Spectral studies of beta-melanocyte-stimulating hormone and beta-lipotropic hormone fragment]

Secondary structure of beta-melanocyte-stimulating hormone was studied by circular dichoism and infra-red spectroscopy. Left-helical conformation of poly-L-proline II type which was stabilized by temperature reduction was found in aqueous solution; in 60% ethanole the quota of this structure sharply decreased. The investigation of hormone films at different values of relative humidity (in the course of H--D metabolism) made it possible to discover a twisted beta-form and an elongated helix of poly-L-proline II type. Temperature induced changes of circular dichroism spectra specify the peculiarities of poly-L-proline II conformation in C-end fragment of beta-lipotropic hormone.     

CD spectra of indolicidin antimicrobial peptides suggest turns, not polyproline helix.

Indolicidin is a 13-residue antimicrobial peptide-amide isolated from the cytoplasmic granules of bovine neutrophils that contains five Trp and three Pro residues. Falla et al. [(1996) J. Biol. Chem. 271, 19298] suggested that indolicidin forms a poly-L-proline II helix based upon the circular dichroism (CD) spectra of a closely related peptide (indolicidin methyl ester). In contrast, we found no evidence of poly-L-proline II helix formation in the CD spectra of native indolicidin in various solvents or when bound to micelles and membranes [Ladokhin et al. (1997) Biophys. J. 72, 794]. We interpreted the spectra as arising from unordered and/or beta-turn structures, but noted a sharp negative band at 227 nm arising from the tryptophan residues that would mask spectral features characteristic of poly-L-proline II helix. We have reexamined this issue by means of CD measurements of native indolicidin and several of its analogues. None of the features characteristic of a poly-L-proline helix (or alpha- or 3(10)-helix) were observed for any of the peptides studied. To eliminate artifacts associated with tryptophan, we synthesized indolicidin-L and indolicidin-F in which all five tryptophans were replaced with leucines or phenylalanines, respectively. The changes in CD spectra of these Trp-free peptides upon transfer into membrane-like environments were found to be consistent with the formation of beta-turns. For the native indolicidin in SDS micelles, temperature increases resulted in a coupled diminution of two sharp bands, a negative one at 227 nm and a positive one at 217 nm. This phenomenon, which is absent in indolicidin-L variants with single Leu-->Trp substitutions, is consistent with exciton splitting produced by the stacking of indole rings. Type VI turns in model peptides in aqueous solution are known to be promoted by stacking interactions between cis-proline and neighboring aromatic residues [Yao et al. (1994) J. Mol. Biol. 243, 754]. Molecular modeling of indolicidin with a -Trp(6)-cis-Pro(7)-Trp(8)- type VIa turn demonstrated the feasibility of this turn conformation and revealed the possibility of an accompanying amphipathic structure. We therefore suggest that turn conformations are the principal structural motif of indolicidin and that these turns greatly enhance membrane activity.     

Hydration of compact and extended forms of the pFh fragments of myeloma IgG3

It has been shown by scanning microcalorimetry and densitometry that the partial specific heat and the partial specific volume of pFh fragments of two myeloma IgG3 increase during breakdown of the tertiary structure, while the secondary structure—left-handed poly-L-proline II double helix—does not change. This effect may be explained by a high degree of hydration, which increases upon globule decompactization because of enhanced solvent accessibility of the peptide groups of the helix.     

Prediction of conformation of rat galanin in the presence and absence of water with the use of monte Carlo methods and the ECEPP/3 force field

The conformation of the 29-residue rat galanin neuropeptide was studied using the Monte Carlo with energy minimization (MCM) and electrostatically driven Monte Carlo (EDMC) methods. According to a previously elaborated procedure, the polypeptide chain was first treated in a united-residue approximation, in order to enable extensive exploration of the conformational space to be carried out (with the use of MCM), Then the low-energy united-residue conformations were converted to the all-atom representations, and EDMC simulations were carried out for the all-atom polypeptide chains, using the ECEPP/3 force field with hydration included. In order to estimate the effect of environment on galanin conformation, the low-energy conformations obtained as a result of these simulations were taken as starting structures for further EDMC runs that did not include hydration. The lowest-energy conformation obtained in aqueous solution calculations had a nonhelical N-terminal part packed against the nonpolar face of a residual helix that extended from Pro¹³ toward the C-terminus. One next lowest-energy structure was a nearly-all-helical conformation, but with a markedly higher energy. In contrast, all of the low-energy conformations in the absence of water were all-helical differing only by the extent to which the helix was kinked around Pro¹³. These results are in qualitative agreement with the available NMR and CD data of galanin in aqueous and nonaqueous solvents.     

A test for the structure of the left helix of poly-L-proline type II in peptides

The spectral criterion of a left-handed helix of the poly-L-proline II type was elaborated during the study of a number of synthesized oligopeptides (in a solid state and solution): (Gly-Pro-Pro)1-8, (Gly-Pro)1, (Gly-Pro-Ala)1-4, (Gly-Pro-Gly)1-4, (Gly-Pro-Pro) X (Gly-Pro-Gly)1-2(Gly-Pro-Pro), (Gly-Pro-Pro)n, (Orn3-Gly)n and also rat skin collagen by X-ray diffraction, circular dichroism and infrared spectroscopy methods; the characteristic shape of the left-handed helix CD spectrum was found. The change of spectral characteristics with the change of left-handed helix distortion was established. The linear noncooperative melting process of the left-handed conformation was demonstrated. The data obtained allow to determine qualitatively the presence of the left-handed helix in different polypeptides and proteins.     

Hydration of the compact and extended forms of pFh fragments from IgG3 Kuc and Sur

It has been shown using scanning microcalorimetry and densitometry that partial specific heat and specific partial volume of two pFh fragments of IgG3 increase during the decay of its tertiary structure, the secondary structure, the double poly-L-proline helix, being unchanged. This effect may be explained by a high degree of hydration, which increases on globule decompactization due to increased accessibility of peptide groups of the helix to solvent.     

Investigation of cis/trans proline isomerism in a multiply occurring peptide fragment from human salivary proline-rich glycoprotein.

The solution-state conformations of eight proline-containing peptide fragments found in human salivary proline-rich glycoprotein (PRG) were investigated in 2 x distilled water (treated with metal ion chelating resin) using 13C-nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. The peptide sequences and acronyms were as follows: PRG9-2 = NH2-G(1)-P(2)-CONH2, PRG9-3 = NH2-G(1)P(2)-P(3)-CONH2, PRG9-4 = NH2-G(1)-P(2)-P(3)-P(4)-CONH2, PRG9-5 = NH2-G(1)-P(2)-P(3)-P(4)-H(5)-CONH2, PRG9-6 = NH2-G(1)-P(2)-P(3)-P(4)-H(5)-P(6)-CONH2, PRG9-7 = NH2-G(1)-P(2)-P(3)-P(4)-H(5)-P(6)-G(7)-CONH2, PRG9-8 = NH2-G(1)-P(2)-P(3)-P(4)-H(5)-P(6)-G(7)-K(8)-CONH2 and PRG9-9 = NH2-G(1)-P(2)-P(3)-P(4)-H(5)-P(6)-G(7)-K(8)-P(9)-CONH2. Sequence-specific resonance assignments from the 13C-NMR spectra indicated that the trans proline isomer dominated the conformations of the peptides. CD results clearly showed the presence of the poly-L-proline II helix as the major conformation in PRG9-3----PRG9-5, supplemented by beta- and/or gamma-turns in PRG9-6----PRG9-9. These data suggest that in "metal free" water, native PRG could contain several small poly-L-proline II helices along with beta- and/or gamma-turns. Since proline is the major amino acid present in native PRG, these localized conformations may contribute to PRG's global conformation and act as a primary force in determining its biological activities.     

Identification of the calcium channel alpha 1E (Ca(v)2.3) isoform expressed in atrial myocytes

The consensus octapeptide repeat motif of the barley seed storage protein C hordein, Pro-Gln-Gln-Pro-Phe-Pro-Gln-Gln, forms the epitope of two anti-prolamin monoclonal antibodies (Mabs), IFRN 0061 and 0614. The Mabs were found to exhibit unusual temperature-dependent binding characteristics, recognising C hordein and a peptide corresponding to the consensus repeat at 5 degrees C but not at 37 degrees C, as determined by enzyme-linked immunosorbent assay (ELISA). The K(d) of IFRN 0614 for the consensus peptide was found to be 1.2x10(12) mol(-1) at 12 degrees C, but no constant could be calculated at 37 degrees C due to a lack of binding. Similar ELISA binding characteristics were observed with an anti-C hordein polyclonal antiserum and a Mab raised to the consensus peptide. Circular dichroism (CD) and Fourier-transform infrared (FTIR) spectroscopy showed that the protein and the consensus peptide exist in a temperature-dependent equilibrium of poly-L-proline II type structures and beta-turn conformations. Whilst thermodynamic and kinetic effects may reduce antibody binding at higher temperatures, they cannot account for the complete loss of Mab recognition at higher temperatures. It seems likely that the Mabs preferentially recognise the Pro-Gln-Gln-Pro-Phe-Pro-Gln-Gln motif when presented in a conformation which may correspond to the poly-L-proline II type conformation which dominates the CD and FTIR spectra at 4-12 degrees C.     

The peptide-substrate-binding domain of collagen prolyl 4-hydroxylases is a tetratricopeptide repeat domain with functional aromatic residues

Collagen prolyl 4-hydroxylases catalyze the formation of 4-hydroxyproline in -X-Pro-Gly-sequences and have an essential role in collagen synthesis. The vertebrate enzymes are alpha2beta2 tetramers in which the catalytic alpha-subunits contain separate peptide-substrate-binding and catalytic domains. We report on the crystal structure of the peptide-substrate-binding domain of the human type I enzyme refined at 2.3 A resolution. It was found to belong to a family of tetratricopeptide repeat domains that are involved in many protein-protein interactions and consist of five alpha-helices forming two tetratricopeptide repeat motifs plus the solvating helix. A prominent feature of its concave surface is a deep groove lined by tyrosines, a putative binding site for proline-rich Tripeptides. Solvent-exposed side chains of three of the tyrosines have a repeat distance similar to that of a poly-L-proline type II helix. The aromatic surface ends at one of the tyrosines, where the groove curves almost 90 degrees away from the linear arrangement of the three tyrosine side chains, possibly inducing a bent conformation in the bound peptide. This finding is consistent with previous suggestions by others that a minimal structural requirement for proline 4-hydroxylation may be a sequence in the poly-L-proline type II conformation followed by a beta-turn in the Pro-Gly segment. Site-directed mutagenesis indicated that none of the tyrosines was critical for tetramer assembly, whereas most of them were critical for the binding of a peptide substrate and inhibitor both to the domain and the alpha2beta2 enzyme tetramer.     

The unusual thermodynamic properties of compact forms pFh fragments (hinge region) IgG3 Kuc and Sur

pFh fragments from the hinge region of human IgG3 Kuc and Sur can fold into compact form, resulting the formation of proteins with secondary (super-secondary) structure, which is represented almost exclusively double poly-L-proline helix. It was demonstrated by several methods that the thermal denaturation of compact form pFh fragment (hinge region) IgG3 Kuc and Sur occurs in two stages. The "two-state" model described the disintegration of the compact structure with preservation of the secondary structure (double poly-L-proline helix). In the second stage melts itself helix consisting of four cooperative units, which are formed by the sections with a high content of proline residues. Poliproline conformation of secondary structure and large number of disulfide bonds is responsible for high specific enthalpy of denaturation and high thermal stability.     

Vibrational circular dichroism spectra of unblocked proline oligomers.

Vibrational Circular Dichroism (VCD) spectra of unblocked L-proline oligopeptides, (Pro)n n = 3 to 7, dissolved in D2O are reported. For these oligomers, the VCD spectra can be attributed to a conformational dominance of the trans amide conformation with subunits interrelated by a left-handed twist, particularly for the longer oligomers. As a function of oligomer length, formation of this conformation starts at n = 3; and by n = 5 a spectrum closely resembling that of the poly-L-proline II helix in shape and magnitude is seen. The VCD data are compared with previous (Pro)n results using IR, CD, Raman and NMR spectroscopies, and reasons for the variations in interpretation are discussed.     

Third type of secondary structure: noncooperative mobile conformation. Protein Data Bank analysis

Analysis of 68 proteins from Protein Data Bank disclosed a new widely spread type of the secondary structure that is designated as mobile (M-) conformation. Helical parameters of M-conformation are close to the poly-L-proline II type helix. Its occurrence in globular proteins approximates that of the beta-sheet. The angles corresponding to the position of the M-conformation maximum in distribution of amino acid residues on a conformational map are phi: -65 degrees, psi: 140 degrees. Unique features and high occurrence in proteins make it possible to distinguish the M-conformation as an independent third type of the secondary structure in globular proteins, that should be included in the present classification.     

Structure of illexine I2 and its complexes with DNA

Conformational peculiarities of illexine I2 both in the solution and in the complexes with DNA were studied by circular dichroism, UV-spectroscopy and spectrophotometric melting. IIlexine I2 is shown to have an extended left-handed helical conformation of poly-L-proline II type, that are stable in a wide range of experimental conditions. Upon interaction of illexine I2 with DNA, the parameters of conformation are somewhat distorted but the main peculiarities remain. The DNA double helix changes from B- to the divection of C-form at its interaction with illexine I2. The interaction of illexine I2 with DNA at low ionic strength is non-cooperative and is characterized by some specificity to A--T sequences of DNA. Illexine I2 strongly affects the DNA stability by increasing the melting temperature of DNA.     

Two different molecular conformations found in chitosan type II salts

The type II structure of chitosan acidic salts prepared from crab tendon in solid state was studied using an X-ray fiber diffraction technique together with the linked-atom least-squares (LALS) technique. The cylindrical Patterson method was applied to confirm the molecular conformation of the chitosan. It was shown that there are two different helical conformations for type II salts. One is the relaxed twofold helix having a tetrasaccharide as an asymmetric unit as found in chitosan.HCl salt, which was previously reported as a conformation of chitosan.HCOOH salt. The other is the fourfold helix having a disaccharide as an asymmetric unit newly found in chitosan.HI salt.     

Temperature-dependent binding of monoclonal antibodies to C hordein

The consensus octapeptide repeat motif of the barley seed storage protein C hordein, Pro-Gln-Gln-Pro-Phe-Pro-Gln-Gln, forms the epitope of two anti-prolamin monoclonal antibodies (Mabs), IFRN 0061 and 0614. The Mabs were found to exhibit unusual temperature-dependent binding characteristics, recognising C hordein and a peptide corresponding to the consensus repeat at 5°C but not at 37°C, as determined by enzyme-linked immunosorbent assay (ELISA). The K_d of IFRN 0614 for the consensus peptide was found to be 1.2×10¹² mol⁻¹ at 12°C, but no constant could be calculated at 37°C due to a lack of binding. Similar ELISA binding characteristics were observed with an anti-C hordein polyclonal antiserum and a Mab raised to the consensus peptide. Circular dichroism (CD) and Fourier-transform infrared (FTIR) spectroscopy showed that the protein and the consensus peptide exist in a temperature-dependent equilibrium of poly-L-proline II type structures and β-turn conformations. Whilst thermodynamic and kinetic effects may reduce antibody binding at higher temperatures, they cannot account for the complete loss of Mab recognition at higher temperatures. It seems likely that the Mabs preferentially recognise the Pro-Gln-Gln-Pro-Phe-Pro-Gln-Gln motif when presented in a conformation which may correspond to the poly-L-proline II type conformation which dominates the CD and FTIR spectra at 4-12°C.     

Three D structures of chitosan

Crystal structures of two polymorphs of chitosan, tendon (hydrated) and annealed (anhydrous) polymorphs, have been reported. In both crystals, chitosan molecule takes up similar conformation (Type I form) to each other, an extended two-fold helix stabilized by intramolecular O3-O5 hydrogen bond, which is also similar to the conformation of chitin or cellulose. Three chitosan conformations other than Type I form have been found in the crystals of chitosan-acid salts. In the salts with acetic and some other acids, called Type II salts, chitosan molecule takes up a relaxed two-fold helix composed of asymmetric unit of tetrasaccharide. This conformation seems to be unstable because no strong intramolecular hydrogen bond like Type I form. Type II crystal changes to the annealed polymorph of chitosan by a spontaneous water-removing action of the acid. Chitosan molecule in its hydrogen iodide salt prepared at low temperature takes a 4/1 helix with asymmetric unit of disaccharide. The fourth chitosan conformation was found to be a 5/3 helix in chitosan salts with medical organic acids having phenyl group such as salicylic or gentisic acids. Similar conformation of chitosan molecule in the aspirin (acetylsalicylic acid) salt was suggested by a solid-sate NMR measurement.     

Raman and infrared spectroscopic study of gramicidin A conformations

Raman scattering and infrared spectroscopic techniques were used to study the vibrational spectrum and conformation of the membrane channel protein gramicidin A in the solid state, in organic solutions and, using Raman scattering only, in a phospholipid environment. The investigation also includes measurements on head- and tail-group-modifled gramicidin A and a potassium thiocyanate-gramicidin A complex. Tentative identification of the molecular vibrations is proposed on the basis of the data on model compounds. The existence of four distinct conformations of the gramicidin A chain is established: conformation I present in the solid state, and CH₃OH and CD₃OD solutions; conformation II present in films cast from CHCl₃ solution; conformation III present in (CH₃)₂SO and (CD₃)₂SO solutions at concentrations below 0.5 m gramicidin A; and conformation IV present in the potassium thiocyanate-gramicidin A complex. The data obtainable on a gramicidin A-phospholipid suspension indicate a gramicidin A conformation in this environment corresponding either to the conformation I or II. The details of the spectra in the amide I region are shown to be consistent with a β-parallel hydrogen-bonded π_LD helix for conformational I, in terms of the polypeptide vibrational calculations of Nevskaya and co-workers. Conformation II is found to be consistent with an antiparallel double-stranded π_LD helix, while conformations III and IV probably have π-helical structures with larger channel diameters. The data on head- and tail-modified gramicidin A molecules indicate that their conformations are only slightly different from that of gramicidin A in conformation I.     

Conformational study of the basic proline-rich polypeptides from human parotid saliva

The conformational study of two basic proline-rich polypeptides from human parotid saliva, P--D and P--E of known primary structures, was performed by CD and 1H--n.m.r. spectra measurements. These polypeptides contain consecutive sequences of five prolyl residues in their amino acid sequences. The troughs in CD spectra of P--D and P--E were found at 202 and 201 nm, respectively. These wavelengths were different from the value of 206 nm of poly-L-proline form II conformation. In spite of this, the existence of poly-L-proline form II conformation was suggested in the structure of P--D, because the trough for a fragmental peptide of P--D containing five consecutive prolyl residues was found at 204 nm. No remarkable change was detected in CD and 1H--n.m.r. spectra of P--D and P--E in the range of pH 3.0-11.0. The result suggests that no folding of polypeptide which might be affected by ionic interaction exists in its structure.     

Study of the conformational properties of C-terminal fragments of histones H1, H5, and beta-endorphin by circular dichroism]

Circular dichroism technique has been used for investigating the conformation of histone H1 and H5 C-terminal fragments and beta-endorphin. It has been shown that in aqueous solution these polypeptides adopt preferably the left-handed helical conformation of the poly-L-proline II type. The linear temperature dependence of the CD value during solution heating was found to be broken in the temperature interval between 50 and 55 degrees C. It was supposed to occur due to the conformation destruction.