Separation of starch oligosaccharides by high temperature paper chromatography

Elucidation of the subsite structure of bacterial saccharifying alpha-amylase and its mode of degradation of maltose

The subsite structure of bacterial saccharifying alpha-amylase (BSAm) was elucidated by two methods using a series of maltooligosaccharides labeled with [14C]D-glucose at the reducing end. The rate parameter k0/Km and the cleavage frequency were obtained using the labeled substrates at sufficiently low concentrations to eliminate transglycosylation and condensation. This evaluation showed that the active center is composed of five subsites, with the catalytic site located between the 3rd and the 4th subsites from the nonreducing end. The evaluated affinity values of a subsite varied with the set of data used, which suggests some stimulation factor resulting from the chain length effect. The appearance of a time lag during the digestion of the poor substrate, maltose, was studied using radioactively labeled maltose (81.6 mM). Radioactive oligosaccharides larger than maltose were found at a significant level of more than 2% of the initial substrate in the digests, including a product peculiar to condensation, G-G*-G, as 8-10% of the maltotriose in the digests. This indicates that transglycosylation is a main side reaction (ca. 90%). A degradation pathway for maltose via maltosyl transfer was proposed, in which G3 behaves as a kind of catalyst.

The high maltose-producing alpha-amylase of the thermophilic actinomycete, Thermomonospora curvata

The alpha-amylase of Thermomonospora curvata catalyses the formation of very high levels of maltose from starch (73%, w/w) without the attendant production of glucose. The enzyme was produced extracellularly in high yield during batch fermentation in a 5-1 fermentor. Purification was achieved by ammonium sulphate fractionation, Superose-12 gel filtration and DEAE-Sephacel ion-exchange chromatography. The enzyme exhibited maxima for activity at pH 6.0 and 65 degrees C, had a relative molecular mass of 60,900-62,000 and an isoelectric point at 6.2. The exceptionally high levels of maltose produced and the unique action pattern exhibited on starch and related substrates indicate a very unusual maltogenic system. The predominance of maltose as the final end-product may be explained by the participation of reactions other than simple hydrolysis and the preferential cleavage of maltotriose from higher maltooligosaccharides. The enzyme exhibits very low affinity for maltotriose (Km = 7.7 x 10(-3) M) and its conversion to maltose is achieved by synthetic followed by hydrolytic events, which result in the very high levels of maltose observed and preclude glucose formation. This system is distinguished from other very high maltose-producing amylases by virtue of its high temperature maximum, very low affinity for maltotriose and the absence of glucose in the final saccharide mixture.

The mechanism of acceptor reactions of Leuconostoc mesenteroides B-512F dextransucrase

Reactions of dextransucrase and sucrose in the presence of sugars (acceptors) of low molecular weight have been observed to give a dextran of low molecular weight and a series of oligosaccharides. The acceptor reaction of dextransucrase was examined in the absence and presence of sucrose by using D-[14C]glucose, D-[14C]fructose, and 14C-reducing-end labeled maltose as acceptors. A purified dextransucrase was preincubated with sucrose, and the resulting D-fructose and unreacted sucrose were removed from the enzyme by chromatography of columns of Bio-Gel P-6. The enzyme, which migrated at the void volume was collected and referred to as "charged enzyme". The charged enzyme was incubated with 14C-acceptor in the absence of sucrose. Each of the three acceptors gave two fractions of labeled products, a high molecular weight product, identified as dextran, and a product of low molecular weight that was an oligosaccharide. It was found that all three of the acceptors were incorporated into the products at the reducing end. Similar results were obtained when the reactions were performed in the presence of sucrose, but higher yields of labeled products were obtained and a series of homologous oligosaccharides was produced when D-glucose or maltose was the acceptor. We propose that the acceptor reaction proceeds by nucleophilic displacement of glucosyl and dextranosyl groups from a covalent enzyme-complex by a specific, acceptor hydroxyl group, and that this reaction effects a glycosidic linkage between the D-glucosyl and dextranosyl groups and the acceptor. We conclude that the acceptor reactions serve to terminate polymerization of dextran by displacing the growing dextran chain from the active site of the enzyme; the acceptors, thus, do not initiate dextran polymerization by acting as primers.

Purification, characterization, and action-pattern studies on the endo-(1 linked to 3)-beta-D-glucanase from Rhizopus arrhizus QM 1032

The extracellular (1 linked to 3)-beta-D-glucanase [(1 linked to 3)-beta-D-glucan glucanohydrolase, EC 3.2.1.6] produced by Rhizopus arrhizus QU 1032 was purified 305-fold in 70% overall yield. This preparation was found to be homogeneous by ultracentrifugation (sedimentation velocity and equilibrium studies), electrophoresis on acrylamide gel with normal, sodium dodecyl sulfate, and urea-acetic acid gels, and upon isoelectric focusing. The amino acid composition of the enzyme has been determined and it possesses a carbohydrate moiety compose of mannose and galactose (in the ratio approximately 5:1) that is linked to the protein through a 2-acetamido-2-deoxyglucose residue. The molecular weight, as determined by equilibrium sedimentation, is 28,800 and this number was confirmed by electrophoresis on gels of sodium dodecyl sulfate. The enzyme does not possess subunit structure. It hydrolyzes its substrates with retention of configuration and possesses transglycosylating ability. The rates of hydrolysis of a wide variety of substrates were determined, and its action pattern on a series of oligosaccharides containing mixed (1 linked to 3)-, (1 linked to 4)-, and (1 linked to 6)-beta-D-glucopyranosyl residues was investigated. The enzyme favors stretches of beta-D-(1 linked to 3) linkages, but it can hydrolyze beta-D-(1 linked to 4) linkages that are flanked on the non-reducing side with stretches of beta-D-(1 linked to 3) links. The enzyme will not act on (1 linked to 6)-beta-D-glucosyl linkages located in stretches of beta-D-(1 linked to 3) and will not act on (1 linked to 3) beta-D-glycosidic linkages involving sugars other than D-glucose.

Purification and some properties of an extracellular alpha-amylase from Bacteroides amylophilus

A medium was developed to obtain maximum yields of extracellular amylase from Bacteroides amylophilus 70. Crude enzyme preparation, obtained by ammonium sulfate precipitation of cell-free broth, contained six amylolytic isoenzymes that were detected by isoelectric focusing and polyacrylamide gel electrophoresis. One of these amylases was purified by diethylaminoethyl-Sephadex A-50 ion-exchange chromatography and Sephadex G-200 gel filtration techniques. Some properties of the purified extracellular alpha-amylase were: optimum pH, 6.3; optimum temperature, 43 degrees C: PH stability range, 5.8 to 7.5; isoelectric point, pH 4.6; molecular weight, 92,000 (by sodium dodecyl sulfatedisc gel electrophoresis); and sugars causing inhibition, cyclomaltoheptaose, cyclomaltohexaose, and alpha-d-phenylglucoside. In addition, Ca2+ and Co2+ were strong activators,and Hg2+ was a strong inhibitior; all other cations were slightly stimulatory. Dialysis against 0.01 M ethylenediaminetetraacetic acid caused a 58% loss of activity that was restored to 92% of the original by the addition of 0.04 M Ca2+. The enzyme affected a blue-value-reducing-value curve characteristic of alpha-type amylases. The relative rates of hydrolysis of amylose, soluble starch, amylopectin, and dextrin were 100, 97, 92, and 60%, respectively; Michaelis constants for these substrates were 18.2, 18.7, 18.2, and 16.7 mumol of d-glucosidic bond/liter, respectively. The enzyme degraded maize (corn) starch granules to some extent and had relatively little activity on potato starch granules.

Amylolytic isoenzymes of Thermoactinomyces vulgaris

Thermoactinomyces vulgaris strain 5 produced two electrophoretically different alpha-amylases. Precipitation with ammonium sulfate and acetone did not alter the electrophoretic mobilities of either amylase isoenzyme. Patterns of the hydrolysis products of amylose by the two amylase isoenzymes were essentially identical.

Extracellular transglucosylase and alpha-amylase of Streptococcus equinus

Culture filtrates of Streptococcus equinus 1091 contained alpha-amylase and transglucosylase. The effects of calcium carbonate, age of inoculum, concentration of maltose, and duration of the fermentation on alpha-amylase and transglucosylase production were determined. The extracellular alpha-amylase was purified 48-fold and was free of transglucosylase activity. The alpha-amylase (amylose substrate) required Cl(-) for maximum activity; ethylenediaminetetraacetic acid (EDTA) partially inhibited activity, but CaCl(2) prevented EDTA inhibition. The temperature optimum was 38 C at pH 7.0, and the pH optimum was 7.0 at 37 C in the presence of CaCl(2). Predominant final products of amylose hydrolysis, in order of decreasing prevalence, were maltose, maltotriose, maltotetraose, and glucose. The alpha-amylase showed no evidence of multiple attack. The extracellular transglucosylase was purified 27-fold, but a small amount of alpha-amylase remained. Transglucosylase activity (amylose substrate) was not increased in the presence of CaCl(2). The temperature optimum was 37 C at pH 6.5, and the pH optimum was 6.0 at 37 C. Carbohydrates that served as acceptors for the transglucosylase to degrade amylose were, in order of decreasing acceptor efficiency: d-glucose, d-mannose, l-sorbose, maltose, sucrose, and trehalose. The extracellular transglucosylase of S. equinus 1091 synthesized higher maltodextrins in the medium when the cells were grown in the presence of maltose.

Properties of the amylase from Halobacterium halobium

Halobacterium halobium amylase had optimal activity at pH 6.4 to 6.6 in sodium beta-glycerophosphate buffer containing 0.05% NaCl at 55 C; Ca(2+) was not required. End products from amylose were maltose, maltotriose, and glucose. The amylase, which was devoid of transglucosylase activity, had a multichain attack mechanism.