Degradation of neurotensin by rabbit brain endo-oligopeptidase A and endo-oligopeptidase B (proline-endopeptidase)

The degradation of neurotensin and D-Tyr11 neurotensin by apparently homogeneous preparations of rabbit brain endo-oligopeptidase A and endo-oligopeptidase B (Proline-endopeptidase) was studied. Peptide fragments were isolated by high performance liquid chromatography and identified by amino acid analysis. Endo-oligopeptidase A cleaved neurotensin at the Arg8-Arg9 bond whereas D-Tyr11 neurotensin was not significantly hydrolysed. Endo-oligopeptidase B cleaved at the carboxyl side of Pro7, Pro10 in neurotensin and at Pro7 in D-Tyr11 neurotensin. The concentration dependent inhibition of neurotensin degradation by bradykinin and vice-versa represents additional evidence that endo-oligopeptidase A cleaves both Phe5-Ser6 bond of bradykinin and the Arg8-Arg9 bond of neurotensin.     

A systematic evaluation of different hydrogen bonding patterns in unsymmetrical 1,n′-disubstituted ferrocenoyl peptides

The synthesis and spectroscopic characterization of 21 l,l′-disubstituted ferrocenoyl peptides of the general formula [Fe(C₅H₄-CO-Aal-OR) (C₅H₄-CO-Aa2-OR′)] is reported, with Aal and Aa2 being different amino acids. The one-pot synthesis from activated ferrocene-l,l′-dicarboxylic acid and two different amino acid esters gives the unsymmetrical ferrocenoyl peptides in yields between 27% and 42%, which can be easily separated from their symmetrical byproducts by column chromatography. All new compounds are comprehensively characterized by mass spectrometry (El and FAB, including high-resolution EI-MS), ¹H and ¹³C NMR, and UV/Vis spectroscopy. CD spectroscopy in conjunction with ¹H NMR is used to elucidate the solution structures. Using the achiral glycine (Gly) as Aal permits to determine qualitatively the structure-determining influence of the different amino acids Aa2. Helically chiral structures in ferrocene amino acids in this study are stabilized by hydrogen bonds. If one hydrogen bond partner is systematically moved away by the introduction of methylene groups, then indeed the strength of the hydrogen bond decreases as indicated by ¹H NMR chemical shifts of the amide protons and the strength of characteristic CD bands. As proline (Pro) is the only naturally accuring secondary amino acid it cannot contribute any amide proton to intra-strand hydrogen bonding. DFT calculations on the compound [Fe(C₅H₄-CO-Gly-OMe)(C₅H₄-CO-Pro-OMe)] with one achiral and one secondary amino acid were therefore performed to quantify the more subtle influence of the relative orientations of the ferrocene carbonyl groups and the cis-/trans-conformation of both amide bonds. Not unexpectedly, the conformations with both amide bonds in cis orientation are highest in energy. Surprisingly, the calculations suggest the presence of a low-energy conformation with a non-classical hydrogen bond between the proline ester carbonyl oxygen and a glycine H_α atom. However, a second conformation with no apparent intra-strand contacts but optimal positioning of all relevant groups is similar in energy. Although two conformations were observed in solution for this compound, the experimental data did not permit to assign those two conformations.     

Biosynthesis of bacillomycin D by Bacillus subtilis. Evidence for amino acid-activating enzymes by the use of affinity chromatography.

Bacillomycin D is an antifungal lipopeptide produced by B. subtilis. The formation of the peptidyl bonds of bacillomycin D occurs non-ribosomally, as demonstrated by the use of chloramphenicol, an inhibitor of protein biosynthesis. Amino acid-activating enzymes were found in B. subtilis cell lysates purified by affinity chromatography on a gel containing L-Pro, an amino acid of bacillomycin D. Presence of ATP during this purification increases the binding of enzymatic proteins and their activity. An enzyme, with an apparent molecular weight of 230 kDa, catalyzed ATP-PPi exchange reactions, which were mediated by specific amino acids, corresponding to a partial sequence of bacillomycin D.     

Antimicrobial activities of amino acid derivatives of monascus pigments

Amino acid derivatives of monascus pigments were produced by fermentation, and their antimicrobial activities were determined. Thirty-nine l- and d-forms of amino acids were added as a precursor to the fermentation medium for derivation of pigments. Derivatives with L-Phe, D-Phe, L-Tyr, and D-Tyr exhibited high activities against Gram(+) and Gram(-) bacteria with MIC values of c. 4-8 microg mL(-1). The control red pigment exhibited minimal inhibitory concentration (MIC) values higher than 32 microg mL(-1). Derivatives with L-Asp, D-Asp, L-Tyr, and D-Tyr were effective against the filamentous fungi Aspergillus niger, Penicillium citrinum, and Candida albicans. Monascus derivatives of amino acids having a phenyl ring like Phe and Tyr derivatives showed high antimicrobial activities. Incubation of the l-Phe derivative with Bacillus subtilis caused cells to aggregate with formation of pellets. Easy adsorption of the L-Phe pigment derivative to the surface of Escherichia coli cells was observed via SEM and TEM. Addition of monascus pigment derivatives decreased the oxygen uptake rate of E. coli in culture. The antimicrobial activities of pigment derivatives are considered to be related to the reduced availability of oxygen for the cells adsorbed with pigment.     

Asymmetric recognition of DNA local distortion. Structure-based functional studies of eukaryotic Msh2-Msh6

Crystal structures of bacterial MutS homodimers bound to mismatched DNA reveal asymmetric interactions of the two subunits with DNA. A phenylalanine and glutamate of one subunit make mismatched base-specific interactions, and residues of both subunits contact the DNA backbone surrounding the mismatched base, but asymmetrically. A number of amino acids in MutS that contact the DNA are conserved in the eukaryotic Msh2-Msh6 heterodimer. We report here that yeast strains with amino acids substituted for residues inferred to interact with the DNA backbone or mismatched base have elevated spontaneous mutation rates consistent with defective mismatch repair. Purified Msh2-Msh6 with substitutions in the conserved Phe(337) and Glu(339) in Msh6 thought to stack or hydrogen bond, respectively, with the mismatched base do have reduced DNA binding affinity but normal ATPase activity. Moreover, wild-type Msh2-Msh6 binds with lower affinity to mismatches with thymine replaced by difluorotoluene, which lacks the ability to hydrogen bond. The results suggest that yeast Msh2-Msh6 interacts asymmetrically with the DNA through base-specific stacking and hydrogen bonding interactions and backbone contacts. The importance of these contacts decreases with increasing distance from the mismatch, implying that interactions at and near the mismatch are important for binding in a kinked DNA conformation.     

Ammonium scanning in an enzyme active site. The chiral specificity of aspartyl-tRNA synthetase

D-amino acids are largely excluded from protein synthesis, yet they are of great interest in biotechnology. Aspartyl-tRNA synthetase (AspRS) can misacylate tRNA(Asp) with D-aspartate instead of its usual substrate, L-Asp. We investigate how the preference for L-Asp arises, using molecular dynamics simulations. Asp presents a special problem, having pseudosymmetry broken only by its ammonium group, and AspRS must protect not only against D-Asp, but against an "inverted" orientation where the two substrate carboxylates are swapped. We compare L-Asp and D-Asp, in both orientations, and succinate, where the ammonium group is removed and the ligand has an additional negative charge. All possible ammonium positions on the ligand are thus scanned, providing information on electrostatic interactions. As controls, we simulate a Q199E mutation, obtaining a reduction in binding free energy in agreement with experiment, and we simulate TyrRS, which can misacylate tRNA(Tyr) with D-Tyr. For both TyrRS and AspRS, we obtain a moderate binding free energy difference DeltaDeltaG between the L- and D-amino acids, in agreement with their known ability to misacylate their tRNAs. In contrast, we predict that AspRS is strongly protected against inverted L-Asp binding. For succinate, kinetic measurements reveal a DeltaDeltaG of over 5 kcal/mol, favoring L-Asp. The simulations show how chiral discriminations arises from the structures, with two AspRS conformations acting in different ways and proton uptake by nearby histidines playing a role. A complex network of charges protects AspRS against most binding errors, making the engineering of its specificity a difficult challenge.     

Analysis of tachykinin-binding site interactions using NMR and energy calculation data of potent cyclic analogues of substance P

The three-dimensional structures of [Cys3,6,Tyr8]-, [Gly2,Cys3,6,Tyr8]- and [DCys3,Cys6]substance P, designed as conformational analogues of substance P, have been studied by 1H-NMR (500 MHz) in different solvents and by energy calculations. As previously observed for substance P and physalaemin, two tachykinins acting via the NK-1 receptor, [Cys3,6,Tyr8]substance P presents an alpha-helical structure of the 4----8 sequence in methanol. This structure is stabilized by a beta-turn III via the formation of three hydrogen bonds involving the Cys-6, Phe-7 and Tyr-8 NH groups. In contrast to substance P, two of these hydrogen bonds are still present in dimethyl sulfoxide and in water the Cys-6 NH hydrogen bond is the only one remaining, such that a beta-turn structure inside the ring can be envisaged. In close agreement with the NMR data, the energy calculations lead to three types of folding for the core of [Cys3,6,Tyr8]substance P: a beta-turn III, a less stable beta-turn I (delta E = 3 kcal), and a beta-turn II (delta E = 4.6 kcal). The structure of Gly-Leu-Met-NH2 is strongly affected by changing the hydrophobicity of the medium. The most stable calculated conformation is the helix; however, numerous unrelated structures are destabilized by about 2-3 kcal/mol. These data are analyzed and discussed in connection with the high potency of [Cys3,6,Tyr8]substance P for both the NK-1 and NK-3 binding sites; that is the internal region of tachykinins (non-homologous amino acids) might present a similar three-dimensional structure when bound to the receptors (which may be at the origin of some lack of selectivity), whereas paradoxically the selectivity may be due to the common C-terminal sequence.     

Identification of the conserved spatial position of key active-site atoms in glycoside hydrolase 13 family members

A computational study on the glycoside hydrolase 13 (GH13) family of the CAZy database has been carried out at the atomic level in order to identify the conserved positions that may be responsible for recognition of the substrate. Analysis with substrate analog-, inhibitor-, or product-bound 3D structures was carried out to find the atomic spatial arrangement of the amino acids that make −2, −1, +1, and +2 subsites and water oxygen atoms around the ligand. The identified conserved positions of subsites were independent from the nature of the amino acid. The −1 and +1 subsites have more conserved positions than the −2 and +2 subsites. Some of the clusters of the −1 and +1 subsites have atoms of the same chemical nature. A spatially conserved position for water, which is stabilized by a hydrogen bond with the carboxyl group of a proton donor (Glu) and Asp of the catalytic triad, was found in the −1 subsite of 75% of the enzymes subjected to analysis. This position could be the region of hydrolytic water.     

The catalytic mechanism of dye-decolorizing peroxidase DyP may require the swinging movement of an aspartic acid residue

The dye-decolorizing peroxidase (DyP)-type peroxidase family is a unique heme peroxidase family. The primary and tertiary structures of this family are obviously different from those of other heme peroxidases. However, the details of the structure-function relationships of this family remain poorly understood. We show four high-resolution structures of DyP (EC1.11.1.19), which is representative of this family: the native DyP (1.40 ?), the D171N mutant DyP (1.42 ?), the native DyP complexed with cyanide (1.45 ?), and the D171N mutant DyP associated with cyanide (1.40 ?). These structures contain four amino acids forming the binding pocket for hydrogen peroxide, and they are remarkably conserved in this family. Moreover, these structures show that OD2 of Asp171 accepts a proton from hydrogen peroxide in compound I formation, and that OD2 can swing to the appropriate position in response to the ligand for heme iron. On the basis of these results, we propose a swing mechanism in compound I formation. When DyP reacts with hydrogen peroxide, OD2 swings towards an optimal position to accept the proton from hydrogen peroxide bound to the heme iron.     

Structural basis of activation of bitter taste receptor T2R1 and comparison with Class A G-protein-coupled receptors (GPCRs)

The human bitter taste receptors (T2Rs) are non-Class A members of the G-protein-coupled receptor (GPCR) superfamily, with very limited structural information. Amino acid sequence analysis reveals that most of the important motifs present in the transmembrane helices (TM1-TM7) of the well studied Class A GPCRs are absent in T2Rs, raising fundamental questions regarding the mechanisms of activation and how T2Rs recognize bitter ligands with diverse chemical structures. In this study, the bitter receptor T2R1 was used to systematically investigate the role of 15 transmembrane amino acids in T2Rs, including 13 highly conserved residues, by amino acid replacements guided by molecular modeling. Functional analysis of the mutants by calcium imaging analysis revealed that replacement of Asn-66(2.65) and the highly conserved Asn-24(1.50) resulted in greater than 90% loss of agonist-induced signaling. Our results show that Asn-24(1.50) plays a crucial role in receptor activation by mediating an hydrogen bond network connecting TM1-TM2-TM7, whereas Asn-66(2.65) is essential for binding to the agonist dextromethorphan. The interhelical hydrogen bond between Asn-24(1.50) and Arg-55(2.54) restrains T2R receptor activity because loss of this bond in I27A and R55A mutants results in hyperactive receptor. The conserved amino acids Leu-197(5.50), Ser-200(5.53), and Leu-201(5.54) form a putative LXXSL motif which performs predominantly a structural role by stabilizing the helical conformation of TM5 at the cytoplasmic end. This study provides for the first time mechanistic insights into the roles of the conserved transmembrane residues in T2Rs and allows comparison of the activation mechanisms of T2Rs with the Class A GPCRs.     

Structure of bacillomycin F, a new peptidolipid antibiotic of the iturin group

The structure of a new antibiotic of the iturin group, bacillomycin F, has been demonstrated. It is a mixture of homologous peptidolipids, essentially C51H80N12O14 and C52N82N12O14. The lipid moiety consists of minor isoC15, anteisoC15 beta-amino acids and major isoC16, isoC17 and anteisoC17 beta-amino acids. The peptide sequence was determined by studying the peptides obtained after mild HCl hydrolysis and by Edman degradation of bacillomycin F treated with N-bromosuccinimide. The sequence was confirmed by two-dimensional NMR spectrometry and fast-atom-bombardment mass spectrometry gave the molecular masses of the homologous compounds. Bacillomycin F is a cyclic peptidolipid; its complete structure is given in the paper.     

Solution conformation of the type I collagen alpha-1 chain N-telopeptide studied by 1H NMR spectroscopy

The solution conformation of the type I collagen alpha-1 chain N-telopeptide has been studied by CD and 1H NMR spectroscopy at 600 MHz in CD3OH/H2O (60/40 v/v) and H2O solutions. The 19 amino acids form the N-terminal end of the alpha-1 polypeptide chain. By the combined application of several two-dimensional, phase-sensitive NMR techniques (COSY, RELAY, ROESY), a complete assignment of all proton resonances was achieved, and the conformation of the backbone could be established on the basis of the coupling constant and NOE data. In CD3OH/H2O solutions the spectroscopic evidence clearly indicates that two sections of the molecule (pE1-Y6 and T11-M19) are extended and that the D7-S10 segment forms a beta-turn, stabilized by a hydrogen bond between NH(S10) and CO(D7). The data suggest that the turn is of the type I kind (minor) and that it coexists with an extended structure (major conformer). Interactions between the two extended parts of the peptide were not observed, thus excluding the existence of a beta-sheet. In H2O solution the conformation is significantly different, with no beta-turn, but a completely extended structure is observed.     

NMR studies of exocyclic 1,N2-propanodeoxyguanosine adducts (X) opposite purines in DNA duplexes: protonated X(syn).A(anti) pairing (acidic pH) and X(syn).G(anti) pairing (neutral pH) at the lesion site

Proton and phosphorus two-dimensional NMR studies are reported for the complementary d(C1-A2-T3-G4-X5-G6-T7-A8-C9).d(G10-T11-A12-C13-A14-C15-A 16-T17-G18) nonanucleotide duplex (designated X.A 9-mer) that contains a 1,N2-propanodeoxyguanosine exocyclic adduct, X5, opposite deoxyadenosine A14 in the center of the helix. The NMR studies detect a pH-dependent conformational transition; this paper focuses on the structure present at pH 5.8. The two-dimensional NOESY studies of the X.A 9-mer duplex in H2O and D2O solution establish that X5 adopts a syn orientation while A14 adopts an anti orientation about the glycosidic bond at the lesion site. The large downfield shift of the amino protons of A14 demonstrates protonation of the deoxyadenosine base at pH 5.8 such that the protonated X5(syn).A14(anti) pair is stabilized by two hydrogen bonds at low pH. At pH 5.8, the observed NOE between the H8 proton of X5 and the H2 proton of A14 in the X.A 9-mer duplex demonstrates unequivocally the formation of the protonated X5(syn).A14(anti) pair. The 1,N2-propano bridge of X5(syn) is located in the major groove. Selective NOEs from the exocyclic methylene protons of X5 to the major groove H8 proton of flanking G4 but not G6 of the G4-X5-G6 segment provide additional structural constraints on the local conformation at the lesion site. A perturbation in the phosphodiester backbone is detected at the C13-A14 phosphorus located at the lesion site by 31P NMR spectroscopy. The two-dimensional NMR studies have been extended to the related complementary X.G 9-mer duplex that contains a central X5.G14 lesion in a sequence that is otherwise identical with the X.A 9-mer duplex. The NMR experimental parameters are consistent with formation of a pH-independent X5(syn).G14(anti) pair stabilized by two hydrogen bonds with the 1,N2-propano exocyclic adduct of X5(syn) located in the major groove.     

Conformational studies of two bradykinin antagonists by using two-dimensional NMR techniques and molecular dynamics simulations

The solution conformations of two potent antagonists of bradykinin (Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9), [Aca(-1),DArg0,Hyp3,Thi5,DPhe7,(N-Bzl)Gly8]BK (1) and [Aaa(-1),DArg0,Hyp3,Thi5,(2-DNal)7,Thi8]BK (2), were studied by using 2D NMR spectroscopy in DMSO-d6 and molecular dynamics simulations. The NMR spectra of peptide 1 reveals the existence of at least two isomers arising from isomerization across the DPhe7-(N-Bzl)Gly8 peptide bond. The more populated isomer possesses the cis peptide bond at this position. The ratio of cis/trans isomers amounted to 7:3. With both antagonists, the NMR data indicate a beta-turn structure for the Hyp3-Gly4 residues. In addition, for peptide 2, position 2,3 is likely to be occupied by turn-like structures. The cis peptide bond between DPhe7 and (N-Bzl)Gly8 in analogue 1 suggests type VI beta-turn at position 7,8. The molecular dynamics runs were performed on both peptides in DMSO solution. The results indicate that the structure of peptide 1 is characterized by type VIb beta-turn comprising residues Ser6-Arg9 and the betaI or betaII-turn involving the Pro2-Thi5 fragment, whereas peptide 2 shows the tendency towards the formation of type I beta-turn at position 2,3. The structures of both antagonists are stabilized by a salt bridge between the guanidine moiety of Arg1 and the carboxyl group of Arg9. Moreover, the side chain of DArg0 is apart of the rest of molecule and is not involved in structural elements except for a few calculated structures.     

Synthetic peptides derived from the beta2-beta3 loop of Raphanus sativus antifungal protein 2 that mimic the active site.

Rs-AFPs are antifungal proteins, isolated from radish (Raphanus sativus) seed or leaves, which consist of 50 or 51 amino acids and belong to the plant defensin family of proteins. Four highly homologous Rs-AFPs have been isolated (Rs-AFP1-4). The structure of Rs-AFP1 consists of three beta-strands and an alpha-helix, and is stabilized by four cystine bridges. Small peptides deduced from the native sequence, still having biological activity, are not only important tools to study structure-function relationships, but may also constitute a commercially interesting target. In an earlier study, we showed that the antifungal activity of Rs-AFP2 is concentrated mainly in the beta2-beta3 loop. In this study, we synthesized linear 19-mer peptides, spanning the entire beta2-beta3 loop, that were found to be almost as potent as Rs-AFP2. Cysteines, highly conserved in the native protein, are essential for maintaining the secondary structure of the protein. Surprisingly, in the 19-mer loop peptides, cysteines can be replaced by alpha-aminobutyric acid, which even improves the antifungal potency of the peptides. Analogous cyclic 19-mer peptides, forced to adopt a hairpin structure by the introduction of one or two non-native disulfide bridges, were also found to possess high antifungal activity. The synthetic 19-mer peptides, like Rs-AFP2 itself, cause increased Ca2+ influx in pregerminated fungal hyphae.     

Conformation, hydrogen bonding and aggregate formation of guanosine 5'-monophosphate and guanosine in dimethylsulfoxide.

The tetrabutylammonium salt of guanosine 5'-monophosphate (5'-GMP) dissolves in DMSO-d6 forming aggregated species which exhibit some properties of reverse micelles. 1H NOESY experiments show that the 5'-GMP adopts the syn conformation about the glycosidic bond. Molecular mechanics calculations reveal a stable structure with this conformation in which the phosphate group and the amino group of the base are in close enough proximity to hydrogen bond. In contrast inosine 5'-monophosphate in DMSO-d6, which has no NH2 group for hydrogen bond stabilization of the syn conformation, is shown by NMR to have the anti structure. Guanosine in DMSO-d6 behaves differently from 5'-GMP. Guanosine adopts the anti conformation and forms a symmetric dimer via hydrogen bonding between the N3 and NH2 of the bases.     

How many hydrogen-bonded α-turns are possible?

The formation of α-turns is a possibility to reverse the direction of peptide sequences via five amino acids. In this paper, a systematic conformational analysis was performed to find the possible isolated α-turns with a hydrogen bond between the first and fifth amino acid employing the methods of ab initio MO theory in vacuum (HF/6-31G*, B3LYP/6-311?+?G*) and in solution (CPCM/HF/6-31G*). Only few α-turn structures with glycine and alanine backbones fulfill the geometry criteria for the i←(i?+?4) hydrogen bond satisfactorily. The most stable representatives agree with structures found in the Protein Data Bank. There is a general tendency to form additional hydrogen bonds for smaller pseudocycles corresponding to β- and γ-turns with better hydrogen bond geometries. Sometimes, this competition weakens or even destroys the i←(i?+?4) hydrogen bond leading to very stable double β-turn structures. This is also the reason why an “ideal” α-turn with three central amino acids having the perfect backbone angle values of an α-helix could not be localized. There are numerous hints for stable α-turns with a distance between the \( {{\hbox{C}}_\alpha } \)-atoms of the first and fifth amino acid smaller than 6-7 Å, but without an i←(i?+?4) hydrogen bond.     

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.     

Structural basis for new pattern of conserved amino acid residues related to chitin-binding in the antifungal peptide from the coconut rhinoceros beetle Oryctes rhinoceros

Scarabaecin isolated from hemolymph of the coconut rhinoceros beetle Oryctes rhinoceros is a 36-residue polypeptide that has antifungal activity. The solution structure of scarabaecin has been determined from twodimensional 1H NMR spectroscopic data and hybrid distance geometry-simulated annealing protocol calculation. Based on 492 interproton and 10 hydrogen-bonding distance restraints and 36 dihedral angle restraints, we obtained 20 structures. The average backbone root-mean-square deviation for residues 4-35 is 0.728 +/- 0.217 A from the mean structure. The solution structure consists of a two-stranded antiparallel beta-sheet connected by a type-I beta-turn after a short helical turn. All secondary structures and a conserved disulfide bond are located in the C-terminal half of the peptide, residues 18-36. Overall folding is stabilized by a combination of a disulfide bond, seven hydrogen bonds, and numerous hydrophobic interactions. The structural motif of the C-terminal half shares a significant tertiary structural similarity with chitin-binding domains of plant and invertebrate chitin-binding proteins, even though scarabaecin has no overall sequence similarity to other peptide/polypeptides including chitin-binding proteins. The length of its primary structure, the number of disulfide bonds, and the pattern of conserved functional residues binding to chitin in scarabaecin differ from those of chitin-binding proteins in other invertebrates and plants, suggesting that scarabaecin does not share a common ancestor with them. These results are thought to provide further strong experimental evidence to the hypothesis that chitin-binding proteins of invertebrates and plants are correlated by a convergent evolution process.     

Molecular characterization and analysis of the operon encoding the antifungal lipopeptide bacillomycin D

Bacillus subtilis AU195 produces bacillomycin D, a cyclic lipopeptide that is an inhibitor of the aflatoxin producing fungus Aspergillus flavus. Sequence analysis of the bacillomycin D operon revealed four ORFs with the structural organization of the peptide synthetases. Disruption of ORF 2, which links the amino acid moiety to the b-amino fatty acid, resulted in the loss of antifungal activity. By comparing the sequence of bacillomycin D, iturin A and mycosubtilin operons, our results showed that intergenic module replacement have occurred between B. subtilis lipopeptide synthetases including the iturin family and the plipastatin and fengycin family.