Contribution of a neopullulanase, a pullulanase, and an alpha-glucosidase to growth of Bacteroides thetaiotaomicron on starch.

Bacteroides thetaiotaomicron, a gram-negative colonic anaerobe, can utilize three forms of starch: amylose, amylopectin, and pullulan. Previously, a neopullulanase, a pullulanase, and an alpha-glucosidase from B. thetaiotaomicron had been purified and characterized biochemically. The neopullulanase and alpha-glucosidase appeared to be the main enzymes involved in the breakdown of starch, because they were responsible for most of the starch-degrading activity detected in B. thetaiotaomicron cell extracts. To determine the importance of these enzymes in the starch utilization pathway, we cloned the genes encoding the neopullulanase and alpha-glucosidase. The gene encoding the neopullulanase (susA) was located upstream of the gene encoding the alpha-glucosidase (susB). Both genes were closely linked to another starch utilization gene, susC, which encodes a 115-kDa outer membrane protein that is essential for growth on starch. The gene encoding the pullulanase, pulI, was not located in this region in the chromosome. Disruption of the neopullulanase gene, susA, reduced the rate of growth on starch by about 30%. Elimination of susA in this strain allowed us to detect a low residual level of enzyme activity, which was localized to the membrane fraction. Previously, we had shown that a disruption in the pulI gene did not affect the rate of growth on pullulan. We have now shown that a double mutant, with a disruption in susA and in the pullulanase gene, pulI, was also able to grow on pullulan. Thus, there is at least one other starch-degrading enzyme besides the neopullulanase and the pullulanase. Disruption of the alpha-glucosidase gene, susB, reduced the rate of growth on starch only slightly. No residual alpha-glucosidase activity was detectable in extracts from this strain. Since this strain could still grow on maltose, maltotriose, and starch, there must be at least one other enzyme capable of degrading the small oligomers produced by the starch-degrading enzymes. Our results show that the starch utilization system of B. thetaiotaomicron is quite complex and contains a number of apparently redundant degradative enzymes.     

Three Forms of α-Glucosidase from Suspension-cultured Rice Cells

Three forms of α-glucosidase (EC 3.2.1.20), designated as I, II, and III, have been isolated from suspension-cultured rice cells by a procedure including fractionation with ammonium sulfate, CM-cellulose column chromatography, and preparative disc gel electrophoresis. The three enzymes were homogeneous by Polyacrylamide disc gel electrophoresis. α-Glucosidase I was secreted in the culture medium during growth, α-glucosidase II was readily extracted from rice cells with the buffer alone, and α-glucosidase III required NaCl to be solubilized. The molecular weights of the three enzymes were 96,000 (I), 84,000 (II), and 58,000 (III). The three enzymes readily hydrolyzed maltose, maltotriose, maltotetraose, amylose, and soluble starch. α-Glucosidase I possessed strong isomaltose-hydrolyzing activity and hydrolyzed isomaltose about three times as rapidly as α-glucosidase III. The three enzymes produced panose as the main α-glucosyltransfer product from maltose. Half the maltose-hydrolyzing activities of the three enzymes were inhibited by 11.25 ng of castanospermine. The inhibition was competitive.     

In vitro utilization of amylopectin and high-amylose maize (Amylomaize) starch granules by human colonic bacteria.

It has been well established that a certain amount of ingested starch can escape digestion in the human small intestine and consequently enters the large intestine, where it may serve as a carbon source for bacterial fermentation. Thirty-eight types of human colonic bacteria were screened for their capacity to utilize soluble starch, gelatinized amylopectin maize starch, and high-amylose maize starch granules by measuring the clear zones on starch agar plates. The six cultures which produced clear zones on amylopectin maize starch- containing plates were selected for further studies for utilization of amylopectin maize starch and high-amylose maize starch granules A (amylose; Sigma) and B (Culture Pro 958N). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was used to detect bacterial starch-degrading enzymes. It was demonstrated that Bifidobacterium spp., Bacteroides spp., Fusobacterium spp., and strains of Eubacterium, Clostridium, Streptococcus, and Propionibacterium could hydrolyze the gelatinized amylopectin maize starch, while only Bifidobacterium spp. and Clostridium butyricum could efficiently utilize high-amylose maize starch granules. In fact, C. butyricum and Bifidobacterium spp. had higher specific growth rates in the autoclaved medium containing high-amylose maize starch granules and hydrolyzed 80 and 40% of the amylose, respectively. Starch-degrading enzymes were cell bound on Bifidobacterium and Bacteroides cells and were extracellular for C. butyricum. Active staining for starch-degrading enzymes on SDS-PAGE gels showed that the Bifidobacterium cells produced several starch-degrading enzymes with high relative molecular (M(r)) weights (>160,000), medium-sized relative molecular weights (>66,000), and low relative molecular weights (<66,000). It was concluded that Bifidobacterium spp. and C. butyricum degraded and utilized granules of amylomaize starch.     

Genetic evidence that outer membrane binding of starch is required for starch utilization by Bacteroides thetaiotaomicron

Mutagenesis of Bacteroides thetaiotaomicron with the transposon Tn4351 produced five classes of mutants that were not able to grow on amylose or amylopectin. These classes of mutants differed in their ability to grow on maltoheptaose (G7) and in the level of starch-degrading enzymes produced when bacteria were grown on maltose. All of the mutants were deficient in starch binding. Since one class of mutants retained normal levels of starch-degrading enzymes, this indicates that binding of the starch molecule by a cell surface receptor is necessary for starch utilization by B. thetaiotaomicron. Analysis of a starch-negative mutant that grew on G7 indicated that B. thetaiotaomicron possessed two starch-binding components or sites. One component (site A), apparently missing in this mutant, had an absolute preference for larger starch oligomers, whereas the other component (site M) also had a high affinity for maltodextrins (G4 through G7). Mutants not able to grow on maltodextrins (greater than G4) probably lacked both of these binding components. Only one class of mutants did not grow normally on maltose, but instead had a 4- to 5-h lag on maltose and a slower growth rate than the wild type. This class of mutants did not produce any of the starch-degrading enzymes or bind starch, even when growing on maltose. Such a phenotype probably resulted from transposon inactivation of a central regulatory gene or a gene encoding an enzyme that produces the inducer. The fact that both the degradative enzymes and the starch-binding activity were affected in this mutant indicates that genes encoding the cell surface starch-binding site are under the same regulatory control as genes encoding the enzymes.     

Two Forms of Glucoamylase from Mucor rouxianus

Both of the two forms of glucoamylase (glucoamylases I and II) from the wheat bran culture of Mucor rouxianus hydrolyzed amylopectin, amylose, glycogen, soluble starch, maltotriose, and maltose, but did not act on isomaltose and isomaltotriose. Phenyl α-maltoside was hydrolyzed into glucose and phenyl α-glucoside by both glucoamylases. Maltose was hydrolyzed about one-fifth as rapidly as amylopectin. Both enzymes produced glucose from amylopectin, amylose, glycogen, soluble starch in the yields of almost complete hydrolysis. They hydrolyzed amylose with the inversion of configuration, producing the β-anomer of glucose. Glucoamylase II hydrolyzed raw starch at 3-fold higher rate than glucoamylase I. The former hydrolyzed rice starch almost completely into glucose, whereas the latter hydrolyzed it incompletely (nearly 50%).     

Hydrolysis of alpha-D-glucans and alpha-D-gluco-oligosaccharides by Cladosporium resinae glucoamylases

Culture filtrates of Cladosporium resinae ATCC 20495 contain a mixture of enzymes able to convert starch and pullulan efficiently into D-glucose. Culture conditions for optimal production of the pullulan-degrading activity have been established. The amylolytic enzyme preparation was fractionated by ion-exchange and molecular-sieve chromatography, and shown to contain alpha-D-glucosidase, alpha-amylase, and two glucoamylases. The glucoamylases have been purified to homogeneity and their substrate specificities investigated. One of the glucoamylases (termed P) readily hydrolyses the (1 leads to 6)-alpha-D linkages in pullulan, amylopectin, isomaltose, panose, and 6(3)-alpha-D-glucosylmaltotriose. Each of the glucoamylases cleaves the (1 leads to 6)-alpha-D linkage in panose much more readily than that in isomaltose.     

Purification and Properties of Wall-bound α-Glucosidase from Suspension-cultured Rice Cells

Wall-bound α-glucosidase (EC 3.2.1.20) has been solubilized from suspension-cultured rice cells with Sumyzyme C and Pectolyase Y-23 and isolated by a procedure including fractionation with ammonium sulfate, Sephadex G-100 column chromatography, CM-cellulose column chroma-tography, Sephadex G-200 column chromatography, and preparative disc gel electrophoresis. The molecular weight of the enzyme was 64,000. The enzyme readily hydrolyzed maltose, maltotriose, and amylose, but hydrolyzed isomaltose and soluble starch more slowly. The Michaelis constant for maltose of the enzyme was estimated to be 0.272 mm. The enzyme produced panose as the main α- glucosyltransferred product from maltose.     

Purification and Properties of α-Glucosidase and Glucoamylase from Lentinus edodes (Berk.) Sing.

An α-glucosidase and a glucoamylase have been isolated from fruit bodies of Lentinus edodes (Berk.) Sing., by a procedure including fractionation with ammonium sulfate, DEAE-cellulose column chromatography, and preparative gel electrofocusing. Both of them were homogeneous on gel electrofocusing and ultracentrifugation. The molecular weight of α-glucosidase and glucoamylase was 51,000 and 55,000, respectively. The α-glucosidase hydrolyzed maltose, maltotriose, phenyl α-maltoside, amylose, and soluble starch, but did not act on sucrose. The glucoamylase hydrolyzed maltose, maltotriose, phenyl α-maltoside, soluble starch, amylose, amylopectin, and glycogen, glucose being the sole product formed in the digests of these substrates. Both enzymes hydrolyzed phenyl a-maltoside into glucose and phenyl α-glucoside. The glucoamylase hydrolyzed soluble starch, amylose, amylopectin, and glycogen, converting them almost completely into glucose. It was found that β-glucose was liberated from amylose by the action of glucoamylase, while α-glucose was produced by the α-glucosidase.

Maltotriose was the main α-glucosyltransfer product formed from maltose by the α-glucosidase.     

Purification and characterization of cyclic maltosyl-(1-->6)-maltose hydrolase and alpha-glucosidase from an Arthrobacter globiformis strain

Cyclic maltosyl-maltose [CMM, cyclo-[-->6)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->]], a novel cyclic tetrasaccharide, has a unique structure. Its four glucose residues are joined by alternate alpha-1,4 and alpha-1,6 linkages. CMM is synthesized from starch by the action of 6-alpha-maltosyltransferase from Arthrobacter globiformis M6. Recently, we determined the mechanism of extracellular synthesis of CMM, but the degrading pathway of the saccharide remains unknown. Hence we tried to identify the enzymes involved in the degradation of CMM to glucose from the cell-free extract of the strain, and identified CMM hydrolase (CMMase) and alpha-glucosidase as the responsible enzymes. The molecular mass of CMMase was determined to be 48.6 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and 136 kDa by gel filtration column chromatography. The optimal pH and temperature for CMMase activity were 6.5 and 30 degrees C. The enzyme remained stable from pH 5.5 to 8.0 and up to 25 degrees C. CMMase hydrolyzed CMM to maltose via maltosyl-maltose as intermediates, but it did not hydrolyze CMM to glucose, suggesting that it is a novel hydrolase that hydrolyzes the alpha-1,6-linkage of CMM. The molecular mass of alpha-glucosidase was determined to be 60.1 kDa by SDS-PAGE and 69.5 kDa by gel filtration column chromatography. The optimal pH and temperature for alpha-glucosidase activity were 7.0 and 35 degrees C. The enzyme remained stable from pH 7.0 to 9.5 and up to 35 degrees C. alpha-Glucosidase degraded maltosyl-maltose to glucose via panose and maltose as intermediates, but it did not degrade CMM. Furthermore, when CMMase and alpha-glucosidase existed simultaneously in a reaction mixture containing CMM, glucose was detected as the final product. It was found that CMM was degraded to glucose by the synergistic action of CMMase and alpha-glucosidase.     

Characterization of a neopullulanase and an alpha-glucosidase from Bacteroides thetaiotaomicron 95-1.

Previously, we constructed a gene disruption in the pullulanase I gene of Bacteroides thetaiotaomicron 5482A. This mutant, designated B. thetaiotaomicron 95-1, had a lower level of pullulanase specific activity than did wild-type B. thetaiotaomicron but still exhibited a substantial amount of pullulanase activity. Characterization of the remaining pullulanase activity present in B. thetaiotaomicron 95-1 has identified an alpha(1----4)-D-glucosidic bond cleaving pullulanase which has been tentatively designated a neopullulanase. The neopullulanase (pullulanase II) is a 70-kDa soluble protein which cleaves alpha(1----4)-D-glucosidic bonds in pullulan to produce panose. The neopullulanase also cleaved alpha(1----4) bonds in amylose and in oligosaccharides of maltotriose through maltoheptaose in chain length. An alpha-glucosidase from B. thetaiotaomicron 95-1 was characterized. The alpha-glucosidase was partially purified to a preparation containing three proteins of 80, 57, and 50 kDa. Pullulan and amylose were not hydrolyzed by the alpha-glucosidase. alpha(1----4)-D-Glucosidic oligosaccharides from maltose to maltoheptaose were hydrolyzed to glucose by the alpha-glucosidase. The alpha-glucosidase also hydrolyzed alpha(1----6)-linked oligosaccharides such as panose (the product of the pullulanase II action on pullulan) and isomaltotriose.     

Bacillus stearothermophilus neopullulanase selective hydrolysis of amylose to maltose in the presence of amylopectin

The specificity of Bacillus stearothermophilus TRS40 neopullulanase toward amylose and amylopectin was analyzed. Although this neopullulanase completely hydrolyzed amylose to produce maltose as the main product, it scarcely hydrolyzed amylopectin. The molecular mass of amylopectin was decreased by only one order of magnitude, from approximately 10(8) to 10(7) Da. Furthermore, this neopullulanase selectively hydrolyzed amylose when starch was used as a substrate. This phenomenon, efficient hydrolysis of amylose but not amylopectin, was also observed with cyclomaltodextrinase from alkaliphilic Bacillus sp. strain A2-5a and maltogenic amylase from Bacillus licheniformis ATCC 27811. These three enzymes hydrolyzed cyclomaltodextrins and amylose much faster than pullulan. Other amylolytic enzymes, such as bacterial saccharifying alpha-amylase, bacterial liquefying alpha-amylase, beta-amylase, and neopullulanase from Bacillus megaterium, did not exhibit this distinct substrate specificity at all, i.e., the preference of amylose to amylopectin.     

In Vitro Utilization of Amylopectin and High-Amylose Maize (Amylomaize) Starch Granules by Human Colonic Bacteria

It has been well established that a certain amount of ingested starch can escape digestion in the human small intestine and consequently enters the large intestine, where it may serve as a carbon source for bacterial fermentation. Thirty-eight types of human colonic bacteria were screened for their capacity to utilize soluble starch, gelatinized amylopectin maize starch, and high-amylose maize starch granules by measuring the clear zones on starch agar plates. The six cultures which produced clear zones on amylopectin maize starch- containing plates were selected for further studies for utilization of amylopectin maize starch and high-amylose maize starch granules A (amylose; Sigma) and B (Culture Pro 958N). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was used to detect bacterial starch-degrading enzymes. It was demonstrated that Bifidobacterium spp., Bacteroides spp., Fusobacterium spp., and strains of Eubacterium, Clostridium, Streptococcus, and Propionibacterium could hydrolyze the gelatinized amylopectin maize starch, while only Bifidobacterium spp. and Clostridium butyricum could efficiently utilize high-amylose maize starch granules. In fact, C. butyricum and Bifidobacterium spp. had higher specific growth rates in the autoclaved medium containing high-amylose maize starch granules and hydrolyzed 80 and 40% of the amylose, respectively. Starch-degrading enzymes were cell bound on Bifidobacterium and Bacteroides cells and were extracellular for C. butyricum. Active staining for starch-degrading enzymes on SDS-PAGE gels showed that the Bifidobacterium cells produced several starch-degrading enzymes with high relative molecular (M_r) weights (>160,000), medium-sized relative molecular weights (>66,000), and low relative molecular weights (<66,000). It was concluded that Bifidobacterium spp. and C. butyricum degraded and utilized granules of amylomaize starch.     

Purification and characterization of an alpha-glucosidase from germinating millet seeds

An α-glucosidase (α-d-glucoside glucohydrolase, EC 3.2.1.20) was isolated from germinating millet (Panicum miliaceum L.) seeds by a procedure that included ammonium sulfate fractionation, chromatography on CM-cellulofine/Fractogel EMD SO₃, Sephacryl S-200 HR and TSK gel Phenyl-5 PW, and preparative isoelectric focusing. The enzyme was homogenous by SDS-PAGE. The molecular weight of the enzyme was estimated to be 86,000 based on its mobility in SDS-PAGE and 80,000 based on gel filtration with TSKgel super SW 3000, which showed that it was composed of a single unit. The isoelectric point of the enzyme was 8.3. The enzyme readily hydrolyzed maltose, malto-oligosaccharides, and α-1,4-glucan, but hydrolyzed polysaccharides more rapidly than maltose. The K_m value decreased with an increase in the molecular weight of the substrate. The value for maltoheptaose was about 4-fold lower than that for maltose. The enzyme preferably hydrolyzed amylopectin in starch, but also readily hydrolyzed nigerose, which has an α-1,3-glucosidic linkage and exists as an abnormal linkage in the structure of starch. In particular, the enzyme readily hydrolyzed millet starch from germinating seeds that had been degraded to some extent.     

Two forms of α-glucosidase from sugar-beet seeds

Two forms of -glucosidase (EC 3.2.1.20), designated as I and II, have been isolated from sugarbeet (Beta vulgaris L.) seeds by a procedure including fractionation with ammonium sulfate and ethanol, carboxymethyl-cellulose column chromatography, and preparative disc gel electrophoresis. The two enzymes were homogeneous by polyacrylamide disc gel electrophoresis. Their molecular weights were 98,000 (I) and 60,000 (II). -Glucosidase I readily hydrolyzed maltose, isomaltose, kojibiose, maltotriose, panose, amylose, soluble starch, amylopectin and glycogen. -Glucosidase II also hydrolyzed maltose, kojibiose and maltotriose but hydrolyzed the other substrates only very weakly or not at all. -Glucosidase I hydrolyzed soluble starch at a faster rate than maltose. It produced isomaltose and panose as the main -glucosyltransfer products from maltose, whereas maltotriose was the main product of -glucosidase II. -Glucosidase I hydrolyzed amylose liberating -glucose. The neutral-sugar content was calculated to be 2.7% for -glucosidase I and 8.8% for -glucosidase II. The main neutral sugar was mannose in -glucosidase I, and glucose in -glucosidase II.     

Transglucosylation activities of multiple forms of alpha-glucosidase from spinach

Transglucosylation activities of spinach alpha-glucosidase I and IV, which have different substrate specificity for hydrolyzing activity, were investigated. In a maltose mixture, alpha-glucosidase I, which has high activity toward not only maltooligosaccharides but also soluble starch and can hydrolyze isomaltose, produced maltotriose, isomaltose, and panose, and alpha-glucosidase IV, which has high activity toward maltooligosaccharides but faint activity toward soluble starch and isomaltose, produced maltotriose, kojibiose, and 2,4-di-alpha-D-glucosyl-glucose. Transglucosylation to sucrose by alpha-glucosidase I and IV resulted in the production of theanderose and erlose, respectively, showing that spinach alpha-glucosidase I and IV are useful to synthesize the alpha-1,6-glucosylated and alpha-1,2- and 1,4-glucosylated products, respectively.     

Novel alpha-glucosidase from Aspergillus nidulans with strong transglycosylation activity

Aspergillus nidulans possessed an alpha-glucosidase with strong transglycosylation activity. The enzyme, designated alpha-glucosidase B (AgdB), was purified and characterized. AgdB was a heterodimeric protein comprising 74- and 55-kDa subunits and catalyzed hydrolysis of maltose along with formation of isomaltose and panose. Approximately 50% of maltose was converted to isomaltose, panose, and other minor transglycosylation products by AgdB, even at low maltose concentrations. The agdB gene was cloned and sequenced. The gene comprised 3,055 bp, interrupted by three short introns, and encoded a polypeptide of 955 amino acids. The deduced amino acid sequence contained the chemically determined N-terminal and internal amino acid sequences of the 74- and 55-kDa subunits. This implies that AgdB is synthesized as a single polypeptide precursor. AgdB showed low but overall sequence homology to alpha-glucosidases of glycosyl hydrolase family 31. However, AgdB was phylogenetically distinct from any other alpha-glucosidases. We propose here that AgdB is a novel alpha-glucosidase with unusually strong transglycosylation activity.     

Molecular characterization of a dimeric intracellular maltogenic amylase of Bacillus subtilis SUH4-2

An additional amylase besides the typical alpha-amylase was detected in the cytoplasm of Bacillus subtilis SUH4-2, an isolate from Korean soil. The corresponding gene encoded a maltogenic amylase, which hydrolyzed cyclodextrin or starch to maltose and glucose; pullulan to panose; acarbose to glucose and acarviosine-glucose. Maltogenic amylase of B. subtilis SUH4-2 transferred sugar molecules to form various branched oligosaccharides upon the hydrolysis of substrates. The enzyme existed in a monomer-dimer equilibrium with a molar ratio of 3:2 in 50 mM KH(2)PO(4)-NaOH buffer (pH 7.0). The maltogenic amylase is most likely to be associated with carbohydrate metabolism in the cytoplasm, since the nucleotide sequence of the gene was highly homologous to the yvdF gene of B. subtilis 168, which is located in a gene cluster involved in maltose/maltodextrin utilization.     

Biochemical evidence that starch breakdown by Bacteroides thetaiotaomicron involves outer membrane starch-binding sites and periplasmic starch-degrading enzymes.

Bacteroides thetaiotaomicron can utilize amylose, amylopectin, and pullulan as sole sources of carbon and energy. The enzymes that degrade these polysaccharides were found to be primarily cell associated rather than extracellular. Although some activity was detected in extracellular fluid, this appeared to be the result of cell lysis. The cell-associated amylase, amylopectinase, and pullulanase activities partitioned similarly to the periplasmic marker, acid phosphatase, when cells were exposed to a cold-shock treatment. Two other enzymes associated with starch breakdown, alpha-glucosidase and maltase, appeared to be located in the cytoplasm. Intact cells of B. thetaiotaomicron were found to bind 14C-starch. Binding was probably mediated by a protein because it was saturable and was decreased by treatment of cells with proteinase K. Results of competition experiments showed that the starch-binding proteins had a preference for maltodextrins larger than maltohexaose and a low affinity for maltose and maltotriose. Both the degradative enzymes and starch binding were induced by maltose. These findings indicate that starch utilization by B. thetaiotaomicron apparently does not involve secretion of extracellular enzymes. Rather, binding of the starch molecule to the cell surface appears to be a first step to passing the molecule through the outer membrane and into the periplasmic space.     

Bacillus stearothermophilus Neopullulanase Selective Hydrolysis of Amylose to Maltose in the Presence of Amylopectin

The specificity of Bacillus stearothermophilus TRS40 neopullulanase toward amylose and amylopectin was analyzed. Although this neopullulanase completely hydrolyzed amylose to produce maltose as the main product, it scarcely hydrolyzed amylopectin. The molecular mass of amylopectin was decreased by only one order of magnitude, from approximately 10⁸ to 10⁷ Da. Furthermore, this neopullulanase selectively hydrolyzed amylose when starch was used as a substrate. This phenomenon, efficient hydrolysis of amylose but not amylopectin, was also observed with cyclomaltodextrinase from alkaliphilic Bacillus sp. strain A2-5a and maltogenic amylase from Bacillus licheniformis ATCC 27811. These three enzymes hydrolyzed cyclomaltodextrins and amylose much faster than pullulan. Other amylolytic enzymes, such as bacterial saccharifying α-amylase, bacterial liquefying α-amylase, β-amylase, and neopullulanase from Bacillus megaterium, did not exhibit this distinct substrate specificity at all, i.e., the preference of amylose to amylopectin.     

Overexpression, purification, and characterization of a barley alpha-glucosidase secreted by Pichia pastoris

alpha-Glucosidases (EC 3.2.1.20) are recognized as important in starch degradation during cereal seed germination. A barley (Hordeum vulgare) alpha-glucosidase expressed in Pichia pastoris was cultured in flasks; however, the yield was low necessitating the use of multiple batches. Problems arose because of significant variation between batches. We solved these problems by switching to a fermentation system producing a sufficient quantity of a uniform sample. Here we present the expression and purification of a recombinant alpha-glucosidase grown under fermentation conditions. We also present the results of experiments to characterize the thermostability, pH optimum, and substrate specificity of the recombinant enzyme. The optimal pH for the hydrolysis of maltose by recombinant alpha-glucosidase is between 3.5 and 4.5. The thermostability of recombinant alpha-glucosidase was determined at pH 4, where activity is optimal, and at pH 5 and 6, which better mimic the conditions used to convert barley starch to fermentable sugars during industrial processing. The results indicate the enzyme is most thermolabile at pH 4. However, the enzyme is protected from heat inactivation at pH 4 by high concentrations of sucrose. The purified enzyme hydrolyzed maltose three times more rapidly than nigerose and 20 times more rapidly than trehalose and isomaltose. Concentrations of maltose greater than 20 mM inhibited maltose hydrolysis. This is the first report of substrate inhibition for any alpha-glucosidase. The results indicate that the only significant difference between the recombinant enzyme and the previously characterized barley isoforms was the V(max) for maltose hydrolysis.