Biochemical characterization of WbdN, a β1,3-glucosyltransferase involved in O-antigen synthesis in enterohemorrhagic Escherichia coli O157

The enterohemorrhagic O157 strain of Escherichia coli, which is one of the most well-known bacterial pathogens, has an O-antigen repeating unit structure with the sequence [-2-d-Rha4NAcα1-3-l-Fucα1-4-d-Glcβ1-3-d-GalNAcα1-]. The O-antigen gene cluster of E. coli O157 contains the genes responsible for the assembly of this repeating unit and includes wbdN. In spite of cloning many O-antigen genes, biochemical characterization has been done on very few enzymes involved in O-antigen synthesis. In this work, we expressed the wbdN gene in E. coli BL21, and the His-tagged protein was purified. WbdN activity was characterized using the donor substrate UDP-[(14)C]Glc and the synthetic acceptor substrate GalNAcα-O-PO(3)-PO(3)-(CH(2))(11)-O-Ph. The enzyme product was isolated by high pressure liquid chromatography, and mass spectrometry showed that one Glc residue was transferred to the acceptor by WbdN. Nuclear magnetic resonance analysis of the product structure indicated that Glc was β1-3 linked to GalNAc. WbdN contains a conserved DxD motif and requires divalent metal ions for full activity. WbdN activity has an optimal pH between 7 and 8 and is highly specific for UDP-Glc as the donor substrate. GalNAcα derivatives lacking the diphosphate group were inactive as substrates, and the enzyme did not transfer Glc to GlcNAcα-O-PO(3)-PO(3)-(CH(2))(11)-O-Ph. Our results illustrate that WbdN is a specific UDP-Glc:GalNAcα-diphosphate-lipid β1,3-Glc-transferase. The enzyme is a target for the development of inhibitors to block O157-antigen synthesis.     

Synthesis and properties of some O-(2,2-dialkoxyethyl)glycolaldehydes

β-d-Mannosidase (β-d-mannoside mannohydrolase EC 3.2.1.25) was purified 160-fold from crude gut-solution of Helix pomatia by three chromatographic steps and then gave a single protein band (mol. wt. 94,000) on SDS-gel electrophoresis, and three protein bands (of almost identical isoelectric points) on thin-layer iso-electric focusing. Each of these protein bands had enzyme activity. The specific activity of the purified enzyme on p-nitrophenyl β-d-mannopyranoside was 1694 nkat/mg at 40° and it was devoid of α-d-mannosidase, β-d-galactosidase, 2-acet-amido-2-deoxy-d-glucosidase, (1→4)-β-d-mannanase, and (1→4)-β-d-glucanase activities, almost devoid of α-d-galactosidase activity, and contaminated with <0.02% of β-d-glucosidase activity. The purified enzyme had the same K_m for borohydride-reduced β-d-manno-oligosaccharides of d.p. 3–5 (12.5mm). The initial rate of hydrolysis of (1→4)-linked β-d-manno-oligosaccharides of d.p. 2–5 and of reduced β-d-manno-oligosaccharides of d.p. 3–5 was the same, and o-nitrophenyl, methylumbelliferyl, and naphthyl β-d-mannopyranosides were readily hydrolysed. β-d-Mannobiose was hydrolysed at a rate ～25 times that of 6¹-α-d-galactosyl-β-d-mannobiose and 6³-α-d-galactosyl-β-d-mannotetraose, and at ～90 times the rate for β-d-mannobi-itol.     

Biochemical characterization of chitinase 2 expressed during the autolytic phase of the inky cap, Coprinellus congregatus

Fungal cell walls consist of various glucans and chitin. The inky cap, Coprinellus congregatus, produces mushrooms at 25°C in a regime of 15 h light/9 h dark, and then the mushroom is autolyzed rapidly to generate black liquid droplets in which no cell walls are detected by microscopy. Chitinase cDNA from the mature mushroom tissues of C. congregatus, which consisted of 1,622 nucleotides (chi2), was successfully cloned using the rapid amplification of cDNA ends polymerase chain reaction technique. The deduced 498 amino acid sequence of Chi2 had a conserved catalytic domain as in other fungal chitinase family 18 enzymes. The Chi2 enzyme was purified from the Pichia pastoris expression system, and its estimated molecular weight was 68 kDa. The optimum pH and temperature of Chi2 was pH 4.0 and 35°C, respectively when 4-nitrophenyl N,N′-diacetyl-β-D-chitobioside was used as the substrate. The K _m value and V _max for the substrate A, 4-nitrophenyl N,N′-diacetyl-β-D-chitobioside, was 0.175 mM and 0.16 OD min^?1unit^?1, respectively.     

Bacterial chitin hydrolysis in two lakes with contrasting trophic statuses

Chitin, which is a biopolymer of the amino sugar glucosamine (GlcN), is highly abundant in aquatic ecosystems, and its degradation is assigned a key role in the recycling of carbon and nitrogen. In order to study the significance of chitin decomposition in two temperate freshwater lakes with contrasting trophic and redox conditions, we measured the turnover rate of the chitin analog methylumbelliferyl-N,N'-diacetylchitobioside (MUF-DC) and the presence of chitinase (chiA) genes in zooplankton, water, and sediment samples. In contrast to the eutrophic and partially anoxic lake, chiA gene fragments were detectable throughout the oligotrophic water column and chiA copy numbers per ml of water were up to 15 times higher than in the eutrophic waters. For both lakes, the highest chiA abundance was found in the euphotic zone--the main habitat of zooplankton, but also the site of production of easily degradable algal chitin. The bulk of chitinase activity was measured in zooplankton samples and the sediments, where recalcitrant chitin is deposited. Both, chiA abundance and chitinase activity correlated well with organic carbon, nitrogen, and concentrations of particulate GlcN. Our findings show that chitin, although its overall contribution to the total organic carbon is small (~0.01 to 0.1%), constitutes an important microbial growth substrate in these temperate freshwater lakes, particularly where other easily degradable carbon sources are scarce.     

Activity of three β-1,4-galactanases on small chromogenic substrates

β-1,4-Galactanases belong to glycoside hydrolase family GH 53 and degrade galactan and arabinogalactan side chains of the complex pectin network in plant cell walls. Two fungal β-1,4-galactanases from Aspergillus aculeatus, Meripileus giganteus and one bacterial enzyme from Bacillus licheniformis have been kinetically characterized using the chromogenic substrate analog 4-nitrophenyl β-1,4-d-thiogalactobioside synthesized by the thioglycoligase approach. Values of k_cat/K_m for this substrate with A. aculeatus β-1,4-galactanase at pH 4.4 and for M. giganteus β-1,4-galactanase at pH 5.5 are 333 M⁻¹ s⁻¹ and 62 M⁻¹ s⁻¹, respectively. By contrast the B. licheniformis β-1,4-galactanase did not hydrolyze 4-nitrophenyl β-1,4-d-thiogalactobioside. The different kinetic behavior observed between the two fungal and the bacterial β-1,4-galactanases can be ascribed to an especially long loop 8 observed only in the structure of B. licheniformis β-1,4-galactanase. This loop contains substrate binding subsites −3 and −4, which presumably cause B. licheniformis β-1,4-galactanase to bind 4-nitrophenyl -1,4-β-d-thiogalactobioside non-productively. In addition to their cleavage of 4-nitrophenyl -1,4-β-d-thiogalactobioside, the two fungal enzymes also cleaved the commercially available 2-nitrophenyl-1,4-β-d-galactopyranoside, but kinetic parameters could not be determined because of transglycosylation at substrate concentrations above 4 mM.     

Studies on Some Properties of the Apoplastic β-N-Acetyl-D-Hexosaminidase from Tomato Leaves

Some properties of the β-N-acetyl-D-hexosaminidase purified from intercellular fluid of tomato leaves after the plant was systematically infected by TMV (tobacco mosaic virus) were studied. When pNP β-D-GlcNAc (p nitrophenyl-N-aeetyl β-D-glucosaminide) or pNP β-D- GalNAc (p-nitrophenyl-N-acetyl-β-D galactosaminide) was used as the substrate, it showed the optical pH between 4. 8--5.0 and optical temperature between 44— 47℃. Studies of thermostabillty indicated that the enzyme had a biphasic denaturation curve. Using pNP-β-D-GIcNAc or pNP-β-D GalNAc as the substrate, the Km value of the enzyme was 0. 36 and 0. 67 mmol/L respectively. N acetyi-D glucosamine and N acetyl-D-galactosamine were competitive inhibitors of the enzyme activities. Ag+ and Hg2+ were sensitive inhibitors and Fe2+ . Fe3+ and Cu2+ were also inhibitors enzyme activities.     

Studies on the Chitinolytie Enzymes of Black-koji Mold

In an attempt to separate the enzyme system participating in the decomposition of glycol chitin to constituent aminosugar, the purification of chitinase of Aspergillus niger was carried out by detemining both liquefying and saccharifying activities. Using fractionation with ammonium sulfate and column chromatography by hydroxylapatite, the chitinase system of the mold was separated into different enzyme fractions, which were required for the complete hydrolysis of glycol chitin. It was found that one of these enzymes caused a rapid decrease in viscosity of glycol chitin solution, another enzyme possessed N-acetyl-β-glucosaminidase activity upon N, N′-diacetylchitobiose and β-methyl-N-acetylglucosaminide, and that glycol chitin was decomposed to constituent aminosugar by a successive action of the two different enzymes.     

An apparatus for safe and convenient handling of anhydrous, liquid hydrogen fluoride at controlled temperatures and reaction times. Application to the generation of oligosaccharides from polysaccharides

β-d-Gal-(1 → 4)-β-d-GlcNAc-OC₆H₄NO₂-p (p-nitrophenyl N-acetyl-β-lactosaminide) and β-d-Gal-(1 → 6)-β-d-GlcNAc-OC₆H₄NO₂-p (p-nitrophenyl N-acetyl-β-isolactosaminide) were regioselectively synthesized from lactose and p-nitrophenyl 2-acetamido-2-deoxy-glucopyranoside, employing transglycosylation by the β-d-galactosidase from Bacillus circulans and by controlling the concentration of organic solvent in the reaction system. The (1 → 4)-linked disaccharide was formed exclusively when the concentration of organic solvent was high, whereas the (1 → 6)-linked isomer was produced with a low concentration. Further utilization of the transglycosylation by the enzyme led to the regioselective formation of β-d-Gal-(1 → 4)-d-GalNAc and β-d-Gal-(1 → 4)-β-d-GalNAc-OC₆H₄NO₂-p. With the enzyme, β-d-galactosyl transfer occurred preferentially at the O-4 position of GlcNAc and GalNAc, regardless of the configuration of the hydroxyl group.     

Photoreversible Modulators of Escherichia coli β-Galactosidase. 1-Benzoyl-1-cyano-2-(4,5-dimethoxy-2-nitrophenyl)-ethene and 1,1-Dicyano-2-(4,5-dimethoxy-2-nitrophenyl)-ethene

β-Galactosidase (EC 3.2.1.23) is known to be inhibited by some thiol reagents. 1-Benzoyl-1-cyano-2-(4,5-dimethoxy-2-nitrophenyl)-ethene (1) was shown to be an irreversible inhibitor, while 1, 1-dicyano-2-(4,5-dimethoxy-2-nitrophenyl)-ethene (2) was demonstrated as a positive irreversible modulator causing a rise of up to 186% in β-galactosidase activity. Compound 2 is, however, an irreversible inhibitor of the cysteine proteinase papain (preceding paper). Kinetic values of β-galactosidase at pH 8.3 with o-nitrophenyl β-D-galactopyranoside (ONPG) as the substrate and for compounds 1 and 2 were determined and in view of model experiments, it was assumed that both compounds possibly reacted with the thiol side chain of Cys in the active site inducing allosteric changes in the enzyme. Since the enzyme, modified by compound 1 or 2, was a 2-nitrobenzyl derivative, near-UV irradiation resulted in a recovery of up to 91% and a reduction of the enzyme's activity to 90%, respectively.     

Identification and characterization of the gene cluster involved in chitin degradation in a marine bacterium, Alteromonas sp. strain O-7.

Alteromonas sp. strain O-7 secretes chitinase A (ChiA), chitinase B (ChiB), and chitinase C (ChiC) in the presence of chitin. A gene cluster involved in the chitinolytic system of the strain was cloned and sequenced upstream of and including the chiA gene. The gene cluster consisted of three different open reading frames organized in the order chiD, cbp1, and chiA. The chiD, cbp1, and chiA genes were closely linked and transcribed in the same direction. Sequence analysis indicated that Cbp1 (475 amino acids) was a chitin-binding protein composed of two discrete functional regions. ChiD (1,037 amino acids) showed sequence similarity to bacterial chitinases classified into family 18 of glycosyl hydrolases. The cbp1 and chiD genes were expressed in Escherichia coli, and the recombinant proteins were purified to homogeneity. The highest binding activities of Cbp1 and ChiD were observed when alpha-chitin was used as a substrate. Cbp1 and ChiD possessed a chitin-binding domain (ChtBD) belonging to ChtBD type 3. ChiD rapidly hydrolyzed chitin oligosaccharides in sizes from trimers to hexamers, but not chitin. However, after prolonged incubation with large amounts of ChiD, the enzyme produced a small amount of (GlcNAc)(2) from chitin. The optimum temperature and pH of ChiD were 50 degrees C and 7.0, respectively.     

在大鼠发育过程中β1,4半乳糖基转移酶的组织分布及其变化的研究

用HPLC纯化了荧光标记的底物（Gnβ1-2Ma1-6（Gnβ1-2Mα1-3）Mβ1-4Goβ1-4Gn-PA）用β-1,4-半乳糖基转移酶的荧光标记底物的HPLC测定方法,测定了在发育过程中大鼠肝,肾,脑中的酶活性的变化,结果表明,（1）在正常成年大鼠中,各组织酶活性具有组织特异性,（2）不同的发育期,其酶活性不同。胎鼠（孕20d,以下同）时最高,以后就渐渐下降,各组织酶活力变化幅度是不一致的,这些变化的生理意义有待子进一步研究．     

Mercapto-chitins: a new type of supports for effective immobilization of acid phosphatase

Acid phosphatase was immobilized on two kinds of mercapto-chitins, 2-mercapto-chitin and 6-mercapto-chitin, and assayed with 4-nitrophenyl phosphate as the substrate. The optimal pH values for immobilization were 4.5 and 4.8, respectively. The resulting immobilized enzymes showed maximum activities at pH 6.0 and 5.5, almost the same as that for the soluble enzyme. 6-Mercapto-chitin/enzyme conjugate retained high activity even after repeated uses in batch systems, suggesting effective immobilization through covalent bond formation, while 2-mercapto-chitin/enzyme and chitin/enzyme conjugates showed decreases in activity after a few runs.     

The roles of the C-terminal domain and type III domains of chitinase A1 from Bacillus circulans WL-12 in chitin degradation.

The mature form of chitinase A1 from Bacillus circulans WL-12 comprises a C-terminal domain, two type III modules (domains), and a large N-terminal domain which contains the catalytic site of the enzyme. In order to better define the roles of these chitinase domains in chitin degradation, modified chiA genes encoding various deletions of chitinase A1 were constructed. The modified chiA genes were expressed in Escherichia coli, and the gene products were analyzed after purification by high-performance liquid chromatography. Intact chitinase A1 specifically bound to chitin, while it did not show significant binding activity towards partially acetylated chitosan and other insoluble polysaccharides. Chitinases lacking the C-terminal domain lost much of this binding activity to chitin as well as colloidal chitin-hydrolyzing activity. Deletion of the type III domains, on the other hand, did not affect chitin-binding activity but did result in significantly decreased colloidal chitin-hydrolyzing activity. Hydrolysis of low-molecular-weight substrates, soluble high-molecular-weight substrates, and insoluble high-molecular-weight substrates to which chitinase A1 does not bind were not significantly affected by these deletions. Thus, it was concluded that the C-terminal domain is a chitin-binding domain required for the specific binding to chitin and that this chitin-binding activity is important for efficient hydrolysis of the sufficiently acetylated chitin. Type III modules are not directly involved in the chitin binding but play an important functional role in the hydrolysis of chitin by the enzyme bound to chitin.     

G561 site-directed deletion mutant chitinase from Aeromonas caviae is active without its 304 C-terminal amino acid residues

A G561 mutant of the Aeromonas caviae chitinase ChiA was made by PCR site-directed deletion mutagenesis in order to study the role of the 304 C-terminal amino acid residues of ChiA in the enzymatic hydrolysis of chitin. The recombinant ChiAG561 encoded on a 1.6-kb DNA fragment of A. caviae chiA was expressed in a heterologous Escherichia coli host using the pET20b(+) expression system. The His-Tag-affinity-purified recombinant ChiAG561 had a calculated molecular mass of 63,595 Da, which was consistent with the 67,000 Da estimated by SDS-PAGE. The G561 deletion mutant enzyme had the same optimum pH (6.5) as the full-length ChiA and a lower optimum temperature (37 degrees C instead of 42.5 degrees C). Biochemical properties of the recombinant ChiAG561 suggested that deletion of the 304 C-terminal amino acid residues of ChiA did not significantly affect ChiA enzyme activity. However, compared to the full-length ChiA, the mutant chitinase had a ten-fold higher relative activity with 4-methylumbelliferyl-N-N'-N"-triacetylchitotriose [4-MU-(GlcNAc)3] as a substrate, and higher rates of hydrolysis with both chitin and colloidal chitin substrates. Results obtained from this study suggest that the active region of A. caviae ChiA is located in the region before G561 of the protein molecule.     

Activity of bile-salt-stimulated human milk lipase in the presence of liposomes and mixed taurocholate-phosphatidylcholine micelles

(1) The interaction of bile-salt-stimulated human milk lipase and liposomal membranes has been investigated in the presence or absence of sodium taurocholate. Freshly purified enzyme enhances the permeability of liposomal membranes but thermally inactivated enzyme does not. (2) The ability of the enzyme to catalyze the hydrolisys of a relatively hydrophilic substrate, 4-nitrophenyl acetate, and a more hydrophobic substrate, 4-nitrophenyl palmitate, has also been measured in media containing small unilamelar vesicles of egg phosphatidylcholine in both the absence and presence of taurocholate, and also in the presence of free taurocholate in the absence of liposomes. (3) The enzyme-catalyzed hydrolysis of 4-nitrophenyl acetate is enhanced in all of these systems, but 4-nitrophenyl palmitate is protected from enzymic attack in the phosphatidylcholine-bile salt systems. If free taurocholate be present in the system before 4-nitrophenyl palmitate is added, then, and only then, is enzymic activity observed. (4) These results have been interpreted in terms of the importance of the microenvironment around the substrate and the role played by the bile salt surfactant in stimulating the enzyme.     

Purification of β-glucosidase from the salivary glands of the green rice leafhopper, Nephotettix cincticeps (Uhler) (Hemiptera: Cicadellidae), and its detection in the salivary sheath

The green rice leafhopper, Nephotettix cincticeps (Uhler), is an insect pest of rice and discharges β-glucosidase (EC 3.2.1.21) from its salivary glands during feeding. To investigate the biological function of this enzyme, we purified it from the heads of 18,000 adult females by acetone precipitation and a series of chromatography steps: gel filtration, cation-exchange chromatography, metal-affinity chromatography and hydrophobic interaction chromatography. During cation-exchange chromatography, β-glucosidases were eluted in three peaks (isozymes). These β-glucosidases were monomeric proteins of 58 kDa as estimated by SDS-PAGE and 62 kDa based on gel filtration. All of the purified β-glucosidase isozymes exhibited maximum activity for p-nitrophenyl β-glucoside (NPGlc) and p-nitrophenyl β-galactopyranoside (NPGal) at pH 5.5 and 5.0, respectively. There was no significant difference in substrate specificity among the three isozymes. The Km values were estimated to be 0.13 μM for NPGlc and 0.9 μM for NPGal. Among the oligosaccharide substrates examined, laminaribiose (Glc β1-3 Glc) was the most extensively hydrolyzed, sophorose (Glc β1-2 Glc) and cellobiose (Glc β1-4 Glc) were comparatively well hydrolyzed, and gentiobiose (Glc β1-6 Glc), lactose (Gal β1-4 Glc), laminaritriose, cellotriose and cellotetraose were poorly hydrolyzed. Among the glycoside substrates examined, salicin was considerably well hydrolyzed. β-Glucosidase was detected in the salivary sheaths by activity staining with a fluorescent substrate. The salivary β-glucosidase of N. cincticeps may be involved in the hydrolysis of a phenol glucoside present in the saliva, which is a step in the solidification of gelling saliva to form salivary sheaths.     

A unique chitinase with dual active sites and triple substrate binding sites from the hyperthermophilic archaeon Pyrococcus kodakaraensis KOD1

We have found that the hyperthermophilic archaeon Pyrococcus kodakaraensis KOD1 produces an extracellular chitinase. The gene encoding the chitinase (chiA) was cloned and sequenced. The chiA gene was found to be composed of 3,645 nucleotides, encoding a protein (1,215 amino acids) with a molecular mass of 134,259 Da, which is the largest among known chitinases. Sequence analysis indicates that ChiA is divided into two distinct regions with respective active sites. The N-terminal and C-terminal regions show sequence similarity with chitinase A1 from Bacillus circulans WL-12 and chitinase from Streptomyces erythraeus (ATCC 11635), respectively. Furthermore, ChiA possesses unique chitin binding domains (CBDs) (CBD1, CBD2, and CBD3) which show sequence similarity with cellulose binding domains of various cellulases. CBD1 was classified into the group of family V type cellulose binding domains. In contrast, CBD2 and CBD3 were classified into that of the family II type. chiA was expressed in Escherichia coli cells, and the recombinant protein was purified to homogeneity. The optimal temperature and pH for chitinase activity were found to be 85 degrees C and 5.0, respectively. Results of thin-layer chromatography analysis and activity measurements with fluorescent substrates suggest that the enzyme is an endo-type enzyme which produces a chitobiose as a major end product. Various deletion mutants were constructed, and analyses of their enzyme characteristics revealed that both the N-terminal and C-terminal halves are independently functional as chitinases and that CBDs play an important role in insoluble chitin binding and hydrolysis. Deletion mutants which contain the C-terminal half showed higher thermostability than did N-terminal-half mutants and wild-type ChiA.     

Genome mining and motif modifications of glycoside hydrolase family 1 members encoded by Geobacillus kaustophilus HTA426 provide thermostable 6-phospho-β-glycosidase and β-fucosidase

Members of glycoside hydrolase family 1 (GH1) hydrolyze various glycosides and are widely distributed in organisms. With the aim of producing thermostable GH1 catalysts with potential applications in biotechnology, three GH1 members encoded by the thermophile Geobacillus kaustophilus HTA426 (GK1856, GK2337, and GK3214) were characterized using 24 p-nitrophenyl glycosides as substrates. GK1856 and GK3214 exhibited 6-phospho-β-glycosidase activity, while GK2337 did not. GK3214 was extremely thermostable and retained most of its activity during 7 days of incubation at 60 °C. GK3214 was found to have transglycosylation activity, a dimeric structure, and a possible motif that governed its substrate specificity. Substitution of the GK3214 motif with that of a β-glucosidase resulted in the unexpected generation of a thermostable, highly specific β-fucosidase, concomitant with large increases in β-glucosidase, β-cellobiosidase, α-arabinofuranosidase, β-mannosidase, β-glucuronidase, β-xylopyranosidase, and β-fucosidase activities and a dramatic decline in 6-phospho-β-glycosidase activity. This is the first report to identify a gene encoding thermostable 6-phospho-β-glycosidase and to generate a thermostable β-fucosidase. These results provided thermostable enzyme catalysts and also suggested a promising approach to develop novel GH1 biocatalysts.     

Acylspermidine derivatives isolated from a soft coral,Sinularia sp,inhibit plant vacuolar H(+)-pyrophosphatase

H(+)-pyrophosphatase (H(+)-PPase), which pumps H(+) across membranes coupled with PP(i) hydrolysis, is found in most plants, and some parasitic protists, eubacteria and archaebacteria. We assayed a number of extracts derived from 145 marine invertebrates as to their inhibitory effect on plant vacuolar H(+)-PPase. Acylspermidine derivatives [RCONH(CH(2))(3)N(CH(3))(CH(2))(4)N(CH(3))(2)] from a soft coral (Sinularia sp.) inhibited the PPi-hydrolysis activity of purified H(+)-PPase and the PP(i)-dependent H(+) pump activity (half inhibition concentration, 1 micro M) of vacuolar membranes of mung bean. The apparent K(i) was determined to be 0.9 micro M. Acylspermidines did not affect the activity of vacuolar H(+)-ATPase, plasma membrane H(+)-ATPase, mitochondrial ATPase or cytosolic PPase. Acylspermidines inhibited the acidification of vacuoles in protoplasts, as found on monitoring by the acridine orange fluorescent method. These results indicate that acylspermidine derivatives represent new inhibitors of H(+)-PPase with relatively high specificity.     

Some kinetic properties of the β-d-glucosidase (cellobiase) in a commercial cellulase product from Penicillium funiculosum and its relevance in the hydrolysis of cellulose

Some kinetic parameters of the β-d-glucosidase (cellobiase, β-d-glucoside glucohydrolase, EC 3.2.1.21) component of Sturge Enzymes CP cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] from Penicillium funiculosum have been determined. The Michaelis constants (K_m) for 4-nitrophenyl β-d-glucopyranoside (4NPG) and cellobiose are 0.4 and 2.1 mM, respectively, at pH 4.0 and 50°C. d-Glucose is shown to be a competitive inhibitor with inhibitor constants (K_i) of 1.7 mM when 4NPG is the substrate and 1 mM when cellobiose is the substrate. Cellobiose, at high concentrations, exhibits a substrate inhibition effect on the enzyme. d-Glucono-1,5-lactone is shown to be a potent inhibitor (K_i = 8 μM; 4NPG as substrate) while d-fructose exhibits little inhibition. Cellulose hydrolysis progress curves using Avicel or Solka Floc as substrates and a range of commercial cellulase preparations show that CP cellulase gives the best performance, which can be attributed to the activity of the β-d-glucosidase in this preparation in maintaining the cellobiose at low concentrations during cellulose hydrolysis.