Quantification of glycosidase activities in selected yeasts and lactic acid bacteria

Using a model system, the activities of α-L-arabinofuranosidase, β-glucosidase, and α-L-rhamonopyranosidase were determined in 32 strains of yeasts belonging to the genera Aureobasidium, Candida, Cryptococcus, Hanseniaspora, Hansenula, Kloeckera, Metschnikowia, Pichia, Saccharomyces, Torulaspora and Brettanomyces (10 strains); and seven strains of the bacterium Leuconostoc oenos. Only one Saccharomyces strain exhibited β-glucosidase activity, but several non-Saccharomyces yeast species showed activity of this enzyme. Aureobasidium pullulans hydrolyzed α-L-arabinofuranoside, β-glucoside, and α-L-rhamnopyranoside. Eight Brettanomyces strains had β-glucosidase activity. Location of enzyme activity was determined for those species with enzymatic activity. The majority of β-glucosidase activity was located in the whole cell fraction, with smaller amounts found in permeabilized cells and released into the growth medium. Aureobasidium pullulans hydrolyzed glycosides found in grapes. Received 02 February 1999/ Accepted in revised form 26 June 1999     

The importance of aeration strategy in fuel alcohol fermentations contaminated with Dekkera/Brettanomyces yeasts

Whole corn mash fermentations infected with industrially-isolated Brettanomyces yeasts were not affected even when viable Brettanomyces yeasts out-numbered Saccharomyces yeasts tenfold at the onset of fermentation. Therefore, aeration, a parameter that is pivotal to the physiology of Dekkera/Brettanomyces yeasts, was investigated in mixed culture fermentations. Results suggest that aeration strategy plays a significant role in Dekkera/Brettanomyces-mediated inhibition of fuel alcohol fermentations. Although growth of Saccharomyces cerevisiae was not impeded, mixed culture fermentations aerated at rates of ≥20 ml air l⁻¹ mash min⁻¹ showed decreased ethanol yields and an accumulation of acetic acid. The importance of aeration was examined further in combination with organic acid(s). Growth of Saccharomyces occurred more rapidly than growth of Brettanomyces yeasts in all conditions. The combination of 0.075% (w/v) acetic acid and contamination with Brettanomyces TK 1404W did not negatively impact the final ethanol yield under fermentative conditions. Aeration, however, did prove to be detrimental to final ethanol yields. With the inclusion of aeration in the control condition (no organic acid stress) and in each fermentation containing organic acid(s), the final ethanol yields were decreased. It was therefore concluded that aeration strategy is the key parameter in regards to the negative effects observed in fuel alcohol fermentations infected with Dekkera/Brettanomyces yeasts.     

Heterologous expression and periplasmic secretion of an antifungal Bacillus amyloliquefaciensBLB369 endo‐β‐1,3‐1,4‐glucanase in Escherichia coli

The endo‐β‐1,3‐1,4‐glucanases are glycoside hydrolases involved in the enzymatic depolymerization of 1,3‐1,4 β‐glucans and showed an antifungal activity against some fungi. Bacillus amyloliquefaciensBLB369 has a high antagonistic activity against phytopathogenic fungi. Its glu369 full‐coding sequence of the endo‐β‐1,3‐1,4‐glucanase gene (732 bp) was sequenced, cloned and successfully expressed in Escherichia coli Top10. The encoded protein (243 amino acids) has a calculated molecular mass of 27.3 kDa. To simplify the purification procedure, the glu369 coding sequence was cloned into the vector pKJD4. The produced OmpA‐His‐Glu369 harboured OmpA signal sequence for E. coli periplasmic localization and followed by a 6His residues for its purification. The purified His‐tagged proteins revealed two bands on SDS‐PAGE analysis with molecular masses of about 30.5 (His‐Glu369) and 32.5 kDa (OmpA‐His‐Glu369). They had the ability to inhibit the growth of phytopathogenic fungus Alternaria alternata. These favourable properties make the endo‐β‐1,3‐1,4‐glucanase a good candidate for biotechnological applications.     

Beta-xylosidase activity of a GH3 glucosidase/xylosidase from yak rumen metagenome promotes the enzymatic degradation of hemicellulosic xylans

Aims: To characterize the duel activities of a glycosyl hydrolase family 3 β‐glucosidase/xylosidase from rumen bacterial metagenome and to investigate the capabilities of its β‐d ‐xylosidase activities for saccharification of hemicellulosic xylans. Methods and Results: A β‐glucosidase/xylosidase gene RuBGX1 was cloned from yak (Bos grunniens) rumen using the metagenomic technology. Recombinant RuBGX1, expressed in Escherichia coli, demonstrated high hydrolytic activities on both p‐nitrophenyl‐β‐d ‐glucopyranoside (pNP‐Glc) and p‐nitrophenyl‐β‐d ‐xylopyranoside (pNP‐Xyl) substrates. Analysis of the kinetic properties indicated that RuBGX1 had a lower affinity for pNP‐Glc substrate as the K_m was 0·164 mmol l^?1 for pNP‐Glc and 0·03 mmol l^?1 for pNP‐Xyl at pH 6·0 and 50°C, respectively. The capabilities of RuBGX1 β‐xylosidase for hydrolysis of xylooligosaccharide substrates were further investigated using an endoxylanase‐coupled assay. Hydrolysis time courses illustrated that a significant increase (about 50%) in the reducing sugars, including xylobiose, xylotriose and xylotetraose, was achieved by supplementing endoxylanase with RuBGX1. Enzymatic product analysis using high‐performance anion‐exchange chromatography‐pulsed amperometric detection showed that RuBGX1 could release xyloses from intermediate xylooligosaccharides produced by endoxylanase. Conclusions: The RuBGX1 shows β‐glucosidase activity in hydrolysis of cello‐oligosaccharides; meanwhile, it has β‐xylosidase activity and functions synergistically with endoxylanase to promote the degradation of hemicellulosic xylans. Significance and Impact of the study: This was the first to report the β‐xylosidase activity of family 3 β‐glucosidase/xylosidase functioned in the degradation of hemicellulosic xylans. The bifunctional β‐glucosidase/xylosidase property of RuBGX1 can be used in simultaneous saccharification of cellulose and xylan into fermentable glucose and xylose.     

Cell wall-associated isoflavonoids and β-glucosidase activity in Lupinus albus plants responding to environmental stimuli

Plants respond to various biotic or abiotic stimuli with different mechanisms and the mobilization of phenolic compounds is one of them. In white lupin (Lupinus albus L.) plants, isoflavones and their glucosides were localized in cell walls where the high constitutive activity of β‐glucosidase (EC 3·2·1·21) was also identified. The enzyme was partially purified from root cell walls. Its polymeric active form has 180 or 200 kDa as determined by non‐denaturing electrophoresis and gel filtration, respectively, and the isoelectric point is at pH 6·9. The enzyme is an exoglucosidase, preferentially hydrolysing conjugates of phenolic compounds with β anomers of glucose. It is not active against purified lupin cell walls. The specific β‐glucosidase activity varies in different tissues with the highest one in roots, and always higher in cell walls than in protoplast. The cell wall location of the enzyme was confirmed biochemically by its activity in intercellular washing fluids. Both aglycones and glycosides were also present in these fluids. The specific β‐glucosidase activity correlated well with the isoflavonoid aglycone/glycoside ratios in various tissues: the higher β‐glucosidase activity, the higher relative aglycone content. β‐glucosidase activity was found to be inducible under conditions of yeast elicitor treatment. Induction of the enzyme was accompanied by changes in the isoflavone secretion and accumulation, suggesting the regulatory role of β‐glucosidase activity in root exudation of isoflavonoids. No correlation however, was found between changes in β‐glucosidase activity and the presence of isoflavonoids in root exudates of plants grown under various nitrogen nutrition regimes.     

Isolation and basic characterization of a β‐glucosidase from a strain of Lactobacillus brevis isolated from a malolactic starter culture

Aims: To study glycosidase activities of a Lactobacillus brevis strain and to isolate an intracellular β‐glucosidase from this strain. Methods and Results: Lactic acid bacteria (LAB) isolated from a commercially available starter culture preparation for malolactic fermentation were tested for β‐glycosidase activities. A strain of Lact. brevis showing high intracellular β‐d ‐glucosidase, β‐d ‐xylosidase and α‐l ‐arabinosidase activities was selected for purification and characterization of its β‐glucosidase. The pure glucosidase from Lact. brevis has also side activities of xylosidase, arabinosidase and cellobiosidase. It is a homotetramer of 330 kDa and has an isoelectric point at pH 3·5. The K_m for p‐nitrophenyl‐β‐d ‐glucopyranoside and p‐nitrophenyl‐β‐d ‐xylopyranoside is 0·22 and 1·14 mmol l^?1, respectively. The β‐glucosidase activity was strongly inhibited by gluconic acid δ‐lactone, partially by glucose and gluconate, but not by fructose. Ethanol and methanol were found to increase the activity up to twofold. The free enzyme was stable at pH 7·0 (t_1/2 = 50 day) but not at pH 4·0 (t_1/2 = 4 days). Conclusions: The β‐glucosidase from Lact. brevis is widely different to that characterized from Lactobacillus casei ( Coulon et al. 1998 ) and Lactobacillus plantarum ( Sestelo et al. 2004 ). The high tolerance to fructose and ethanol, the low inhibitory effect of glucose on the enzyme activity and the good long‐term stability could be of great interest for the release of aroma compounds during winemaking. Significance and Impact of the study: Although the release of aroma compounds by LAB has been demonstrated by several authors, little information exists on the responsible enzymes. This study contains the first characterization of an intracellular β‐glucosidase isolated from a wine‐related strain of Lact. brevis.     

Low rates of iridoid glycoside hydrolysis in two Longitarsus leaf beetles with different feeding specialization confer tolerance to iridoid glycoside containing host plants

Iridoid glycosides are plant defence compounds that are deterrent and/or toxic for unadapted herbivores but are readily sequestered by dietary specialists of different insect orders. Hydrolysis of iridoid glycosides by β‐glucosidase leads to protein denaturation. Insect digestive β‐glucosidases thus have the potential to mediate plant–insect interactions. In the present study, mechanisms associated with iridoid glycoside tolerance are investigated in two closely‐related leaf beetle species (Coleoptera: Chrysomelidae) that feed on iridoid glycoside containing host plants. The polyphagous Longitarsus luridus Scopoli does not sequester iridoid glycosides, whereas the specialist Longitarsus tabidus Fabricius sequesters these compounds from its host plants. To study whether the biochemical properties of their β‐glucosidases correspond to the differences in feeding specialization, the number of β‐glucosidase isoforms and their kinetic properties are compared between the two beetle species. To examine the impact of iridoid glycosides on the β‐glucosidase activity of the generalist, L. luridus beetles are kept on host plants with or without iridoid glycosides. Furthermore, β‐glucosidase activities of both species are examined using an artificial β‐glucosidase substrate and the iridoid glycoside aucubin present in their host plants. Both species have one or two β‐glucosidases with different substrate affinities. Interestingly, host plant use does not influence the specific β‐glucosidase activities of the generalist. Both species hydrolyse aucubin with a much lower affinity than the standard substrate. The neutral pH reduces the β‐glucosidase activity of the specialist beetles by approximately 60% relative to its pH optimum. These low rates of aucubin hydrolysis suggest that the ability to sequester iridoid glycosides has evolved as a key to potentially preventing iridoid glycoside hydrolysis by plant‐derived β‐glucosidases.     

Enzyme‐triggered fluorescence turn‐off/turn‐on of carbon dots for monitoring β‐glucosidase and its inhibitor in living cells

Energy transfer engineering based on fluorescent probes for directly sensing enzyme activities are in great demand as enzyme‐mediated transformations, which are central to all biological processes. Here, a fluorescence carbon dot (CD)‐based assay exhibiting selective responses to the quantitation of β‐glucosidase and the effect of its inhibitor was developed. The most common substrate, para‐nitrophenyl‐β‐d ‐glucopyranoside (pNPG) was hydrolyzed by β‐glucosidase to release p‐nitrophenol (pNP), which can efficiently quench fluorescence of CDs via an inner filter effect and electron transfer. However, in the presence of inhibitors of β‐glucosidase, the fluorescence intensity gradually recovered as the concentration of inhibitors increased. Therefore, the enzyme‐triggered fluorescence turn‐off/turn‐on of specific CDs successfully achieved sensitive detection of β‐glucosidase and monitored the effect of its inhibitors. This new strategy was applied to detect β‐glucosidase and monitor β‐glucosidase inhibitor in hepatoma cells using cell imaging. All results suggest that the new method is sensitive and promising for use in cancer diagnosis and treatment.     

The relation between glucovanillin, β-d-glucosidase activity and cellular compartmentation during the senescence, freezing and traditional curing of vanilla beans

The aim of this research was to improve our understanding of the mechanism of glucovanillin hydrolysis by β‐d ‐glucosidase activity in vanilla beans by studying their senescence, freezing and traditional curing. A batch of green pods from Madagascar was ripened at 30°C until fruits turned black; another batch was frozen for few days at ?18°C and defrosted at 35°C for 24 h and a third batch was cured using traditional methods. During treatments, samples were analysed for the yield of glucovanillin hydrolysis, and β‐glucosidase activity was measured. Cellular structures were also examined by light and transmission electron microscopy. Green fruits had a low yield of glucovanillin hydrolysis (<5%), a high level of β‐glucosidase activity (～1000 nkatal g^?1 fresh weight) and a perfect cellular integrity. Senescent fruits had a high yield of glucovanillin hydrolysis (>95%), no measurable β‐glucosidase activity and complete cellular degradation. Similar results were observed in beans after defrosting. During curing, beans had a medium yield of glucovanillin hydrolysis (<50%), no measurable β‐glucosidase activity and partial cellular degradation compared with senescent or defrosted beans. Results show that the mechanism of glucovanillin hydrolysis in vanilla beans is regulated by cellular compartmentation and that the β‐glucosidase activity level is not the limiting factor for complete hydrolysis. If total decompartmentation is obtained, then complete glucovanillin hydrolysis is observed even if most of the β‐glucosidase activity is lost. The β‐glucosidase activity level only has an effect on glucovanillin hydrolysis kinetics.     

Structural analysis of CPF_2247, a novel α-amylase from Clostridium perfringens

CPF_2247 from Clostridium perfringens ATCC 13124 was identified as a putative carbohydrate‐active enzyme by its low sequence identity to endo‐β‐1,4‐glucanases belonging to family 8 of the glycoside hydrolase classification. The X‐ray crystal structure of CPF_2247 determined to 2.0 Å resolution by single‐wavelength anomalous dispersion using seleno‐methionine‐substituted protein revealed an (α/α)₆ barrel fold. A large cleft on the surface of the protein contains residues that are structurally conserved with key elements of the catalytic machinery in clan GH‐M glycoside hydrolases. Assessment of CPF_2247 as a carbohydrate‐active enzyme disclosed α‐glucanase activity on amylose, glycogen, and malto‐oligosaccharides. Proteins 2011;. © 2011 Wiley‐Liss, Inc.     

Basic characterization and partial purification of β-glucosidase from cell-free extracts of Oenococcus oeni ST81

Aims: This study was designed to characterize a β‐glucosidase of Oenococcus oeni ST81, a strain isolated from a Spanish wine of the origin appellation Ribeira Sacra. Methods and Results: The β‐glucosidase of O. oeni ST81 seems to have a periplasmic localization into the cells. This activity was strongly inhibited by gluconic acid, partially inhibited by glucose and not inhibited by fructose, lactate, malate, mannitol or sorbitol. Ethanol increased the activity of this enzyme up to 147%. Among the several metal ions assayed, only Fe²⁺ (10 mmol l^?1) and Cu²⁺ (5 mmol l^?1) exhibited a partial inhibitory effect (40%). This enzyme was partially purified using a combination of ammonium sulfate precipitation and chromatographic methods. The single peak because of β‐glucosidase in all chromatographic columns indicates the presence of a single enzyme with an estimated molecular mass of 140 kDa. The calculated K_m and V_max values for 4‐nitrophenyl‐β‐d ‐glucopyranoside were 0·38 mmol l^?1 and 5·21 nmol min^?1, respectively. The enzyme was stable at pH 5·0 with a value of t_1/2 = 50 days for the crude extract. Conclusions: The β‐glucosidase of O. oeni ST81 is substantially different from those characterized from other wine‐related lactic acid bacteria (LAB), such as Lactobacillus plantarum and Lactobacillus brevis; however, it appears to be closely related to a β‐glucosidase from O. oeni ATCC BAA‐1163 cloned into Escherichia coli. The periplasmic localization of the enzyme together with its high tolerance to ethanol and fructose, the low inhibitory effect of some wine‐related compounds on the enzymatic activity and long‐term stability of the enzyme could be of interest for winemaking. Significance and Impact of the Study: Information regarding a β‐glucosidase from O. oeni ST81 is presented. Although the release of aroma compounds by LAB has been demonstrated, little information exists concerning the responsible enzymes. To our knowledge, this study contains the first characterization of a native β‐glucosidase purified from crude extracts of O. oeni ST81.     

PURIFICATION AND CHARACTERIZATION OF β‐GLUCOSIDASE FROM GREATER WAX MOTH Galleria mellonella L. (LEPIDOPTERA: PYRALIDAE)

The greater wax moth, Galleria mellonella, is one of the most ruinous pests of honeycomb in the world. Beta‐glucosidases are a type of digestive enzymes that hydrolytically catalyzes the beta‐glycosidic linkage of glycosides. Characterization of the beta‐glucosidase in G. mellonella could be a significant stage for a better comprehending of its role and establishing a safe and effective control procedure primarily against G. mellonella and also some other insect pests. Laboratory reared final instar stage larvae were randomly selected and homogenized for beta‐glucosidase activity assay and subsequent analysis. The enzyme was purified to apparent homogeneity by salting out with ammonium sulfate and using sepharose‐4B‐l ‐tyrosine‐1‐naphthylamine hydrophobic interaction chromatography. The purification was 58‐fold with an overall enzyme yield of 29%. The molecular mass of the protein was estimated as ca. 42 kDa. The purified beta‐glucosidase was effectively active on para/ortho‐nitrophenyl‐beta‐d ‐glucopyranosides (p‐/o‐NPG) with Km values of 0.37 and 1.9 mM and Vmax values of 625 and 189 U/mg, respectively. It also exhibits different levels of activity against para‐nitrophenyl‐β‐d ‐fucopyranoside (p‐NPF), para/ortho‐nitrophenyl β‐d ‐galactopyranosides (p‐/o‐NPGal) and p‐nitrophenyl 1‐thio‐β‐d ‐glucopyranoside. The enzyme was competitively inhibited by beta‐gluconolactone and also was very tolerant to glucose against p‐NPG as substrate. The Ki and IC₅₀ values of δ‐gluconolactone were determined as 0.021 and 0.08 mM while the enzyme was more tolerant to glucose inhibition with IC50 value of 213.13 mM for p‐NPG.     

Evaluation of the cellobiose-fermenting yeastBrettanomyces custersii in the simultaneous saccharification and fermentation of cellulose

Summary Brettanomyces custersii (CBS 5512) was identified as a promising glucose- and cellobiose-fermenting yeast for the simultaneous saccharification and fermentation (SSF) of cellulose for ethanol production. In SSF studies with 75 g/L of cellulose,B. custersii produced 32 g/L of ethanol in just 3 days (75% of theoretical yield). This yield represents an increase of more than 16% over the yields of other fementative yeasts and the time to achieve it is less than that with other organisms. In addition, the ethanol tolerance ofB. custersii seems to be greater than that of other cellobiose-fermenting yeasts considered to date. Overall, the combination of higher yields, rates, and ethanol concentrations obtained withB. custersii improves the economics of ethanol production.     

A TLC bioautographic method for the detection of α‐ and β‐glucosidase inhibitors in plant extracts

Introduction – Bioautographic assays using TLC play an important role in the search for active compounds from plants. A TLC assay has previously been established for the detection of β‐glucosidase inhibitors but not for α‐glucosidase. Nonetheless, α‐glucosidase inhibition is an important target for therapeutic agents against of type 2 diabetes and anti‐viral infections. Objective – To develop a TLC bioautographic method to detect α‐ and β‐glucosidase inhibitors in plant extracts. Methodology – The enzymes α‐ and β‐d ‐glucosidase were dissolved in sodium acetate buffer. After migration of the samples, the TLC plate was sprayed with enzyme solution and incubated at room temperature for 60 min in the case of α‐d ‐glucosidase, and 37°C for 20 min in the case of β‐d ‐glucosidase. For detection of the active enzyme, solutions of 2‐naphthyl‐α‐D‐glucopyranoside or 2‐naphthyl‐β‐D‐glucopyranoside and Fast Blue Salt were mixed at a ratio of 1 : 1 (for α‐d ‐glucosidase) or 1 : 4 (for β‐d ‐glucosidase) and sprayed onto the plate to give a purple background colouration after 2–5 min. Results – Enzyme inhibitors were visualised as white spots on the TLC plates. Conduritol B epoxide inhibited α‐d ‐glucosidase and β‐d ‐glucosidase down to 0.1 µg. Methanol extracts of Tussilago farfara and Urtica dioica after migration on TLC gave enzymatic inhibition when applied in amounts of 100 µg for α‐glucosidase and 50 µg for β‐glucosidase. Conclusion – The screening test was able to detect inhibition of α‐ and β‐glucosidases by pure reference substances and by compounds present in complex matrices, such as plant extracts. Copyright © 2009 John Wiley & Sons, Ltd.     

Immunolocalization of 1,3‐β‐Glucanases Secreted by Gaeumannomyces graminis var. tritici in Infected Wheat Roots

The distribution of extracellular 1,3‐β‐glucanase secreted by Gaeumannomyces graminis var. tritici (Ggt) was investigated in situ in inoculated wheat roots by immunogold labelling and transmission electron microscopy. Antiserum was prepared by subcutaneously injecting rabbits with purified 1,3‐β‐glucanase secreted by the pathogenic fungus. A specific antibody of 1,3‐β‐glucanase, anti‐GluGgt, was purified and characterized. Double immunodiffusion tests revealed that the antiserum was specific for 1,3‐β‐glucanase of Ggt, but not for 1,3‐β‐glucanase from wheat plants. Native polyacrylamide gel electrophoresis of the purified and crude enzyme extract and immunoblotting showed that the antibody was monospecific for 1,3‐β‐glucanase in fungal extracellular protein populations. After incubation of ultrathin sections of pathogen‐infected wheat roots with anti‐1,3‐β‐glucanase antibody and the secondary antibody, deposition of gold particles occurred over hyphal cells and the host tissue. Hyphal cell walls and septa as well as membranous structures showed regular labelling with gold particles, while few gold particles were detected over the cytoplasm and other organelles such as mitochondria and vacuoles. In host tissues, cell walls in contact with the hyphae usually exhibited a few gold particles, whereas host cytoplasm and cell walls distant from the hyphae were free of labelling. Furthermore, over lignitubers in the infected host cells labelling with gold particles was detected. No gold particles were found over sections of non‐inoculated wheat roots. The results indicate that 1,3‐β‐glucanase secreted by Ggt may be involved in pathogenesis of the take‐all fungus through degradation of callose in postinfectionally formed cell wall appositions, such as lignitubers.     

A GHF7 CELLULASE FROM THE PROTIST SYMBIONT COMMUNITY OF Reticulitermes flavipes ENABLES MORE EFFICIENT LIGNOCELLULOSE PROCESSING BY HOST ENZYMES

Termites and their gut microbial symbionts efficiently degrade lignocellulose into fermentable monosaccharides. This study examined three glycosyl hydrolase family 7 (GHF7) cellulases from protist symbionts of the termite Reticulitermes flavipes. We tested the hypotheses that three GHF7 cellulases (GHF7‐3, GHF7‐5, and GHF7‐6) can function synergistically with three host digestive enzymes and a fungal cellulase preparation. Full‐length cDNA sequences of the three GHF7s were assembled and their protist origins confirmed through a combination of quantitative PCR and cellobiohydrolase (CBH) activity assays. Recombinant versions of the three GHF7s were generated using a baculovirus‐insect expression system and their activity toward several model substrates compared with and without metallic cofactors. GHF7‐3 was the most active of the three cellulases; it exhibited a combination of CBH, endoglucanase (EGase), and β‐glucosidase activities that were optimal around pH 7 and 30°C, and enhanced by calcium chloride and zinc sulfate. Lignocellulose saccharification assays were then done using various combinations of the three GHF7s along with a host EGase (Cell‐1), beta‐glucosidase (β‐glu), and laccase (LacA). GHF7‐3 was the only GHF7 to enhance glucose release by Cell‐1 and β‐glu. Finally, GHF7‐3, Cell‐1, and β‐glu were individually tested with a commercial fungal cellulase preparation in lignocellulose saccharification assays, but only β‐glu appreciably enhanced glucose release. Our hypothesis that protist GHF7 cellulases are capable of synergistic interactions with host termite digestive enzymes is supported only in the case of GHF7‐3. These findings suggest that not all protist cellulases will enhance saccharification by cocktails of other termite or fungal lignocellulases.     

Purification and characterization of thermostable β-1,3-1,4 glucanase from<Emphasis Type="Italic">Bacillus</Emphasis> sp. A8-8

In this study, the extracellular enzyme activity ofBacillus sp. A8-8 was detected on LB agar plates containing 0.5% of the following substrates: carboxymethylcellulose (CMC), xylan, cellulose, and casein, respectively. The β-1,3-1,4 glucanase produced fromBacillus sp. A8-8 was purified by ammonium sulfate and hydrophobic chromatography. The molecular size of the protein was estimated by SDS-PAGE as approximately 33 kDa. The optimum pH and temperature for the enzyme activity were 6.0 and 60°C, respectiveley. However, enzyme activity was shown over a broad range of pH values and temperatures. The purified β-1,3-1,4 glucanase retained over 70% of its original activity after incubation at 80°C for 2 h, and showed over 40% of its original activity within the pH range of 9 to 12. This suggests that β-1,3-1,4 glucanase fromBacillus sp. A8-8 is thermostable and alkalistable. In addition, β-1,3-1,4 glucanase had higher substrate specificity to lichenan than to CMC. Finally the activity of the endoglucanase was inhibited by Fe³⁺, Mg²⁺, and Mn²⁺ ions. However Co²⁺ and Ca²⁺ ions were increased its activity. These authors contributed equally to this work.