Toshifumi Yui

The directionality of chitin biosynthesis: a revisit

The molecular directionality of chitin biosynthesis was investigated by transmission electron microscopy (TEM) using electron crystallography methods applied to reducing-end-labelled beta-chitin microcrystals from vestimentiferan Lamellibrachia satsuma tubes and nascent beta-chitin microfibrils from the diatom Thalassiosira weissflogii. The data allowed confirmation that the microfibrils were extruded with their reducing end away from the biosynthetic loci, an orientation consistent only with elongation through polymerization at the non-reducing end of the growing chains. Such a chain-extension mechanism, which has also been demonstrated for cellulose and hyaluronan, appears to be general for glycosyltransferases that belong to the GT2 (glycosyl transferase 2) family. The data also allowed confirmation that in beta-chitin the chains are crystallized in a parallel-up mode, in contrast with hypotheses proposed in previous reports.

Directional degradation of β‐chitin by chitinase A1 revealed by a novel reducing end labelling technique

A novel procedure for labelling the molecular ends of β‐chitin crystals has been established. By introducing a hydrazide derivative of biotin at the reducing end of a chitin chain, followed by a specific interaction between biotin and streptavidin coupled with a colloidal gold particle, the chain directionality of β‐chitin microcrystals could be directly visualized by transmission electron microscopy. This method allowed to certify the parallelism of the chitin chains in the β‐chitin microcrystals, and also to label the reducing tips of β‐chitin microcrystals degraded by Bacillus circulans chitinase A1. With these substrates, the labelling occurred only at their tapered tip, which indicates that the digestion of these crystals proceeded from their reducing end. The generalization of this new labelling method to other polysaccharide crystals is discussed.

Molecular cloning and characterization of the nitric oxide synthase gene from kuruma shrimp, Marsupenaeus japonicus

Nitric oxide (NO) signaling is involved in many physiological processes in vertebrates and invertebrates. In crustaceans, nitric oxide synthase (NOS) plays a significant role in the regulation of the nervous system and in innate immunity. Here, we describe the entire cDNA sequence (4616 bp) of the kuruma shrimp Marsupenaeus japonicus NOS (Mj NOS) generated using the reverse transcriptase-polymerase chain reaction (RT-PCR) and 5- and 3- rapid amplification PCRs of cDNA ends from brain and gill mRNAs. The open reading frame of Mj NOS encoded a protein of 1187 amino acids with an estimated mass of 134 kDa, and had an 82.3% sequence homology with the NOS gene of the land crab Gecarcinus lateralis. Highly conserved amino acid sequences in heme and tetrahydrobiopterin were observed in the oxygenase domain. FMN, FAD and NADPH were found in the reductase domain. Mj NOS mRNA was constitutively expressed in the brain, gill, intestine, thoracic ganglion and testis of the kuruma shrimp. When Vibrio penaeicida was injected into the kuruma shrimp, Mj NOS was expressed in the brain, gill, heart, lymphoid organ, intestine and thoracic ganglion. Mj NOS expression in the gill reached its peak 12 h and decreased to its normal level 24 h after V. penaeicida injection.

Amylose's recognition of chirality in polylactides on formation of inclusion complexes in vine-twining polymerization.

Amylose selectively includes poly(L-lactide) (PLLA) among the poly(lactide)s (PLAs) to produce an inclusion complex when the phosphorylase-catalyzed polymerization of α-D-glucose 1-phosphate is performed in the presence of PLLA, poly(D-lactide) (PDLA), or poly(DL-lactide) (PDLLA) (vine-twining polymerization). This result indicates that amylose recognizes the chirality in PLAs on the formation of an inclusion complex in vine-twining polymerization. Modeling calculations support the amyloses chiral recognition in favor of PLLA and the atomistic details of the inclusion complex which involved the preferred orientation of the constituent molecular chains with respect to their fiber axis is proposed.

Partial crystalline transformation of solvated cellulose IIII crystals, reproduced by theoretical calculations

In hot-water molecular dynamics simulation at 370xa0K, four cellulose IIII crystal models, with different lattice planes and dimensions, exhibited partial crystalline transformations of (1 −1 0) chain sheets, in which hydroxymethyl groups were irreversibly rotated from gt into tg conformations, accompanied by hydrogen-bond exchange from the original O3–O6 to cellulose-I-like O2–O6 bonds. The final hydrogen-bond exchange ratio was about 95xa0% for some of the crystal models after 50xa0ns simulation. The corrugated (1 −1 0) chain sheet was converted to a cellulose-I-like flat chain sheet with a slightly right-handed twist. The 3D structures of the three types of isolated chain sheet models were optimized using density functional theory calculations to compare their stabilities without crystal packing forces. The cellulose Iβ (1 0 0) models were more stable than the cellulose IIII (1 −1 0) models. The optimized structure of cellulose IIII (1 0 0) models deviated largely from the initial sheet form. It was proposed to the crystalline transformation from cellulose IIII to Iβ that conversion of the chain sheet structure first take place, followed by sliding of the chain sheet along the fiber axis.

Molecular dynamics study of carbohydrate binding module mutants of fungal cellobiohydrolases

The present study reports the systematic survey of binding free energies at the interface between a carbohydrate-binding module (CBM) and a cellulose Iα crystal model using molecular dynamics calculations. The two wild type CBMs (Cel7A CBM and Cel6A CBM) have been studied, as well as seven mutants of Cel7A CBM. A comparison of the experimental data for the two wild type and the four mutants CBMs (i.e., Y5A, Y5W, N29A, and Q34A) revealed that the interaction energies of Y5W and Q34A were larger than that of the wild type Cel7A CBM, whereas Y5A and N29A gave smaller values. These predicted values of the interaction energies were compared with the results observed for the adsorbing behaviors of the CBMs.

Molecular simulation study with complex models of the carbohydrate binding module of Cel6A and the cellulose Iα crystal

A computer docking study was carried out on the (110) crystal surface of the cellulose Iα crystal model for the carbohydrate binding module (CBM) of cellobiohydrolase Cel6A, which is produced by the filamentous fungus Trichoderma reesei. Three-dimensional structures of the CBM were constructed by the homology modeling method using the Cel7A CBM, which is another cellobiohydrolase from T. reesei, as a template, and refined by molecular dynamics calculations in the solution state. Among the three models tested, those with three disulfide bonds were selected for a docking analysis. The binding free energy maps represented changes in non-covalent interactions and solvation free energies with respect to the CBM position. These indicated two minimum positions within the unit cell for both the parallel and antiparallel orientation modes of the CBM with respect to the cellulose fiber axis. Molecular dynamics calculations under an explicit solvent system were performed for the four complex models derived from the minimum positions of the binding free energy maps. The complex models with CBM in the parallel orientation had the lowest binding energies.

Prediction of cellulose nanotube models through density functional theory calculations

We report the generation of a nano-scale tubular structure of cellulose molecules (CelNT), through density functional theory (DFT) calculations. When a cellulose IIII (1 0 0) chain sheet model is optimized by DFT calculations, the sheet models spontaneously roll into tubes. The oligomers arrange in a right-handed, four-fold helix with one-quarter chain staggering, oriented with parallel polarity similar to the original crystal structure. Based on a one-quarter chain staggering relationship, six large CelNT models, consisting of 16 cellulose chains with DPxa0=xa080, are constructed by combinations of two types of chain polarities and three types of symmetry operations to generate a circular arrangement of molecular chains. All six CelNT models are examined by molecular dynamics (MD) calculations in chloroform. While four CelNT models retain a tubular form throughout MD calculations, the remaining two deform. 3D-RISM theory model is used to estimate the solvation free energies of the four CelNT models. The results suggest that the CelNT model with a chain arrangement of parallel polarity and right-handed helical symmetry forms the most stable tube structure.

Double helix formation from non-natural amylose analog polysaccharides

Double helix formation from the non-natural anionic and cationic amylose analog polysaccharides (amylouronic acid and amylosamine, respectively) was achieved through electrostatic interactions. A water-insoluble complex was obtained by simply mixing the two polysaccharides in water. The 1H NMR analysis indicated that the formation of the complexes with an approximately equimolar unit ratio from the two polysaccharides was resulted regardless of feed ratios for mixing. The powder X-ray diffraction (XRD) measurement suggested that the helix had larger sizes both in diameter and pitch compared with well-known amylose double helix. The formation of the double helical structure was also examined by theoretical calculations. The double helix models, differing in a chain polarity and a charge state of the residues, were constructed based on the 6-fold left-handed amylose chain of the A-amylose crystal structure. Molecular dynamics calculations indicated that those with an antiparallel chain polarity retained an intertwined form. The antiparallel double helical model with the free form residues was suggested to be the most likely structure for the non-natural polysaccharides.

Molecular dynamics simulations of theoretical cellulose nanotube models

Nanotubes are remarkable nanoscale architectures for a wide range of potential applications. In the present paper, we report a molecular dynamics (MD) study of the theoretical cellulose nanotube (CelNT) models to evaluate their dynamic behavior in solution (either chloroform or benzene). Based on the one-quarter chain staggering relationship, we constructed six CelNT models by combining the two chain polarities (parallel (P) and antiparallel (AP)) and three symmetry operations (helical right (HR), helical left (HL), and rotation (R)) to generate a circular arrangement of molecular chains. Among the four models that retained the tubular form (P-HR, P-HL, P-R, and AP-R), the P-R and AP-R models have the lowest steric energies in benzene and chloroform, respectively. The structural features of the CelNT models were characterized in terms of the hydroxymethyl group conformation and intermolecular hydrogen bonds. Solvent structuring more clearly occurred with benzene than chloroform, suggesting that the CelNT models may disperse in benzene.