Effect of Deletions of the Genes Encoding Pho3p and Bgl2p on Polyphosphate Level, Stress Adaptation, and Attachments of These Proteins to Saccharomyces cerevisiae Cell Wall.

Inorganic polyphosphates (polyP), according to literature data, are involved in the regulatory processes of molecular complex of the Saccharomyces cerevisiae cell wall (CW). The aim of the work was to reveal relationship between polyP, acid phosphatase Pho3p, and the major CW protein, glucanosyltransglycosylase Bgl2p, which is the main glucan-remodelling enzyme with amyloid properties. It has been shown that the yeast cells with deletion of the PHO3 gene contain more high molecular alkali-soluble polyP and are also more resistant to exposure to alkali and manganese ions compared to the wild type strain. This suggests that Pho3p is responsible for hydrolysis of the high molecular polyP on the surface of yeast cells, and these polyP belong to the stress resistance factors. The S. cerevisiae strain with deletion of the BGL2 gene is similar to the Δpho3 strain both in the level of high molecular alkali-soluble polyP and in the increased resistance to alkali and manganese. Comparative analysis of the CW proteins demonstrated correlation between the extractability of the acid phosphatase and Bgl2p, and also revealed a change in the mode of Bgl2p attachment to the CW of the strain lacking Pho3p. It has been suggested that Bgl2p and Pho3p are able to form a metabolon or its parts that connects biogenesis of the main structural polymer of the CW, glucan, and catabolism of an important regulatory polymer, polyphosphates.

Analysis and application of a suite of recombinant endo-ß(1,3)-D-glucanases for studying fungal cell walls.

BACKGROUND: The fungal cell wall is an essential and robust external structure that protects the cell from the environment. It is mainly composed of polysaccharides with different functions, some of which are necessary for cell integrity. Thus, the process of fractionation and analysis of cell wall polysaccharides is useful for studying the function and relevance of each polysaccharide, as well as for developing a variety of practical and commercial applications. This method can be used to study the mechanisms that regulate cell morphogenesis and integrity, giving rise to information that could be applied in the design of new antifungal drugs. Nonetheless, for this method to be reliable, the availability of trustworthy commercial recombinant cell wall degrading enzymes with non-contaminating activities is vital. RESULTS: Here we examined the efficiency and reproducibility of 12 recombinant endo-ß(1,3)-D-glucanases for specifically degrading the cell wall ß(1,3)-D-glucan by using a fast and reliable protocol of fractionation and analysis of the fission yeast cell wall. This protocol combines enzymatic and chemical degradation to fractionate the cell wall into the four main polymers: galactomannoproteins, α-glucan, ß(1,3)-D-glucan and ß(1,6)-D-glucan. We found that the GH16 endo-ß(1,3)-D-glucanase PfLam16A from Pyrococcus furiosus was able to completely and reproducibly degrade ß(1,3)-D-glucan without causing the release of other polymers. The cell wall degradation caused by PfLam16A was similar to that of Quantazyme, a recombinant endo-ß(1,3)-D-glucanase no longer commercially available. Moreover, other recombinant ß(1,3)-D-glucanases caused either incomplete or excessive degradation, suggesting deficient access to the substrate or release of other polysaccharides. CONCLUSIONS: The discovery of a reliable and efficient recombinant endo-ß(1,3)-D-glucanase, capable of replacing the previously mentioned enzyme, will be useful for carrying out studies requiring the digestion of the fungal cell wall ß(1,3)-D-glucan. This new commercial endo-ß(1,3)-D-glucanase will allow the study of the cell wall composition under different conditions, along the cell cycle, in response to environmental changes or in cell wall mutants. Furthermore, this enzyme will also be greatly valuable for other practical and commercial applications such as genome research, chromosomes extraction, cell transformation, protoplast formation, cell fusion, cell disruption, industrial processes and studies of new antifungals that specifically target cell wall synthesis.

Functional characterisation and product specificity of Endo-ß-1,3-glucanase from alkalophilic bacterium, Bacillus lehensis G1.

Endo-ß-1,3-glucanase from alkalophilic bacterium, Bacillus lehensis G1 (Blg32) composed of 284 amino acids with a predicted molecular mass of 31.6 kDa is expressed in Escherichia coli and purified to homogeneity. Herein, Blg32 characteristics, substrates and product specificity as well as structural traits that might be involved in the production of sugar molecules are analysed. This enzyme functions optimally at the temperature of 70 °C, pH value of 8.0 with its catalytic activity strongly enhanced by Mn2+. Remarkably, the purified enzyme is highly stable in high temperature and alkaline conditions. It exhibits the highest activity on laminarin (376.73 U/mg) followed by curdlan and yeast ß-glucan. Blg32 activity increased by 62% towards soluble substrate (laminarin) compared to insoluble substrate (curdlan). Hydrolytic products of laminarin were oligosaccharides with degree of polymerisation (DP) of 1 to 5 with the main product being laminaritriose (DP3). This suggests that the active site of Blg32 could recognise up to five glucose units. High concentration of Blg32 mainly produces glucose whilst low concentration of Blg32 yields oligosaccharides with different DP (predominantly DP3). A theoretical structural model of Blg32 was constructed and structural analysis revealed that Trp156 is involved in multiple hydrophobic stacking interactions. The amino acid was predicted to participate in substrate recognition and binding. It was also exhibited that catalytic groove of Blg32 has a narrow angle, thus limiting the substrate binding reaction. All these properties and knowledge of the subsites are suggested to be related to the possible mode of action of how Blg32 produces glucooligosaccharides.

Biochemical Characterization of a Novel Endo-1,3-ß-Glucanase from the Scallop Chlamys farreri.

Endo-1,3-ß-glucanases derived from marine mollusks have attracted much attention in recent years because of their unique transglycosylation activity. In this study, a novel endo-1,3-ß-glucanase from the scallop Chlamys farreri, named Lcf, was biochemically characterized. Unlike in earlier studies on marine mollusk endo-1,3-ß-glucanases, Lcf was expressed in vitro first. Enzymatic analysis demonstrated that Lcf preferred to hydrolyze laminarihexaose than to hydrolyze laminarin. Furthermore, Lcf was capable of catalyzing transglycosylation reactions with different kinds of glycosyl acceptors. More interestingly, the transglycosylation specificity of Lcf was different from that of other marine mollusk endo-1,3-ß-glucanases, although they share a high sequence identity. This study enhanced our understanding of the diverse enzymatic specificities of marine mollusk endo-1,3-ß-glucanases, which facilitated development of a unique endo-1,3-ß-glucanase tool in the synthesis of novel glycosides.

Improving Regulation of Enzymatic and Non-Enzymatic Antioxidants and Stress-Related Gene Stimulation in Cucumber mosaic cucumovirus-Infected Cucumber Plants Treated with Glycine Betaine, Chitosan and Combination.

Cucumber mosaic cucumovirus (CMV) is a deadly plant virus that results in crop-yield losses with serious economic consequences. In recent years, environmentally friendly components have been developed to manage crop diseases as alternatives to chemical pesticides, including the use of natural compounds such as glycine betaine (GB) and chitosan (CHT), either alone or in combination. In the present study, the leaves of the cucumber plants were foliar-sprayed with GB and CHT-either alone or in combination-to evaluate their ability to induce resistance against CMV. The results showed a significant reduction in disease severity and CMV accumulation in plants treated with GB and CHT, either alone or in combination, compared to untreated plants (challenge control). In every treatment, growth indices, leaf chlorophylls content, phytohormones (i.e., indole acetic acid, gibberellic acid, salicylic acid and jasmonic acid), endogenous osmoprotectants (i.e., proline, soluble sugars and glycine betaine), non-enzymatic antioxidants (i.e., ascorbic acid, glutathione and phenols) and enzymatic antioxidants (i.e., superoxide dismutase, peroxidase, polyphenol oxidase, catalase, lipoxygenase, ascorbate peroxidase, glutathione reductase, chitinase and ß-1,3 glucanase) of virus-infected plants were significantly increased. On the other hand, malondialdehyde and abscisic acid contents have been significantly reduced. Based on a gene expression study, all treated plants exhibited increased expression levels of some regulatory defense genes such as PR1 and PAL1. In conclusion, the combination of GB and CHT is the most effective treatment in alleviated virus infection. To our knowledge, this is the first report to demonstrate the induction of systemic resistance against CMV by using GB.

Cloning and expression analysis of an endo-1,3-ß-D-glucosidase from Phytophthora cinnamomi.

Phytophthora is considered one of the most destructive genus for many agricultural plant species worldwide, with a strong environmental and economic impact. Phytophthora cinnamomi is a highly aggressive Phytophthora species associated with the forest decline and responsible for the ink disease in chestnut trees (Castanea sativa Miller), a culture which is extremely important in Europe. This pathogenicity occurs due to the action of several enzymes like the hydrolysis of 1,3-ß-glucans at specific sites by the enzyme endo-1,3-ß-D-glucosidase. The aim of this work to analyze the heterologous expression in two microorganisms, Escherichia coli and Pichia pastoris, of an endo-1,3-ß-D-glucosidase encoded by the gene ENDO1 (AM259651) from P. cinnamomi. Different plasmids were used to clone the gene on each organism and the real-time quantitative polymerase chain reaction was used to determine its level of expression. Homologous expression was also analyzed during growth in different carbon sources (glucose, cellulose, and sawdust) and time-course experiments were used for endo-1,3-ß-D-glucosidase production. The highest expression of the endo-1,3-ß-D-glucosidase gene occurred in glucose after 8 h of induction. In vivo infection of C. sativa by P. cinnamomi revealed an increase in endo-1,3-ß-D-glucosidase expression after 12 h. At 24 h its expression decreased and at 48 h there was again a slight increase in expression, and more experiments in order to further explain this fact are underway.

Characterization of Pneumocystis murina Bgl2, an Endo-ß-1,3-Glucanase and Glucanosyltransferase.

Glucan is the major cell wall component of Pneumocystis cysts. In the current study, we have characterized Pneumocystis Bgl2 (EC 3.2.1.58), an enzyme with glucanosyltransferase and ß-1,3 endoglucanase activity in other fungi. Pneumocystis murina, Pneumocystis carinii, and Pneumocystis jirovecii bgl2 complementary DNA sequences encode proteins of 437, 447, and 408 amino acids, respectively. Recombinant P. murina Bgl2 expressed in COS-1 cells demonstrated ß-glucanase activity, as shown by degradation of the cell wall of Pneumocystis cysts. It also cleaved reduced laminaripentaose and transferred oligosaccharides, resulting in polymers of 6 and 7 glucan residues, demonstrating glucanosyltransferase activity. Surprisingly, confocal immunofluorescence analysis of P. murina-infected mouse lung sections using an antibody against recombinant Bgl2 showed that the native protein is localized primarily to the trophic form of Pneumocystis in both untreated mice and mice treated with caspofungin, an antifungal drug that inhibits ß-1,3-glucan synthase. Thus, like other fungi, Bgl2 of Pneumocystis has both endoglucanase and glucanosyltransferase activities. Given that it is expressed primarily in trophic forms, further studies are needed to better understand its role in the biology of Pneumocystis.

Transglycosylation Activity of Catalytic Domain Mutant of Endo-1,3-ß-glucanase from Cellulosimicrobium cellulans.

BACKGROUND: Oligosaccharides are of great value in drug discovery programs which address a wide range of therapeutic strategies in medical specialties. However, owing to difficulties in oligosaccharide synthesis by conventional methods, oligosaccharide assembly using enzymes has been explored. The transglycosylases have been demonstrated to be effective for the oligosaccharide synthesis. Further studies are required to improve the specificity and activity of transglycosylases. There is an additional approach to use mutated glycosidase which transforms into glycosyltransferase with a decreased hydrolytic activity. The substitution of catalytic residue in glycosidase results in the loss of hydrolytic activity. During the reaction with glucanase, reaction of water with the substrate - enzyme intermediate results in the production of a hydrolyzed sugar. When the water molecule is replaced by a competing sugar, a new glycoside linkage is formed as a result of transglycosylation. OBJECTIVE: In this article, we evaluated the transglycosylation activity of endo-1,3-ß-glucanase mutant, E119G, toward laminarioligosaccharides under various pH and temperature conditions, in comparison with those of the wild-type enzyme. We also analyzed the effect of glucose and laminaribiose on the transglycosylation activity. METHOD: In this article, we generated the E119G mutant of endo-1,3-ß-glucanase from Cellulosimicrobium cellulans DK-1. The residue, Glu119, would act as a nucleophile in the reaction and affect the balance between hydrolysis and transglycosylation. The enzymatic activities of wild-type and E119G were estimated by detecting the products obtained from laminarioligosaccharides as substrates. We also analyzed the effect of reaction conditions such as temperature and pH on the enzymatic activity of E119G toward laminaritriose. We further analyzed the enzymatic activity of E119G toward laminaritriose in the presence of glucose or laminaribiose to investigate whether these additional molecules could accelerate the transglycosylation activity. RESULTS: The purified E119G mutant of endo-1,3-ß-glucanase was properly folded, and exhibited the secondary structure, similar to that of wild-type. The E119G mutant exhibited enhanced transglycosylation activity and decreased hydrolytic activity, relative to the wild-type. The hydrolytic as well as transglycosylation activities of E119G decreased with the decrease in temperature, however, the ratio of transglycosylation products increased. The temperature-dependent degree of reduction in hydrolytic activity was higher than that in the transglycosylation activity. The enzymatic activities were similar within the range of pH 4.0 - 7.4, while those at pH 8.0 and 8.5 were slightly decreased. The enzymatic activity of E119G toward laminaritriose in the presence of glucose was ineffective, while the addition of laminaribiose evidently increased the transglycosylation products such as laminaritetraose and laminaripentaose. CONCLUSION: A mutation of catalytic residue, Glu119 to Gly, in endo-1,3-ß-glucanase from Cellulosimicrobium cellulans exhibited transglycosylation activity on laminarioligosaccharides. The combination of laminaribiose and laminaritriose as a substrate enhanced the transglycosylation activity. According to the structural information previously reported, laminaritriose mainly binds to the enzyme at the subsites from -1 to -3 and forms a link with laminaribiose, which transiently binds to the subsites +1 and +2. To increase the amount of transglycosylation product, the reaction was found to be effective at low temperature.

[Evaluation of Conventional Antifungal Agents against Recombinant Yeast Overexpressing ß-1,3-Glucanase].

　Only 4 classes of antifungal agents comprising 9 compounds are effective against deep mycosis in Japan, and it has been difficult to develop new antifungal specific agents. Micafungin, which has been used as an antifungal agent since 2002, inhibits ß-1,3-glucan synthesis in fungal cell walls, thereby killing yeast and filamentous fungi with no septum. In this study, we constructed a pYES2-BGL2 vector to overexpress ß-1,3-glucanase (BGL2) in yeast (Saccharomyces cerevisiae INVSc1) and evaluated the synergy between BGL2 overexpression and conventional antifungal agents. The recombinant yeast was incubated in SC-Ura medium, which contained galactose to induce BGL2 overexpression. The recombinant yeast with induced BGL2 overexpression was also frozen and crushed to obtain crude protein for sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), which revealed robust BGL2 overexpression compared with that in the control yeast without the expression vector. Therefore, we considered that we successfully constructed the recombinant yeast to express more BGL2. Further, 3 conventional antifungal agents (amphotericin B, micafungin, and miconazole) were more effective against the recombinant yeast than against the control yeast. From this result, it is suggested that BGL2 overexpression has an enhancing effect on conventional antifungal agents. Hence, glucanase-inducing compounds could act as novel antifungal drugs by augmenting the effectiveness of conventional antifungal agents.

Transcriptome and secretome analysis of Aspergillus fumigatus in the presence of sugarcane bagasse.

BACKGROUND: Sugarcane bagasse has been proposed as a lignocellulosic residue for second-generation ethanol (2G) produced by breaking down biomass into fermentable sugars. The enzymatic cocktails for biomass degradation are mostly produced by fungi, but low cost and high efficiency can consolidate 2G technologies. A. fumigatus plays an important role in plant biomass degradation capabilities and recycling. To gain more insight into the divergence in gene expression during steam-exploded bagasse (SEB) breakdown, this study profiled the transcriptome of A. fumigatus by RNA sequencing to compare transcriptional profiles of A. fumigatus grown on media containing SEB or fructose as the sole carbon source. Secretome analysis was also performed using SDS-PAGE and LC-MS/MS. RESULTS: The maximum activities of cellulases (0.032 U mL-1), endo-1,4-ß--xylanase (10.82 U mL-1) and endo-1,3-ß glucanases (0.77 U mL-1) showed that functional CAZymes (carbohydrate-active enzymes) were secreted in the SEB culture conditions. Correlations between transcriptome and secretome data identified several CAZymes in A. fumigatus. Particular attention was given to CAZymes related to lignocellulose degradation and sugar transporters. Genes encoding glycoside hydrolase classes commonly expressed during the breakdown of cellulose, such as GH-5, 6, 7, 43, 45, and hemicellulose, such as GH-2, 10, 11, 30, 43, were found to be highly expressed in SEB conditions. Lytic polysaccharide monooxygenases (LPMO) classified as auxiliary activity families AA9 (GH61), CE (1, 4, 8, 15, 16), PL (1, 3, 4, 20) and GT (1, 2, 4, 8, 20, 35, 48) were also differentially expressed in this condition. Similarly, the most important enzymes related to biomass degradation, including endoxylanases, xyloglucanases, ß-xylosidases, LPMOs, α-arabinofuranosidases, cellobiohydrolases, endoglucanases and ß-glucosidases, were also identified in the secretome. CONCLUSIONS: This is the first report of a transcriptome and secretome experiment of Aspergillus fumigatus in the degradation of pretreated sugarcane bagasse. The results suggest that this strain employs important strategies for this complex degradation process. It was possible to identify a set of genes and proteins that might be applied in several biotechnology fields. This knowledge can be exploited for the improvement of 2G ethanol production by the rational design of enzymatic cocktails.

C-Terminal sequence is involved in the incorporation of Bgl2p glucanosyltransglycosylase in the cell wall of Saccharomyces cerevisiae.

A cell wall (CW) provides a protective barrier for a yeast cell and is a firm structure that nevertheless dynamically changes during cell's growth. Bgl2p is a non-covalently anchored glucanosyltransglycosylase in the CW of the yeast Saccharomyces cerevisiae. The mode of its anchorage is poorly understood, while its association with CW components is tight and resistant to 1-h treatment with 1% SDS at 37°C. In order to demarcate the potential structural block responsible for incorporation of Bgl2p into the CW, bioinformatics analysis of its sequence was performed, and a conservative structural region was identified in the C-terminal region of Bgl2p, which was absent in its homologues in S. cerevisiae, the Scw4p and Scw10p. Deletion of this region disrupted the incorporation of Bgl2p into the CW and led to release of this protein through the CW into the culture medium. Two left-handed polyproline-II helices were identified in the C-terminal region of the structure model of a wild-type Bgl2p. These helices potentially formed binding sites, which were absent in the truncated protein. Using immune fluorescence microscopy, we demonstrated that C-truncated Bgl2p was exported into culture medium and lost its ability to form fibrils described earlier. It was also shown that the C-terminal truncation of Bgl2p led to a more severe decrease of cell survivability in extreme conditions than BGL2 deletion.

A first glycoside hydrolase family 50 endo-ß-1,3-d-glucanase from Pseudomonas aeruginosa.

A novel ß-1,3-glucanase gene (PaBglu50A) from Pseudomonas aeruginosa CAU 342A was cloned and expressed in Escherichia coli. The deduced amino acid sequence of PaBglu50A showed the highest identity of 34% with the ß-agarase belonging to glycoside hydrolase (GH) family 50. The purified PaBglu50A had maximal activity at pH 5.5 and 45°C, respectively. It was stable in the range of pH 4.0-8.0 and at temperatures below 40°C. The Km and Vmax of PaBglu50A for curdlan and laminarin were 94.4mgml-1 and 23.4µmolmin-1mg-1, 3.65mgml-1 and 8.89µmolmin-1mg-1, respectively. All characterized members of GH family 50 were only active towards agarose so far. However, the recombinant protein PaBglu50A did not display activity towards agarose but showed activity towards water-insoluble curdlan and laminarin. The hydrolysis products for curdlan supported this protein to be an endo-ß-1,3-glucanase, making a significant difference from the reported enzymes of GH family 50. These results suggested that PaBglu50A is the first endo-type ß-1,3-glucanase (EC 3.2.1.39) in GH family 50.

The Dual Activity Responsible for the Elongation and Branching of ß-(1,3)-Glucan in the Fungal Cell Wall.

ß-(1,3)-Glucan, the major fungal cell wall component, ramifies through ß-(1,6)-glycosidic linkages, which facilitates its binding with other cell wall components contributing to proper cell wall assembly. Using Saccharomyces cerevisiae as a model, we developed a protocol to quantify ß-(1,6)-branching on ß-(1,3)-glucan. Permeabilized S. cerevisiae and radiolabeled substrate UDP-(14C)glucose allowed us to determine branching kinetics. A screening aimed at identifying deletion mutants with reduced branching among them revealed only two, the bgl2Δ and gas1Δ mutants, showing 15% and 70% reductions in the branching, respectively, compared to the wild-type strain. Interestingly, a recombinant Gas1p introduced ß-(1,6)-branching on the ß-(1,3)-oligomers following its ß-(1,3)-elongase activity. Sequential elongation and branching activity of Gas1p occurred on linear ß-(1,3)-oligomers as well as Bgl2p-catalyzed products [short ß-(1,3)-oligomers linked by a linear ß-(1,6)-linkage]. The double S. cerevisiae gas1Δ bgl2Δ mutant showed a drastically sick phenotype. An ScGas1p ortholog, Gel4p from Aspergillus fumigatus, also showed dual ß-(1,3)-glucan elongating and branching activity. Both ScGas1p and A. fumigatus Gel4p sequences are endowed with a carbohydrate binding module (CBM), CBM43, which was required for the dual ß-(1,3)-glucan elongating and branching activity. Our report unravels the ß-(1,3)-glucan branching mechanism, a phenomenon occurring during construction of the cell wall which is essential for fungal life.IMPORTANCE The fungal cell wall is essential for growth, morphogenesis, protection, and survival. In spite of being essential, cell wall biogenesis, especially the core ß-(1,3)-glucan ramification, is poorly understood; the ramified ß-(1,3)-glucan interconnects other cell wall components. Once linear ß-(1,3)-glucan is synthesized by plasma membrane-bound glucan synthase, the subsequent event is its branching event in the cell wall space. Using Saccharomyces cerevisiae as a model, we identified GH72 and GH17 family glycosyltransferases, Gas1p and Bgl2p, respectively, involved in the ß-(1,3)-glucan branching. The sick phenotype of the double Scgas1Δ bgl2Δ mutant suggested that ß-(1,3)-glucan branching is essential. In addition to ScGas1p, GH72 family ScGas2p and Aspergillus fumigatus Gel4p, having CBM43 in their sequences, showed dual ß-(1,3)-glucan elongating and branching activity. Our report identifies the fungal cell wall ß-(1,3)-glucan branching mechanism. The essentiality of ß-(1,3)-glucan branching suggests that enzymes involved in the glucan branching could be exploited as antifungal targets.

The cell wall-localized atypical ß-1,3 glucanase ZERZAUST controls tissue morphogenesis in Arabidopsis thaliana.

Orchestration of cellular behavior in plant organogenesis requires integration of intercellular communication and cell wall dynamics. The underlying signaling mechanisms are poorly understood. Tissue morphogenesis in Arabidopsis depends on the receptor-like kinase STRUBBELIG. Mutations in ZERZAUST were previously shown to result in a strubbelig-like mutant phenotype. Here, we report on the molecular identification and functional characterization of ZERZAUST We show that ZERZAUST encodes a putative GPI-anchored ß-1,3 glucanase suggested to degrade the cell wall polymer callose. However, a combination of in vitro, cell biological and genetic experiments indicate that ZERZAUST is not involved in the regulation of callose accumulation. Nonetheless, Fourier-transformed infrared-spectroscopy revealed that zerzaust mutants show defects in cell wall composition. Furthermore, the results indicate that ZERZAUST represents a mobile apoplastic protein, and that its carbohydrate-binding module family 43 domain is required for proper subcellular localization and function whereas its GPI anchor is dispensable. Our collective data reveal that the atypical ß-1,3 glucanase ZERZAUST acts in a non-cell-autonomous manner and is required for cell wall organization during tissue morphogenesis.

Tryptophan introduction can change ß-glucan binding ability of the carbohydrate-binding module of endo-1,3-ß-glucanase.

Endo-1,3-ß-glucanase from Cellulosimicrobium cellulans DK-1 has a carbohydrate-binding module (CBM-DK) at the C-terminal side of a catalytic domain. Out of the imperfect tandem α-, ß-, and γ-repeats in CBM-DK, the α-repeat primarily contributes to ß-glucan binding. This unique feature is derived from Trp273 in α-repeat, whose corresponding residues in ß- and γ-repeats are Asp314 and Gly358, respectively. In this study, we generated Trp-switched mutants, W273A/D314W, D270A/W273A/D314W, W273A/G358W, and D270A/W273A/G358W, and analyzed their binding abilities toward laminarioligosaccharides and laminarin. While the binding affinities of D270A/W273A and W273A mutants were either lost or much lower than that of the wild-type, those of Trp-switched mutants recovered, indicating that a Trp introduction in ß- or γ-repeat can substitute the α-repeat by primarily contributing to ß-glucan binding. Thus, we have successfully engineered a CBM-DK that binds to laminarin by a mechanism different from that of the wild-type, but with similar affinity.

A new recombinant endo-1,3-ß-D-glucanase from the marine bacterium Formosa algae KMM 3553: enzyme characteristics and transglycosylation products analysis.

A specific endo-1,3-ß-D-glucanase (GFA) gene was found in genome of marine bacterium Formosa algae KMM 3553. For today this is the only characterized endo-1,3-ß-D-glucanase (EC 3.2.1.39) in Formosa genus and the only bacterial EC 3.2.1.39 GH16 endo-1,3-ß-D-glucanase with described transglycosylation activity. It was expressed in E. coli and isolated in homogeneous state. Investigating the products of polysaccharides digestion with GFA allowed to establish it's substrate specificity and classify this enzyme as glucan endo-1,3-ß-D-glucosidase (EC 3.2.1.39). The amino-acid sequence of GFA consists of 556 residues and shows sequence similarity of 45-85% to ß-1,3-glucanases of bacteria belonging to the CAZy 16th structural family of glycoside hydrolases GH16. Enzyme has molecular weight 61 kDa, exhibits maximum of catalytic activity at 45 °C, pH 5.5. Half-life period at 45 °Ð¡ is 20 min, complete inactivation happens at 55 °C within 10 min. Km for hydrolysis of laminarin is 0.388 mM. GFA glucanase from marine bacteria F. algae is one of rare enzymes capable to catalyze reactions of transglycosylation. It catalyzed transfer of glyconic part of substrate molecule on methyl-ß-D-xylopyranoside, glycerol and methyl-α-D-glucopyranoside. The enzyme can be used in structure determination of ß-1,3-glucans (or mixed 1,3;1,4- and 1,3;1,6-ß-D-glucans) and enzymatic synthesis of new carbohydrate-containing compounds.

Antipathy of Trichoderma against Sclerotium rolfsii Sacc.: Evaluation of Cell Wall-Degrading Enzymatic Activities and Molecular Diversity Analysis of Antagonists.

The fungus Trichoderma is a teleomorph of the Hypocrea genus and associated with biological control of plant diseases. The microscopic, biochemical, and molecular characterization of Trichoderma was carried out and evaluated for in vitro antagonistic activity against the fungal pathogen Sclerotium rolfsii causing stem rot disease in groundnut. In total, 11 isolates of Trichoderma were examined for antagonism at 6 and 12 days after inoculation (DAI). Out of 11, T. virens NBAII Tvs12 evidenced the highest (87.91%) growth inhibition of the test pathogen followed by T. koningii MTCC 796 (67.03%), T. viride NBAII Tv23 (63.74%), and T. harzianum NBAII Th1 (60.44%). Strong mycoparasitism was observed in the best antagonist Tvs12 strain during 6-12 DAI. The specific activity of cell wall-degrading enzymes - chitinase and ß-1,3-glucanase - was positively correlated with growth inhibition of the test pathogen. In total, 18 simple sequence repeat (SSR) polymorphisms were reported to amplify 202 alleles across 11 Trichoderma isolates. The average polymorphism information content for SSR markers was found to be 0.80. The best antagonist Tvs 12 was identified with 7 unique SSR alleles amplified by 5 SSR markers. Clustering patterns of 11 Trichoderma strains showed the best antagonist T. virens NBAII Tvs 12 outgrouped with a minimum 3% similarity from the rest of Trichoderma.

The ß-1,3-glucanosyltransferases (Gels) affect the structure of the rice blast fungal cell wall during appressorium-mediated plant infection.

The fungal wall is pivotal for cell shape and function, and in interfacial protection during host infection and environmental challenge. Here, we provide the first description of the carbohydrate composition and structure of the cell wall of the rice blast fungus Magnaporthe oryzae. We focus on the family of glucan elongation proteins (Gels) and characterize five putative ß-1,3-glucan glucanosyltransferases that each carry the Glycoside Hydrolase 72 signature. We generated targeted deletion mutants of all Gel isoforms, that is, the GH72+ , which carry a putative carbohydrate-binding module, and the GH72- Gels, without this motif. We reveal that M. oryzae GH72+ GELs are expressed in spores and during both infective and vegetative growth, but each individual Gel enzymes are dispensable for pathogenicity. Further, we demonstrated that a Δgel1Δgel3Δgel4 null mutant has a modified cell wall in which 1,3-glucans have a higher degree of polymerization and are less branched than the wild-type strain. The mutant showed significant differences in global patterns of gene expression, a hyper-branching phenotype and no sporulation, and thus was unable to cause rice blast lesions (except via wounded tissues). We conclude that Gel proteins play significant roles in structural modification of the fungal cell wall during appressorium-mediated plant infection.

The role of Bgl2p in the transition to filamentous cells during biofilm formation by Candida albicans.

The fungal pathogen Candida albicans undergoes a transition from yeast cells to filamentous cells that is related to its pathogenicity. The complex multicellular processes involved in biofilm formation by this fungus also include this transition. In this work, we investigated the morphological role of the Bgl2 protein (Bgl2p) in the transition to filamentous cells during biofilm formation by C. albicans. Bgl2p has been identified as a ß-1, 3-glucosyltransferase, and transcription of the CaBGL2 gene is upregulated during biofilm formation. We used scanning electron microscopy to observe the microstructure of a bgl2 null mutant during biofilm formation and found a delay in the transition to filamentous cells in the premature phase (24 hours) of biofilm formation. Deletion of the CaBGL2 gene led to a decrease in the expression of CPH2 and TEC1, which encode transcription factors required for the transition to the filamentous form. These findings indicate that Bgl2p plays a role in the transition to filamentous cells during biofilm formation by C. albicans.

Glycosylphosphatidylinositol (GPI) Modification Serves as a Primary Plasmodesmal Sorting Signal.

Plasmodesmata (Pd) are membranous channels that serve as a major conduit for cell-to-cell communication in plants. The Pd-associated ß-1,3-glucanase (BG_pap) and CALLOSE BINDING PROTEIN1 (PDCB1) were identified as key regulators of Pd conductivity. Both are predicted glycosylphosphatidylinositol-anchored proteins (GPI-APs) carrying a conserved GPI modification signal. However, the subcellular targeting mechanism of these proteins is unknown, particularly in the context of other GPI-APs not associated with Pd Here, we conducted a comparative analysis of the subcellular targeting of the two Pd-resident and two unrelated non-Pd GPI-APs in Arabidopsis (Arabidopsis thaliana). We show that GPI modification is necessary and sufficient for delivering both BG_pap and PDCB1 to Pd Moreover, the GPI modification signal from both Pd- and non-Pd GPI-APs is able to target a reporter protein to Pd, likely to plasma membrane microdomains enriched at Pd As such, the GPI modification serves as a primary Pd sorting signal in plant cells. Interestingly, the ectodomain, a region that carries the functional domain in GPI-APs, in Pd-resident proteins further enhances Pd accumulation. However, in non-Pd GPI-APs, the ectodomain overrides the Pd targeting function of the GPI signal and determines a specific GPI-dependent non-Pd localization of these proteins at the plasma membrane and cell wall. Domain-swap analysis showed that the non-Pd localization is also dominant over the Pd-enhancing function mediated by a Pd ectodomain. In conclusion, our results indicate that segregation between Pd- and non-Pd GPI-APs occurs prior to Pd targeting, providing, to our knowledge, the first evidence of the mechanism of GPI-AP sorting in plants.