chain folding in water.     

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.     

Photoresponsive polymers: Azobenzene-containing poly(L-lysine)

Poly(L -lysine) was reacted with various azo-reagents, including p-phenylazobenzoic acid, p-phenylazobenzoyl chloride, and p-phenylazobenzoic N-hydroxy-succinimide ester, to give polypeptides containing 5–44 mol % azobenzene units in the side chains. The conformation of the azo-modified polypeptides was investigated in connection with their photochromic behavior caused by the trans ? cis photoisomerization of the azo groups present in the side chains. In methanol/water solvent mixture, the 20% azo-poly(L -lysine) adopts the α-helix conformation. The helix stability was found to be higher when the azo side chains are in cis than when they are in trans configuration. So irradiation at 340 nm (trans-to-cis isomerization), and alternately at 450 nm (cis-to-trans isomerization), produced reversible variations of the α-helix content. In hexafluoro-2-propanol/water/sodium dodecyl sulfate mixture, the 43% azo-poly(L -lysine) adopts a β-structure, as indicated by CD spectra. Irradiation at 340 nm caused the disruption of the β-structure and promoted the α-helix conformation. The effect was reversed upon irradiation at 450 nm. The photoinduced β ? helix change was explained on the basis of the different geometry and hydrophobic character of the trans and the cis azobenzene units.     

Stereospecific assignments of 1H-nmr methyl lines and conformation of valyl residues in the lac repressor headpiece

Two-dimensional ¹H-nmr methods are described to obtain information on the sidechain conformation of valyl residues of the lac repressor headpiece and to assign the resonances of their methyl groups stereospecifically. The spin–spin coupling constants (J_αβ) between C^αand C^β protons are obtained from two-dimensional correlated spectroscopy experiments. Large values for J_αβ(10–12 Hz) corresponding to trans orientations for these protons (g⁺ conformation) are found for all valyl residues in α-helical segments. For these valyl residues, the distance between one methyl group (γ₁)and the valyl amide proton is much shorter than for the other methyl group, so that stereospecific resonance assignments follow from relative intensities of the corresponding cross peaks in a two-dimensional nuclear Overhauser enhancement spectrum. Thus, streospecific assignments could be made for the methyl groups of Val 9, 20, 23, and 38 (of a total of eight valyl residues).     

Stereoselectivity and structural determinants in molecular recognition by the ACC transport system in isolated maize mesophyll vacuoles

The ethylene precursor, 1-aminocyclopropane-1-carboxylic acid (ACC), is actively transported across the tonoplast of plant cells, impacting cellular compartmentation of ACC and ethylene biosynthesis. In the present study, the effects of ACC and amino acid analogs on ACC uptake into isolated maize (Zea mays L. cv. Golden Cross Bantam) mesophyll vacuoles were investigated to identify the stereospecific and structural features that are important in molecular recognition by the ACC transport system. Of the four stereoisomers of l-amino-2-ethylcyclopropane-l-carboxylic acid (AEC), (1S, 2R)-(–)-AEC having a configuration corresponding to an L-amino acid was the preferred substrate for the ACC transport system, competitively inhibiting ACC transport with a Ki of 18 μM. Of 11 neutral amino acid stereoisomers, L-isomers were stronger inhibitors of ACC transport than corresponding D-isomers. Neutral L-amino acids with nonpolar side chains generally were more inhibitory than those with polar side chains, whereas several cationic and anionic L-amino acids were ineffective antagonists of ACC transport. These observations suggest that the ACC transport system is stereospecific for relatively nonpolar, neutral L-amino acids. This conclusion was supported by the observation that group additions, substitutions, or deletions at the carboxyl. α-amino and the Pro- (R) methylene or hydrogen moieties (analogous to D-amino acids) of ACC and other neutral amino acids and analogs essentially eliminated transport inhibition. In contrast, L-amino acid analogs with variable substitutions at the distal end of the molecule remained antagonists. The relative activity of analogs was influenced by the length and degree of unsaturation of the side chain and by the location of side chain branching. Increasing the ring size of ACC analogs reduced antagonism whereas incorporating the α-amino group into the ring structure as an L-amino acid increased antagonism. The kinetics of L-methoxyvinylglycine, L-methionine. p-nitro-L-phenylalanine and 1-aminocyclobutane-l-carboxylic acid were competitive with Ki values of 3, 13, 16 and 19 μM, respectively. These results indicate that the ACC transport system can be classifie as a neutral L-amino acid carrier having a relatively high affinity for ACC and other nonpolar amino acids. The results also suggest that the carrier interacts with the carboxyl, α-amino and Pro-(R) groups and with other less restricted side chain substituents of substrate amino acids.     

Specificity of a milk clotting enzyme extracted from the thistleCynara cardunculus L.: Action on oxidised insulin and k-casein

Summary K-casein and oxidised insulin were digested with an acid protease extracted fromCynara cardunculus L. The fragments produced were isolated and characterised. In k-casein cleavage occured specifically at Phe 105-Met 106 bond. In oxidised insulin seven fragments were obtained and cleavage was found to occur at the carboxylic side of (Phe, Leu, He)-X, where X was preferentially Val or Tyr. The results obtained with insulin B chain suggest thatCynara cardunculus L. protease possesses a greater specificity than other acid proteases reported.     

Calculations of the Conformations of Iturin A in Relation with NMR Studies

Abstract

Iturin A is an antifungal antibiotic which was isolated from a strain of Bacillus subtilis, and contains a lipophilic β amino acid closing an heptapeptide cycle with polar L and D residues. Iturin A belongs to a lipopeptide family of which the LDDLLDL sequence is kept constant.

NMR spectroscopy and semi-empirical energy calculations are combined to design the conformations of Iturin A in pyridine solution. J coupling constants and nOes (nuclear Overhauser enhancements) are used as guiding line for energy calculations. This preliminary study shows that Iturin A in pyridine appears as rather rigid, especially in the L Pro 5—D Asn 6 region, probably involved in a β turn. The polar side chains can form different networks of intramolecular hydrogen bonds. The Tyr side chain, relatively mobile, could be involved in interactions with an hydrophobic environment as the β amino acid side chain found away from the peptide cycle.     

Experimental investigations on the backbone folding of proline-containing model tripeptides

Some proline-containing tripeptides with the general formulas R⁰CO-L -Pro-X-NHR³ (X = Gly,Sar,L -Ala,D -Ala) and R⁰CO-X-L -Pro-NHR³ (X = Gly,L -Ala,D -Ala) have been investigated in solution by ir and ¹H-nmr spectroscopies. Their favored conformational states depend mainly on both the primary structure and the chiral sequence of the molecules. In inert solvents the βII-folding mode is the most favored conformation for the L -Pro-D -Ala and L -Pro-Gly tripeptides, while the βII′-turn is largely preferred by D -Ala-L -Pro derivatives. Under the same conditions only about one-third of the whole conformers of L -Pro-L -Ala molecules adopts the βI-folding mode. Semiopened C₇C₅ and C₅C₇ conformations are appreciably populated in the L -Pro-L -Ala sequence, on the one hand, and in the Gly-L -Pro and L -Ala-L -Pro derivatives, on the other hand. In L -Pro-Sar and X-L -Pro models, the cis–trans isomerism around the middle tertiary amide function is observed. Thus cis L -Pro-Sar and L -Ala-L -Pro conformers are folded by an intramolecular i + 3 → i hydrogen bond, whereas cis D -Ala-L -Pro and Gly-L -Pro molecules accommodate an open conformation. In dimethylsulfoxide the βII- and βII′-folding modes are not essentially destabilized, as contrasted with the βI conformation, which is less populated. In water solution all the above-mentioned conformations, with the possible exception of the βII′-folding mode for D -Ala-L -Pro molecules, seem to vanish. Solute conformations are also compared with the crystal structures of four proline-containing tripeptides.     

The effects of isolated N-methylated residues on the conformational characteristics of polypeptides

Conformational energies have been estimated for the tripeptide fragments L -Ala-N-methyl-L -Ala-L -Ala, L -Ala-L -Ala-N-methyl-L -Ala, L -Ala-Sar-L -Ala, and L -Ala-Gly-N-methyl-L -Ala. The peptide bonds connecting L -Ala and Gly with N-methyl-L -Ala and L -Ala with Sar were permitted to adopt the planar cis as well as the usual trans conformation. Contour maps of the conformational energies of the central residue in these tripeptide fragments are presented and compared to the conformational energy maps previously calculated for unmethylated L -Ala and Gly surrounded by residues which are also unmethylated. In generl it is observed that L -Ala and Gly residues that are either N-methylated in their conformational freedom relative to the same residues in an unmethylated polypeptide chain.     

Strategy for trapping intermediates in the folding of ribonuclease and for using 1H-nmr to determine their structures

The major unfolded form of ribonuclease A is known to show well-populated structural intermediates transiently during folding at 0°–10°C. We describe here how the exchange reaction between D₂O and peptide NH protons can be used to trap folding intermediates. The protons protected from exchange during folding can be characterized by ¹H-nmr after folding is complete. The feasibility of using ¹H-nmr to resolve a set of protected peptide protons is demonstrated by using a specially prepared sample of ribonuclease S in D₂O in which only the peptide protons of residues 7–14 are in the ¹H-form. All eight of these protected peptide protons are H-bonded. Resonance assignments made on isolated peptides containing these residues have been used to identify the protected protons. Other sets of protected protons trapped in the ¹H-form can also be isolated by differential exchange, using either ribonuclease A or S. Earlier model compound studies have indicated that H-bonded folding intermediates should be unstable in water unless stabilized by additional interactions. Nevertheless, peptides derived from ribonuclease A that contain residues 3–13 do show partial helix formation in water at low temperatures. We discuss the possibility that specific interactions between side chains can stabilize short α-helixes by nucleating the helix, and that specific interactions may also define the helix boundaries at early stages in folding.     

The analysis of merino wool cuticle and cortical cells by Fourier transform Raman spectroscopy

Wool fibers are comprised of proteins known as α-keratins and have a complex morphological structure. The major components of this structure, the cuticle and cortical cells, differ in the conformations of their peptide chains as well as their amino acid compositions. High quality Fourier transform Raman spectra of cortical and cuticle cells isolated from fine Merino wool fibers have been obtained. Raman spectroscopy has been shown to be sensitive to the differences in both secondary structure and amino acid composition. The cortical cells were found to be higher in α-helical content as compared to the cuticle cells, which had an increased disordered content. Specific information, consistent with amino acid analysis results, regarding cystine, tyrosine, tryptophan, and phenylalanine residues, were obtained for both the cortical and cuticle cells. In addition, the Raman spectra provided information about free thiol groups, amino acids residues with amide group side chains, and residues with protonated carboxyl group side chains. Middle ir transmission spectra of these isolated cells were also obtained. In comparison to the Raman data, the middle ir spectra were found to be not as rich in information. © 1997 John Wiley & Sons, Inc. Biopoly 42: 7–17, 1997