MoChia1, a family 18 glycoside hydrolase from the rice blast fungus Magnaporthe oryzae, was identified as an enzyme that binds chitin oligosaccharide elicitor to suppress the chitin-induced rice immune response. It hydrolyzed chitin oligosaccharides with a degree of polymerization of at least 3 [ (GlcNAc)n (n≥3)] in an exo-splitting manner with anomeric retention. HPLC analysis of (GlcNAc)n cleavage by MoChia1 revealed that it specifically recognizes the β-anomer of the substrate at the +1 subsite and cleaves the terminal glycosidic linkage at the reducing end. It also hydrolyzed the hetero-chitotriose GlcN-GlcNAc-GlcNAc, producing GlcN-GlcNAc and GlcNAc, but not GlcN-GlcN-GlcNAc, indicating the requirement of the N-acetyl group at the -1 subsite for the hydrolytic reaction. MoChia1 released p-nitrophenol from pNP-(GlcNAc)2, p-nitrophenyl di-N-acetyl-β-chitotrioside. Furthermore, it hydrolyzed the chitotriose derivatives with a modified GlcNAc residue on the reducing end, (GlcNAc)2-G, 4-O-β-di-N-acetylchitobiosyl-2-acetamido-2-deoxy-2,3-anhydro-glucopyranose and (GlcNAc)2-L, 4-O-β-di-N-acetylchitobiosyl-2-acetamido-2-deoxy-2,3-anhydro-glucono-δ-lactone, to (GlcNAc)2 and the modified GlcNAc, respectively. However, it did not hydrolyze 4-O-β-di-N-acetylchitobiosyl moranoline [ (GlcNAc)2-M], reduced chitotriose (chitotriitol), and α-(GlcNAc)2 fluoride [ (α-(GlcNAc)2-F]. MoChia1 did not bind to chitin and barely hydrolyzed the polymeric substrate, glycol chitin. Taken together, we concluded that MoChia1 is a GH18 reducing-end GlcNAc-releasing chitin oligosaccharide hydrolase with the β-anomer selectivity. Allosamidin, a potent inhibitor of GH18 chitinases, was found to bind to MoChia1 and inhibit its hydrolytic activity with an IC50 of 54.4 ± 6.91 μM, indicating that allosamidin may be a potential candidate for a pesticide to prevent rice blast infection by inhibiting the chitinase activity of MoChia1.

The mechanism of chitin recognition by a periplasmic chitooligosaccharide-binding protein from Vibrio cholerae (VcCBP) was studied by thermal shift assays and isothermal titration calorimetry using di-N-acetylchitobiose, (GlcNAc)2; mono-N-acetylchitobioses, GlcN-GlcNAc and GlcNAc-GlcN; and fully de-N-acetylated chitobiose, (GlcN)2; as the ligands. As judged from the thermal shifts (ΔTm) of VcCBP upon the addition of individual chitobioses, the binding abilities toward VcCBP appeared to decrease in the order of (GlcNAc)2 > GlcN-GlcNAc > GlcNAc-GlcN ≫ (GlcN)2. Although the de-N-acetylation effect of the reducing end GlcNAc was more significant than that of the non-reducing end, both N-acetyl groups were found to cooperatively contribute to the interaction between VcCBP and (GlcNAc)2. The binding affinity of GlcN-GlcNAc to VcCBP was lower than that of (GlcNAc)2 by only 0.5 kcal·mol-1 of ΔG°; however, the entropy gain (-TΔS°) was enhanced in the former compared with the latter. GlcN-GlcNAc are likely to bind loosely to VcCBP but unlikely to undergo translocation by the VcCBP-mediated transporter system.

Plants have evolved xylanase inhibitor proteins as part of their defense mechanisms against phytopathogens. The rice xylanase inhibitor protein (OsXIP) is structurally similar to GH18 chitinase and homologous to wheat XIP-type inhibitor (XIP-I), which inhibits both GH10 and GH11 xylanases. Various inhibition and interaction analyses showed that OsXIP competitively inhibits the hydrolytic activity of GH11 xylanase RXyn2, but not the activity of GH10 xylanase RXyn1 from Rhizopus oryzae. The crystal structure of the OsXIP/RXyn2 complex showed that OsXIP, which has a (β/α)8-barrel fold, extrudes the loop between α4 and β5 (Lα4β5OsXIP) and inserts the loop into the xylotriose binding site (-3 to -1 subsite) formed by the inner β-sheet (palm) of RXyn2 jelly roll. The guanidyl group of Arg155 in Lα4β5OsXIP was shown to be critical for the inhibitory activity by mutational analysis. Notably, in the complex structure, the cylindrical cavity formed by the palm of RXyn2 jelly roll stacked upright on the loops at the N-terminal ends of the β-strands of OsXIP (I-formation). On the other hand, in the complex structure of XIP-I and GH11 xylanase from Talaromyces funiculosus (XYNC), the cavity of XYNC laid tangentially to the part of the corresponding region of XIP-I through the Lα4β5XIP-I (T-formation). The dissociation constant of the OsXIP/RXyn2 complex was one tenth of that of the XIP-I/XYNC complex (4.2 versus 41.5 nM). OsXIP may have adapted to bind and inhibit GH11 enzymes, which are resistant to the inhibition by XIP-I type proteins, by changing its binding mode.

Abstract The chemoenzymatic synthesis of oligosaccharides presents a highly attractive methodology with significant potential for diverse applications, particularly through using various glycosidases. In this study, the O‐glycan core 6 disaccharide moiety, GlcNAcβ1‐6GalNAc, was successfully synthesized via enzymatic glycosylation using an N‐acetyl‐β‐D‐glucosaminidase from Bacteroides thetaiotaomicron (BtOGA), a member of glycoside hydrolase family 84 (GH84), alongside an N‐acetyl‐D‐glucosamine oxazoline derivative (GlcNAc‐oxa) as the glycosyl donor. Furthermore, an investigation into glycosyl acceptor recognition in BtOGA‐catalyzed enzymatic glycosylation indicated that the presence of an aromatic group at the anomeric position and an axial hydroxy group at the 4‐position of the saccharide moiety is crucial for effective recognition of BtOGA as a glycosyl acceptor. The protecting‐group‐free chemoenzymatic synthesis of the core 6 disaccharide moiety was achieved by integrating the direct synthesis of GlcNAc‐oxa thorough Shoda activation method using a water‐soluble dehydration condensing agent in an aqueous medium, followed by BtOGA‐catalyzed enzymatic glycosylation.

Periplasmic solute-binding proteins (SBPs) specific for chitooligosaccharides, (GlcNAc)n (n = 2, 3, 4, 5 and 6), are involved in the uptake of chitinous nutrients and the negative control of chitin signal transduction in Vibrios. Most translocation processes by SBPs across the inner membrane have been explained thus far by two-domain open/closed mechanism. Here we propose three-domain mechanism of the (GlcNAc)n translocation based on experiments using a recombinant VcCBP, SBP specific for (GlcNAc)n from Vibrio cholerae. X-ray crystal structures of unliganded or (GlcNAc)3-liganded VcCBP solved at 1.2-1.6 Å revealed three distinct domains, the Upper1, Upper2 and Lower domains for this protein. Molecular dynamics simulation indicated that the motions of the three domains are independent and that in the (GlcNAc)3-liganded state the Upper2/Lower interface fluctuated more intensively, compared to the Upper1/Lower interface. The Upper1/Lower interface bound two GlcNAc residues tightly, while the Upper2/Lower interface appeared to loosen and release the bound sugar molecule. The three-domain mechanism proposed here was fully supported by binding data obtained by thermal unfolding experiments and ITC, and may be applicable to other translocation systems involving SBPs belonging to the same cluster.

O-Glycosylated N-acetyl-β-d-glucosamine-selective N-acetyl-β-d-glucosaminidase (O-GlcNAcase), belonging to glycoside hydrolase family 84 (GH84), is known as a retaining glycosidase with the possibility of enzymatic transglycosylation. However, no enzymatic transglycosylation catalyzed by GH84 O-GlcNAcase has been reported. Here, enzymatic transglycosylation catalyzed by GH84 O-GlcNAcase was first reported. The enzymatic transglycosylation catalyzed by the GH84 O-GlcNAcase from Bacteroides thetaiotaomicron (BtGH84 O-GlcNAcase) was attained using 1,2-oxazoline derivative of N-acetyl-d-glucosamine (GlcNAc oxazoline) as a glycosyl donor substrate. The β-linked N-acetyl-d-glucosamine (GlcNAc) derivative was enzymatically synthesized using N-(2-hydroxyethyl)acrylamide as an acceptor substrate. Interestingly, the β1,6-linked disaccharide derivative of GlcNAc was also obtained in the case of using the GlcNAc derivative with a triazole-linked acrylamide group as an acceptor substrate. Additionally, a one-pot chemo-enzymatic transglycosylation starting from unprotected GlcNAc through GlcNAc oxazoline successfully showed through the combination with the direct synthesis of GlcNAc oxazoline in water and the enzymatic transglycosylation.

Two rice GH18 chitinases, Oschib1 and Oschib2, belonging to family 8 of plant pathogenesis-related proteins (PR proteins) were expressed, purified, and characterized. These enzymes, which have the structural features of class IIIb chitinases, preferentially cleaved the second glycosidic linkage from the non-reducing end of substrate chitin oligosaccharides as opposed to rice class IIIa enzymes, OsChib3a and OsChib3b, which mainly cleaved the fourth linkage from the non-reducing end of chitin hexasaccharide [ (GlcNAc)6]. Oschib1 and Oschiab2 inhibited the growth of Fusarium solani, but showed only a weak or no antifungal activity against Aspergillus niger and Trichoderma viride on the agar plates. Structural analysis of Oschib1 and Oschib2 revealed that these enzymes have two large loops extruded from the (β/α)8 TIM-barrel fold, which are absent in the structures of class IIIa chitinases. The differences in the cleavage site preferences toward chitin oligosaccharides between plant class IIIa and IIIb chitinases are likely attributed to the additional loop structures found in the IIIb enzymes. The class IIIb chitinases, Oschib1 and Oschib2, seem to play important roles for the effective hydrolysis of chitin oligosaccharides released from the cell wall of the pathogenic fungi by the cooperative actions with the extracellular chitinases in rice.

Sugar oxazolines, (GlcNAc)n-oxa (n = 2, 3, 4, and 5), were synthesized from a mixture of chitooligosaccharides, (GlcNAc)n (n = 2, 3, 4, and 5), and utilized for synthesis of (GlcNAc)7 with higher elicitor activity using plant chitinase mutants as the catalysts. From isothermal titration calorimetry, the binding affinity of (GlcNAc)2-oxa toward an inactive mutant obtained from Arabidopsis thaliana GH18 chitinase was found to be higher than those of the other (GlcNAc)n-oxa (n = 3, 4, and 5). To synthesize (GlcNAc)7, the donor/acceptor substrates with different size combinations, (GlcNAc)2-oxa/(GlcNAc)5 (1), (GlcNAc)3-oxa/(GlcNAc)4 (2), (GlcNAc)4-oxa/(GlcNAc)3 (3), and (GlcNAc)5-oxa/(GlcNAc)2 (4), were incubated with hypertransglycosylating mutants of GH18 chitinases from A. thaliana and Cycas revoluta. The synthetic activities of these plant chitinase mutants were lower than that of a mutant of Bacillus circulans chitinase A1. Nevertheless, in the plant chitinase mutants, the synthetic efficiency of combination (1) was higher than those of the other combinations (2), (3), and (4), suggesting that the synthetic reaction is mostly dominated by the binding affinities of (GlcNAc)n-oxa. In contrast, the Bacillus enzyme mutant with a different subsite arrangement synthesized (GlcNAc)7 from combination (1) in the lowest efficiency. Donor/acceptor-size dependency of the enzymatic synthesis appeared to be strongly related to the subsite arrangement of the enzyme used as the catalyst. The A. thaliana chitinase mutant was found to be useful when combination (1) is employed for the substrates.

A unique GH18 chitinase containing two N-terminal lysin motifs (PrLysM1 and PrLysM2) was first found in fern, Pteris ryukyuensis (Onaga and Taira, Glycobiology, 18, 414-423, 2008). This type of LysM-chitinase conjugates is not usually found in plants but in fungi. Here, we produced a similar GH18 chitinase with one N-terminal LysM module (EaLysM) from the fern, Equisetum arvense (EaChiA, Inamine et al., Biosci. Biotechnol. Biochem., 79, 1296-1304, 2015), using an Escherichia coli expression system and characterized for its structure and mechanism of action. The crystal structure of EaLysM exhibited an almost identical fold (βααβ) to that of PrLysM2. From isothermal titration calorimetry and nuclear magnetic resonance, the binding mode and affinities of EaLysM for chitooligosaccharides (GlcNAc)n (3, 4, 5, and 6) were found to be comparable to those of PrLysM2. The LysM module in EaChiA is likely to bind (GlcNAc)n almost independently through CH-π stacking of a Tyr residue with the pyranose ring. The (GlcNAc)n-binding mode of LysMs in the LysM-chitinase conjugates from fern plants appears to differ from that of plant LysMs acting in chitin- or Nod-signal perception, in which multiple LysMs cooperatively act on (GlcNAc)n. Phylogenetic analysis suggested that LysM-GH18 conjugates of fern plants formed a monophyletic group and had been separated earlier than forming the clade of fungal chitinases with LysMs.

Plant GH19 chitinases have several loop structures, which may define their enzymatic properties. Among these loops, the longest loop, Loop-III, is most frequently conserved in GH19 enzymes. A GH19 chitinase from the moss Bryum coronatum (BcChi-A) has only one loop structure, Loop-III, which is connected to the catalytically important β-sheet region. Here, we produced and characterized a Loop-III-deleted mutant of BcChi-A (BcChi-A-ΔIII) and found that its stability and chitinase activity were strongly reduced. The deletion of Loop-III also moderately affected the chitooligosaccharide binding ability as well as the binding mode to the substrate-binding groove. The crystal structure of an inactive mutant of BcChi-A-ΔIII was successfully solved, revealing that the remaining polypeptide chain has an almost identical fold to that of the original protein. Loop-III is not necessarily essential for the folding of the enzyme protein. However, closer examination of the crystal structure revealed that the deletion of Loop-III altered the arrangement of the catalytic triad, Glu61, Glu70 and Ser102, and the orientation of the Trp103 side chain, which is important for sugar residue binding. We concluded that Loop-III is not directly involved in the enzymatic activity but assists the enzyme function by stabilizing the conformation of the β-sheet region and the adjacent substrate-binding platform from behind the core-functional regions.

4-O-β-tri-N-acetylchitotriosyl moranoline (GN₃M) is a transition-state analogue for hen egg white lysozyme (HEWL) and identified as the most potent inhibitor till date. Isothermal titration calorimetry experiments provided the thermodynamic parameters for binding of GN₃M to HEWL and revealed that the binding is driven by a favorable enthalpy change (ΔH° = −11.0 kcal/mol) with an entropic penalty (−TΔS° = 2.6 kcal/mol), resulting in a free energy change (ΔG°) of −8.4 kcal/mol [Ogata et al. (2013) 288, 6,072–6,082]. Dissection of the entropic term showed that a favorable solvation entropy change (−TΔS_solv° = −9.2 kcal/mol) is its sole contributor. The change in heat capacity (ΔC_p°) for the binding of GN₃M was determined to be −120.2 cal/K·mol. These results indicate that the bound water molecules play a crucial role in the tight interaction between GN₃M and HEWL.

Chemo-enzymatic synthesis of lacto-N-biose I (LNB) catalyzed by β-1,3 galactosidase from Bacillus circulans (BgaC) has been developed using 4,6-dimethoxy-1,3,5-triazin-2-yl β-galactopyranoside [DMT-β-Gal] and GlcNAc as the donor and acceptor substrates, respectively. BgaC transferred the Gal moiety to the acceptor, giving rise to LNB. The maximum yield of LNB was obtained at the acceptor: donor substrate ratio of 1:30.

GH19 and GH22 glycoside hydrolases belonging to the lysozyme superfamily have a related structure/function. A highly conserved tryptophan residue, Trp103, located in the binding groove of a GH19 chitinase from moss Bryum coronatum (BcChi-A) appears to have a function similar to that of well-known Trp62 in GH22 lysozymes. Here, we found that mutation of Trp103 to phenylalanine (W103F) or alanine (W103A) strongly reduced the enzymatic activity of BcChi-A. NMR experiments and the X-ray crystal structure suggested a hydrogen bond between the Trp103 side chain and the -2 sugar. Chitooligosaccharide binding experiments using NMR indicated that the W103F mutation reduced the sugar-binding abilities of nearby amino acid residues (Tyr105/Asn106) in addition to Trp103. This appeared to be derived from enhanced aromatic stacking of Phe103 with Tyr105 induced by disruption of the Trp103 hydrogen bond with the -2 sugar. Since the stacking with Tyr105 was unlikely in W103A, Tyr105/Asn106 of W103A was not so affected as in W103F. However, the W103A mutation appeared to reduce the catalytic potency, resulting in the lowest enzymatic activity in W103A. We concluded that Trp103 does not only interact with the sugar, but also controls other amino acids responsible for substrate binding and catalysis. Trp103 (GH19) and Trp62 (GH22) with such a multi-functionality may be advantageous for enzyme action and conserved in the divergent evolution in the lysozyme superfamily.

We investigated the inhibition kinetics of VhGlcNAcase, a GH20 exo-β-N-acetylglucosaminidase (GlcNAcase) from the marine bacterium Vibrio campbellii (formerly V. harveyi) ATCC BAA-1116, using TMG-chitotriomycin, a natural enzyme inhibitor specific for GH20 GlcNAcases from chitin-processing organisms, with p-nitrophenyl N-acetyl-β-d-glucosaminide (pNP-GlcNAc) as the substrate. TMG-chitotriomycin inhibited VhGlcNAcase with an IC50 of 3.0 ± 0.7 μM. Using Dixon plots, the inhibition kinetics indicated that TMG-chitotriomycin is a competitive inhibitor, with an inhibition constant Ki of 2.2 ± 0.3 μM. Isothermal titration calorimetry experiments provided the thermodynamic parameters for the binding of TMG-chitotriomycin to VhGlcNAcase and revealed that binding was driven by both favorable enthalpy and entropy changes (ΔH° = -2.5 ± 0.1 kcal/mol and -TΔS° = -5.8 ± 0.3 kcal/mol), resulting in a free energy change, ΔG°, of -8.2 ± 0.2 kcal/mol. Dissection of the entropic term showed that a favorable solvation entropy change (-TΔSsolv° = -16 ± 2 kcal/mol) is the main contributor to the entropic term.

A 38 kDa β-1,3-glucanase allergen from Cryptomeria japonica pollen (CJP38) was recombinantly produced in E. coli and purified to homogeneity with the use of Ni-affinity resin. CJP38 hydrolyzed β-1,3-glucans such as CM-curdlan and laminarioligosaccharides in an endo-splitting manner. The optimum pH and temperature for β-1,3-glucanase activity were approximately 4.5 and 50 °C, respectively. The enzyme was stable at 30-60 °C and pH 4.0-10.5. Furthermore, CJP38 catalyzed a transglycosylation reaction to yield reaction products with a molecular weight higher than those of the starting laminarioligosaccharide substrates. The three-dimensional structure of CJP38 was determined using X-ray crystallography at 1.5 Å resolution. CJP38 exhibited the typical (β/α)8 TIM-barrel motif, similar to allergenic β-1,3-glucanases from banana (Mus a 5) and rubber tree latex (Hev b 2). Amino acid sequence alignment of these proteins indicated that the two-consensus IgE epitopes identified on the molecular surfaces of Mus a 5 and Hev b 2 were highly conserved in CJP38. Their conformations and surface locations were quite similar for these proteins. Sequence and structural conservation of these regions suggest that CJP38 is a candidate allergen responsible for the pollen-latex-fruit syndrome relating to Japanese cedar pollinosis.

Two N-terminal lysin motifs (LysMs) found in a chitinase from the green alga Volvox carteri (VcLysM1 and VcLysM2) were produced, and their structures and chitin-binding properties were characterized. The binding affinities of VcLysM1 toward chitin oligomers determined by isothermal titration calorimetry (ITC) were higher than those of VcLysM2 by 0.8-1.1 kcal/mol of ΔG°. Based on the NMR solution structures of the two LysMs, the differences in binding affinities were found to result from amino acid substitutions at the binding site. The NMR spectrum of a two-domain protein (VcLysM1+2), in which VcLysM1 and VcLysM2 are linked in tandem through a flexible linker, suggested that the individual domains of VcLysM1+2 independently fold and do not interact with each other. ITC analysis of chitin-oligomer binding revealed two different binding sites in VcLysM1+2, showing no cooperativity. The binding affinities of the VcLysM1 domain in VcLysM1+2 were lower than those of VcLysM1 alone, probably due to the flexible linker destabilizing the interaction between the chito-oligosaccahrides and VcLysM1 domain. Overall, two LysMs attached to the chitinase from the primitive plant species, V. carteri, were found to resemble bacterial LysMs reported thus far.

We characterized SaHEX, which is a glycoside hydrolase (GH) family 20 exo-β-N-acetylhexosaminidase found in Streptomyces avermitilis. SaHEX exolytically hydrolyzed chitin oligosaccharides from their non-reducing ends, and yielded N-acetylglucosamine (GlcNAc) as the end product. According to the initial rate of substrate hydrolysis, the rates of (GlcNAc)3 and (GlcNAc)5 hydrolysis were greater than the rates for the other oligosaccharides. The enzyme exhibited antifungal activity against Aspergillus niger, which was probably due to hydrolytic activity with regard to chitin in the hyphal tips. Therefore, SaHEX has potential for use in GlcNAc production and food preservation.

A novel method for the chemo-enzymatic synthesis of chitin oligosaccharide catalyzed by mutants of BcChi-A, an inverting family GH19 chitinase from Bryum coronatum, has been developed using 4,6-dimethoxy-1,3,5-triazin-2-yl α-chitobioside [DMT-α-(GlcNAc)2)] as a donor substrate. Based on the glycosynthase derived from BcChi-A, Glu70, which acts as a catalytic base, and Ser102, which fixes a nucleophilic water molecule, were changed to generate several single and double mutants of BcChi-A, which were employed in synthetic reactions. Among the double mutants tested, E70G/S102G, E70G/S102C and E70G/S102A were found to successfully synthesize chitotetraose [ (GlcNAc)4] from DMT-α-(GlcNAc)2 and (GlcNAc)2; however, the single mutants, E70G, S102G, S102C and S102A, did not. Among the mutants, E70G/S102A showed the highest synthetic activity. This is the first report of a glycosynthase that employs a dimethoxytriazine-type glycoside as a donor substrate.

KEY MESSAGE: Euglena gracilis is a unicellular microalga showing characteristics of both plants and animals, and extensively used as a model organism in the research works of biochemistry and molecular biology. Biotechnological applications of E. gracilis have been conducted for production of numerous important compounds. However, chitin-mediated defense system intensively studied in higher plants remains to be investigated in this microalga. Recently, Taira et al. (Biosci Biotechnol Biochem 82:1090-1100, 2018) isolated a unique chitinase gene, comprising two catalytic domains almost homologous to each other (Cat1 and Cat2) and two chitin-binding domains (CBD1 and CBD2), from E. gracilis. We herein examined the mode of action and the specificity of the recombinant Cat2 by size exclusion chromatography and NMR spectroscopy. Both Cat1 and Cat2 appeared to act toward chitin substrate with non-processive/endo-splitting mode, recognizing two contiguous N-acetylglucosamine units at subsites - 2 and - 1. This is the first report on a chitinase having two endo-splitting catalytic domains. A cooperative action of two different endo-splitting domains may be advantageous for defensive action of the E. gracilis chitinase. The unicellular alga, E. gracilis, produces a chitinase consisting of two GH18 catalytic domains (Cat1 and Cat2) and two CBM18 chitin-binding domains (CBD1 and CBD2). Here, we produced a recombinant protein of the Cat2 domain to examine its mode of action as well as specificity. Cat2 hydrolyzed N-acetylglucosamine (A) oligomers (An, n = 4, 5, and 6) and partially N-acetylated chitosans with a non-processive/endo-splitting mode of action. NMR analysis of the product mixture from the enzymatic digestion of chitosan revealed that the reducing ends were exclusively A-unit, and the nearest neighbors of the reducing ends were mostly A-unit but not exclusively. Both A-unit and D-unit were found at the non-reducing ends and the nearest neighbors. These results indicated strong and absolute specificities for subsites - 2 and - 1, respectively, and no preference for A-unit at subsites + 1 and + 2. The same results were obtained from sugar sequence analysis of the individual enzymatic products from the chitosans. The subsite specificities of Cat2 are similar to those of GH18 human chitotriosidase, but differ from those of plant GH18 chitinases. Since the structures of Cat1 and Cat2 resemble to each other (99% similarity in amino acid sequences), Cat1 may hydrolyze the substrate with the same mode of action. Thus, the E. gracilis chitinase appears to act toward chitin polysaccharide chain through a cooperative action of the two endo-splitting catalytic domains, recognizing two contiguous A-units at subsites - 2 and - 1.

In the model species Streptomyces coelicolor A3(2), the uptake of chitin-degradation byproducts, mainly N,N'- diacetylchitobiose ([GlcNAc]2) and N-acetylglucosamine (GlcNAc), is performed by the ATP-binding cassette (ABC) transporter DasABC-MsiK and the sugar-phosphotransferase system (PTS), respectively. Studies on the S. coelicolor chromosome have suggested the occurrence of additional uptake systems of GlcNAc-related compounds, including the SCO6005-7 cluster, which is orthologous to the ABC transporter NgcEFG of S. olivaceoviridis. However, despite conserved synteny between the clusters in S. coelicolor and S. olivaceoviridis, homology between them is low, with only 35% of residues being identical between NgcE proteins, suggesting different binding specificities. Isothermal titration calorimetry experiments revealed that recombinant NgcESco interacts with GlcNAc and (GlcNAc)2, with Kd values (1.15 and 1.53 μM, respectively) that were higher than those of NgcE of S. olivaceoviridis (8.3 and 29 nM, respectively). The disruption of ngcESco delayed (GlcNAc)2 consumption, but did not affect GlcNAc consumption ability. The ngcESco-dasA double mutation severely decreased the ability to consume (GlcNAc)2 and abolished the induction of chitinase production in the presence of (GlcNAc)2, but did not affect the GlcNAc consumption rate. The results of these biochemical and reverse genetic analyses indicate that NgcESco acts as a (GlcNAc)2- binding protein of the ABC transporter NgcEFGSco-MsiK. Transcriptional and biochemical analyses of gene regulation demonstrated that the ngcESco gene was slightly induced by GlcNAc, (GlcNAc)2, and chitin, but repressed by DasR. Therefore, a model was proposed for the induction of the chitinolytic system and import of (GlcNAc)2, in which (GlcNAc)2 generated from chitin by chitinase produced leakily, is mainly transported via NgcEFG-MsiK and induces the expression of chitinase genes and dasABCD.

A cDNA of putative chitinase from Euglena gracilis, designated EgChiA, encoded 960 amino acid residues, which is arranged from N-terminus in the order of signal peptide, glycoside hydrolase family 18 (GH18) domain, carbohydrate binding module family 18 (CBM18) domain, GH18 domain, CBM18 domain, and transmembrane helix. It is likely that EgChiA is anchored on the cell surface. The recombinant second GH18 domain of EgChiA, designated as CatD2, displayed optimal catalytic activity at pH 3.0 and 50 °C. The lower the polymerization degree of the chitin oligosaccharides [ (GlcNAc)4-6] used as the substrates, the higher was the rate of degradation by CatD2. CatD2 degraded chitin nanofibers as an insoluble substrate, and it produced only (GlcNAc)2 and GlcNAc. Therefore, we speculated that EgChiA localizes to the cell surface of E. gracilis and is involved in degradation of chitin polymers into (GlcNAc)2 or GlcNAc, which are easily taken up by the cells.

Chitinases belonging to the GH19 family have diverse loop structure arrangements. A GH19 chitinase from rye seeds (RSC-c) has a full set of (six) loop structures that form an extended binding cleft from -4 to +4 ("loopful"), while that from moss (BcChi-A) lacks several loops and forms a shortened binding cleft from -2 to +2 ("loopless"). We herein inserted a loop involved in sugar residue binding at subsites +3 and +4 of RSC-c (Loop-II) into BcChi-A (BcChi-A+L-II), and the thermal stability and enzymatic activity of BcChi-A+L-II were then characterized and compared with those of BcChi-A. The transition temperature of thermal unfolding decreased from 77.2 ˚C (BcChi-A) to 63.3 ˚C (BcChi-A+L-II) by insertion of Loop-II. Enzymatic activities toward the chitin tetramer (GlcNAc)4 and the polymeric substrate glycol chitin were also suppressed by the Loop-II insertion to 12 and 9 %, respectively. The Loop-II inserted into BcChi-A was found to be markedly flexible and disadvantageous for protein stability and enzymatic activity.

DESCRIPTIONS: The structure of a GH19 chitinase from the moss Bryum coronatum (BcChi-A) in complex with the substrate was examined by X-ray crystallography and NMR spectroscopy in solution. The X-ray crystal structure of the inactive mutant of BcChi-A (BcChi-A-E61A) liganded with chitin tetramer (GlcNAc)4 revealed a clear electron density of the tetramer bound to subsites -2, -1, +1, and +2. Individual sugar residues were recognized by several amino acids at these subsites through a number of hydrogen bonds. This is the first crystal structure of GH19 chitinase liganded with oligosaccharide spanning the catalytic center. NMR titration experiments of chitin oligosaccharides into the BcChi-A-E61A solution showed that the binding mode observed in the crystal structure is similar to that in solution. The C-1 carbon of -1 GlcNAc, the Oε1 atom of the catalytic base (Glu70), and the Oγ atom of Ser102 form a "triangle" surrounding the catalytic water, and the arrangement structurally validated the proposed catalytic mechanism of GH19 chitinases. The glycosidic linkage between -1 and +1 sugars was found to be twisted and under strain. This situation may contribute to the reduction of activation energy for hydrolysis. The complex structure revealed a more refined mechanism of the chitinase catalysis.

Recombinant class V chitinases from Nicotiana tabacum and Arabidopsis thaliana (NtChiV and AtChiC) were produced by the Escherichia coli expression system, and the antifungal activity of the enzymes was investigated using the hyphal extension inhibition assay on agar plates with Trichoderma viride as the test fungus. The activity of NtChiV was found to be much higher than that of AtChiC. The inactive mutants of both enzymes, in which the individual catalytic acids were mutated to glutamine, were also tested by the same assay system. The activity was impaired by the mutation, indicating that the hydrolytic activity contributes to the antifungal action of the enzymes. However, the activity of the enzymes toward glycol chitin substrate was not proportional to the antifungal activity, indicating that the hydrolytic activity does not exclusively contribute to the antifungal action. X-ray crystal structures of these enzymes revealed that the aglycon-binding region of NtChiV consists of a number of polar side chains but not in AtChiC. Polarity of the surface of substrate-binding cleft could be another factor controlling the antifungal action of class V chitinases.

Class V chitinase from cycad, Cycas revoluta, (CrChi-A) is the first plant chitinase that has been found to possess transglycosylation activity. To identify the structural determinants that bring about transglycosylation activity, we mutated two aromatic residues, Phe166 and Trp197, which are likely located in the acceptor binding site, and the mutated enzymes (F166A, W197A) were characterized. When the time-courses of the enzymatic reaction toward chitin oligosaccharides were monitored by HPLC, the specific activity was decreased to about 5-10% of that of the wild type and the amounts of transglycosylation products were significantly reduced by the individual mutations. From comparison between the reaction time-courses obtained by HPLC and real-time ESI-MS, we found that the transglycosylation reaction takes place under the conditions used for HPLC but not under the ESI-MS conditions. The higher substrate concentration (5 mM) used for the HPLC determination is likely to bring about chitinase-catalyzed transglycosylation. Kinetic analysis of the time-courses obtained by HPLC indicated that the sugar residue affinity of +1 subsite was strongly reduced in both mutated enzymes, as compared with that of the wild type. The IC(50) value for the inhibitor allosamidin determined by real-time ESI-MS was not significantly affected by the individual mutations, indicating that the state of the allosamidin binding site (from -3 to -1 subsites) was not changed in the mutated enzymes. We concluded that the aromatic side chains of Phe166 and Trp197 in CrChi-A participate in the transglycosylation acceptor binding, thus controlling the transglycosylation activity of the enzyme.