Left handed alpha-helix formation by a bacterial peptide

The alpha-helix is a common element of secondary structure in proteins and peptides. In eukaryotic organisms, which exclusively incorporate L-amino acids into such molecules, stereochemical interactions make such alpha-helices, invariably right-handed. Pseudomonas tolaasii Paine is the causal organism of the economically significant brown blotch disease of the cultivated mushroom Agaricus bisporus (Lange) Imbach. P. Tolaasii proceduces an extracellular lipodepsipeptide toxin, tolaasin, which causes the brown pitted lesions on the mushroom cap. Circular dichroism studies on tolaasin in a membrane-like environment indicate the presence of a left-handed alpha-helix, probably formed by a sequence of 7 D-amino acids in the peptide. P. tolaasii represents the first reported example of an organism which has evolved the ability to biosynthesize a left-handed alpha-helix.     

Dissecting the energetics of protein alpha-helix C-cap termination through chemical protein synthesis

The alpha-helix is a fundamental protein structural motif and is frequently terminated by a glycine residue. Explanations for the predominance of glycine at the C-cap terminal portions of alpha-helices have invoked uniquely favorable energetics of this residue in a left-handed conformation or enhanced solvation of the peptide backbone because of the absence of a side chain. Attempts to quantify the contributions of these two effects have been made previously, but the issue remains unresolved. Here we have used chemical protein synthesis to dissect the energetic basis of alpha-helix termination by comparing a series of ubiquitin variants containing an L-amino acid or the corresponding D-amino acid at the C-cap Gly35 position. D-Amino acids can adopt a left-handed conformation without energetic penalty, so the contributions of conformational strain and backbone solvation can thus be separated. Analysis of the thermodynamic data revealed that the preference for glycine at the C' position of a helix is predominantly a conformational effect.     

Purification of a pore-forming peptide toxin, tolaasin, produced by Pseudomonas tolaasii 6264

Tolaasin, a pore-forming peptide toxin, is produced by Pseudomonas tolaasii and causes brown blotch disease of the cultivated mushrooms. P. tolaasii 6264 was isolated from the oyster mushroom damaged by the disease in Korean. In order to isolate tolaasin molecules, the supernatant of bacterial culture was harvested at the stationary phase of growth. Tolaasin was prepared by ammonium sulfate precipitation and three steps of chromatograpies, including a gel permeation and two ion exchange chromatographies. Specific hemolytic activity of tolaasin was increased from 1.7 to 162.0 HU mg(-1) protein, a 98-fold increase, and the purification yield was 16.3%. Tolaasin preparation obtained at each purification step was analyzed by HPLC and SDS-PAGE. Two major peptides were detected from all chromatographic preparations. Their molecular masses were analyzed by MALDI-TOF mass spectrometry and they were identified as tolaasin I and tolaasin II. These results demonstrate that the method used in this study is simple, time-saving, and successful for the preparation of tolaasin.     

In silico study of the ion channel formed by tolaasin I produced by Pseudomonas tolaasii

A toxin produced by Pseudomonas tolaasii, tolaasin, causes brown blotch disease in mushrooms. Tolaasin forms pores on the cellular membrane and destroys cell structure. Inhibiting the ability of tolaasin to form ion channels may be an effective method to protect against attack by tolaasin. However, it is first necessary to elucidate the three-dimensional structure of the ion channels formed by tolaasin. In this study, the structure of the tolaasin ion channel was determined in silico based on data obtained from nuclear magnetic resonance experiments.     

Temperature‐dependent hemolytic activity of membrane pore‐forming peptide toxin,tolaasin

Tolaasin, a pore‐forming peptide toxin produced by Pseudomonas tolaasii, causes brown blotch disease on cultivated mushrooms. Hemolysis using red blood cells was measured to evaluate the cytotoxicity of tolaasin. To investigate the mechanism of tolaasin‐induced cell disruption, we studied the effect of temperature on the hemolytic process. At 4 °C, poor binding of the tolaasin molecules to the erythrocyte membrane was observed and most of the tolaasin molecules stayed in the solution. However, once tolaasin bound to erythrocytes at 37 °C and the temperature was decreased, complete hemolysis was observed even at 4 °C. These results indicate that tolaasin binding to cell membrane is temperature‐sensitive while tolaasin‐induced membrane disruption is less sensitive to temperature change. The effect of erythrocyte concentration was measured to understand the membrane binding and pore‐forming properties of tolaasin. The percentage of hemolysis measured by both hemoglobin release and cell lysis decreased as erythrocyte concentration increased in the presence of a fixed amount of tolaasin. The result shows that hemolysis is dependent on the amount of tolaasin and multiple binding of tolaasin is required for the hemolysis of a single cell. In analysis of dose‐dependence, the hemolysis was proportional to the tenth power of the amount of tolaasin, implying that tolaasin‐induced hemolysis can be explained by a multi‐hit model. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

Effect of Sequence and Stereochemistry Reversal on p53 Peptide Mimicry

Peptidomimetics effective in modulating protein-protein interactions and resistant to proteolysis have potential in therapeutic applications. An appealing yet underperforming peptidomimetic strategy is to employ D-amino acids and reversed sequences to mimic a lead peptide conformation, either separately or as the combined retro-inverso peptide. In this work, we examine the conformations of inverse, reverse and retro-inverso peptides of p53(15–29) using implicit solvent molecular dynamics simulation and circular dichroism spectroscopy. In order to obtain converged ensembles for the peptides, we find enhanced sampling is required via the replica exchange molecular dynamics method. From these replica exchange simulations, the D-peptide analogues of p53(15–29) result in a predominantly left-handed helical conformation. When the parent sequence is reversed sequence as either the L-peptide and D-peptide, these peptides display a greater helical propensity, feature reflected by NMR and CD studies in TFE/water solvent. The simulations also indicate that, while approximately similar orientations of the side-chains are possible by the peptide analogues, their ability to mimic the parent peptide is severely compromised by backbone orientation (for D-amino acids) and side-chain orientation (for reversed sequences). A retro-inverso peptide is disadvantaged as a mimic in both aspects, and further chemical modification is required to enable this concept to be used fruitfully in peptidomimetic design. The replica exchange molecular simulation approach adopted here, with its ability to provide detailed conformational insights into modified peptides, has potential as a tool to guide structure-based design of new improved peptidomimetics.     

Two types of ion channel formation of tolaasin,a Pseudomonas peptide toxin

Tolaasin is a peptide toxin produced by Pseudomonas tolaasii and causes brown blotch disease of the cultivated mushrooms. Two types of ion channels were identified by the incorporation of tolaasin into lipid bilayer. The slope conductance of type 1 channel measured in the buffer containing 100 mM KCl was 150 pS with a linear current vs. voltage relationship. The type 2 tolaasin channel had two subconductance states of 300 and 500 pS. Both channels were inhibited by Zn(2+). Ion channel formations of tolaasin were concentration-dependent and single channel currents were successfully obtained at 0.6 unit tolaasin, 15.9 nM. The type 1 channel was obtained more frequently than the type 2 channel and the ratio of their appearance was approximately 4:1, respectively.     

Mirrors in the PDB: left-handed α-turns guide design with D-amino acids

Background  

Incorporating variable amino acid stereochemistry in molecular design has the potential to improve existing protein stability and create new topologies inaccessible to homochiral molecules. The Protein Data Bank has been a reliable, rich source of information on molecular interactions and their role in protein stability and structure. D-amino acids rarely occur naturally, making it difficult to infer general rules for how they would be tolerated in proteins through an analysis of existing protein structures. However, protein elements containing short left-handed turns and helices turn out to contain useful information. Molecular mechanisms used in proteins to stabilize left-handed elements by L-amino acids are structurally enantiomeric to potential synthetic strategies for stabilizing right-handed elements with D-amino acids.     

Stabilization of an alpha-helical conformation in an isolated hexapeptide inhibitor of calmodulin.

The conformational properties of two hexapeptides, Ac-LWRILW-NH(2) and its D-amino acid counterpart Ac-lwrilw-NH(2), identified as calmodulin inhibitors using mixture-based synthetic combinatorial library approaches, have been characterised by NMR and CD spectroscopy. The peptides fold into an alpha-helical conformation in aqueous solution. The observed short- and medium-range nuclear Overhauser effects were consistent with the formation of an alpha-helical structure and a reasonably well-defined set of structures was obtained by using restraints from the NMR data in simulated annealing calculations. Analysis of glycine-substitution analogues demonstrated that all the amino acids that make up the peptide sequence are important for the stabilization of the alpha-helical conformation. The results suggest that a well-defined set of interactions is indispensable to allow alpha-helix formation in this short hexapeptide.     

The significance of D-amino acids in soil, fate and utilization by microbes and plants: review and identification of knowledge gaps

Background

D-amino acids are far less abundant in nature than L-amino acids. Both L- and D-amino acids enter soil from different sources including plant, animal and microbial biomass, antibiotics, faeces and synthetic insecticides. Moreover, D-amino acids appear in soil due to abiotic or biotic racemization of L-amino acids. Both L- and D-amino acids occur as bound in soil organic matter and as “free“ amino acids dissolved in soil solution or exchangeably bound to soil colloids. D-amino acids are mineralized at slower rates compared to the corresponding L-enantiomers. Plants have a capacity to directly take up “free“ D-amino acids by their roots but their ability to utilize them is low and thus D-amino acids inhibit plant growth.

Scope

The aim of this work is to review current knowledge on D-amino acids in soil and their utilization by soil microorganisms and plants, and to identify critical knowledge gaps and directions for future research.

Conclusion

Assessment of “free“ D-amino acids in soils is currently complicated due to the lack of appropriate extraction procedures. This information is necessary for consequent experimental determination of their significance for crop production and growth of plants in different types of managed and unmanaged ecosystems. Hypotheses on occurrence of “free“ D-amino acids in soil are presented in this review.     

Molecular dynamics simulations of polypeptide conformations in water: A comparison of alpha, beta, and poly(pro)II conformations.

A significant fraction of the so-called "random coil" residues in globular proteins exists in the left-handed poly(Pro)II conformation. In order to compare the behavior of this secondary structure with that of the other regular secondary structures, molecular dynamics simulations, with the GROMOS suite of programs, of an alanine octapeptide in water, in alpha-helix, beta-strand, and left-handed poly(Pro)II conformations, have been performed. Our results indicate a limited flexibility for the alpha-helix conformation and a relatively larger flexibility for the beta-strand and poly(Pro)II conformations. The behavior of oligopeptides with a starting configuration of beta-strand and poly(Pro)II conformations, both lacking interchain hydrogen bonds, were similar. The (phi, psi) angles reflect a continuum of structures including both beta and P(II) conformations, but with a preference for local P(II) regions. Differences in the network of water molecules involved in hydrogen bonding with the backbone of the polypeptide were observed in local regions of beta and P(II) conformations. Such water bridges help stabilize the P(II) conformation relative to the beta conformation. Proteins 1999;36:400-406.     

Regulation of Gi by the CB1 cannabinoid receptor C-terminal juxtamembrane region: structural requirements determined by peptide analysis

A CB1 cannabinoid receptor peptide fragment from the C-terminal juxtamembrane region autonomously inhibits adenylyl cyclase activity in a neuroblastoma membrane preparation. The cannabinoid receptor antagonist, SR141716A, failed to block the response. The peptide was able to evoke the response in membranes from Chinese hamster ovary (CHO) cells that do not express the CB1 receptor. These studies are consistent with a direct activation of Gi by the peptide. To test the importance of a BXBXXB sequence, Lys403 was acetylated, resulting in a peptide having similar affinity but reduced efficacy. N-Terminal truncation of Arg401 resulted in a 6-fold loss of affinity, which was not further reduced by sequential truncation of up to the first seven amino acids, four of which are charged. N-Terminal-truncated peptides exhibited maximal activity, suggesting that Gi activation can be conferred by the remaining amino acids. Truncation of the C-terminal Glu417 or substitution of Glu417 by a Leu or of Arg401 by a Norleucine reduced activity at 100 microM. The C-terminal juxtamembrane peptide was constrained to a loop peptide by placement of Cys residues at both terminals and disulfide coupling. This modification reduced the affinity 3-fold but yielded near-maximal efficacy. Blocking the Cys termini resulted in a loss of efficacy. Circular dichroism spectropolarimetry revealed that all C-terminal juxtamembrane peptide analogues exist in a random coil conformation in an aqueous environment. A hydrophobic environment (trifluoroethanol) failed to induce alpha-helix formation in the C-terminal juxtamembrane peptide but did so in less active peptides. The anionic detergent sodium dodecyl sulfate induced alpha-helix formation in all analogues except the loop peptide, where it induces a left-handed PII conformation. It is concluded that alpha-helix formation is not required for Gi activation.     

Exploring the sequence patterns in the alpha-helices of proteins

This paper reports an extensive sequence analysis of the alpha-helices of proteins. alpha-Helices were extracted from the Protein Data Bank (PDB) and were divided into groups according to their sizes. It was found that some amino acids had differential propensity values for adopting helical conformation in short, medium and long alpha-helices. Pro and Trp had a significantly higher propensity for helical conformation in short helices than in medium and long helices. Trp was the strongest helix conformer in short helices. Sequence patterns favoring helical conformation were derived from a neighbor-dependent sequence analysis of proteins, which calculated the effect of neighboring amino acid type on the propensity of residues for adopting a particular secondary structure in proteins. This method produced an enhanced statistical significance scale that allowed us to explore the positional preference of amino acids for alpha-helical conformations. It was shown that the amino acid pair preference for alpha-helix had a unique pattern and this pattern was not always predictable by assuming proportional contributions from the individual propensity values of the amino acids. Our analysis also yielded a series of amino acid dyads that showed preference for alpha-helix conformation. The data presented in this study, along with our previous study on loop sequences of proteins, should prove useful for developing potential 'codes' for recognizing sequence patterns that are favorable for specific secondary structural elements in proteins.     

Theoretical approaches to D-amino acid oxidase

Several substrates and roles have been proposed for D-amino acid oxidase (E.C. 1.4.3.3.); however, there is no proof that they possess the required characteristics to account for the ubiquity, large amounts and great activity of the enzyme as found in diverse cells and tissues. Based on the similar stereoposition of identically charged atoms and lateral side chain (R) with respect to the alpha-hydrogen atoms in beta-sheet conformation and in D-amino acids, it is proposed that its substrates may include several membrane-related proteins, partially in beta-sheet conformation, whose alpha-hydrogen atoms would be the real object of D-amino acid oxidase catalysis. A monooxygenase-like enzymatic activity of D-amino acid oxidase with these novel substrates is considered, for which the final products are hypothesized to be protein alpha-carbon hydroxyls resulting from the incorporation of one atom of oxygen into the substrate, the other being reduced to water. Alternatively, it is also proposed that D-amino acid oxidase (and possibly other monooxygenase enzymes) would have a hydroperoxide-synthetase activity. In this case, protein alpha-carbon hydroperoxide and not water, but another reduced molecule, would be the final products. The new enzymatic performances of D-amino acid oxidase and the possible role of its potential final products in redox and other biochemical processes are discussed.     

Structural dynamic of a self-assembling peptide d-EAK16 made of only D-amino acids

We here report systematic study of structural dynamics of a 16-residue self-assembling peptide d-EAK16 made of only D-amino acids. We compare these results with its chiral counterpart L-form, l-EAK16. Circular dichroism was used to follow the structural dynamics under various temperature and pH conditions. At 25 degrees C the d-EAK16 peptide displayed a typical beta-sheet spectrum. Upon increasing the temperature above 70 degrees C, there was a spectrum shift as the 218 nm valley widens toward 210 nm. Above 80 degrees C, the d-EAK16 peptide transformed into a typical alpha-helix CD spectrum without going through a detectable random-coil intermediate. When increasing the temperature from 4 degrees C to 110 degrees C then cooling back from 110 degrees C to 4 degrees C, there was a hysteresis: the secondary structure from beta-sheet to alpha-helix and then from alpha-helix to beta-sheet occurred. d-EAK16 formed an alpha-helical conformation at pH0.76 and pH12 but formed a beta-sheet at neutral pH. The effects of various pH conditions, ionic strength and denaturing agents were also noted. Since D-form peptides are resistant to natural enzyme degradation, such drastic structural changes may be exploited for fabricating molecular sensors to detect minute environmental changes. This provides insight into the behaviors of self-assembling peptides made of D-amino acids and points the way to designing new peptide materials for biomedical engineering and nanobiotechnology.     

Peptide design using alpha,beta-dehydro amino acids: from beta-turns to helical hairpins

Incorporation of alpha,beta-dehydrophenylalanine (DeltaPhe) residue in peptides induces folded conformations: beta-turns in short peptides and 3(10)-helices in larger ones. A few exceptions-namely, alpha-helix or flat beta-bend ribbon structures-have also been reported in a few cases. The most favorable conformation of DeltaPhe residues are (phi,psi) approximately (-60 degrees, -30 degrees ), (-60 degrees, 150 degrees ), (80 degrees, 0 degrees ) or their enantiomers. DeltaPhe is an achiral and planar residue. These features have been exploited in designing DeltaPhe zippers and helix-turn-helix motifs. DeltaPhe can be incorporated in both right and left-handed helices. In fact, consecutive occurrence of three or more DeltaPhe amino acids induce left-handed screw sense in peptides containing L-amino acids. Weak interactions involving the DeltaPhe residue play an important role in molecular association. The C--H.O==C hydrogen bond between the DeltaPhe side-chain and backbone carboxyl moiety, pi-pi stacking interactions between DeltaPhe side chains belonging to enantiomeric helices have shown to stabilize folding. The unusual capability of a DeltaPhe ring to form the hub of multicentered interactions namely, a donor in aromatic C--H.pi and C--H.O==C and an acceptor in a CH(3).pi interaction suggests its exploitation in introducing long-range interactions in the folding of supersecondary structures.     

In vitro stability of alpha-helical peptide nucleic acids (alphaPNAs)

Alpha-helical peptide nucleic acids (alphaPNAs) are synthetic molecules that merge the alpha-helix secondary structure of peptides with the codified Watson-Crick base pairing capability of nucleic acids. It is now demonstrated that alphaPNAs made up of either L- or D-amino acids are resistant to degradation by the proteases present in human serum. The increased stability of alphaPNAs towards proteases may be attributable to the presence of unnatural nucleoamino acid residues [-NHCH(CH(2)OCH(2)B)CO-, where B=thymine or cytosine] since the replacement of these amino acids by serine yields a control peptide that does break down in human serum. The stability of alphaPNAs towards proteases makes them attractive candidates for further development as antisense agents.     

D构象丝氨酸在中枢神经系统中的功能研究进展

哺乳动物中枢神经系统中D构象丝氨酸的区域性高浓度分布与N-甲基-D-天冬氨酸(NMDA)受体相一致.它主要由丝氨酸消旋酶将L丝氨酸直接消旋而来,也可能通过肠道菌群产生后吸收至体内,最终被D构象氨基酸氧化酶氧化.这种从胶质细胞而非神经元来源的“异常”构象氨基酸作为一种新型神经递质,不仅更新了传统“神经递质”的定义,而且为许多与NMDA受体过度兴奋或表达下调相关的神经系统疾病治疗提出了新的线索.     

The primary structure of D-amino acid oxidase from Rhodotorula gracilis

Summary The amino acid sequence of D-amino acid oxidase from Rhodotorula gracilis was determined by automated Edman degradation of peptides generated by enzymatic and chemical cleavage. The enzyme monomer contains 368 amino acid residues and its sequence is homologous to that of other known D-amino acid oxidases. Six highly conserved regions appear to have a specific role in binding of coenzyme FAD, in active site topology and in peroxisomal targeting. Moreover, Rhodotorula gracilis D-amino acid oxidase contains a region with a cluster of basic amino acids, probably exposed to solvent, which is absent in other D-amino acid oxidases.     

Hendecad repeat in segment 2A and linker L2 of intermediate filament chains implies the possibility of a right-handed coiled-coil structure

The conformation adopted by intermediate filament chains (IF) has been described in terms of a central rod domain with four, alpha-helical, left-handed coiled-coil segments (1A, 1B, 2A, and 2B) joined by linkers (L1, L12, and L2, respectively). The rod domain is terminated at its N- and C-terminal ends by "globular" head and tail domains, respectively. This analysis, initially undertaken about 20-25 years ago, was based on the recognition of an underlying heptad substructure in the sequence of the rod domain, the presence of which can be directly associated with an alpha-helical coiled-coil structure. In this work, a hendecad sequence motif that is closely related to the heptad repeat but which is nonetheless significantly different from it has been recognized in the primary structure of segments 2A and linker L2. This motif, which is 11 residues long and structurally equivalent to a true heptad plus another heptad with an inclusive stutter, is consistent with the chains adopting a continuous right-handed coiled-coil structure with a long-period pitch length. It is therefore predicted that segment 2 as a whole may have a coiled-coil conformation with both right-handed (2A+L2) and left-handed (2B) regions. The changeover in handedness would be expected to occur at the C-terminal end of linker L2 and N-terminal end of segment 2B.