Trp residue at subsite - 5 plays a critical role in the substrate binding of two protistan GH26 ß-mannanases from a termite hindgut.

Symbiotic protists in the hindgut of termites provide a novel enzymatic resource for efficient lignocellulytic degradation of plant biomass. In this study, two ß-mannanases, RsMan26A and RsMan26B, from a symbiotic protist community of the lower termite, Reticulitermes speratus, were successfully expressed in the methylotrophic yeast, Pichia pastoris. Biochemical characterization experiments demonstrated that both RsMan26A and RsMan26B are endo-acting enzymes and have a very similar substrate specificity, displaying a higher catalytic efficiency to galactomannan from locust bean gum (LBG) and glucomannan than to ß-1,4-mannan and highly substituted galactomannan from guar gum. Homology modeling of RsMan26A and RsMan26B revealed that each enzyme displays a long open cleft harboring a unique hydrophobic platform (Trp79) that stacks against the sugar ring at subsite - 5. The Km values of W79A mutants of RsMan26A and RsMan26B to LBG increased by 4.8-fold and 3.6-fold, respectively, compared with those for the native enzymes, while the kcat remained unchanged or about 40% of that of the native enzyme, resulting in the decrease in the catalytic efficiency by 4.8-fold and 9.1-fold, respectively. The kinetic values for glucomannan also showed a similar result. These results demonstrate that the Trp residue present near the subsite - 5 has an important role in the recognition of the sugar ring in the substrate.

Novel squalene-producing thraustochytrids found in mangrove water.

On extended screening of squalene-producing strains in Okinawa mangrove water, we identified 14 novel squalene-producing thraustochytrids from 172 unialgal clonal isolates. The novel thraustochytrids produced 13.9-7.54 mg squalene/g dry cell weight. Eight isolates were found to belong to potentially novel squalene-producing genera, forming a monophyletic cluster independent from any known thraustochytrids.

Structural and biochemical analyses of glycoside hydrolase family 26 ß-mannanase from a symbiotic protist of the termite Reticulitermes speratus.

Termites and their symbiotic protists have established a prominent dual lignocellulolytic system, which can be applied to the biorefinery process. One of the major components of lignocellulose from conifers is glucomannan, which comprises a heterogeneous combination of ß-1,4-linked mannose and glucose. Mannanases are known to hydrolyze the internal linkage of the glucomannan backbone, but the specific mechanism by which they recognize and accommodate heteropolysaccharides is currently unclear. Here, we report biochemical and structural analyses of glycoside hydrolase family 26 mannanase C (RsMan26C) from a symbiotic protist of the termite Reticulitermes speratus. RsMan26C was characterized based on its catalytic efficiency toward glucomannan, compared with pure mannan. The crystal structure of RsMan26C complexed with gluco-manno-oligosaccharide(s) explained its specificities for glucose and mannose at subsites -5 and -2, respectively, in addition to accommodation of both glucose and mannose at subsites -3 and -4. RsMan26C has a long open cleft with a hydrophobic platform of Trp(94) at subsite -5, facilitating enzyme binding to polysaccharides. Notably, a unique oxidized Met(85) specifically interacts with the equatorial O-2 of glucose at subsite -3. Our results collectively indicate that specific recognition and accommodation of glucose at the distal negative subsites confers efficient degradation of the heteropolysaccharide by mannanase.

The GH26 ß-mannanase RsMan26H from a symbiotic protist of the termite Reticulitermes speratus is an endo-processive mannobiohydrolase: heterologous expression and characterization.

Symbiotic protists in the gut of termites are prominent natural resources for enzymes involved in lignocellulose degradation. Here we report expression, purification, and biochemical characterization of a glycoside hydrolase family 26 mannanase RsMan26H from the symbiotic protist of the lower termite, Reticulitermes speratus. Biochemical analysis of RsMan26H demonstrates that this enzyme is an endo-processive mannobiohydrolase producing mannobiose from oligo- and polysaccharides, followed by a minor accumulation of oligosaccharides larger than mannobiose. To our knowledge, this is the first report describing the unique mannobiohydrolase enzyme from the eukaryotic origin.

High-throughput recombinant gene expression systems in Pichia pastoris using newly developed plasmid vectors.

We describe here the construction of Gateway-compatible vectors, pBGP1-DEST and pPICZα-DEST, for rapid and convenient preparation of expression plasmids for production of secretory proteins in Pichia pastoris. Both vectors direct the synthesis of fusion proteins consisting of the N-terminal signal and pro-sequences of Saccharomyces cerevisiae α-factor, the recognition sites for Kex2 and Ste13 processing proteases, the mature region of a foreign protein flanked by attB1- and attB2-derived sequences at N- and C-termini, respectively, and myc plus hexahistidine tags added at the extreme C-terminus. To test the usefulness of these vectors, production of endo-glucanases and xylanases from termite symbionts, as well as a fungal glucuronoyl esterase, was performed. Enzyme activities were detected in the culture supernatants, indicating that the chimeric proteins were synthesized and secreted as designed.

Division of functional roles for termite gut protists revealed by single-cell transcriptomes.

The microbiome in the hindgut of wood-feeding termites comprises various species of bacteria, archaea, and protists. This gut community is indispensable for the termite, which thrives solely on recalcitrant and nitrogen-poor wood. However, the difficulty in culturing these microorganisms has hindered our understanding of the function of each species in the gut. Although protists predominate in the termite gut microbiome and play a major role in wood digestion, very few culture-independent studies have explored the contribution of each species to digestion. Here, we report single-cell transcriptomes of four protists species comprising the protist population in worldwide pest Coptotermes formosanus. Comparative transcriptomic analysis revealed that the expression patterns of the genes involved in wood digestion were different among species, reinforcing their division of roles in wood degradation. Transcriptomes, together with enzyme assays, also suggested that one of the protists, Cononympha leidyi, actively degrades chitin and assimilates it into amino acids. We propose that C. leidyi contributes to nitrogen recycling and inhibiting infection from entomopathogenic fungi through chitin degradation. Two of the genes for chitin degradation were further revealed to be acquired via lateral gene transfer (LGT) implying the importance of LGT in the evolution of symbiosis. Our single-cell-based approach successfully characterized the function of each protist in termite hindgut and explained why the gut community includes multiple species.

Functional expression of three Rieske non-heme iron oxygenases derived from actinomycetes in Rhodococcus species for investigation of their degradation capabilities of dibenzofuran and chlorinated dioxins.

The activity of Rieske non-heme iron oxygenases (aromatic hydrocarbon dioxygenases, AhDOs) is important for the bacterial degradation of aromatic pollutants such as polycyclic aromatic hydrocarbons and dioxins. During our analysis of the role of AhDOs in dioxin bioremediation, some enzymes derived from high G + C Gram-positive actinomycetes were difficult to produce in active form in the Escherichia coli protein expression system. In this study, we constructed a heterologous expression system for AhDOs in Rhodococcus species using a constitutive expression promoter, P(dfdB), and a shuttle vector, pRK401, and analyzed the ability of these enzymes to degrade dibenzofuran and deplete several chlorinated dioxins. Three active AhDOs expressed in Rhodococcus strains that were difficult to obtain by the E. coli system showed different regiospecificities for dibenzofuran bioconversion as well as different substrate depletion specificities for chlorinated dioxins. Moreover, AhDO derived from R. erythropolis TA421 showed relatively diverse depletion-substrate specificity for chlorinated dioxins.

Heterologous expression and characterization of a glycoside hydrolase family 45 endo-ß-1,4-glucanase from a symbiotic protist of the lower termite, Reticulitermes speratus.

The termite symbiotic system is one of the efficient lignocellulose degradation systems. We tried to express and characterize a novel cellulolytic enzyme from this system. Here, we report the isolation of an endo-ß-1,4-glucanase gene homolog of glycoside hydrolase family 45 from a symbiotic protistan community of Reticulitermes speratus. Heterologous expression of this gene was performed using the expression system of Aspergillus oryzae. Analysis of enzymatic properties revealed 786 µmol/min/mg protein in specific activity, a V max of 833.0 units/mg protein, and a K m value of 2.58 mg/ml with carboxymethyl cellulose as the substrate. Thin-layer chromatography analysis showed that RsSymEG2 produces cellobiose from cellodextrins larger than cellohexaose. This enzyme showed high specific activity like other endo-ß-1,4-glucanases from the symbiotic system of termites. It means that the termite symbiotic system is a good resource for highly active endo-ß-1,4-glucanases.

Structural basis for chiral substrate recognition by two 2,3-butanediol dehydrogenases.

2,3-butanediol dehydrogenase (BDH) catalyzes the NAD-dependent redox reaction between acetoin and 2,3-butanediol. There are three types of homologous BDH, each stereospecific for both substrate and product. To establish how these homologous enzymes possess differential stereospecificities, we determined the crystal structure of l-BDH with a bound inhibitor at 2.0 A. Comparison with the inhibitor binding mode of meso-BDH highlights the role of a hydrogen-bond from a conserved Trp residue(192). Site-directed mutagenesis of three active site residues of meso-BDH, including Trp(190), which corresponds to Trp(192) of L-BDH, converted its stereospecificity to that of L-BDH. This result confirms the importance of conserved residues in modifying the stereospecificity of homologous enzymes.

The MrpA, MrpB and MrpD subunits of the Mrp antiporter complex in Bacillus subtilis contain membrane-embedded and essential acidic residues.

Bacillus subtilis Mrp is a unique Na+/H+ antiporter with a multicomponent structure consisting of the mrpABCDEFG gene products. We have previously reported that the conserved and putative membrane-embedded Glu-113, Glu-657, Asp-743 and Glu-747 of MrpA (ShaA) are essential for the transport function. In this study, we further investigated the functional involvement of the equivalent conserved acidic residues of other Mrp proteins in heterologous Escherichia coli and natural B. subtilis backgrounds. Asp-121 of MrpB and Glu-137 of MrpD were additionally identified to be essential for the transport function in both systems. Glu-137 of MrpD and Glu-113 of MrpA were found to be conserved in the homologous MrpD/MrpA proteins as well as in the homologous subunits of H+-translocating primary active transporters such as Nuo and Mbh, suggesting their critical role in ion binding. The remaining essential acidic residues clustered in the C-terminal domain of MrpA (Glu-657, Asp-743 and Glu-747) and MrpB (Asp-121); these subunits are fused in some Gram-negative species. It is possible that the MrpA, MrpB and MrpD subunits, which contain essential transmembrane acidic residues, form the ion translocation site(s) of the Mrp antiporter complex.

Complex formation by the mrpABCDEFG gene products, which constitute a principal Na+/H+ antiporter in Bacillus subtilis.

The Bacillus subtilis Mrp (also referred to as Sha) is a particularly unusual Na(+)/H(+) antiporter encoded by mrpABCDEFG. Using His tagging of Mrp proteins, we showed complex formation by the mrpABCDEFG gene products by pull-down and blue native polyacrylamide gel electrophoresis analyses. This is the first molecular evidence that the Mrp is a multicomponent antiporter in the cation-proton antiporter 3 family.