Cell wall autolytic activities and distribution of cell wall glucanases in Zea mays L. seedlings

Exo- and endo-glucanases mediate specific degradation of cell wall (1,3)(1,4)-beta-D-glucans and these enzymes have been related to auxin-mediated growth and development of cereal coleoptiles. However, their distribution and functions have not been well established in other tissues. In this study the glucanase activities and cell wall autolytic activities of different maize organs were determined. Autolysis assays serve to evaluate the hydrolysis of cell wall polymers in situ by measuring the sugars released from the insoluble cell wall matrix resulting from the action of bound enzymes. Autolytic activities were observed in the cell walls of elongating young leaves, mesocotyl and roots of maize. Wall proteins extracted from all of these structures are enriched in several types of glucanases and other wall polysaccharide hydrolases. These enzymes therefore appear to have a widespread and fundamental role in wall metabolism in growing tissues.     

An alpha-glucan elicitor from the cell wall of a biocontrol binucleate Rhizoctonia isolate

Binucleate Rhizoctonia (BNR) isolate (232-C6) is an effective biocontrol agent for protection of potato from Rhizoctonia canker, a disease caused by Rhizoctonia solani. Production of hydrolytic enzymes is one of the best known inducible defense responses following microbial infection. We isolated and characterized a cell wall alpha-glucan from BNR, which induces beta-1,3 glucanase activities in potato sprouts, the primary site of infection by R. solani. An autoclaving method, previously reported for isolation of oligosaccharide elicitors was used, and the glucan purified by chromatographic techniques. Maximal induction of beta-1,3 glucanase activity in potato sprouts was obtained with 250 microg of the alpha-glucan elicitor after 6 days from inoculation time. Both, BNR mycelium and the alpha-glucan produced a similar kinetic response of beta-1,3 glucanase. However, the alpha-glucan did not induce phytoalexin accumulation, previously correlated with the defense response. Uronic acids (approximately 10% with respect to total neutral sugars) were determined and identified as glucuronic acid by high-pH anion-exchange chromatography. Methylation analysis showed that the glucan consists of (1-->3) and (1-->4)-linked glucose units with preponderance of the first ones. Some of the (1-->4) linkages were branched at position 6. The glucan was partially degraded with amyloglucosidase. This, together with the NMR spectra data and the high optical rotation of the original (+195 degrees ) and degraded glucans (+175 degrees ) proved the alpha configuration. Further methylation of the amyloglucosidase degraded glucans indicated that they consist of (1-->3)-linked glucoses. The present study is the first report on the isolation and characterization of an alpha-glucan from Rhizoctonia, that may be important as a biocontrol factor.     

Purification and characterization of beta-1,6-glucanase of Streptomyces rochei application in the study of yeast cell wall proteins

A beta-1,6-glucanase was purified to apparent homogeneity from a commercial yeast digestive enzyme prepared from Streptomyces rochei by a series of column chromatographies. The molecular mass of the purified enzyme was 60 kDa by SDS-PAGE. The purified enzyme had an optimum pH range from 4.0 to 6.0 and was stable in the same pH range. The enzyme was stable under 50 degrees C but lost almost all activity at 60 degrees C. The enzyme was specific to beta-1,6-glucan and had little activity towards beta-1,3-glucan and beta-1,4-glucan. When the beta-1,6-glucan was hydrolyzed with the purified enzyme for 5 h, the reaction products contained 20% glucose, 36% gentiobiose, and 44% other oligosaccharides, suggesting that the enzyme is an endo-type glucanase. When the purified enzyme was used for the digestion of the cell wall of Saccharomyces cerevisiae, cell-wall proteins covalently bound to the cell-wall glucan were recovered as soluble forms, suggesting that this enzyme is useful for analysis of yeast-cell wall proteins.     

Purification and properties of a β-1,6-glucanase from Streptomyces sp. EF-14, an actinomycete antagonistic to Phytophthora spp.

Extracellular enzymes with glucanase activities are an important component of actinomycete-fungus antagonism. Streptomyces sp. EF-14 has been previously identified as one of the most potent antagonists of Phytophthora spp. A beta-1,6-glucanase (EC 3.2.1.75; glucan endo-1,6-beta-glucosidase) was purified by four chromatographic steps from the culture supernatant of strain EF-14 grown on a medium with lyophilized cells of Candida utilis as main nutrient source. The glucanase level in this medium followed a characteristic pattern in which the rise of beta-1,6-glucanase activity always preceded that of beta-1,3-glucanase. The molecular mass of the enzyme was estimated to be 65 kDa and the pI approximately 5.5. It hydrolyzed pustulan by an endo-mechanism generating gentiobiose and glucose as final products. Laminarin was not hydrolyzed indicating that the enzyme does not recognize beta-1,6-links flanked by beta-1,3-links. No significant clearing of yeast cell walls in liquid suspensions or in agar plates was observed indicating that this beta-1,6-glucanase is a non-lytic enzyme. This is the first beta-1,6-glucanase characterized from an actinomycete.     

Analysis of the beta-1,3-Glucanolytic System of the Biocontrol Agent Trichoderma harzianum

The biocontrol agent Trichoderma harzianum IMI206040 secretes beta-1,3-glucanases in the presence of different glucose polymers and fungal cell walls. The level of beta-1,3-glucanase activity secreted was found to be proportional to the amount of glucan present in the inducer. The fungus produces at least seven extracellular beta-1,3-glucanases upon induction with laminarin, a soluble beta-1,3-glucan. The molecular weights of five of these enzymes fall in the range from 60,000 to 80,000, and their pIs are 5.0 to 6.8. In addition, a 35-kDa protein with a pI of 5.5 and a 39-kDa protein are also secreted. Glucose appears to inhibit the formation of all of the inducible beta-1,3-glucanases detected. A 77-kDa glucanase was partially purified from the laminarin culture filtrate. This enzyme is glycosylated and belongs to the exo-beta-1,3-glucanase group. The properties of this complex group of enzymes suggest that the enzymes might play different roles in host cell wall lysis during mycoparasitism.     

Cell wall-linked cryptococcal phospholipase B1 is a source of secreted enzyme and a determinant of cell wall integrity

Phospholipase B (Plb1) is secreted by pathogenic fungi and is a proven virulence determinant in Cryptococcus neoformans. Cell-associated Plb1 is presumptively involved in fungal membrane biogenesis and remodelling. We have also identified it in cryptococcal cell walls. Motif scanning programs predict that Plb1 is attached to cryptococcal membranes via a glycosylphosphatidylinositol (GPI) anchor, which could regulate Plb1 export and secretion. A functional GPI anchor was identified in cell-associated Plb1 by (G)PI-specific phospholipase C (PLC)-induced release of Plb1 from strain H99 membrane rafts and inhibition of GPI anchor synthesis by YW3548, which prevented Plb1 secretion and transport to membranes and cell walls. Plb1 containing beta-1,6-linked glucan was released from H99 (wild-type strain) cell walls by beta-1,3 glucanase, consistent with covalent attachment of Plb1 via beta-1,6-linked glucans to beta-1,3-linked glucan in the central scaffold of the wall. Naturally secreted Plb1 also contained beta-1,6-linked glucan, confirming that it originated from the cell wall. Plb1 maintains cell wall integrity because a H99 deletion mutant, DeltaPLB1, exhibited a morphological defect and was more susceptible than H99 to cell wall disruption by SDS and Congo red. Growth of DeltaPLB1 was unaffected by caffeine, excluding an effect of Plb1 on cell wall biogenesis-related signaling pathways. Environmental (heat) stress caused Plb1 accumulation in cell walls, with loss from membranes and reduced secretion, further supporting the importance of Plb1 in cell wall integrity. This is the first demonstration that Plb1 contributes to fungal survival by maintaining cell wall integrity and that the cell wall is a source of secreted enzyme.     

Beta-1,4-glucanase-like protein from the cyanobacterium Synechocystis PCC6803 is a beta-1,3-1,4-glucanase and functions in salt stress tolerance

In the present study, we characterized the gene (Cyanobase accession number slr0897) designated Ssglc encoding a beta-1,4-glucanase-like protein (SsGlc) from Synechocystis PCC6803. The deduced amino acid sequence for Ssglc showed a high degree of similarity to sequences of GH (glycoside hydrolase) family 9 beta-1,4-glucanases (cellulases) from various sources. Surprisingly, the recombinant protein obtained from the Escherichia coli expression system was able to hydrolyse barley beta-glucan and lichenan (beta-1,3-1,4-glucan), but not cellulose (beta-1,4-glucan), curdlan (beta-1,3-glucan), or laminarin (beta-1,3-1,6-glucan). A 1H-NMR analysis of the enzymatic products revealed that the enzyme hydrolyses the beta-1,4-glycosidic linkage of barley beta-glucan through an inverting mechanism. The data indicated that SsGlc was a novel type of GH9 glucanase which could specifically hydrolyse the beta-1,3-1,4-linkage of glucan. The growth of mutant Synechocystis cells in which the Ssglc gene was disrupted by a kanamycin-resistance cartridge gene was almost the same as that of the wild-type cells under continuous light (40 micromol of photons/m2 per s), a 12 h light (40 micromol of photons/m2 per s)/12 h dark cycle, cold stress (4 degrees C), and high light stress (200 micromol of photons/m2 per s). However, under salt stress (300-450 mM NaCl), growth of the Ssglc-disrupted mutant cells was significantly inhibited as compared with that of the wild-type cells. The Ssglc-disrupted mutant cells showed a decreased rate of O2 consumption and NaHCO3-dependent O2 evolution as compared with the wild-type cells under salt stress. Under osmotic stress (100-400 mM sorbitol), there was no difference in growth between the wild-type and the Ssglc-disrupted mutant cells. These results suggest that SsGlc functions in salt stress tolerance in Synechocystis PCC6803.     

EVIDENCE FOR GLUCAN COMPONENTS IN THE PRIMARY ZYGOTE WALL OF CHLAMYDOMONAS MONOICA

The primary zygote wall of C. monoica is transient and is released from mature zygospores. The fluorochromes aniline blue and primulin, used in other systems to detect β-1,3 glucans, stain the primary wall intensely. Two β-1,3 glucan synthases have been identified in higher plants: a calcium-dependent synthase produced in response to wounding and induced by chitosan, and a magnesium-dependent enzyme, associated with pollen development and unresponsive to chitosan. Chitosan has no effect on C. monoica primary wall synthesis or staining properties. We are presently testing for the effect of magnesium and/or calcium depletion on primary wall synthesis. Aniline blue and primulin do not stain purified cellulose fibers, while the fluorochrome Calcofluor does. Calcofluor also stains the primary wall intensely. For all fluorochormes tested, fluorescence is first detected in motile quadriflagellate zygotes. Aniline blue staining maximizes quickly, while Calcofluor staining continues to intensify until primary wall release. Dinitrobenzonitrile, a specific inhibitor of cellulose synthesis in plants, has no effect on primary wall synthesis in C. monoica. Addition of glucanase or cellulase to partially purified primary walls results in wall thinning and loss of staining. Using electron microscopy, we are evaluating the effects of these enzymes on primary wall ultrastructure. Further studies are needed to determine whether all three fluorochromes are recognizing the same polysaccharide component (a β-1,3 glucan or a β-1,3; β-1,4 mixed glucan), or whether Calcofluor staining indicates the presence of a distinct component containing β-1,4 linkages, such as cellulose or a xyloglucan.     

Chemical analysis of the hyphal wall of Schizophyllum commune.

1. Purified hyphal wall fragments of Schizophyllum commune are analysed and shown to consist of glucose (67.6%), mannose (3.4%), xylose (0.2%), (N-acetyl)glucosamine (12.5%), amino acids (6.4%) and some lipid material (3.0%). 2. The previously proposed structures of two glucans located at the hyphal wall surface (Wessels et al. (1972) Biochim. Biophys. Acta 273, 346-358) were essentially confirmed using methylation analysis. The mucilaginous glucan consists of 1,3-linked beta-glucan chains with branches of single glucose units attached by beta-1,6 linkages on every third unit, on average, along the chain. The alkali soluble S-glucan is an exclusively 1,3-linked alpha-glucan. 3. The alkali-insoluble R-glucan, occurring in close association with chitin, in the inner wall layer, has been characterised by methylation analysis, X-ray diffraction, enzymatic hydrolysis with purified exo-beta-1,3-glucanase and Smith degradation. It appears to be a highly branched beta-1,3,beta-1,6-glucan and a model of this glucan is proposed. Certain parts of this highly insoluble R-glucan bear a close structural similarity to the mucilaginous glucan present at the outer wall surface and in the medium.     

Crystal structure at 1.45-A resolution of the major allergen endo-beta-1,3-glucanase of banana as a molecular basis for the latex-fruit syndrome

Resolution of the crystal structure of the banana fruit endo-beta-1,3-glucanase by synchrotron X-ray diffraction at 1.45-A resolution revealed that the enzyme possesses the eightfold beta/alpha architecture typical for family 17 glycoside hydrolases. The electronegatively charged catalytic central cleft harbors the two glutamate residues (Glu94 and Glu236) acting as hydrogen donor and nucleophile residue, respectively. Modeling using a beta-1,3 linked glucan trisaccharide as a substrate confirmed that the enzyme readily accommodates a beta-1,3-glycosidic linkage in the slightly curved catalytic groove between the glucose units in positions -2 and -1 because of the particular orientation of residue Tyr33 delimiting subsite -2. The location of Phe177 in the proximity of subsite +1 suggested that the banana glucanase might also cleave beta-1,6-branched glucans. Enzymatic assays using pustulan as a substrate demonstrated that the banana glucanase can also cleave beta-1,6-glucans as was predicted from docking experiments. Similar to many other plant endo-beta-1,3-glucanases, the banana glucanase exhibits allergenic properties because of the occurrence of well-conserved IgE-binding epitopes on the surface of the enzyme. These epitopes might trigger some cross-reactions toward IgE antibodies and thus account for the IgE-binding cross-reactivity frequently reported in patients with the latex-fruit syndrome.     

beta-d-Glucan of Avena Coleoptile Cell Walls

A specific glucanase was used to liberate a noncellulosic beta-d-glucan from isolated cell walls of Avena sativa coleoptile tissue. Cell walls of this tissue contain as much as 7 to 9 mg of glucan/100 mg of dry wall. Because of the specific action pattern of the enzyme, a linkage sequence of.. 1 --> 4 Glc 1 --> 3 Glc 1 --> 4 Glc.. is indicated and the predominance of trisaccharide and tetrasaccharide as hydrolytic products suggests a rather regular repeating pattern in the polysaccharide. The trisaccharide and the tetrasaccharide are tentatively identified as 3-O-beta-cellobiosyl-d-glucose and 3-O-beta-cellotriosyl-d-glucose, respectively. Recovery of these oligosaccharides following glucanase treatment of native wall material was feasible only after wall-bound glucosidases were inactivated. In the absence of enzyme inactivation the released fragments were recovered as glucose. The beta-d-glucan was not extracted from walls by either hot water or protease treatment.Cell walls prepared from auxin-treated Avena coleoptile segments yielded less glucan than did segments incubated in buffer suggesting an auxin effect on the quantity of this wall component. No IAA-induced change in the ratio of the trisaccharide and tetrasaccharide could be detected, suggesting no shift in the 1,3 to 1,4 linkage ratio. While the enzyme acts directly on the beta-d-glucan, no elongation response was apparent when Avena sections were treated with the purified glucanase. The presence of the glucan was not associated with any wound response which could be attributed to the preparation of coleoptile segments. The relationship of glucan metabolism to auxin growth responses is discussed.     

MIG1基因和葡萄糖对扣囊复膜孢酵母细胞形态变化的影响及机理探究

【目的】研究MIG1基因和葡萄糖对扣囊复膜孢酵母细胞形态变化的影响及其机理探究。【方法】扣囊复膜孢酵母在不同浓度葡萄糖的YPD培养基中培养,敲除MIG1基因菌株在常规YPD培养基中培养,研究细胞内葡聚糖酶和几丁质酶活性以及细胞壁β-葡聚糖和几丁质含量与细胞形态变化之间的关系。【结果】培养基中葡萄糖浓度越低,扣囊复膜孢酵母菌丝体越少,单细胞酵母越多,且葡聚糖酶和几丁质酶活性越高,β-葡聚糖和几丁质含量越低;葡萄糖浓度对敲除MIG1基因菌株没有显著影响,葡聚糖酶和几丁质酶活性始终保持在较高水平,β-葡聚糖和几丁质含量也较低,菌体多以单细胞酵母形式存在。【结论】MIG1基因和葡萄糖通过葡萄糖阻遏作用调节葡聚糖酶和几丁质酶活性,进而影响细胞壁的葡聚糖和几丁质含量,最终影响扣囊复膜孢酵母细胞的形态变化。     

Autolytic activities of the cell wall in rice coleoptiles. Effects of nojirimycin

Oryza sativa L. var. bahia coleoptile cell walls show sufficient autolytic activity for the release into the surrounding medium of amounts up to 60 μg of sugars per mg of dry weight of cell wall. The products released elute in Bio-gel P.2 as mono- and polysaccharides with glucose as the sole component. The polysaccharide component releases tri- and tetrasaccharides on treatment with a glucanase specific for β (1–3) (1–4) linkages in the same proportion as that of the mixed glucan of the cell wall. This supports the hypothesis that the polysaccharide component originates from the cell wall glucan and that autolysis is therefore related to the processes of the loss of rigidity of the cell wall. Nojirimycin (a specific glucanase inhibitor and inhibitor of auxin-induced elongation) decreases autolytic activity of the cell walls, reducing it to 30% of its normal value. Bio-gel P. 2 elution of the products released in autolysis in the presence of nojirimycin shows that only the monosaccharide fraction was affected.     

Over‐expression of specific HvCslF cellulose synthase‐like genes in transgenic barley increases the levels of cell wall (1,3;1,4)‐β‐d‐glucans and alters their fine structure

Cell walls in commercially important cereals and grasses are characterized by the presence of (1,3;1,4)‐β‐d ‐glucans. These polysaccharides are beneficial constituents of human diets, where they can reduce the risk of hypercholesterolemia, type II diabetes, obesity and colorectal cancer. The biosynthesis of cell wall (1,3;1,4)‐β‐d ‐glucans in the Poaceae is mediated, in part at least, by the cellulose synthase‐like CslF family of genes. Over‐expression of the barley CslF6 gene under the control of an endosperm‐specific oat globulin promoter results in increases of more than 80% in (1,3;1,4)‐β‐d ‐glucan content in grain of transgenic barley. Analyses of (1,3;1,4)‐β‐d ‐glucan fine structure indicate that individual CslF enzymes might direct the synthesis of (1,3;1,4)‐β‐d ‐glucans with different structures. When expression of the CslF6 transgene is driven by the Pro35S promoter, the transgenic lines have up to sixfold higher levels of (1,3;1,4)‐β‐d ‐glucan in leaves, but similar levels as controls in the grain. Some transgenic lines of Pro35S:CslF4 also show increased levels of (1,3;1,4)‐β‐d ‐glucans in grain, but not in leaves. Thus, the effects of CslF genes on (1,3;1,4)‐β‐d ‐glucan levels are dependent not only on the promoter used, but also on the specific member of the CslF gene family that is inserted into the transgenic barley lines. Altering (1,3;1,4)‐β‐d ‐glucan levels in grain and vegetative tissues will have potential applications in human health, where (1,3;1,4)‐β‐d ‐glucans contribute to dietary fibre, and in tailoring the composition of biomass cell walls for the production of bioethanol from cereal crop residues and grasses.     

Molecular organization of the alkali-insoluble fraction of Aspergillus fumigatus cell wall

Physical and biological properties of the fungal cell wall are determined by the composition and arrangement of the structural polysaccharides. Cell wall polymers of fungi are classically divided into two groups depending on their solubility in hot alkali. We have analyzed the alkali-insoluble fraction of the Aspergillus fumigatus cell wall, which is the fraction believed to be responsible for fungal cell wall rigidity. Using enzymatic digestions with recombinant endo-beta-1,3-glucanase and chitinase, fractionation by gel filtration, affinity chromatography with immobilized lectins, and high performance liquid chromatography, several fractions that contained specific interpolysaccharide covalent linkages were isolated. Unique features of the A. fumigatus cell wall are (i) the absence of beta-1,6-glucan and (ii) the presence of a linear beta-1, 3/1,4-glucan, never previously described in fungi. Galactomannan, chitin, and beta-1,3-glucan were also found in the alkali-insoluble fraction. The beta-1,3-glucan is a branched polymer with 4% of beta-1,6 branch points. Chitin, galactomannan, and the linear beta-1, 3/1,4-glucan were covalently linked to the nonreducing end of beta-1, 3-glucan side chains. As in Saccharomyces cerevisiae, chitin was linked via a beta-1,4 linkage to beta-1,3-glucan. The data obtained suggested that the branching of beta-1,3-glucan is an early event in the construction of the cell wall, resulting in an increase of potential acceptor sites for chitin, galactomannan, and the linear beta-1,3/1,4-glucan.     

Antitumor effect of soluble beta-1,3-glucan from Agrobacterium sp. R259 KCTC 1019

Beta-1,3-glucans enhance immune reactions such as antitumor, antibacterial, antiviral, anticoagulatory, and wound healing activities. beta-1,3-Glucans have various functions depending on the molecular weight, degree of branching, conformation, water solubility, and intermolecular association. The molecular weight of the soluble glucan was about 15,000 as determined by a high-performance size exclusion chromatography. From the infrared (IR) and 13C NMR analytical data, the purified soluble glucan was found to exclusively consist of beta-D-glucopyranose with 1,3 linkage. We tested the immunestimulating activities of the soluble beta-1,3-glucan extracted from Agrobacterium sp. R259 KCTC 1019 and confirmed the following activities. IFN-gamma and each cytokines were induced in the spleens and thymus of mice treated with soluble beta-1,3-glucan. Adjuvant effect was observed on antibody production. Nitric oxide was synthesized in monocytic cell lines treated with beta-1,3-glucan. The cytotoxic and antitumor effects were observed on various cancer cell lines and ICR mice. These results strongly suggested that this soluble beta-1,3-glucan could be a good candidate for an immune-modulating agent.     

Molecular cloning and characterization of glucanase inhibitor proteins: coevolution of a counterdefense mechanism by plant pathogens

A characteristic plant response to microbial attack is the production of endo-beta-1,3-glucanases, which are thought to play an important role in plant defense, either directly, through the degradation of beta-1,3/1,6-glucans in the pathogen cell wall, or indirectly, by releasing oligosaccharide elicitors that induce additional plant defenses. We report the sequencing and characterization of a class of proteins, termed glucanase inhibitor proteins (GIPs), that are secreted by the oomycete Phytophthora sojae, a pathogen of soybean, and that specifically inhibit the endoglucanase activity of their plant host. GIPs are homologous with the trypsin class of Ser proteases but are proteolytically nonfunctional because one or more residues of the essential catalytic triad is absent. However, specific structural features are conserved that are characteristic of protein-protein interactions, suggesting a mechanism of action that has not been described previously in plant pathogen studies. We also report the identification of two soybean endoglucanases: EGaseA, which acts as a high-affinity ligand for GIP1; and EGaseB, with which GIP1 does not show any association. In vitro, GIP1 inhibits the EGaseA-mediated release of elicitor-active glucan oligosaccharides from P. sojae cell walls. Furthermore, GIPs and soybean endoglucanases interact in vivo during pathogenesis in soybean roots. GIPs represent a novel counterdefensive weapon used by plant pathogens to suppress a plant defense response and potentially function as important pathogenicity determinants.     

Derepression of beta-1,3-glucanases in Penicillium italicum: localization of the various enzymes and correlation with cell wall glucan mobilization and autolysis.

The localization of the derepressible beta-1,3-glucanases of Penicillium italicum and the cell wall autolysis under conditions of beta-1,3-glucanase derepression (24 h in a low-glucose medium) were studied. About 15% of the total activity was secreted into the culture medium during the 24-h period and consisted of similar amounts of each of the three beta-1,3-glucanases (I, II, III) produced by this species. Treatment of derepressed mycelia with periplasmic enzyme-inactivating agents resulted in a loss of 45% of the mycelium-bound beta-1,3-glucanase. Analysis of periplasmic enzymes solubilized by 2 M NaCl or by autolysis of isolated cell walls revealed that only beta-1,3-glucanases II and III were bound to the cell wall. These two enzymes were capable of releasing in vitro reducing sugars from cell walls, whereas beta-1,3-glucanase I was not. In addition, the autolytic activity of cell walls isolated from derepressed mycelium was greater than that of cell walls isolated from repressed mycelium. The incubation of the fungus in the low-glucose medium also resulted in the in vivo mobilization of 34% of the cell wall beta-1,3-glucan, and this mobilization was fully prevented by cycloheximide, which also blocked derepression of beta-1,3-glucanases. Derepression of beta-1,3-glucanase seems to be coupled to the mobilization of cell wall glucan.