Metabolic classification of microbial genomes using functional probes.

BACKGROUND: Microorganisms able to grow under artificial culture conditions comprise only a small proportion of the biosphere's total microbial community. Until recently, scientists have been unable to perform thorough analyses of difficult-to-culture microorganisms due to limitations in sequencing technology. As modern techniques have dramatically increased sequencing rates and rapidly expanded the number of sequenced genomes, in addition to traditional taxonomic classifications which focus on the evolutionary relationships of organisms, classifications of the genomes based on alternative points of view may help advance our understanding of the delicate relationships of organisms. RESULTS: We have developed a proteome-based method for classifying microbial species. This classification method uses a set of probes comprising short, highly conserved amino acid sequences. For each genome, in silico translation is performed to obtained its proteome, based on which a probe-set frequency pattern is generated. Then, the probe-set frequency patterns are used to cluster the proteomes/genomes. CONCLUSIONS: Features of the proposed method include a high running speed in challenge of a large number of genomes, and high applicability for classifying organisms with incomplete genome sequences. Moreover, the probe-set clustering method is sensitive to the metabolic phenotypic similarities/differences among species and is thus supposed potential for the classification or differentiation of closely-related organisms.

Solution structure of the plant defensin VrD1 from mung bean and its possible role in insecticidal activity against bruchids.

Vigna radiata plant defensin 1 (VrD1) is the first reported plant defensin exhibiting insecticidal activity. We report herein the nuclear magnetic resonance solution structure of VrD1 and the implication on its insecticidal activity. The root-mean-square deviation values are 0.51 +/- 0.35 and 1.23 +/- 0.29 A for backbone and all heavy atoms, respectively. The VrD1 structure comprises a triple-stranded antiparallel beta-sheet, an alpha-helix, and a 3(10) helix stabilized by four disulfide bonds, forming a typical cysteine-stabilized alphabeta motif. Among plant defensins of known structure, VrD1 is the first to contain a 3(10) helix. Glu26 is highly conserved among defensins; VrD1 contains an arginine at this position, which may induce a shift in the orientation of Trp10, thereby promoting the formation of this 3(10) helix. Moreover, VrD1 inhibits Tenebrio molitor alpha-amylase. Alpha-amylase has an essential role in the digestion of plant starch in the insect gut, and expression of the common bean alpha-amylase inhibitor 1 in transgenic pea imparts complete resistance against bruchids. These results imply that VrD1 insecticidal activity has its basis in the inhibition of a polysaccharide hydrolase. Sequence and structural comparisons between two groups of plant defensins having different specificity toward insect alpha-amylase reveal that the loop between beta2 and beta3 is the probable binding site for the alpha-amylase. Computational docking experiments were used to study VrD1-alpha-amylase interactions, and these results provide information that may be used to improve the insecticidal activity of VrD1.

Binding mechanism of nonspecific lipid transfer proteins and their role in plant defense.

Plant nonspecific lipid transfer proteins (nsLTPs) are small basic proteins that transport phospholipids between membranes. On the basis of molecular mass, nsLTPs are subdivided into nsLTP1 and nsLTP2. NsLTPs are all helical proteins stabilized by four conserved disulfide bonds. The existence of an internal hydrophobic cavity, running through the molecule, is a typical characteristic of nsLTPs that serves as the binding site for lipid-like substrates. NsLTPs are known to participate in plant defense, but the exact mechanism of their antimicrobial action against fungi or bacteria is still unclear. To trigger plant defense responses, a receptor at the plant surface needs to recognize the complex of a fungal protein (elicitin) and ergosterol. NsLTPs share high structural similarities with elicitin and need to be associated with a hydrophobic ligand to stimulate a defense response. In this study, binding of sterol molecules with rice nsLTPs is analyzed using various biophysical methods. NsLTP2 can accommodate a planar sterol molecule, but nsLTP1 binds only linear lipid molecules. Although the hydrophobic cavity of rice nsLTP2 is smaller than that of rice nsLTP1, it is flexible enough to accommodate the voluminous sterol molecule. The dissociation constant for the nsLTP2/cholesterol complex is approximately 71.21 microM as measured by H/D exchange and mass spectroscopic detection. Schematic models of the nsLTP complex structure give interesting clues about the reason for differential binding modes. Comparisons of NMR spectra of the sterol/rice nsLTP2 complex and free nsLTP2 revealed the residues involved in binding.