Short fragments of a protein globule with predominant conformation

It has been found that 1500 tetrapeptides out of 160000 possible combinations occurring in proteins exhibit preference for particular conformational states. Most conformationally stable tetrapeptides obtained in the analysis of a sampling containing 706 proteins are in the alpha-helical form. The features of the amino acid composition of conformationally stable oligopeptides have been studied.     

Conformational analysis of tachykinins. III. C-terminal fragment Asx-Xaa-Phe-Yaa-Gly-Leu-Met-NH2]

Theoretical conformational analysis of C-terminal fragments of tachykinin peptides with a common amino acid sequence Asx-Xaa-Phe-Yaa-Gly-Leu-Met-NH2 suggested the conformational states to be independent of the nature of Xaa and Yaa residues. It is shown that among plausible spatial forms of the C-terminal fragments an alpha-helix with the hydrophobic coat consisted of identically oriented side chains is energetically the most stable structure. The preference of this conformation for tachykinins functioning is discussed.     

Calculation of protein conformation by the build-up procedure. Application to bovine pancreatic trypsin inhibitor using limited simulated nuclear magnetic resonance data

Low-energy conformations of a set of tetrapeptides derived from the small protein bovine pancreatic trypsin inhibitor (BPTI) were generated by a build-up procedure from the low-energy conformations of single amino acid residues. At each stage, various-size fragments were built up from all combinations of smaller ones, the total energies were then minimized, and the low-energy conformations were retained for the next stage. The energies of the tetrapeptides were re-ordered by including the effects of hydration. No information other than the amino acid sequence was used to obtain the low-energy conformations of the hydrated tetrapeptides. The latter were then supplemented with a limited set of simulated NMR distance information, derived from the X-ray structure of BPTI, to provide a basis for building the rest of the whole protein molecule by the same procedure. A total of 189 upper bounds, plus 12 pairs of upper and lower bounds pertaining to the location of the three disulfide bonds in this molecule, were used. Four sets of conformations of the entire molecule were generated by utilizing different combinations of smaller fragments. It was possible to obtain low-energy conformations with small rms deviations, 1.1 to 1.4 A for the alpha-carbons, from the structure derived by X-ray diffraction. The average deviations of the backbone dihedral angles were also low, viz. 23 degrees to 26 degrees.     

Spatial structure of the rp142 peptide containing the immunodominant epitope of the HIV-1 gp120 protein. A theoretical study]

A model of spatial structure of the synthetic peptide rp142 (24 amino acid residues) containing the immunodominant epitope of the HIV-1 protein gp120 in the region Gly-10-Phe-15 was constructed by the method of "constrained" molecular mechanics, which uses the algorithms of theoretical conformational analysis, based on NMR spectroscopy data. A comparative analysis of calculated conformations revealed that the spatial structure of rp142 in solution can be described by a family of conformations to which nine different structural clusters involving the sets of topologically close conformers correspond. It is shown that the main chain of the peptide forms irregular but "structured" conformations in which the main portion of amino acid residues is incorporated into beta-turns and helix-like fragments, while Pro-11 and Gly-12 form in some structures inverse gamma-turns, which rarely occur in protein-peptide molecules. It was found that the spatial packing of the Gly-10-Phe-15 hexapeptide in different clusters is realized at different internal rotation angles, to which topologically close structures correspond. It is assumed that this invariant structural element describes the "conformation of complex formation" that is complementary to the antigen-binding center of antibodies and is responsible for their binding to the peptide.     

Correlation between biological activity and conformational dynamics properties of tetra- and pentapeptides derived from fetoplacental proteins

In this work, using molecular dynamics simulation, we study conformational and dynamic properties of biologically active penta- and tetrapeptides derived from fetoplacental proteins such as alpha-fetoprotein, pregnancy specific β1-glycoprotein, and carcinoembryonic antigen. Existence of correlation between flexibility of peptide backbone and biological activity of the investigated peptides was shown. It was also demonstrated that flexibility of peptide backbone depends not only on its length, but also on the presence of reactive functional groups in amino acid side chains that participate in intramolecular interactions. Peptides that demonstrate similar biological effects in regulation of proliferation of lymphocytes and expression of differentiation antigens on their surface (LDSYQCT, PYECE, YECE, and YVCE) are characterized by rigidity of their peptide backbone. Increased backbone flexibility in peptides PYQCE, YQCE, SYKCE, YQCT, YQCS, YVCS, YACS, and YACE is correlated with decreased biological activity. Conformational mobility of amino acid residues does not depend on physicochemical properties only, but also on intramolecular interactions. So, evolutionary restrictions should exist to maintain such interactions in the environment of functionally important sites.     

Carbon-13 NMR chemical shifts of the common amino acid residues measured in aqueous solutions of the linear tetrapeptides H-Gly-Gly- X-L- Ala-OH

The ¹³C nmr chemical shifts of the common amino acid residues were measured in D₂O solutions of the linear tetrapeptides H-Gly-Gly-X-L -Ala-OH. For Asp, Glu, Lys, Tyr and His, the titration shifts arising from the ionization of te amino acid side chains were also obtained. These data are compared with the corresponding ¹³C chemical shifts in the protected tetrapeptides CF₃CO-Gly-Gly-X-L -Ala-OCH₃, the linear pentapeptides H-Gly-Gly-X-Gly-Gly-OH, and the free amino acids. On this basism the selection of suitable “random coil” ¹³C chemical shifts for conformational studies of polypeptides chain is discussed.     

Configurationally driven folding of model tetrapeptides containing L- or D-morpholine-3-carboxylic acids as beta-turn nucleators

The conformational analysis by NMR, IR, and molecular modeling of tetrapeptides containing morpholine-3-carboxylic acid (Mor) as a proline surrogate is presented. The relationship between the chirality of the cyclic amino acid at position i+1 and the turn propensity is maintained with respect to the reference proline-containing peptides, although marked differences in the type of folded structures were observed. The conformational profile of morpholine-containing turn peptides as a function of the chirality of the cyclic amino acid indicated that the heterochiral tetrapeptide containing the D-isomer of the cyclic amino acid is more prone to nucleate compact folded structures, although with no resemblance to the beta-turn structures of D-proline-containing peptides. Also, the solvation system proved to influence the organization of folded structures, as in the more interactive CD(3)CN the model peptides showed more compact conformations. The L-Mor-containing peptide displayed two rotamers at the Val-Mor amide bond. The trans isomer did not experience any turn structures, nor any intramolecular hydrogen-bonds, whereas the cis isomer showed a strong preference for a type VI beta-turn structure, thus providing a different conformational asset with respect to the beta-turn structure as reported for the reference L-proline model peptide.     

Mechanism of action of aspartic proteases. IV.Conformational characteristics of a substrate and an inhibitor of rhizopuspepsin ]

On the basis of theoretical conformational analysis of separate peptide fragments, the conformational characteristics of two substrates and a substrate-like inhibitor of aspartic protease rhizopuspepsin were studied. It was shown that the spatial structure of these molecules is described by several families of conformations, the transition between which does not require the overcoming of high energy barriers. It was assumed that the stabilization of beta-structural conformations experimentally observed in inhibitor complexes is due to the greater predisposition of extended structures to the formation of effective intermolecular contacts with amino acid residues of the active site of the enzyme.     

MgATP binding to the nucleotide-binding domains of the eukaryotic cytoplasmic chaperonin induces conformational changes in the putative substrate-binding domains.

The eukaryotic cytosolic chaperonins are large heterooligomeric complexes with a cylindrical shape, resembling that of the homooligomeric bacterial counterpart, GroEL. In analogy to GroEL, changes in shape of the cytosolic chaperonin have been detected in the presence of MgATP using electron microscopy but, in contrast to the nucleotide-induced conformational changes in GroEL, no details are available about the specific nature of these changes. The present study identifies the structural regions of the cytosolic chaperonin that undergo conformational changes when MgATP binds to the nucleotide binding domains. It is shown that limited proteolysis with trypsin in the absence of MgATP cleaves each of the eight subunits approximately in half, generating two fragments of approximately 30 kDa. Using mass spectrometry (MS) and N-terminal sequence analysis, the cleavage is found to occur in a narrow span of the amino acid sequence, corresponding to the peptide binding regions of GroEL and to the helical protrusion, recently identified in the structure of the substrate binding domain of the archeal group II chaperonin. This proteolytic cleavage is prevented by MgATP but not by ATP in the absence of magnesium, ATP analogs (MgATPyS and MgAMP-PNP) or MgADP. These results suggest that, in analogy to GroEL, binding of MgATP to the nucleotide binding domains of the cytosolic chaperonin induces long range conformational changes in the polypeptide binding domains. It is postulated that despite their different subunit composition and substrate specificity, group I and group II chaperonins may share similar, functionally-important, conformational changes. Additional conformational changes are likely to involve a flexible helix-loop-helix motif, which is characteristic for all group II chaperonins.     

Influence of intramolecular interactions on conformational and dynamic properties of analogs of heptapeptide AFP<Subscript>14–20</Subscript>

Conformational and dynamic properties of proteins and peptides play an important role in their functioning. However, mechanisms that underlie this influence have not been fully elucidated. In the present work we computationally constructed analogs of heptapeptide AFP_14–20 (LDSYQCT) — one of the biologically active sites of human α-fetoprotein (AFP) — to study their conformational and dynamic properties using molecular dynamics simulation. Analogs were obtained by point substitutions of amino acid residues taking into account differences in their physicochemical properties and also on the basis of analysis of amino acid substitutions in the AFP_14–20-like motifs revealed in different physiologically active proteins. It is shown that changes in conformational mobility of amino acid residues of analogs are due to disruption or arising of intramolecular interactions that, in turn, determine existence of steric restrictions during rotation around covalent bonds of the peptide backbone. Substitution of an amino acid by another one with significant difference in physicochemical properties may not lead to remarkable changes in conformational and dynamic properties of the peptide if intramolecular interactions remain unchanged.     

Effect of the degree of modification of trypsin amino groups with polymers on the enzymatic and conformation properties of the protein

Trypsin was modified by introducing fragments containing an azo-bond into its molecule by the reaction of free amino groups of the enzyme with an azide of 2,2'-azobisisobutryic acid. Subsequently free-radical polymerization of N-vinyl pyrrolidone was carried out with the high molecular weight initiator obtained. The degree of modification of amino groups in trypsin was n = 6 divided by 12, which distinguishes this type of modification from that earlier proposed by the authors. In that case dichlorohydrate of dimethylimidate of 2,2'-azobisisobutyric acid was used for introducing azo-bonds into the molecule of the protein, n being equal to 2-3. It is shown that under the conditions of autolytic degradation both high molecular weight initiator based on trypsin and the trypsin-PVP (poly-N-vinyl pyrrolydone) covalent conjugates exhibit higher stability than initial trypsin. The method of circular dichroism was used for comparison of conformational properties of the modified trypsin forms. An increase of the rate of thermal inactivation was found to result from conformational changes occurring on modification of the enzyme.     

Structure-activity relationship study of tetrapeptide inhibitors of the Vascular Endothelial Growth Factor A binding to Neuropilin-1

Neuropilin-1 is considered as one of the key receptors responsible for signaling pathways involved in pathological angiogenesis necessary for tumor progression, therefore targeting of VEGF₁₆₅ binding to NRP-1 could be a relevant strategy for antiangiogenic treatment. It was shown before that the VEGF₁₆₅/NRP-1 interaction can be inhibited by short tetrapeptides with K/RXXR sequence.Here, we present a structure–activity relationship study of the systematic optimization of amino acid residues in positions 1–3 in the above tetrapeptides. All the 13 synthesized analogs possessed C-terminal arginine that is a necessary element for interaction with NRP-1. The obtained results of the inhibitory activity and modeling by molecular dynamics indicate that simultaneous interactions of the basic amino acid residues in position 1 and 4 (Arg) with Neuropilin-1 are crucial and their cooperation strongly affects the inhibitory activity. In addition, the binding strength is modulated by the flexibility of the peptide backbone (in the central part of the peptide), and the nature of the side chain of the amino acids at the second or third position. A dramatic decrease in the activity to the receptor is observed in flexible derivatives that are missing proline residues. The results described in this paper should prove useful for future studies aimed at establishing the best pharmacophore for inhibitors of VEGF₁₆₅ binding to NRP-1.     

Amino acid propensities revisited

Statistical analysis of amino acid patterns in approximately 160,000 alpha-helices in experimentally determined structures revealed di-, tri-, and tetrapeptides, whose frequencies deviate most from the statistical model. Importantly, some sequences were never found in alpha- helices. This fact was detected initially with tripeptides, where nearly 1% of the possible sequences were never seen in the helical segments. For tetrapeptides, this effect is very strong and significant; almost 43% of the possible sequences never appear in alpha-helices. It is possible that there are some steric and energetic restrictions that do not allow these tetrameric amino acid sequences to form alpha-helical structure.     

Packing and recognition of protein structural elements: A new approach applied to the 4-helix bundle of myohemerythrin

We present a novel search strategy for determining the optimal packing of protein secondary structure elements. The approach is based on conformational energy optimization using a predetermined set of side chain rotamers and appropriate methods for sampling the conformational space of peptide fragments having fixed backbone geometries. An application to the 4-helix bundle of myohemerythrin is presented. It is shown that the conformations of the amino acid side chains are largely determined at the level of helix pairs and that superposition of these results can be used to construct the full bundle. The final solution obtained, taking into account restrictions due to the lateral amphiphilicity of the helices, differs from the native structure by only a 20° rotation of a single helix. © 1993 Wiley-Liss, Inc.     

Mapping the path of the nascent peptide chain through the 23S RNA in the 50S ribosomal subunit.

Peptides of different lengths encoded by suitable mRNA fragments were biosynthesized in situ on Escherichia coli ribosomes. The peptides carried a diazirine derivative bound to their N-terminal methionine residue, which was photoactivated whilst the peptides were still attached to the ribosome. Subsequently, the sites of photo-cross-linking to 23S RNA were analyzed by our standard procedures. The N-termini of peptides of increasing length became progressively cross-linked to nucleotide 750 (peptides of 6, 9 or 13-15 amino acids), to nucleotide 1614 and concomitantly to a second site between nucleotides 1305 and 1350 (a peptide of 25-26 amino acids), and to nucleotide 91 (a peptide of 29-33 amino acids). Previously we had shown that peptides of 1 or 2 amino acids were cross-linked to nucleotides 2062, 2506 and 2585 within the peptidyl transferase ring, whereas tri-and tetrapeptides were additionally cross-linked to nucleotides 2609 and 1781. Taken together, the data demonstrate that the path of the nascent peptide chain moves from the peptidyl transferase ring in domain V of the 23S RNA to domain IV, then to domain II, then to domain III, and finally to domain I. These cross-linking results are correlated with other types of topographical data relating to the 50S subunit.     

Mechanism of action of aspartic proteinases. V. Conformational characteristics of fragments of substrate-binding sites in rhizopuspepsin and HIV-1 proteinase

The conformational states of side chains of catalytic Asp residues in active sites of HIV-1 protease and rhizopuspepsin in the potential field of free enzymes were studied by using theoretical conformational analysis. Structural factors that stabilize the conformation of these residues in free enzymes were revealed. Methods of molecular mechanics were used to estimate the stabilization energy of the Met46-Phe53 labile fragments of HIV-1 protease in the potential field of their nearest surrounding amino acid residues for the conformations characteristic of the free protein and similar to that of the protein in enzyme-inhibitor complexes. In solution, the conformational state of the fragments of the free enzyme was concluded to be similar to that observed in the enzyme complex with the ligand and different from that determined by X-ray diffraction analysis. This difference was ascribed to the effect of crystal packing.     

On the properties and sequence context of structurally ambivalent fragments in proteins

The goal of this work is to characterize structurally ambivalent fragments in proteins. We have searched the Protein Data Bank and identified all structurally ambivalent peptides (SAPs) of length five or greater that exist in two different backbone conformations. The SAPs were classified in five distinct categories based on their structure. We propose a novel index that provides a quantitative measure of conformational variability of a sequence fragment. It measures the context-dependent width of the distribution of (phi,xi) dihedral angles associated with each amino acid type. This index was used to analyze the local structural propensity of both SAPs and the sequence fragments contiguous to them. We also analyzed type-specific amino acid composition, solvent accessibility, and overall structural properties of SAPs and their sequence context. We show that each type of SAP has an unusual, type-specific amino acid composition and, as a result, simultaneous intrinsic preferences for two distinct types of backbone conformation. All types of SAPs have lower sequence complexity than average. Fragments that adopt helical conformation in one protein and sheet conformation in another have the lowest sequence complexity and are sampled from a relatively limited repertoire of possible residue combinations. A statistically significant difference between two distinct conformations of the same SAP is observed not only in the overall structural properties of proteins harboring the SAP but also in the properties of its flanking regions and in the pattern of solvent accessibility. These results have implications for protein design and structure prediction.     

Conformational relationships between amino acids and their anticodons in the primitive decoding system

Detailed calculations of the conformational characteristics of a primitive decoding system are presented. A penta-nucleotide serves as the primitive tRNA (PIT) with a triplet of primitive anticodon (PAC) in a helical conformation. This molecular moiety has a cleft in the middle. An amino acid can comfortably nestle into the cleft. The conformation of this molecular association is stabilised by a few hydrogen bonds. The stereochemistry of the moiety restricts the conformational possibilities and the sidechain of the amino acid gets oriented at a proper position and in the correct direction to interact intimately with the PAC in the middle of the PIT. The model favours L-amino acids for beta-D-ribonucleotides. The location of the sidechain of the amino acid in the PIT gives a raison d'être for the important features of the organisation of nucleotide triplets for amino acids in the Genetic Code. The interaction of a few key amino acids with the different combinations of bases as PAC sequences has been studied and the stereochemical basis for the selection of the anticodons for amino acids is elucidated.     

Conformational preferences of sequential fragments of the hinge region of human IgA1 immunoglobulin molecule: II

The mean solution conformation of tetrapeptide fragments of the hinge region of human IgA1 molecule was investigated by CD and 13C-NMR methods. Distinct conformational differences for the partial sequences were found. Tetrapeptides with the Thr-Pro-Ser-Pro sequence were found to show a clear preference for the beta-turn conformation. Conformational equilibria of these peptides are only slightly affected by acetylation or pH changes. In the case of Pro-Thr-Pro-Ser tetrapeptides conformational equilibria are dominated by unordered forms.     

Secondary structure of polypeptide hormones of the anterior lobe of the pituitary gland

The specific secondary structure of a number of polypeptide hormones of the pituitary gland anterior lobe and their fragments were studied by CD in the peptide bond absorption region and by ir spectroscopy. The state of objects was examined in solvents of different polarity over a wide temperature range as well as in the solid state at different relative humidities. The predominant conformational state of a number of hormones in aqueous solution is shown to represent a left-handed helix of the poly(L -proline) II type. The reversible melting process of the left-handed helical conformation when heated in an aqueous solution appears to be noncooperative. Lowering the temperature stabilizes the left-handed structure. The transition mode of the left-handed form to the α-, and the β-forms on changing the solvent conditions was also studied. Contributions of peptide chromophores and of the aromatic amino acid side-group chromophores with CD bands in the region under study were determined by analysis of CD spectra. The data obtained allow correlating the conformation of separate fragments in the hormone chain with functional activity.