4-Azidophlorizin,a high affinity probe and photoaffinity label for the glucose transporter in brush border membranes

A new phlorizin derivative ($\text{2′-O-(β-}\text{d}\text{-}\text{glucopyranosyl}\text{)-4-}\text{azidophloretin}$, 4-azidophlorizin) has been synthesized and its affinity for the d-glucose, Na⁺ co-transport system in brush border vesicles from intestinal and renal membranes has been compared with that of phlorizin. The extent of the reversible interaction of the ligand with the transporter in dim light has been evaluated from three separate measurements: (1) K′_i, the constant for fully-competitive inhibition of (Na⁺, Δψ)-dependent d-glucose uptake, (2) K′_d, the dissociation constant of 4-azido[³H]phlorizin binding in the presence of an NaSCN inward gradient, and (3) K″_i, the constant for fully-competitive inhibition of the specific ((Na⁺, Δψ)-dependent, d-glucose protectable) high-affinity [³H]phlorizin binding. In experiments with vesicles derived from rat kidney, all three constants (K′_i, K′_d and K″_i) were essentially equal and ranged between 3.2 and 5.2 μM, that is, the azide derivative has almost the same affinity for this transporter as phlorizin itself. On the other hand, compared to phlorizin, the 4-azidophlorizin has a lower affinity for the transporter in vesicles prepared from rabbit; its K′_i values are some 15–20-times larger than those determined with rat membranes. However, the affinity of the azide for the sugar transporter in membranes from either the intestine or kidney of the same animal species (rabbit or rat) was essentially the same. In spite of the lower affinity for the transporter in either membrane system from the rabbit, results described elsewhere (Hosang, M., Gibbs, E.M., Diedrich, D.F. and Semenza, G. (1981) FEBS Lett., 130, 244–248) indicate that 4-azidophlorizin is an effective photoaffinity label in this species also. Photolysis of the azide yields a reactive intermediate which reacts with a 72 kDa protein in rabbit intestine brush borders. Covalent labeling of this protein occurred under conditions which suggests that it is (a component of) the glucose transporter.     

Characterization of a β-glucosidase from Glycine max which hydrolyses coniferin and syringin

A β-glucosidase which rapidly hydrolyses the cinnamyl alcohol glucosides coniferin and syringin has been purified from cell cultures, hypocotyls and roots of Glycine max. Isoelectric focusing in a column separated the enzyme from several other β-glucosidases which were inactive against either substrate. Syringin and coniferin were the best substrates tested. Both exhibited identical V_max values, whereas the K_m of coniferin (0.6 mM) was twice that of syringin (0.3 mM). The widely used synthetic substrates 4-nitrophenyl-β-glucoside and 4-methyl-umbelliferyl-β-glucoside were poorly utilized. Glucono-1,5-lactone was an effective competitive inhibitor with a K_i of 0.01 mM. From the observed-substráte specificity, a role in the lignification process of higher plants may be predicted for this β-glucosidase.     

Overexpression and characterization of a novel cold-adapted and salt-tolerant GH1 β-glucosidase from the marine bacterium <Emphasis Type="Italic">Alteromonas</Emphasis> sp. L82

A novel gene (bgl) encoding a cold-adapted β-glucosidase was cloned from the marine bacterium Alteromonas sp. L82. Based on sequence analysis and its putative catalytic conserved region, Bgl belonged to the glycoside hydrolase family 1. Bgl was overexpressed in E. coli and purified by Ni²⁺ affinity chromatography. The purified recombinant β-glucosidase showed maximum activity at temperatures between 25°C to 45°C and over the pH range 6 to 8. The enzyme lost activity quickly after incubation at 40°C. Therefore, recombinant β-glucosidase appears to be a cold-adapted enzyme. The addition of reducing agent doubled its activity and 2 M NaCl did not influence its activity. Recombinant β-glucosidase was also tolerant of 700 mM glucose and some organic solvents. Bgl had a K_m of 0.55 mM, a V_max of 83.6 U/mg, a k_cat of 74.3 s^-1 and k_cat/K_m of 135.1 at 40°C, pH 7 with 4-nitrophenyl-β-D-glucopyranoside as a substrate. These properties indicate Bgl may be an interesting candidate for biotechnological and industrial applications.     

S-(4-Bromo-2,3-dioxobutyl)CoA: an affinity label for certain enzymes than bind acetyl-CoA.

S-(4-Bromo-2,3-dioxobutyl)-CoA, a potential affinity label for enzymes possessing a receptor site(s) for short-chain acyl-CoA, was synthesized by condensing CoA and 1,4-dibromo-2,3-butanedione in acidified methanol. The new reagent was tested as an active site-directed irreversible inhibitor with four enzymes that accept a short-chain acyl-CoA as substrate. With citrate synthase (pig heart) and acetyl-CoA hydrolase (beef kidney) irreversible inhibition was observed, and the rate of inactivation obeyed first-order kinetics. Benzoyl-CoA, a reversible competitive inhibitor versus acetyl-CoA with both citrate synthase and acetyl-CoA hydrolase, protected the active site of both enzymes against the irreversible inhibitor. The new reagent was an exceptionally potent irreversible inhibitor of acetoacetyl-CoA thiolase (beef liver). Relatively low concentrations of the reagent (≥1 μm) completely inhibited the thiolase in less than 2 min. Preincubation of thiolase with acetoacetyl-CoA protected the enzyme against inhibition by S-(4-bromo-2,3-dioxobutyl)-CoA. In contrast, irreversible inhibition of l-3-hydroxyacyl-CoA dehydrogenase (pig heart) was not observed. Instead, the new reagent appeared to be a weak alternate substrate for this dehydrogenase. In all cases, the new reagent exhibited tight reversible binding at the active site since the measured K_i's (and K_m) were in the range, 30 to 120 μm. It is anticipated that the new reagent will be suitable for investigating a number of acyl-CoA using enzymes by affinity labeling techniques.     

High-affinity phlorizin binding to brush border membranes from small intestine: Identity with (a part of) the glucose transport system,dependence on the Na+-gradient,partial purification

In the presence of an NaSCN gradient phlorizin binds with a high affinity (K_d ? 4.7 μM) to vesicles derived from brush border membranes of intestinal cells of rabbits. The value for K_d corresponds closely to that of K_i determined from phlorizin inhibition of sugar transport. The apparent affinity for phlorizin is decreased if NaCl is substituted for NaSCN and decreased substantially if the gradient of NaSCN is allowed to dissipate prior to the phlorizin binding. The number of high affinity binding sites is about 11 pmol/mg protein. Additional binding to low affinity sites can amount to as much as 600 pmol/mg protein after prolonged exposure to phlorizin (5 min). The high affinity sites are related to glucose transport based on the similarity of the K_d and K_i values under a variety of conditions and on the inhibition of the binding by D-glucose but not by D-fructose. The transport system and the high affinity phlorizin binding sites can be enriched by a factor of 2–3 by treatment of vesicles with papain, which does not affect the transport system, but considerably hydrolyzes nonrelevant protein.     

A novel β-glucosidase isolated from the microbial metagenome of Lake Poraquê (Amazon,Brazil)

The Amazon region holds most of the biological richness of Brazil. Despite their ecological and biotechnological importance, studies related to microorganisms from this region are limited. Metagenomics leads to exciting discoveries, mainly regarding non-cultivable microorganisms. Herein, we report the discovery of a novel β-glucosidase (glycoside hydrolase family 1) gene from a metagenome from Lake Poraquê in the Amazon region. The gene encodes a protein of 52.9 kDa, named AmBgl-LP, which was recombinantly expressed in Escherichia coli and biochemically and structurally characterized. Although AmBgl-LP hydrolyzed the synthetic substrate p-nitrophenyl-β-d-glucopyranoside (pNPβG) and the natural substrate cellobiose, it showed higher specificity for pNPβG (k_cat/K_m = 6 s⁻¹·mM⁻¹) than cellobiose (k_cat/K_m = 0.6 s⁻¹·mM⁻¹). AmBgl-LP showed maximum activity at 40 °C and pH 6.0 when pNPβG was used as the substrate. Glucose is a competitive inhibitor of AmBgl-LP, presenting a K_i of 14 mM. X-ray crystallography and Small Angle X-ray Scattering were used to determine the AmBgl-LP three-dimensional structure and its oligomeric state. Interestingly, despite sharing similar active site architecture with other structurally characterized GH1 family members which are monomeric, AmBgl-LP forms stable dimers in solution. The identification of new GH1 members by metagenomics might extend our understanding of the molecular mechanisms and diversity of these enzymes, besides enabling us to survey their industrial applications.     

β-Glucosidase activity is involved in scent production in Narcissus flowers

Extrinsic environmental cues and intrinsic developmental stages of the flower control the production of scent from flowers. Flowers emit scent only when they are open; yet, the precursors for the aromatic compounds are also present in buds, stored as non-fragrant glycosides in the vacuole. We demonstrate that in Narcissus flowers scent emission is concurrent with an increase in the activity of β-glucosidase. The inhibition in vivo of β-glucosidase activity decreases scent emission from Narcissus flowers. The β-glucosidase activity was partially purified and the K_m, V_max and inhibition by gluconic acid lactone was determined.     

The inhibition of β-glucosidase activity in Trichoderma reesei C30 cellulase by derivatives and isomers of glucose

The inhibition of β-glucosidase in Trichoderma reesei C30 cellulase by D -glucose, its isomers, and derivatives was studied using cellobiose and ρ-nitrophenyl-β-glucoside (PNPG) as substrates for determining enzyme activity. The enzymatic hydrolysis of both substrates was inhibited competitively by glucose with approximate K_i values of 0.5mM and 8.7mM for cellobiose and PNPG as substrate, respectively. This inhibition by glucose was maximal at pH 4.8, and no inhibition was observed at pH 6.5 and above. The α anomer of glucose inhibited β-glucosidase to a greater extent than did the β form. Compared with D -glucose, L -glucose, D -glucose-6-phosphate, and D -glucose-1-phosphate inhibited the enzyme to a much lesser extent, unlike D -glucose-L -cysteine which was almost as inhibitory as glucose itself when cellobiose was used as substrate. Fructose (2?100mM) was found to be a poor inhibitor of the enzyme. It is suggested that high rates of cellobiose hydrolysis catalyzed by β-glucosidase may be prolonged by converting the reaction product glucose to fructose using a suitable preparation of glucose isomerase.     

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.     

Functional characterization, homology modeling and docking studies of β-glucosidase responsible for bioactivation of cyanogenic hydroxynitrile glucosides from Leucaena leucocephala (subabul)

Glycosyl hydrolase family 1 β-glucosidases are important enzymes that serve many diverse functions in plants including defense, whereby hydrolyzing the defensive compounds such as hydroxynitrile glucosides. A hydroxynitrile glucoside cleaving β-glucosidase gene (Llbglu1) was isolated from Leucaena leucocephala, cloned into pET-28a (+) and expressed in E. coli BL21 (DE3) cells. The recombinant enzyme was purified by Ni–NTA affinity chromatography. The optimal temperature and pH for this β-glucosidase were found to be 45 °C and 4.8, respectively. The purified Llbglu1 enzyme hydrolyzed the synthetic glycosides, pNPGlucoside (pNPGlc) and pNPGalactoside (pNPGal). Also, the enzyme hydrolyzed amygdalin, a hydroxynitrile glycoside and a few of the tested flavonoid and isoflavonoid glucosides. The kinetic parameters K _m and V _max were found to be 38.59 μM and 0.8237 μM/mg/min for pNPGlc, whereas for pNPGal the values were observed as 1845 μM and 0.1037 μM/mg/min. In the present study, a three dimensional (3D) model of the Llbglu1 was built by MODELLER software to find out the substrate binding sites and the quality of the model was examined using the program PROCHEK. Docking studies indicated that conserved active site residues are Glu 199, Glu 413, His 153, Asn 198, Val 270, Asn 340, and Trp 462. Docking of rhodiocyanoside A with the modeled Llbglu1 resulted in a binding with free energy change (ΔG) of ?5.52 kcal/mol on which basis rhodiocyanoside A could be considered as a potential substrate.     

Physico-kinetic and functional features of a novel β-glucosidase isolated from milk thistle (Silybum marianum Gaertn.) flower petals

A highly abundant β-glucosidase from petals of Silybum marianum has been purified and characterized for its physico-kinetic properties. The 135 kDa enzyme was a homodimer with subunit molecular mass of 67.6 kDa. The characteristic catalytic properties of the enzyme included acidic pH optimum (5.5), meso-thermostability, and β-linked substrate specificity with preference for gluco-conjugate but a marked (>50 %) activity with D-fuco-conjugates and considerable (~16 %) activity towards D-galacto-conjugates. The enzyme showed high affinity for p-nitrophenyl glucoside (pNPG) with K_m and V_max values of 0.25 mM and 5.35 μkat.mg^?1 enzyme protein. Thus, the enzyme had a very high (292,000 M^?1.s^?1) catalytic efficiency (K_cat/K_m). Thermal catalytic optimum of enzyme was 40 °C with activation energy value 8.26 kCal.Mol^?1. The enzyme showed significant insensitivity to D-gluconic acid lactone inhibition (57 % at 5 mM) with an apparent K_i 3.8 mM. The transglucosylating ability of enzyme was noticed for glucosylation of geraniol and withaferin-A with pNPG as glucosyl donor but cellobiose did not serve as the glycosyl donor. Partial proteomics of the enzyme revealed two peptide fragment sequences, VTPSNEVH and KRSEESNF. These motifs showed significant matching/sequence conservation with some other glycohydrolases. The novelties of purified enzyme hold potential to expand a library of catalytically characteristic members of the hydrolase family from plants for use in biotransformation applications.     

Key aromatic residues at subsites + 2 and + 3 of glycoside hydrolase family 31 α-glucosidase contribute to recognition of long-chain substrates

Glycoside hydrolase family 31 α-glucosidases (31AGs) show various specificities for maltooligosaccharides according to chain length. Aspergillus niger α-glucosidase (ANG) is specific for short-chain substrates with the highest k_cat/K_m for maltotriose, while sugar beet α-glucosidase (SBG) prefers long-chain substrates and soluble starch. Multiple sequence alignment of 31AGs indicated a high degree of diversity at the long loop (N-loop), which forms one wall of the active pocket. Mutations of Phe236 in the N-loop of SBG (F236A/S) decreased k_cat/K_m values for substrates longer than maltose. Providing a phenylalanine residue at a similar position in ANG (T228F) altered the k_cat/K_m values for maltooligosaccharides compared with wild-type ANG, i.e., the mutant enzyme showed the highest k_cat/K_m value for maltotetraose. Subsite affinity analysis indicated that modification of subsite affinities at + 2 and + 3 caused alterations of substrate specificity in the mutant enzymes. These results indicated that the aromatic residue in the N-loop contributes to determining the chain-length specificity of 31AGs.     

Gene cloning and characterization of a cold-adapted β-glucosidase belonging to glycosyl hydrolase family 1 from a psychrotolerant bacterium Micrococcus antarcticus

The gene bglU encoding a cold-adapted β-glucosidase (BglU) was cloned from Micrococcus antarcticus. Sequence analysis revealed that the bglU contained an open reading frame of 1419 bp and encoded a protein of 472 amino acid residues. Based on its putative catalytic domains, BglU was classified as a member of the glycosyl hydrolase family 1 (GH1). BglU possessed lower arginine content and Arg/(Arg + Lys) ratio than mesophilic GH1 β-glucosidases. Recombinant BglU was purified with Ni2+ affinity chromatography and subjected to enzymatic characterization. SDS-PAGE and native staining showed that it was a monomeric protein with an apparent molecular mass of 48 kDa. BglU was particularly thermolabile since its half-life time was only 30 min at 30 °C and it exhibited maximal activity at 25 °C and pH 6.5. Recombinant BglU could hydrolyze a wide range of aryl-β-glucosides and β-linked oligosaccharides with highest activity towards cellobiose and then p-nitrophenyl-β-d-glucopyranoside (pNPG). Under the optimal conditions with pNPG as substrate, the K_m and k_cat were 7 mmol/L and 7.85 × 103/s, respectively. This is the first report of cloning and characterization of a cold-adapted β-glucosidase belonging to GH1 from a psychrotolerant bacterium.     

Purification and characterization of cyanogenic β-glucosidase from wild apricot (Prunus armeniaca L.)

β-Glucosidase catalyzes the sequential breakdown of cyanogenic glycosides in cyanogenic plants. The β-glucosidase from Prunus armeniaca L. was purified to 8-fold, and 20% yield was obtained, with a specific activity of 281 U/mg protein. The enzyme showed maximum activity in 0.15 M sodium citrate buffer, pH 6, at 35 °C with p-nitrophenylglucopyranoside as substrate. The β-glucosidase from wild apricot was used successfully for the saccharification of cellobiose into D-glucose. This enzyme has a V_max of 131.6 μmol min⁻¹ mg⁻¹ protein, K_m of 0.158 mM, K_cat of 144.8 s⁻¹, K_cat/K_m of 917.4 mM⁻¹ s⁻¹, and K_m/V_max of 0.0012 mM min mg μmole⁻¹, using cellobiose as substrate. The half-life, deactivation rate coefficient, and activation energy of this β-glucosidase were 12.76 h, 1.509 × 10⁻⁵ s⁻¹, and 37.55 kJ/mol, respectively. These results showed that P. armeniaca is a potential source of β-glucosidase, with high affinity and catalytic capability for the saccharification of cellulosic material.     

Analysis of the <Emphasis Type="Italic">xynB5</Emphasis> gene encoding a multifunctional GH3-BglX β-glucosidase-β-xylosidase-α-arabinosidase member in <Emphasis Type="Italic">Caulobacter crescentus</Emphasis>

The Caulobacter crescentus (NA1000) xynB5 gene (CCNA_03149) encodes a predicted β-glucosidase-β-xylosidase enzyme that was amplified by polymerase chain reaction; the product was cloned into the blunt ends of the pJet1.2 plasmid. Analysis of the protein sequence indicated the presence of conserved glycosyl hydrolase 3 (GH3), β-glucosidase-related glycosidase (BglX) and fibronectin type III-like domains. After verifying its identity by DNA sequencing, the xynB5 gene was linked to an amino-terminal His-tag using the pTrcHisA vector. A recombinant protein (95 kDa) was successfully overexpressed from the xynB5 gene in E. coli Top 10 and purified using pre-packed nickel-Sepharose columns. The purified protein (BglX-V-Ara) demonstrated multifunctional activities in the presence of different substrates for β-glucosidase (pNPG: p-nitrophenyl-β-D-glucoside) β-xylosidase (pNPX: p-nitrophenyl-β-D-xyloside) and α-arabinosidase (pNPA: p-nitrophenyl-α-L-arabinosidase). BglX-V-Ara presented an optimal pH of 6 for all substrates and optimal temperature of 50 °C for β-glucosidase and α-l-arabinosidase and 60 °C for β-xylosidase. BglX-V-Ara predominantly presented β-glucosidase activity, with the highest affinity for its substrate and catalytic efficiency (K_m 0.24 ± 0.0005 mM, V_max 0.041 ± 0.002 µmol min^?1 mg^?1 and K_cat/K_m 0.27 mM^?1 s^?1), followed by β-xylosidase (K_m 0.64 ± 0.032 mM, V_max 0.055 ± 0.002 µmol min^?1 mg^?1 and K_cat/K_m 0.14 mM^?1s^?1) and finally α-l-arabinosidase (K_m 1.45 ± 0.05 mM, V_max 0.091 ± 0.0004 µmol min^?1 mg^?1 and K_cat/K_m 0.1 mM^?1 s^?1). To date, this is the first report to demonstrate the characterization of a GH3-BglX family member in C. crescentus that may have applications in biotechnological processes (i.e., the simultaneous saccharification process) because the multifunctional enzyme could play an important role in bacterial hemicellulose degradation.     

Hydrogen bonding requirements for the insulin-sensitive sugar transport system of rat adipocytes

(1) The $\text{t}\text{1}\text{2}$ for 1.3 mM D-allose uptake and efflux in insulin-stimulated adipocytes is 1.7 ± 0.1 min. In the absence of insulin mediated uptake of D-allose is virtually eliminated and the uptake rate ($\text{t}\text{1}\text{2}\text{= 75.8 ± 4.99}\text{min}$) is near that calculated for nonmediated transport. The kinetic parameters for D-allose zero-trans uptake in insulin-treated cells are K_zt^oi = 271.3 ± 34.2 mM, V_zt^oi = 1.15 ± 0.12 mM · s^?1. (2) A kinetic analysis of the single-gate transporter (carrier) model interacting with two substrates (or substrate plus inhibitor) is presented. The analysis shows that the heteroexchange rates for two substrates interacting with the transporter are not unique and can be calculated from the kinetic parameters for each sugar acting alone with the transporter. This means that the equations for substrate analogue inhibition of the transport of a low affinity substrate such as D-allose can be simplified. It is shown that for the single gate transporter the K_i for a substrate analogue inhibitor should equal the equilibrium exchange K_m for this analogue. (3) Analogues substituted at C-1 show a fused pyranose ring is accepted by the transporter. 1-Deoxy-D-glucose is transported but has low affinity for the transporter. High affinity can be restored by replacing a fluorine in the β-position at C-1. The K_i for $\text{d}\text{-glucose}\text{= 8.62}\text{mM}$; the K_i for $\text{β-}\text{fluoro-}\text{d}\text{-glucose}\text{= 6.87}\text{mM}$. Replacing the ring oxygen also results in a marked reduction in affinity. The K_i for $\text{5-}\text{thio-}\text{d}\text{-glucose}\text{= 42.1}\text{mM}$. (4) A hydroxyl in the gluco configuration at C-2 is not required as 2-deoxy-d-galactose (K_i = 20.75 mM) has a slightly higher affinity than d-galactose (K_i = 24.49 mM). A hydroxyl in the manno configuration at C-2 interferes with transport as d-talose (K_i = 35.4 mM) has a lower affinity than d-galactose. (5) d-Allose (K_m = 271.3 mM) and 3-deoxy-d-glucose (K_i = 40.31 mM) have low affinity but high affinity is restored by substituting a fluorine in the gluco configuration at C-3. The K_i for $\text{3-}\text{fluoro-}\text{d}\text{-glucose}\text{= 7.97}\text{mM}$. (6) Analogues modified at C-4 and C-6 do not show large losses in affinity. However, 6-deoxy-d-glucose (K_i = 11.08 mM) has lower affinity than d-glucose and 6-deoxy-d-galactose K_i = 33.97 mM) has lower affinity than d-galactose. Fluorine substitution at C-6 of d-galactose restores high affinity. The K_i for $\text{6-}\text{fluoro-}\text{d}\text{-galactose}\text{= 6.67}\text{mM}$. Removal of the C-5 hydroxymethyl group results in a large affinity loss. The K_i$\text{d}\text{-xylose}\text{= 45.5}\text{mM}$. The K_i for $\text{l}\text{-arabinose}\text{= 49.69}\text{mM}$. (7) These results indicate that the important hydrogen bonding positions involved in sugar interaction with the insulin-stimulated adipocytes transporter are the ring oxygen, C-1 and C-3. There may be a weaker hydrogen bond to C-6. Sugar hydroxyls in non-gluco configurations may sterically hinder transport.     

A recruited protease is involved in catabolism of pyrimidines

In nature, the same biochemical reaction can be catalyzed by enzymes having fundamentally different folds, reaction mechanisms and origins. For example, the third step of the reductive catabolism of pyrimidines, the conversion of N-carbamyl-β-alanine to β-alanine, is catalyzed by two β-alanine synthase (βASase, EC 3.5.1.6) subfamilies. We show that the “prototype” eukaryote βASases, such as those from Drosophila melanogaster and Arabidopsis thaliana, are relatively efficient in the conversion of N-carbamyl-βA compared with a representative of fungal βASases, the yeast Saccharomyces kluyveri βASase, which has a high K_m value (71 mM). S. kluyveri βASase is specifically inhibited by dipeptides and tripeptides, and the apparent K_i value of glycyl-glycine is in the same range as the substrate K_m. We show that this inhibitor binds to the enzyme active center in a similar way as the substrate. The observed structural similarities and inhibition behavior, as well as the phylogenetic relationship, suggest that the ancestor of the fungal βASase was a protease that had modified its profession and become involved in the metabolism of nucleic acid precursors.     

Selective α-glucosidase substrates and inhibitors containing short aromatic peptidyl moieties

We constructed a library of sugar-dipeptide conjugate to find out the best complementary against hydrophobic pocket of α-glucosidase. The best substrate showed 150-fold improved K_m value relative p-acetaminophenyl-α-d-glucopyranoside for α-glucosidase from Bacillus stearothermophillus. Using information from the complementary, we synthesized sp-WY and β-Glc-sp-WY, which selectivity inhibited the cognate enzyme.     

Role of Glu445 in the substrate binding of β-glucosidase

A previously uncharacterized gene in Neosartorya fischeri was cloned and expressed in Escherichia coli. It was found to encode a β-glucosidase (NfBGL1) distinguishable from other BGLs by its high turnover of p-nitrophenyl β-d-glucopyranoside (pNPG). Molecular determinants for the substrate recognition of NfBGL1 were studied through an initial screening of residues by sequence alignment, a second screening by homology modeling and subsequent site-directed mutagenesis to alter individual screened residues. A conserved amino acid, E445, in the substrate binding pocket of wild-type NfBGL1 was identified as an important residue affecting substrate affinity. Replacement of E445 with amino acids other than aspartate significantly decreased the catalytic efficiency (k_cat/K_m) of NfBGL1 towards pNPG, mainly through decreased binding affinity. This was likely due to the disruption of hydrogen bonding between the substrate and the carboxylate oxygen of the residue at position 445. Density functional theory (DFT) based studies suggested that an acidic amino acid at position 445 raises the substrate affinity of NfBGL1 through hydrogen bonding. The residue E445 is completely conserved indicating that this position can be considered as a crucial determinant for the substrate binding among GHs tested.     

The kinetic advantage for transport into hamster intestine of glucose generated from phlorizin by brush border β-glucosidase

Phlorizin, labeled with tritium only in the glucose moiety, was used as substrate for the β-glucosidase present in brush border membranes from hamster intestine in order to study, simultaneously, the kinetics of hydrolysis and the fate of the [³H]glucose liberated by the enzyme. The [³H]glucose seems to experience the same hydrolase related transport into the intestinal villi as the hexoses liberated from the common disaccharides by their respective hydrolases. The released [³H]glucose accumulation rate is only partially inhibited by unlabelled glucose added to the medium as either the free sugar or as the precursors sucrose, lactose or glucose 1-phosphate, and then only when these sugars are present at very high levels. Furthermore, glucose oxidase, added to the medium as a glucose scavenger, has no effect on the uptake rate of the phlorizin hydrolase-liberated sugar. These and other findings are presented as evidence that, under conditions where the Na⁺-dependent glucose carrier is more than 97% inhibited by phlorizin, the glucose derived from the inhibitor, like the hexoses from disaccharides, has a kinetic advantage for transfer into the intestinal tissue.