Hyaluronic acid: structure of a fully extended 3-fold helical sodium salt and comparison with the less extended 4-fold helical forms.

The consequences of enzyme and template interaction were examined by several independent methods in the replication reactions catalyzed by calf thymus low molecular weight DNA polymerase, calf thymus high molecular weight DNA polymerase, and Eacherichia coli polymerase I. All methods used support a distributive, rather than processive, mechanism for enzyme in the replication of homopolymer templates in vitro. First, addition of an excess of initiated poly(dC) template to an ongoing poly(dA) replication reaction results in immediate cessation of dTTP polymerization. Second, the kinetics of monomer and initiator incorporation in reactions where a large number of initiated template molecules are available to each enzyme molecule show early incorporation of all initiators followed by simultaneous replication of the total population of template molecules. Third, alkaline sucrose gradient analysis of the products formed at various stages during replication show simultaneous growth in product chain lengths. Fourth, analysis of products formed when an average of one to two nucleotides are added at the end of the growing chain, in reactions having a molecular ratio of template to enzyme of about 900, show that the enzyme can dissociate from the replicating template after a single addition. Increasing the ionic strength of the reaction mixture, to decrease the secondary interactions between the enzyme and the template, results in nearly random interaction of the enzyme and the template. The results from this study suggest that translocation of template chain during replication is not an obligatory function of purified DNA polymerases. The possible involvement of other proteins required for DNA replication in vivo in the interaction of DNA polymerase and DNA is discussed.     

Supramolecular assembly using helical peptides

We investigated supramolecular assemblies of various hydrophobic helical peptides. The assemblies were formed at the air/water interface or in aqueous medium. The hexadecapeptide, Boc-(Ala-Aib)₈-OMe (BA16M), was reported to take α-helical structure by X-ray analysis. Several derivatives were prepared, which have the repeating sequence of Ala-Aib, Lys(Z)-Aib or Leu-Aib, or have the terminal chemically modified. CD spectra of the peptides indicated helical conformation in ethanol solution. The surface pressure-area isotherms of the peptide monolayers showed an inflection at the surface area corresponding to the cross section along the helix axis, and the monolayers were collapsed by further compression. All the helical peptides oriented their helix axis parallel to the air/water interface on the basis of the results of transmission IR spectra and RAS of the monolayers transferred onto substrates.A small mound was observed in the isotherm of BA16M and other derivatives, which was ascribed to the phase transition from the liquid state to the solid state. One mol% of FITC-labeled peptide was mixed into the monolayers to visualize the phase separation of the solid and liquid states at the surface pressure of the coexisting region. Various shapes of the dark domain were observed at the top of the mound in the isotherms by fluorescence microscopy. The helical peptides formed two-dimensional crystals at the air/water interface when they were compressed to the solid state.An amino-terminated helical peptide, HA16B, was suspended in an aqueous medium by a sonication method and transparent dispersion was obtained. The dynamic light scattering measurement of the dispersion revealed the particle size of 75 nm with a narrow size distribution. The molecular assembly of the helical peptide in water was called “Peptosome”, because it takes a vesicular structure.     

Analysis of peptides for helical prediction

Two terminally blocked peptides, acetylAETAAAKFLRQHMamide and acetylAETSSSRYLRQHMamide, were obtained by solid-phase synthesis, purified by reversed-phase chromatography, and characterized by fast atom bombardment mass spectrometry. Both peptides were soluble in aqueous solutions and remained monomeric over the concentration range examined. Changes in the temperature, pH, and trifluoroethanol concentration of solutions of each peptide produced changes in the far-ultraviolet circular dichroic spectrum characteristic of a two-state helix/coil transition. The limiting mean residue ellipticity of the coil and helix form of each peptide was estimated by addition of the denaturant guanidinium chloride at elevated temperature and by addition of trifluoroethanol at subzero temperatures, respectively. The midpoint for the thermal transition of the peptide SSSRY is lowered by about 30 degrees C relative to that of peptide AAAKF, in qualitative agreement from predictions based on helix probabilities of amino acid residues. The magnitude of the change observed in the midpoint of the thermal transitions suggests that the effect of single amino acid replacements on helix formation should be experimentally measurable.     

Amphipathic alpha helical antimicrobial peptides.

Antimicrobial peptides (AMPs) that assume an amphipathic alpha helical structure are widespread in nature. Their activity depends on several parameters including the sequence, size, degree of structure formation, cationicity, hydrophobicity and amphipathicity. The analysis of numerous natural AMPs provided representative values for these parameters and led to a sequence template with which to generate potent artificial lead AMPs. Sequences were then varied in a rational manner, using both natural and nonproteinogenic amino acids, to probe the individual roles of each parameter in modulating biological activity. A high cationicity combined with a stabilized amphipathic alpha helical structure conferred enhanced cidal activity towards all the cell types considered, and was a requirement for Gram-positive bacteria and fungi. An elevated helicity also correlated with increased hemolytic activity. The structural requirements for activity against several Gram-negative bacteria were instead considerably less stringent, so that it persisted in peptides in which formation of a helical structure and/or amphipathicity were impeded. Either a reduced charge or a reduced hydrophobicity resulted in generally inactive peptides. These observations, combined with the kinetics of bacterial membrane permeabilization and time-killing are discussed in terms of currently accepted models of action for this type of peptide. The simple guidelines obtained in this study allowed the design of highly active shortened AMPs and may be generally useful in the development of this type of peptides as anti-infective agents.     

The design of self-replicating helical peptides

The self-assembly of helical peptides and information transfer through autocatalysis and cross-catalysis are the foundation of peptide-based molecular evolution models. Many fundamental properties of living systems, such as environmental sensitivity, chiroselectivity, cross-catalysis, dynamic error correction and conditional selection, are exhibited by various self-replicating peptide systems. Recently, advances have been made in the design of peptide systems with autocatalytic and cross-catalytic properties.     

Ion channels formed by amphipathic helical peptides

Channel forming peptides (CFPs) are amphipathic peptides, of length ca. 20 residues, which adopt an -helical conformation in the presence of lipid bilayers and form ion channels with electrophysiological properties comparable to those of ion channel proteins. We have modelled CFP channels as bundles of parallel trans-bilayer helices surrounding a central ion-permeable pore. Ion-channel interactions have been explored via accessible surface area calculations, and via evaluation of changes in van der Waals and electrostatic energies as a K⁺ ion is translated along the length of the pore. Two CFPs have been modelled: (a) zervamicin-A1-16, a synthetic apolar peptaibol related to alamethicin, and (b) -toxin from Staphylococcus aureus. Both of these CFPs have previously been shown to form ion channels in planar lipid bilayers, and have been shown to have predominantly helical conformations. Zervamicin-A1-16 channels were modelled as bundles of 4 to 8 parallel helices. Two related helix bundle geometries were explored. K⁺channel interactions have been shown to involve exposed backbone carbonyl oxygen atoms. -Toxin channels were modelled as bundles of 6 parallel helices. Residues Q3, D11 and D18 generate favourable K⁺-channel interactions. Rotation of W15 about its C-C bond has been shown to be capable of occluding the central pore, and is discussed as a possible model for sidechain conformational changes in relation to ion channel gating.     

Anti-plasmodial action of de novo-designed, cationic, lysine-branched, amphipathic, helical peptides

ABSTRACT: BACKGROUND: A lack of vaccine and rampant drug resistance demands new anti-malarials. METHODS: In vitro blood stage anti-plasmodial properties of several de novo-designed, chemically synthesized, cationic, amphipathic, helical, antibiotic peptides were examined against Plasmodium falciparum using SYBR Green assay. Mechanistic details of anti-plasmodial action were examined by optical/fluorescence microscopy and FACS analysis. RESULTS: Unlike the monomeric decapeptides {(Ac-GXRKXHKXWA-NH2) (X = F,DeltaF) (Fm, DeltaFm IC50 >100 muM)}, the lysine-branched,dimeric versions showed far greater potency {IC50 (muM) Fd 1.5 , DeltaFd 1.39}. The more helical and proteolytically stable DeltaFd was studied for mechanistic details. DeltaFq, a K-K2 dendrimer of DeltaFm and (DeltaFm)2 a linear dimer of DeltaFm showed IC50 (muM) of 0.25 and 2.4 respectively. The healthy/infected red cell selectivity indices were >35 (DeltaFd), >20 (DeltaFm)2 and 10 (DeltaFq). FITC-DeltaFd showed rapid and selective accumulation in parasitized red cells. Overlaying DAPI and FITC florescence suggested that DeltaFd binds DNA. Trophozoites and schizonts incubated with DeltaFd (2.5 muM) egressed anomalously and Band-3 immunostaining revealed them not to be associated with RBC membrane. Prematurely egressed merozoites from peptide-treated cultures were found to be invasion incompetent. CONCLUSION: Good selectivity (>35), good resistance index (1.1) and low cytotoxicity indicate the promise of DeltaFd against malaria.     

Differential self assembly of amphiphilic helical peptides

Summary A series of amphiphilic, helical peptides was designed and synthesized to investigate the components necessary for formation of helical bundles with differing aggregation states. Minimalistic sequences were employed for the peptides which contained either four (Leu4), six (Leu6) or eight (Leu8) leucine residues within a sixteen amino acid sequence. All peptides were highly helical as evaluated by circular dichroism, and the helical content of each peptide exhibited a concentration dependence. Size exclusion chromatography confirmed aggregation states of dimer/trimer forLeu4, tetramer forLeu6, and hexamer octamer forLeu8. Disulfide crosslinking studies also confirmed that the dimer ofLeu4 favored a parallel orientation with respect to the helical dipole. This systematic study clearly defines the role of hydrophobicity in the self assembly of helical peptides; peptides with a small hydrophobic face favor small bundle sizes, whereas peptides containing larger hydrophobic faces form correspondingly larger helical bundles.     

C-terminal capping motifs in model helical peptides

Solution structures of a series of consensus sequence peptides with N- and C-terminal capping interactions have been determined by 2-D nuclear magnetic resonance spectroscopy and a simulated annealing strategy. All peptides are found to be stabilized by a hydrophobic interaction and a capping box structure (SXXE) at the N-terminus whereas several different capping motifs are discerned near the peptide C-terminus. Among these, the asparagine side chain-backbone main chain (i, i-4) capping structure is most stabilizing and highly populated in the simulated annealing calculation. A glycine alphaL capping motif stabilizes the peptide terminus, which otherwise tends to fray, but this is occupied only a fraction of the time in the trial structures determined. Our experimental search over several models for a second type of C-terminal capping structure, the so-called 'Schellman motif', which is seen in native proteins, is unsuccessful, indicating this structural element contributes less to oligopeptide stability in solution and most probably populates only transiently.     

Crystal-state 3D-structural characterization of novel, Aib-based, turn and helical peptides.

The crystal-state conformations of the hexapeptide amide Pht-(Aib)(6)-NH-C(CH(3))(2)-O-OtBu (7), the hexapeptide Ac-L-aIle-(Aib)(5)-OtBu (6), the pentapeptide Z-(Aib)(3)-L-Glu(OtBu)-Aib-O-(CH(2))(2)-(1)Nap (5), the tetrapeptides Z-(Aib)(2)-L-His(N(tau)-Trt)-Aib-OMe (4 I) and Z-(Aib)(2)-L-Nva-Aib-OtBu (4 II), the tripeptide Pyr-(Aib)(3)-OtBu (3 I), the dipeptide amides Pyr-(Aib)(2)-(4)NH-TEMPO (3 II) and Piv-(Aib)(2)-NH-C(CH(3))(2)-O-OtBu (3 III), and the dipeptides Pht-Aib-betaAc(6)c-OtBu (2 I), Pht-Aib-NH-C(CH(3))(2)-O-OtBu (2 II) and Boc-gGly-mAib-OH (2 III) have been determined by X-ray diffraction analyses. All peptides investigated are characterized by one or more turn/helix forming Aib residues. Except the three short dipeptides, all are folded into C==O...H--N intramolecularly H-bonded 3(10)-helices, or into various types of beta-turns. In the structure of 6, two independent molecules of opposite screw sense were observed in the asymmetric unit, generating diastereomeric 3(10)-helices.     

Self-association of helical peptides in a lipid environment

The self-association of two model transmembrane helical peptides, differing in their surface topography, was compared in mixed micelles containing 3-([3-cholamidopropyl]dimethylammonio)-1-propanesulfonate (CHAPS) and dimyristoylphosphatidylcholine (DMPC). One peptide, Ac-KKL₂₄KK-amide (L₂₄), has large, rotationally mobile leucine side chains and a relatively rough surface. The other peptide, Ac-KKLLLLLLAALLALLAALLALLLLLLKK-amide (L₁₈A₆), has a patch of small alanines on one side of the helix that forms a smooth surface. The aggregation state of the peptides was sampled by chemical cross-linking with bis-sulfosuccinimidyl suberate (B53). A monomer-aggregate association constant was obtained from the cross-linking results in the range of 2 × 10⁵ M^–1 to 3 × 10⁵ M^–1 for both peptides. Kinetics of formation of cross-linked dimers indicated that the ratio of dimerization constants for L₁₈A₆ to L₂₄ was between 10 and 20. This suggests that the alanine patch contributes about 1.5 Kcal/mol more stabilization free energy to dimer formation of L₁₈A₆ compared to L₂₄.     

Backbone dynamics, fast folding, and secondary structure formation in helical proteins and peptides

We discuss the construction of a simple, off-lattice model protein with a comparatively detailed representation of the protein backbone, and use it to address some general aspects of the folding kinetics of a small helical protein and two peptide fragments. The model makes use of an associative memory hamiltonian to smoothly interpolate between the limits of a native contact only, or Go, potential and a statistical pair potential derived from a database of known structures. We have observed qualitatively different behavior in these two limits. In the Go limit, we see apparently barrier-less folding. As we increase the roughness of the model energy landscape, we can observe the emergence of the characteristic activated temperature dependence previously seen in lattice studies and analytical theories. We are also able to study the dependence of the folding kinetics on local interactions such as hydrogen bonds, and we discuss the implications of these results for the formation of secondary structure at intermediate stages of the folding reaction.     

Helix stability confers salt resistance upon helical antimicrobial peptides

Salt sensitivity of antimicrobial peptides poses a major obstacle in their development as novel antibiotics. Here we report the use of helix-capping motifs to confer salt resistance upon helical antimicrobial peptides. The helical content of the template peptide [RLLR](5) was almost completely destroyed at salt concentrations over 200 mm NaCl, leading to a 8-32-fold decrease in antimicrobial activity. However, the introduction of helix-capping motifs at the helix termini resulted in a structurally stable peptide, which retained membrane-permeabilizing and antimicrobial activities upon exposure to salt. Furthermore, the peptide with helix-capping motifs directly inhibited the in vivo growth of Streptococcus pyogenes, which causes localized fasciitis in mice, and prevented the necrosis of the epidermis, dermis, and subcutaneous muscle layers. Results indicate that the adoption of helix-capping motifs into salt-sensitive antimicrobial peptides provides the necessary structural stability for the peptides to permeabilize cell membranes and cause cell death at physiological salt concentrations.     

Aggregation studies in crystals of apolar helical peptides: Boc-Aib-Val-Ala-Leu-Aib-Val-Ala-Leu-Aib-OMe

In the crystal, the backbone of Boc-(Aib-Val-Ala-Leu)2-Aib-OMe adopts a helical form with four alpha-type hydrogen bonds in the middle, flanked by 3(10)-type hydrogen bonds at either end. The helical molecules stack in columns with head-to-tail hydrogen bonds, either directly between NH and CO, or bridged by solvent molecules. The packing of the helices is parallel, even in space group P2(1). Cell parameters are a = 9.837(2) A, b = 15.565(3) A, c = 20.087(5) A, beta = 96.42(2) degrees, dcalc = 1.091 g/cm3 for C46H83N9O12.1.5H2O.0.67CH3OH. There appears to be some hydration of the backbone in this apolar helix.     

Self-complementary peptides for the formation of collagen-like triple helical supramolecules

Collagen is acknowledged as one of the most prominent biomaterials on account of its high biocompatibility and biostability. The development of artificial collagens to replace the animal-derived collagens presents a challenge in the formation of safer and highly functionalized biomaterials. Here, a novel peptide-based system for obtaining collagen-like supramolecules via a spontaneous self-assembling process is described. The designed collagen-like peptides are self-complementary trimers in which each of the 24-mer peptide strands is tethered by two cystine knots forming a staggered arrangement. Their self-assembling ability in aqueous solution was analyzed by circular dichroism, ultrafiltration, and laser diffraction particle size estimation. The obtained results indicate that the staggered trimers form large supramolecular architectures through intermolecular triple helix-formation.     

Distance dependence of long-range electron transfer through helical peptides.

Helical peptides of 8mer, 16mer, and 24mer carrying a disulfide group at the N-terminal and a ferrocene moiety at the C-terminal were synthesized, and they were self-assembled on gold by a sulfur-gold linkage. Infrared reflection-absorption spectroscopy and ellipsometry confirmed that they formed a monolayer with upright orientation. Cyclic voltammetry showed that the electron transfer from the ferrocene moiety to gold occurred even with the longest 24mer peptide. Chronoamperometry and electrochemical impedance spectroscopy were carried out to determine the standard electron transfer rate constants. It was found that the dependence of the electron-transfer rates on the distance was significantly weak with the extension of the chain from 16mer to 24mer (decay constant beta = 0.02-0.04). This dependence on distance cannot be explained by an electron tunneling mechanism even if increased hydrogen-bonding cooperativity or molecular dynamics is considered. It is thus concluded that this long-range electron transfer is operated by an electron hopping mechanism.     

Study of the spatial structure of globular proteins by tritium planigraphy. Short peptides as a model of a fully extended polypeptide chain]

The interaction of tritium atoms with amino acid residue from short peptides was studied. The short peptides were considered as a model of extended polypeptides chain. Every residue in this chain has 100% steric accessibility. It was shown that: 1. The linear correlation exists between the residue accessible surface area (that is composed of hydrocarbon fragments) and the amount of tritium interacting with this residue; 2. The presence of the tertiary carbon atom in the residue side chain influences on the reactivity of this residue; 3. The N- or C-terminal residue presence does not influences on the possibility of interaction of this residue with tritium atoms. The obtained reactivity scale of amino acid residues is compared with other theoretical and experimental data.