苦荞α-螺旋发夹抗菌肽的分子改造抑制植物真菌活性

本研究对来源于苦荞的α-螺旋发夹抗菌肽FtAMP抗真菌机制与结构之间的关系进行了研究。首先人工合成了FtAMP分子中N-端和C-端的α-螺旋(FtAMP-N和FtAMP-C）,探究两个α-螺旋究竟是哪个螺旋在起抗菌作用。然后以FtAMP为模板,α-螺旋区电荷和两亲性特征为变化要素,利用螺旋轮投影和特定氨基酸残基替换的方法,对其进行初步分子改造,并通过对多肽结构和活性比较,探讨FtAMP结构-功能的关系。研究表明,FtAMP-N和FtAMP-C都显示出良好的抗菌活性。根据螺旋轮投影方法分析螺旋的两亲性特征,并以FtAMP氨基酸序列为模板,分别表达4个FtAMP突变体(FtAMP-E12A、FtAMP-E12A/E9K、FtAMP-E12A/E9A和FtAMP-E12A/E9K/T24E）。圆二色光谱分析显示,4个多肽都可正确折叠成α-螺旋结构,在208 nm和222 nm处有典型的双负峰,表明氨基酸的改变及其表达过程中并未改变多肽的二级结构。抗真菌活性分析显示,与FtAMP相比,4种突变体对植物真菌的抑制作用均有一定增强。特别是FtAMP-E12A/E9K突变体,其抗真菌作用增强约1倍,同时诱导溶血活性并不显著,选择特异性提高近2倍。该研究也进一步表明,α-螺旋发夹抗菌肽发挥抗真菌效应主要与其螺旋结构有关,而与其抑制剂的活性位点没有关系,为该类抗菌肽结构和功能的关系提供了一定的参考。     

High resolution NMR analysis of the seven transmembrane domains of a heptahelical receptor in organic-aqueous medium

The NMR properties of seven peptides representing the transmembrane domains of the alpha-factor receptor from Saccharomyces cerevisiae were examined in trifluoroethanol/water (4:1) at 10 to 55 degrees C. The parameters extracted indicated all peptides were helical in this membrane mimetic solvent. Using chemical shift indices as the criterion, helicity varied from 64 to 83%. The helical residues in the peptides corresponded to the region predicted to cross the hydrocarbon interior of the bilayer. A study of a truncated 25-residue peptide corresponding to domain 2 gave evidence that the helix extended all the way to the N-terminus of this peptide, indicating that sequence and not chain end effects are very important in helix termination for our model peptides. Both nuclear Overhauser effect spectroscopy (NOESY) connectivities and chemical shift indices revealed significant perturbations around prolyl residues in the helices formed by transmembrane domains 6 and 7. Molecular models of the transmembrane domains indicate that helices for domains 6 and 7 are severely kinked at these prolyl residues. The helix perturbation around proline 258 in transmembrane domain 6 correlates with mutations that cause phenotypic changes in this receptor.     

Antifungal activity of Latarcin 1 derived cell-penetrating peptides against Fusarium solani

Cell-penetrating peptides and antimicrobial peptides share physicochemical characteristics and mechanisms of interaction with biological membranes, hence, termed as membrane active peptides. The present study aims at evaluating AMP activity of CPPs. LDP-NLS and LDP are Latarcin 1 derived cell-penetrating peptides and in the current study we have evaluated antifungal and cell-penetrating properties of these CPPs in Fusarium solani. We observed that LDP-NLS and LDP exhibited excellent antifungal activity against the fungus. Cellular uptake experiments with LDP-NLS and LDP showed that LDP-NLS acted as a CPP but LDP uptake into fungal spores and hyphae was negligible. CPP and AMP activity of mutated version of LDP-NLS was also evaluated and it was observed that both the activities of the peptide were compromised, signifying the importance of arginines and lysines present in LDP-NLS for initial interaction of membrane active peptides with biological membranes. Dextrans and Propidium Iodide uptake studies revealed that the mode of entry of LDP-NLS into fungal hyphae is through pore formation. Also, both LDP-NLS and LDP showed no cytotoxicity when infiltered into leaf tissues. Overall, our results suggest that LDP-NLS and LDP are selectively cytotoxic to F. solani and can be a potent peptide based antifungal agents.     

alpha beta Spectrin coiled coil association at the tetramerization site

On the basis of sequence homology studies, it has been suggested that the association of human erythrocytes alpha and beta spectrin at the tetramerization site involves interactions between helices. However, no empirical details are available, presumably due to the experimental difficulties in studying spectrin molecules because of its size and/or its structural flexibility. It has been speculated that erythrocyte tetramerization involves helical bundling rather than coiled coil association. We have used recombinant spectrin peptides to model alpha and beta spectrin to study their association at the tetramerization site. Two alpha peptides, Sp alpha 1-156 and Sp alpha 1-368, and one beta peptide, Sp beta 1898-2083, were used as model peptides to demonstrate the formation of the alpha beta complex. We also found that the replacement of R28 in Sp alpha 1-368 to give Sp alpha 1-368R28C abolished complex formation with the beta peptide. Circular dichroism techniques were used to monitor the secondary structures of the individual peptides and of the complex, and the results showed that both Sp alpha 1-156 and Sp beta 1898-2083 peptides in solution, separately, included helices that were not paired with other helices in the absence of their binding partners. However, in a mixture of Sp alpha 1-156 and Sp beta 1898-2083 and formation of the alpha beta complex, the unpaired helices associated to form coiled coils. Since the sequences of these two peptides that are involved in the coiled coil association are derived from a native protein, the information obtained from this study also provides insight toward a better understanding of naturally occurring coiled coil subunit-subunit association.     

Proteolytic Activity of the MMGP1 Antifungal Peptide Derived from Marine Metagenome

An antifungal peptide, MMGP1 with direct cell penetrating property was recently reported from marine metagenome. The peptide showed efficient in vitro proteolytic activity, which could be associated with its antifungal activity. The proteolytic activity of MMGP1 was confirmed by tricine SDS-PAGE and gel filtration chromatography. Liquid chromatography-mass spectrometry analysis of MMGP1 treated bovine serum albumin (BSA), RNaseA and casein substrates revealed that the peptide does not have common cleavage position and it cleaves the substrates non-specifically at all peptide bonds. The proteolytic activity of MMGP1 was enhanced in the presence of Mn²⁺. Molecular docking studies revealed that the predicted active site residues of MMGP1 could interact with BSA, RNaseA and casein.     

A Monte Carlo Study of the Relative Stability of Protein Helical Forms

We present simulation results on a simple model to describe the hydrogen bonding in proteins with helical structures. The approximation distinguishes between ! helices, where each amino acid interacts with another one located four residues apart, 3 10 structures, where the number of amino acids in between is three, and the ? arrangement, in which that number is five. We found that the main features of the system are determined by the most stable structure (the ! helix) and that the other type of hydrogen bonds appears just below the denaturation temperature of the peptide. The probability of finding a 3 10 -type bond is greater at the beginning or at the end of the peptide chain, irrespectively of its length, while in short peptides the existence of those bonds increases appreciably the denaturation temperature, promoting stability. On the other hand, the temperature of denaturation decreases with the length of the peptide to reach a value independent of the number of amino acid residues.     

Mapping and analysis of the lytic and fusogenic domains of surfactant protein B

Surfactant protein B (SP-B) is a hydrophobic, 79 amino acid peptide that regulates the structure and function of surfactant phospholipid membranes in the airspaces of the lung. Addition of SP-B to liposomes composed of DPPC/PG (7:3) leads to membrane binding, destabilization, and fusion, ultimately resulting in rearrangement of membrane structure. The goal of this study was to map the fusogenic and lytic domains of SP-B and assess the effects of altered fusion and lysis on surface activity. Synthetic peptides were generated to predicted helices and/or interhelical loops of SP-B and tested for fusion, lytic, and surface activities. The N-terminal half of SP-B (residues 1-37), which includes the nonhelical N-terminal amino acids in addition to helices 1 and 2, promoted rapid liposome fusion whereas shorter peptides were significantly less effective. The requirements for optimal surface tension reduction were similar to those for fusion; in contrast, helix 1 (residues 7-22) alone was sufficient for liposome lysis. The C-terminal half of SP-B (residues 43-79), which includes helices 3, 4, and 5, exhibited significantly lower levels of fusogenic, lytic, and surface tension reducing activities compared to the N-terminal region. These results indicate that SP-B fusion, lytic and surface activities map predominantly to the N-terminal half of SP-B. Amino acid substitutions in synthetic peptides corresponding to the N-terminal half of SP-B indicated that, in general, decreased fusion or lytic activities were associated with altered surface tension reducing properties of the peptide. However, the presence of fusion and lytic activities alone could not account for the surface tension reducing property of SP-B. We propose a model in which association of helix 1 with lipids leads to membrane permeabilization but not aggregation; helix 2 mediates membrane cross-linking (aggregation), which, in turn, facilitates lipid mixing, membrane fusion, and interfacial adsorption/surface tension reduction.     

Antifungal activity of a de novo synthetic peptide and derivatives against fungal food contaminants

The development of novel solutions to fight microbial food contaminants rests upon two pillars, which are the development of resistant strains and consumers' desire for a reduced consumption of synthetic drugs. Natural antimicrobial peptides possess the qualities to overcome these issues. De novo synthesis of novel antifungal compounds is a major progress that has been facilitated by the identification of parameters involved in the antimicrobial activity. A 14‐residue peptide named KK14, with the sequence KKFFRAWWAPRFLK‐NH₂, was designed and inhibited conidial germination and fungal growth of food contaminants within the range 6.25 to 50 μg/ml and 6.25 to 100 μg/ml, respectively. The study of three analogues of the peptide highlighted the role of some residues in the structural conformation of the peptide and its antifungal activity. The substitution of a Pro residue with Arg increased the helical content of the peptide not only its antifungal activity but also its cytotoxicity. The insertion of an unnatural bulky residue β‐diphenylalanine or a full d ‐enantiomerization overall increased the antifungal potency. The four peptides showed similar behaviour towards salt increase, heat treatment, and pH decrease. Interestingly, the d enantiomer remained the most active at high pH and after proteolytic digestion. The four peptides did not present haemolytic activity up to 200 μg/ml but had different behaviours of cytotoxicity. These differences could be crucial for potential application as pharmaceutical or food preservatives.     

Molecular dynamics simulations of the E1/E2 transmembrane domain of the Semliki Forest virus

Transmembrane (TM) helix-helix interactions are important for virus budding and fusion. We have developed a simulation strategy that reveals the main features of the helical packing between the TM domains of the two glycoproteins E1 and E2 of the alpha-virus Semliki Forest virus and that can be extrapolated to sketch TM helical packing in other alpha-viruses. Molecular dynamics simulations were performed in wild-type and mutant peptides, both isolated and forming E1/E2 complexes. The simulations revealed that the isolated wild-type E1 peptide formed a more flexible helix than the rest of peptides and that the wild-type E1/E2 complex consists of two helices that intimately pack their N-terminals. The residues located at the interhelical interface displayed the typical motif of the left-handed coiled-coils. These were small and medium residues as Gly, Ala, Ser, and Leu, which also had the possibility to form interhelical Calpha-H...O hydrogen bonds. Results from the mutant complexes suggested that correct packing is a compromise between these residues at both E1 and E2 interhelical interfaces. This compromise allowed prediction of E1-E2 contact residues in the TM spanning domain of other alphaviruses even though the sequence identity of E2 peptides is low in this domain.     

Ion-channel formation assisted by electrostatic interhelical interactions in covalently dimerized amphiphilic helical peptides

An ultimate goal of synthetic ion-channel peptide design is to construct stable and functional ion-conducting pores. It is expected that specific interhelical interactions would facilitate the association of helices in phospholipid membranes and the successive helix-bundle formation. In the present study, we rationally designed helix-bundle ion channels using the synthetic hybrid peptide K20E20, a disulfide dimer of cationic- and anionic-amphiphilic helices Ac-CGG-(BKBA) 5-NH 2 and Ac-CGG-(BEBA) 5-NH 2. Circular dichroism (CD) measurements in aqueous media implied helix stabilization in the peptide caused by the interhelical electrostatic interactions. In addition, CD spectra recorded in the presence of DPPC liposomes and dye-leakage measurements suggested a high degree of association of peptide monomers in phospholipid membranes as well as high affinities between peptide and lipid bilayers. These features allowed ion-channel formation at extremely low peptide concentrations (as low as 1 nM). According to electrophysiological analyses, stable helix bundles were constructed of six peptide helices by association of three K20E20 molecules. Helix-helix association in lipid membranes, peptide-membrane interactions, and ion-channel formation of K20E20 peptides were all facilitated by intramolecular electrostatic interactions between the helices of the hybrid peptide and were pH-dependent. Conductance through K20E20 ion channels decreased under acidic conditions because of the interruption of the salt bridges.     

Helix packing motif common to the crystal structures of two undecapeptides containing dehydrophenylalanine residues: implications for the de novo design of helical bundle super secondary structural modules

De novo designed peptide based super secondary structures are expected to provide scaffolds for the incorporation of functional sites as in proteins. Self-association of peptide helices of similar screw sense, mediated by weak interactions, has been probed by the crystal structure determination of two closely related peptides: Ac-Gly1-Ala2-Delta Phe3-Leu4-Val5-DeltaPhe6-Leu7-Val8-DeltaPhe9-Ala10-Gly11-NH2 (I) and Ac-Gly1-Ala2-DeltaPhe3-Leu4-Ala5-DeltaPhe6-Leu7-Ala8-DeltaPhe9-Ala10-Gly11-NH2 (II). The crystal structures determined to atomic resolution and refined to R factors 8.12 and 4.01%, respectively, reveal right-handed 3(10)-helical conformations for both peptides. CD has also revealed the preferential formation of right-handed 3(10)-helical conformations for both molecules. Our aim was to critically analyze the packing of the helices in the solid state with a view to elicit clues for the design of super secondary structural motifs such as two, three, and four helical bundles based on helix-helix interactions. An important finding is that a packing motif could be identified common to both the structures, in which a given peptide helix is surrounded by six other helices reminiscent of transmembrane seven helical bundles. The outer helices are oriented either parallel or antiparallel to the central helix. The helices interact laterally through a combination of N--H...O, C--H...O, and C--H...pi hydrogen bonds. Layers of interacting leucine residues are seen in both peptide crystal structures. The packing of the peptide helices in the solid state appears to provide valuable leads for the design of super secondary structural modules such as two, three, or four helix bundles by connecting adjacent antiparallel helices through suitable linkers such as tetraglycine segments.     

Antifungal activity of C3a and C3a-derived peptides against Candida

Antimicrobial peptides are generated during activation of the complement system [Nordahl et al. Proc. Natl. Acad. Sci. U. S. A. 2004, 101:16879-16884]. Here we show that the anaphylatoxin C3a exerts antimicrobial effects against the yeast Candida. Fluorescence microscopy and electron microscopy analysis demonstrated that C3a-derived peptides bound to the cell surface of Candida, and induced membrane perturbations and release of extracellular material. Various Candida isolates were found to induce complement degradation, leading to generation of C3a. Arginine residues were found to be critical for the antifungal and membrane breaking activity of a C3a-derived antimicrobial peptide, CNY21 (C3a; Cys57-Arg77). A CNY21 variant with increased positive net charge displayed enhanced antifungal activity. Thus, C3a-derived peptides can be utilized as templates in the development of peptide-based antifungal therapies.     

Structures of the intradiskal loops and amino terminus of the G-protein receptor, rhodopsin.

The intradiskal surface of the transmembrane protein, rhodopsin, consists of the amino terminal domain and three loops connecting six of the seven transmembrane helices. This surface corresponds to the extracellular surface of other G-protein receptors. Peptides that represent each of the extramembraneous domains on this surface (three loops and the amino terminus) were synthesized. These peptides also included residues which, based on a hydrophobic plot, could be expected to be part of the transmembrane helix. The structure of each of these peptides in solution was then determined using two-dimensional 1H nuclear magnetic resonance. All peptide domains showed ordered structures in solution. The structures of each of the peptides from intradiskal loops of rhodopsin exhibited a turn in the central region of the peptide. The ends of the peptides show an unwinding of the transmembrane helices to form this turn. The amino terminal domain peptide exhibited alpha-helical regions with breaks and bends at proline residues. This region forms a compact domain. Together, the structures for the loop and amino terminus domains indicate that the intradiskal surface of rhodopsin is ordered. These data further suggest a structural motif for short loops in transmembrane proteins. The ordered structures of these loops, in the absence of the transmembrane helices, indicate that the primary sequences of these loops are sufficient to code for the turn.     

抗真菌肽研究进展

有害真菌已造成植物真菌病害、食物污染和人类真菌感染等问题,给人们的生活和生产带来极大危害,且其逐渐增加对抗真菌药物的耐药性,导致真菌防治日益困难。传统的合成类抗真菌药物具有药物残留和毒副作用,已不能满足需求,作为生物机体天然防御分子的抗真菌肽已成为应对真菌危害及耐药性的重要研究对象。抗真菌肽能够抑制有害真菌,具有高效、广谱、安全的特性,且其独特的抑菌机理解决了真菌耐药性的问题,在真菌防治中逐渐受到关注。基于此,主要从真菌的危害以及抗真菌肽的来源、分离纯化方法、抑菌机理等几个方面进行分析与论述,以期为抗真菌肽的研究提供参考。     

Design and synthesis of peptides capable of specific binding to DNA

In the present communication, design, synthesis and DNA binding activities of the following two peptides are reported: Dns-Gly-Ala-Gln-Lys-Leu-Ala-Cly-Lys-Val-Gly-Thr-Lys-Val-Lys-Val-Gl y-Thr-Lys-Thr - Val-OH (I) and [(H-Ala-Lys-Leu-Ala-Thr-Lys-Ala-Gly-Val-Lys-Gln-Gln-Ser-Ile-Gln-Leu-Ile- Thr- Ala-Aca-Lys-Aca)2Lys-Aca]2Lys-Val-OH (II), where Aca = NH(CH2)5CO--; Dns is a residue of 5-dimethylaminonaphtalene-1-sulfonic acid. Peptide I contains a large fraction (ca.30%) of valyl and threonyl residues, which possess a high potential for beta structure formation. Peptide II contains four repeats of the amino acid sequence present in the presumed DNA binding helix-turn-helix unit of 434 Cro repressor. These four domains are linked in such a way that two domains can interact with two halves a 14 base pair long operator site on DNA. From CD studies we have found that peptide I is in a random coil conformation in the aqueous solution in the presence of 20% trifluoroethanol. By contrast, amino acid residues of peptide II assume alpha helical, beta and random coiled conformations under the same conditions. A change in the secondary structure of the two peptides upon binding to DNA is observed. The difference CD spectra obtained by subtracting the spectra of free DNA from the spectra of peptide I--DNA complexes gives rise to a beta-like pattern. The difference CD spectra obtained for complexes of peptide II with various natural and synthetic DNAs suggest that alpha-beta-transition takes place in the presumed helix-turn-helix repeat units of peptide II upon binding to DNA. Peptide I binds more strongly to poly(dG).poly(dC) than to poly(dA).poly(dT) and poly[d(GC)].poly[d(GC)]. The binding takes place in the minor DNA groove because minor groove binding antibiotic sibiromycin can displace peptide I from a complex with poly(dG).poly(dC). Analysis of footprinting diagramms shows that peptide I specifically protects phosphodiester bonds within operator sites OR1 and OR2 of phage lambda from nuclease cleavage. By contrast, peptide II does not react specifically with operators OR1, OR2 and OR3 of phage 434 although it forms very tight complexes with DNA which are stable in the presence of 1M NH4F.     

Crystal structure of the amino-terminal coiled-coil domain of the APC tumor suppressor

Coiled coils serve as dimerization domains for a wide variety of proteins, including the medically important oligomeric tumor suppressor protein, APC. Mutations in the APC gene are associated with an inherited susceptibility to colon cancer and with approximately 75 % of sporadic colorectal tumors. To define the basis for APC pairing and to explore the anatomy of dimeric coiled coils, we determined the 2.4 A resolution X-ray crystal structure of the N-terminal dimerization domain of APC. The peptide APC-55, encompassing the heptad repeats in APC residues 2-55, primarily forms an alpha-helical, coiled-coil dimer with newly observed core packing features. Correlated asymmetric packing of four core residues in distinct, standard rotamers is associated with a small shift in the helix register. At the C terminus, the helices splay apart and interact with a symmetry-related dimer in the crystal to form a short, anti-parallel, four-helix bundle. N-terminal fraying and C-terminal splaying of the helices, as well as the asymmetry and helix register shift describe unprecedented dynamic excursions of coiled coils. The low stability of APC-55 and divergence from the expected coiled-coil fold support the suggestion that the APC dimerization domain may extend beyond the first 55 residues.     

"De novo" design of peptides with specific lipid-binding properties

In this study, we describe an in silico method to design peptides that can be made of non-natural amino acids and elicit specific membrane-interacting properties. The originality of the method holds in the capacities developed to design peptides from any non-natural amino acids as easily as from natural ones, and to test the structure stability by an angular dynamics rather than the currently-used molecular dynamics. The goal of this study was to design a non-natural tilted peptide. Tilted peptides are short protein fragments able to destabilize lipid membranes and characterized by an asymmetric distribution of hydrophobic residues along their helix structure axis. The method is based on the random generation of peptides and their selection on three main criteria: mean hydrophobicity and the presence of at least one polar residue; tilted insertion at the level of the acyl chains of lipids of a membrane; and conformational stability in that hydrophobic phase. From 10,000,000 randomly-generated peptides, four met all the criteria. One was synthesized and tested for its lipid-destabilizing properties. Biophysical assays showed that the "de novo" peptide made of non-natural amino acids is helical either in solution or into lipids as tested by Fourier transform infrared spectroscopy and is able to induce liposome fusion. These results are in agreement with the calculations and validate the theoretical approach.     

Effects of chain length on the aggregation of model polyglutamine peptides: molecular dynamics simulations

Aggregation in the brain of polyglutamine-containing proteins is either a cause or an associated symptom of nine hereditary neurodegenerative disorders including Huntington's disease. The molecular level mechanisms by which these proteins aggregate are still unclear. In an effort to shed light on this important phenomenon, we are investigating the aggregation of model polyglutamine peptides using molecular-level computer simulation with a simplified model of polyglutamine that we have developed. This model accounts for the most important types of intra- and inter-molecular interactions-hydrogen bonding and hydrophobic interactions-while allowing the folding process to be simulated in a reasonable time frame. The model is used to examine the folding of isolated polyglutamine peptides 16, 32, and 48 residues long and the folding and aggregation of systems of 24 model polyglutamine peptides 16, 24, 32, 36, 40, and 48 residues long. Although the isolated polyglutamine peptides did form some alpha and beta backbone-backbone hydrogen bonds they did not have as many of these bonds as they would have if they had folded into a complete alpha helix or beta sheet. In one of the simulations on the isolated polyglutamine peptide 48 residues long, we observed a structure that resembles a beta helix. In the multi-chain simulations we observed amorphous aggregates at low temperatures, ordered aggregates with significant beta sheet character at intermediate temperatures, and random coils at high temperatures. We have found that the temperature at which the model peptides undergo the transition from amorphous aggregates to ordered aggregates and the temperature at which the model peptides undergo the transition from ordered aggregates to random coils increase with increasing chain length. Our finding that the stability of the ordered aggregates increases as the peptide chain length increases may help to explain the experimentally observed relation between polyglutamine tract length and aggregation in vitro and disease progression in vivo. We have also observed in our simulations that the optimal temperature for the formation of beta sheets increases with chain length up to 36 glutamine residues but not beyond. Equivalently, at fixed temperature we find a transition from a region dominated by random coils at chain lengths less than 36 to a region dominated by relatively ordered beta sheet structures at chain lengths greater than 36. Our finding of this critical chain length of 36 glutamine residues is interesting because a critical chain length of 37 glutamine residues has been observed experimentally.