Immobilized β-glucanases and their applications

Summary A number of -glucanase active enzyme preparations were successfully immobilized either by adsorption on Duolite S-761 phenol-formaldehyde resin or covalently on silanized Spherosil XOB-075 porous silica beads to obtain remarkably stable active biocatalysts. A Duolite immobilized -glucanase could be employed for continuous treatment of barley wort in a packed-bed column reactor to decrease viscosity and to improve filtrability. A Duolite immobilized cellulase that exhibited no detectable Avicel hydrolyzing activity could be applied for batch treatment of wheat starch process water. The same enzyme when covalently bound on Spherosil was, however, capable of hydrolyzing microcrystalline cellulose in a recirculating fluidized-bed reactor.     

Plant hydrolytic enzymes (chitinases and β-1,3-glucanases) in root reactions to pathogenic and symbiotic microorganisms

Within the last decade, a great deal of attention has been devoted to the role of chitinases and -1,3-glucanases in plant/microbe interactions. While there is strong evidence that these hydrolases are antifungal proteins, there are also recent indications of roles in both plant morphogenesis and plant/microbe signal perception. This paper reviews recent findings pertinent to root/microbe interactions, and discusses the nature and significance of specific hydrolase isoforms in symbioses with arbuscular mycorrhizal (AM) fungi.     

Pathogenesis-related functions of plant β-1,3-glucanases investigated by antisense transformation — a review

Plant β-1,3-glucanases (βGlu) have been implicated in several physiological and developmental processes, e.g., cell division, microsporogenesis, pollen germination, fertilization and seed germination. These enzymes, particularly the antifungal class-I vacuolar isoforms, are also believed to be part of the defences of plants against fungal infection. The function of βGlu in tobacco and Nicotiana sylvestris has been investigated by antisense transformation. Transformation with GLA, the gene encoding the A isoform of tobacco class-I βGlu, in reverse orientation regulated by the strong cauliflower mosaic virus 35S RNA promoter effectively and specifically blocked the induction of class-I βGlu. This induction was in response to ethylene treatment and following infection with the pathogenic fungus, Cercospora nicotianae, tobacco mosaic virus (TMV) and tobacco necrosis virus (TNV). Nevertheless, the plants compensated for this deficiency by producing a functionally equivalent (i.e., ‘ersatz’) enzyme or enzymes. The fact that compensation occurred specifically in response to infection suggests that βGlu activity has an important role in pathogenesis. Antisense transformation substantially reduced lesion size and number in virus-infected local-lesion hosts. These results suggest novel antisense-based strategies for protecting plants against virus infection. They also raise the intriguing possibility that viruses use a defence mechanism of the host, production of antifungal βGlu, to promote their own replication and spread.     

Exogenous β-glucanases and pentosanases and their impact on mashing

Commercial enzymes differ in their content of β-glucanases and xylanases and, in their ability to reduce mash viscosity and increase extract. No simple relationship exists between measurable enzyme activity and these parameters, suggesting that the benefit of these enzymes in mashing is not simply predicted from absolute levels of enzyme, reinforcing the view that enzyme efficacy should be evaluated directly in mashes. Preparations comprising principally xylanase increase wort viscosity when added in lower levels to mashes, probably by releasing β-glucan from its entrapment by arabinoxylan within the cell walls of barley. The glucanases have greater impact than xylanases on viscosity. Combinations of xylanase and β-glucanase have the greatest impact on viscosity and extract yield.     

Revisiting the Cellulosimicrobium cellulans yeast-lytic β-1,3-glucanases toolbox: A review

Cellulosimicrobium cellulans (also known with the synonyms Cellulomonas cellulans, Oerskovia xanthineolytica, and Arthrobacter luteus) is an actinomycete that excretes yeast cell wall lytic enzyme complexes containing endo-β-1,3-glucanases [EC 3.2.1.39 and 3.2.1.6] as key constituents. Three genes encoding endo-β-1,3-glucanases from two C. cellulans strains have been cloned and characterised over the past years. The βglII and βglII _A genes from strain DSM 10297 (also known as O. xanthineolytica LL G109) encoded proteins of 40.8 and 28.6 kDa, respectively, whereas the β-1,3-glucanase gene from strain ATCC 21606 (also known as A. luteus 73–14) encoded a 54.5 kDa protein. Alignment of their deduced amino acid sequences reveal that βglII and βglII _A have catalytic domains assigned to family 16 of glycosyl hydrolases, whereas the catalytic domain from the 54.5 kDa glucanase belongs to family 64. Notably, both βglII and the 54.5 kDa β-1,3-glucanase are multidomain proteins, having a lectin-like C-terminal domain that has been assigned to family 13 of carbohydrate binding modules, and that confers to β-1,3-glucanases the ability to lyse viable yeast cells. Furthermore, βglII may also undergo posttranslational proteolytic processing of its C-terminal domain, resulting in a truncated enzyme retaining its glucanase activity but with very low yeast-lytic activity. In this review, the diversity in terms of structural and functional characteristics of the C. cellulans β-1,3-glucanases has been compiled and compared.     

Cloning of β-1,3-glucanases expressed during Cichorium somatic embryogenesis

Three different -1,3-glucanase cDNA fragments, CG1, CG2 and CG3, were obtained by RT-PCR from RNA isolated from Cichorium hybrid `474' leaf fragments cultured for 11 days under somatic embryogenesis-inducing conditions. When expressed in Escherichia coli the proteins encoded by the three cDNAs were recognized by antibodies raised against 38 kDa extracellular -1,3-glucanases studied previously (Helleboid et al., Planta 205 (1998) 56–63). The CG2 and CG3 cDNAs may represent expressed alleles of one gene because their sequences showed a very high identity (98.5%) and are only 70% identical with CG1. Southern blot analysis revealed the presence of 3–4 genes coding for -1,3-glucanases in the Cichorium genome. Expression analysis of the genes corresponding to the three clones analysed by semi-quantitative RT-PCR indicated that CG1 mRNAs were only detectable in Cichorium hybrid `474' leaf fragments from day 3 of somatic embryogenesis induction, whereas CG2-CG3 mRNAs were already present in non-induced leaf tissue of both the embryogenic hybrid `474' and a non-embryogenic genotype. The level of CG1 mRNAs was particularly high when embryogenic cells were dividing to produce embryos, and when the amount of callose deposited in cell walls surrounding embryogenic cells and young embryos decreased. These results indicate that expression of the CG1 gene is correlated to the somatic embryogenesis process and that it encodes a 38 kDa -1,3-glucanase protein that may be involved in the degradation of callose localized around embryogenic cells and young embryos. A full-length CG1 cDNA clone was obtained using 3 and 5 RACE-PCR, and its sequence revealed that it encodes a -1,3-glucanase that is equally homologous to both class III and class IV plant -1,3-glucanases.     

Distinct ethylene- and tissue-specific regulation of β-1,3-glucanases and chitinases during pea seed germination

The expression of β-1,3-glucanase (βGlu) and chitinase (Chn) was investigated in the testa, cotyledons, and embryonic axis of germinating Pisum sativum L. cv. `Espresso generoso' seeds. High concentrations of βGlu and Chn activity were found in the embryonic axis. Treatment with ethylene alone or in combination with the inhibitor of ethylene action 2,5-norbornadiene showed that an early, 4-fold induction of βGlu activity in the embryonic axis during the first 20 h after the start of imbibition is ethylene-independent. This initial increase was followed by a later 4-fold ethylene-dependent induction in the embryonic axis starting at 50 h, which is after the onset of ethylene evolution and after completion of radicle emergence. The βGlu activity in cotyledons increased gradually throughout germination and was ethylene-independent. In contrast, the ethylene-independent Chn activity increased slightly after the onset of radical emergence in the embryonic axis and remained at a constant low level in cotyledons. Immunoinactivation assays and immunoblot analyses suggest that early βGlu activity in the embryonic axis is due to a 54-kDa antigen, whereas late induction is due to a 34.5-kDa antigen, which is likely to be the ethylene-inducible class I βGlu G2 described for immature pea pods. Increases in Chn in the embryonic axis were correlated with a 26-kDa antigen, whereas amounts of the additional 32- and 20-kDa antigens remained roughly constant. Thus, ethylene-dependent and ethylene-independent pathways regulate βGlu and Chn during pea seed germination. The pattern of regulation differs from that of leaves and immature pods, and from that described for germinating tobacco seeds. The functional significance of this regulation and its underlying mechanisms are discussed. Received: 12 January 1999 / Accepted: 22 March 1999     

Characterization and expression of β-1,3-glucanase genes in peach

Beta-1,3-glucanase is one of the pathogenesis-related (PR) proteins involved in plant defense responses. A peach beta-1,3-glucanase gene, designated PpGns1, has been isolated and characterized. The deduced amino acid sequence of the product of PpGns indicates that it is a basic isoform (pI 9.8), and contains a putative signal peptide of 38 amino acids but has no C-terminal extension. Amino acid sequence comparisons revealed that PpGns1 is 69% and 67% identical to citrus and soybean beta-1,3-glucanases, respectively. Southern analysis of total genomic DNA also indicates that at least three genes for beta-1,3-glucanases exist in peach, forming a small gene family. Characterization of four additional clones by PCR has identified a second beta-1,3-glucanase gene, PpGns2. PpGns2 has been partially sequenced, and when compared to PpGns1, it shows high sequence homology, 96% and 99% nucleotide identity in the first and (partial) second exons, respectively. The deduced partial sequence of the PpGns2 product displays only two differences from PpGns1 in the signal peptide and one in the (partial) mature protein (141 amino acids). The 5'-flanking promoter regions of these two genes share 90% identity in nucleotide sequences interrupted by five major gaps (4-109 nt long). The promoter region contains various sequences similar to cis-regulatory elements present in different stress-induced plant genes. In leaves and stems of peach shoot cultures grown in vitro, PpGns1 is induced within 12 h after exposure to a culture filtrate of Xanthomonas campestris pv. pruni or ethephon. However, it is not induced following treatment with mercuric chloride.     

Nutrition supply affects the activity of pathogenesis-related β-1,3-glucanases and chitinases in wheat

Nitrogen (N) is an essential mineral for plants and both its deficiency and excess causes serious problems in agriculture. As stress-inducible defense is costly, N conditions likely affect the trade-off between the growth and defense. Previous studies identified a few defense-related enzymes dependent on N nutrition. Chitinases (EC 3.2.1.14) and glucanases (EC 3.2.1.39) are typical plant defense enzymes belonging to the group of pathogenesis-related (PR) proteins with multiple functions in plants. Since a comprehensive study on the impact of N nutrition on their activity is missing, we studied their profiles and activities at isoforms level in wheat plants grown hydroponically at N doses corresponding to limited (0, 0.75 and 5.25 mM N), optimal N (7.5 mM N) as well as excess (15, 30 and 35 mM N) N supply in the form of nitrate. Our results show that several isoforms of both enzymes in wheat leaves and/or shoots clearly depended on N supply, while their activities rather depended on organ type. Furthermore, glucanases and chitinases appeared to be regulated in an opposite way. The activities of particular chitinases and glucanases correlated with a proline content that has multiple functions in plants. Proline typically accumulated with increasing the N supply when certain excessive N doses induced the gene for proline synthase (P5CS) in shoots and that for ornithine aminotransferase (OAT) in roots. This work points to a N-dependent activity of several defense-related compounds suggesting the possibly of altered plant defense potential under various N regimes.     

Plant viruses spread by diffusion on ER-associated movement-protein-rafts through plasmodesmata gated by viral induced host β-1,3-glucanases

Plant viruses spread cell-to-cell by exploiting and modifying plasmodesmata, coaxial membranous channels that cross cell walls and interlink the cytoplasm, endoplasmic reticulum and plasma-membranes of contiguous cells. To facilitate viral spread, viruses encode for one or more movement proteins that interact with ER and ER derived membranes, bind vRNA and target to Pd. Mounting evidence suggests that RNA viruses that do not spread as virions employ the same basic mechanism to facilitate cell-to-cell spread. In light of the research reviewed here, we propose a general functional model for the cell-to-cell spread of these viruses. This model posits that MPs have multiple functions: one function involves directing virus induced β-1,3-glucanases which accumulate in ER derived vesicles to the cell wall to hydrolyze Pd associated callose in order to gate open the Pd; independently, the MPs form ER-associated protein rafts which transport bound vRNA by diffusion along ER to adjacent cells via the ER component of the plasmodesmata. The driving force for spread is the diffusion gradient between infected and non-infected adjacent cells.     

The extracellular system of β-1,3-glucanases ofAlternaria tenuissima andAspergillus vesicolor

During cultivation in a minimal medium with glucoseAlternaria tenuissima andAspergillus vesicolor produce constitutively α- and β-glucanases. Fractions of β-1,3-glucanases exhibiting affinity for laminarin were separated by means of gel filtration chromatography. Two neutral β-1,3-glucanases with affinity for yeast glucan were isolated by affinity chromatography and further characterized.     

Broad-specificity GH131 β-glucanases are a hallmark of fungi and oomycetes that colonize plants

Plant-tissue-colonizing fungi fine-tune the deconstruction of plant-cell walls (PCW) using different sets of enzymes according to their lifestyle. However, some of these enzymes are conserved among fungi with dissimilar lifestyles. We identified genes from Glycoside Hydrolase family GH131 as commonly expressed during plant-tissue colonization by saprobic, pathogenic and symbiotic fungi. By searching all the publicly available genomes, we found that GH131-coding genes were widely distributed in the Dikarya subkingdom, except in Taphrinomycotina and Saccharomycotina, and in phytopathogenic Oomycetes, but neither other eukaryotes nor prokaryotes. The presence of GH131 in a species was correlated with its association with plants as symbiont, pathogen or saprobe. We propose that GH131-family expansions and horizontal-gene transfers contributed to this adaptation. We analysed the biochemical activities of GH131 enzymes whose genes were upregulated during plant-tissue colonization in a saprobe (Pycnoporus sanguineus), a plant symbiont (Laccaria bicolor) and three hemibiotrophic-plant pathogens (Colletotrichum higginsianum, C. graminicola, Zymoseptoria tritici). These enzymes were all active on substrates with β-1,4, β-1,3 and mixed β-1,4/1,3 glucosidic linkages. Combined with a cellobiohydrolase, GH131 enzymes enhanced cellulose degradation. We propose that secreted GH131 enzymes unlock the PCW barrier and allow further deconstruction by other enzymes during plant tissue colonization by symbionts, pathogens and saprobes.     

Extracellular β-1,3-glucanases are induced during early somatic embryogenesis in Cichorium

In leaf tissues of the Cichorium hybrid clone `474' (C. intybus L. var. sativum × C. endivia L. var. latifolia), the acquisition and expression of embryogenic competence was characterised by the appearance of 15 polypeptides (Boyer et al., 1993, Plant Sci 93: 41–53). The 38-kDa proteins were found to be abundantly present in conditioned embryogenic medium after the first division of the induced cells. These proteins seemed to be glycosylated as indicated by general carbohydrate detection methods. Internal amino-acid sequences obtained after microsequencing tryptic peptides appeared to be 36–57% homologous with plant β-1,3-endoglucanases. In addition, these 38-kDa proteins were recognised by antibodies raised against the pathogenesis-related tobacco glucanase PR2a and their β-1,3-glucanase activity was demonstrated by direct detection in polyacrylamide gels after electrophoresis. These results strongly suggested that the 38-kDa somatic-embryogenesis-related (SER) polypeptides are β-1,3-glucanases. Moreover, the level of glucanase activity was nearly three times higher in the medium of the embryogenic `474' line than in the medium of a non-embryogenic line. The possible involvement of the extracellular 38-kDa proteins in callose degradation during somatic embryogenesis is discussed. Received: 5 May 1997 / Accepted: 25 September 1997     

Synthesis of β(1,3) oligoglucans exhibiting a Dectin-1 binding affinity and their biological evaluation

In this report, we describe the synthesis and biological evaluation of β(1,3) oligosaccharides that contain an aminoalkyl group and their biological evaluation. A 2,3 diol glycoside with a 4,6 benzylidene protecting group was used as an effective glycosyl acceptor for the synthesis of some β(1,3) linked glycosides. The use of a combination of a linear tetrasaccharide and a branched pentasaccharide as glycosyl donors led to the preparation of β(1,3) linear octa- to hexadecasaccharides and branched nona- to heptadecasaccharides in good total yields. Measurements of the competitive effects of the oligosaccharides on the binding of a soluble form of Dectin-1 to a solid-supported Schizophyllan (SPG) revealed that the branched heptadecasaccharide and the linear hexadecasaccharides also have binding activity for Dectin-1. In addition, the two oligosaccharides, both of which contain a β(1,3) hexadecasaccharide backbone, exhibited agonist activity in a luciferase-assisted NF-κB assay. STD-NMR analyses of complexes of Dectin-1 and the linear hexadecasaccharides clearly indicate Dectin-1 specifically recognizes the sugar part of the oligosaccharides and not the aminoalkyl chain.     

Characterization of the type of action of β-1,3-glucanases from marine invertebrates

• 1.1. Ten species of marine invertebrates possessing the highest laminarinase activity have been investigated.
• 2.2. The following approaches were used in determining the type of action of partially purified β-1,3-glucanases: effect on modified substrates, comparative study of enzymolysis products by the Nelson's and glucose oxidase methods and stereochemistry of the enzymolysis products.
• 3.3. Experimental results indicate that the examined marine invertebrates contain β-1,3-glucanases with endo-type activity; exo-enzymes are apparently absent.

     

Isolation and characterization of two types of β-1,3-glucanases from the common sea hare Aplysia kurodai

Two types of β-1,3-glucanases, AkLam36 and AkLam33 with the molecular masses of 36 kDa and 33 kDa, respectively, were isolated from the digestive fluid of the common sea hare Aplysia kurodai. AkLam36 was regarded as an endolytic enzyme (EC 3.2.1.6) degrading laminarin and laminarioligosaccharides to laminaritriose, laminaribiose, and glucose, while AkLam33 was regarded as an exolytic enzyme (EC 3.2.1.58) directly producing glucose from polymer laminarin. AkLam36 showed higher activity toward β-1,3-glucans with a few β-1,6-linked glucose branches such as Laminaria digitata laminarin (LLam) than highly branched β-1,3-glucans such as Eisenia bicyclis laminarin (ELam). AkLam33 showed moderate activity toward both ELam and LLam and high activity toward smaller substrates such as laminaritetraose and laminaritriose. Although both enzymes did not degrade laminaribiose as a sole substrate, they were capable of degrading it via transglycosylation reaction with laminaritriose. The N-terminal amino-acid sequences of AkLam36 and AkLam33 indicated that both enzymes belong to the glycosyl hydrolase family 16 like other molluscan β-1,3-glucanases.     

Inhibition of fungal growth by plant chitinases andβ-1,3-glucanases

Summary Plant chitinases and -1,3-glucanases have been demonstrated to inhibit fungal growth in model experiments, both on agar plates or in liquid media. Here,Trichoderma longibrachiatum was taken as a model to study the morphological changes caused by chitinase and glucanase treatments, using cytochemical techniques in combination with fluorescence and electron microscopy. Chitinase, alone or in the presence of glucanase, arrested growth of the hypha: it affected the extreme tip of the fungus producing a thinning of the wall, a balloon-like swelling and a rupture of the plasma membrane. Chitin and glucans were present in the wall, as shown by lectinand enzyme-binding experiments, but they had a different susceptibility to chitinase and -1,3-glucanase. Chitin was present at the apex and in the inner parts of the lateral walls; it was more susceptible to chitinase at the tip than in the subapical part. Glucans mostly occurred on the outer layer where they were degraded by glucanase. The latter did not affect the inner hyphal skeleton. It is suggested that the growth inhibition ofTrichoderma by hydrolytic enzymes is the consequence of a thinning of the cell wall in the hyphal apex, leading to an imbalance of turgor pressure and wall tension which causes the tip to swell and to burst.Abbreviations WGA-FITC wheat germ agglutinin labelled with fluorescein isothiocyanate - ConA-FITC concanavalin A labelled with fluorescein isothiocyanate - PEG polyethylene glycol - SEM scanning electron microscopy - TEM transmission electron microscopy     

Catalytic efficiency diversification of duplicate β-1,3-1,4-glucanases from Neocallimastix patriciarum J11

Four types of β-1,3-1,4 glucanase (β-glucanase, EC 3.2.1.73) genes, designated bglA13, bglA16, bglA51, and bglM2, were found in the cDNA library of Neocallimastix patriciarum J11. All were highly homologous with each other and demonstrated a close phylogenetic relationship with and a similar codon bias to Streptococcus equinus. The presence of expansion and several predicted secondary structures in the 3' untranslated regions (3'UTRs) of bglA16 and bglM2 suggest that these two genes were duplicated recently, whereas bglA13 and bglA16, which contain very short 3'UTRs, were replicated earlier. These findings indicate that the β-glucanase genes from N. patriciarum J11 may have arisen by horizontal transfer from the bacterium and subsequent duplication in the rumen fungus. β-Glucanase genes of Streptococcus equinus, Ruminococcus albus 7, and N. patriciarum J11 were cloned and expressed by Escherichia coli. The recombinant β-glucanases cloned from S. equinus, R. albus 7, and N. patriciarum J11 were endo-acting and had similar substrate specificity, but they demonstrated different properties in other tests. The specific activities and catalytic efficiency of the bacterial β-glucanases were also significantly lower than those of the fungal β-glucanases. Our results also revealed that the activities and some characteristics of enzymes were changed during the horizontal gene transfer event. The specific activities of the fungal β-glucanases ranged from 26,529 to 41,209 U/mg of protein when barley-derived β-glucan was used as the substrate. They also demonstrated similar pH and temperature optima, substrate specificity, substrate affinity, and hydrolysis patterns. Nevertheless, BglA16 and BglM2, two recently duplicated β-glucanases, showed much higher k(cat) values than others. These results support the notion that duplicated β-glucanase genes, namely, bglA16 and bglM2, increase the reaction efficiency of β-glucanases and suggest that the catalytic efficiency of β-glucanase is likely to be a criterion determining the evolutionary fate of duplicate forms in N. patriciarum J11.