Production of amylase by Arthrobacter psychrolactophilus

Arthrobacter psychrolactophilus ATCC 700733 grew with a doubling time of 1.5–2.3 h (22°C) and produced up to 0.2 units/mL (soluble starch assay) of extracellular amylase in tryptic soy broth without dextrose (TSBWD) containing 0.5% or 1.0% (w/v) soluble starch or maltose as the fermentable substrate. Time-course experiments in media containing soluble starch as substrate showed that amylolytic activity appeared in cultures at 24 h (after exponential growth had ceased), reached peak levels in 72–96 h, and declined rapidly after reaching peak levels. Peak levels were highest in TSBWD containing 1.0% soluble starch. Proteolytic activity appeared at about the same time as amylolytic activity and increased during the period of amylase production. Significant amylase production was not observed in cultures in TSBWD with 0.5% glucose or in cultures grown at 28°C, but low levels of amylase were observed in TSBWD cultures grown at 19–23°C which contained no added carbohydrate. A single band of activity was observed after electrophoresis of supernatant fractions in non-denaturing gels, followed by in situ staining for amylolytic activity. The amylase possessed a raw starch-binding domain and bound to uncooked corn, wheat or potato starch granules. It was active in the Phadebas assay for -amylase. Activity was maximum on soluble starch at a temperature between 40°C and 50°C. The amylase after purification by affinity chromatography on raw starch granules exhibited two starch-binding protein bands on SDS gels of 105 kDa and 26 kDa.     

Purification and Properties of Extracellular Amylase from the Hyperthermophilic Archaeon Thermococcus profundus DT5432

A hyperthermophilic archaeon, Thermococcus profundus DT5432, produced extracellular thermostable amylases. One of the amylases (amylase S) was purified to homogeneity by ammonium sulfate precipitation, DEAE-Toyopearl chromatography, and gel filtration on Superdex 200HR. The molecular weight of the enzyme was estimated to be 42,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The amylase exhibited maximal activity at pH 5.5 to 6.0 and was stable in the range of pH 5.9 to 9.8. The optimum temperature for the activity was 80(deg)C. Half-life of the enzyme was 3 h at 80(deg)C and 15 min at 90(deg)C. Thermostability of the enzyme was enhanced in the presence of 5 mM Ca(sup2+) or 0.5% soluble starch at temperatures above 80(deg)C. The enzyme activity was inhibited in the presence of 5 mM iodoacetic acid or 1 mM N-bromosuccinimide, suggesting that cysteine and tryptophan residues play an important role in the catalytic action. The amylase hydrolyzed soluble starch, amylose, amylopectin, and glycogen to produce maltose and maltotriose of (alpha)-configuration as the main products. Smaller amounts of larger maltooligosaccharides were also produced with a trace amount of glucose. Pullulan; (alpha)-, (beta)-, and (gamma)-cyclodextrins; maltose; and maltotriose were not hydrolyzed.     

Mechanisms of action of the α-amylase of Micromonospora melanosporea

The -amylase of Micromonospora melanosporea was produced extracellularly during batch fermentation in a 5.0-1 fermentor. The absence of an organic nitrogen source in its growth medium facilitated subsequent purification of the enzyme by ammonium sulphate fractionation and two consecutive Superose-12 gel-filtration steps. The enzyme exhibited maxima for activity at pH 7.0 and 55° C and was 72% stable at pH 6.0–12.0 for 30 min at 40° C. It had a relative molecular mass of 45 000 and an isoelectric point at pH 7.6. The enzyme catalyses the conversion of starch to maltose (53%, w/w) as the predominant final end-product. Initial hydrolysis of this substrate, however, gave rise to the formation of maltooligosaccharides in the range maltotriose to maltohexaose. Maximum yields of these intermediate sugars accumulated to between 31 and 42% (w/w) as the reaction proceeded. The action of the M. melanosporea amylase on high concentrations of saccharides larger than maltotriose resulted in the formation of mainly maltose and maltotriose without concomitant glucose production. A combination of hydrolytic and transfer events is postulated to be responsible for this phenomenon and for the high maltose levels achieved. Correspondence to: C. T. Kelly     

Extracellular enzyme production byThermomonospora curvata grown on bagasse

Summary Extracellular enzyme production by the actinomycete,Thermomonospora curvata, was characterized during growth at 55°C on bagasse as sole carbon source. Mycelia adhered to the bagasse fibers during early growth and were released in mature cultures. Extracellular protein reached a maximum on 4% (w/v) bagasse and yielded an electrophoretic profile similar to those produced on purified cellulose. Cellulase production on bagasse exceeded that observed forT. curvata on any previously employed substrate. Amylase and pectinase, which were diminished by their instability in culture fluid at growth temperature and by the lack of inducing substrate, were readily inducible by addition of starch or pectin, respectively. Extracellular activities of -glucosidase and -xylosidase remained insignificant throughout growth. Xylanase production equaled or exceeded that observed on a variety of other substrates. The combined activity of extracellular enzymes from bagasse-grownT. curvata caused a 27% solubilization of the fiber, yielding a mixture of cellooligosaccharides, cellobiose, xylobiose, glucose, xylose, fructose, arabinose and mannitol. Fractionation of concentrated extracellular proteins by size exclusion chromatography yielded single peaks for amylase and pectinase (estimated molecular weights of 58 K and 34 K respectively), while cellulase and xylanase activities were distributed throughout a series of multiple unresolved peaks spanning a molecular weight range of 26–180 K.     

The high maltose-forming α-amylase ofSaccharomonospora viridis: mechanisms of action

Summary The thermophilic actinomycete,Saccharomonospora viridis produces a thermostable -amylase which forms 63% (w/w) maltose on hydrolysis of starch. Maltotriose and maltotetraose are the only intermediate products observed during this reaction, with maltotriose accumulating to 40% (w/w). Both unimolecular and multimolecular mechanisms (transfers and condensation) have been shown to occur during the concentration-dependent degradation of maltotriose and maltotetraose. Such reactions result in the almost exclusive formation of maltose from maltotriose at high initial concentration. These mechanisms of action result in the production of the high levels of maltose obtained upon hydrolysis of starch and related substrates.     

Starch conversion by amylases fromAureobasidium pullulans

Summary A color variant strain (NRRL Y-12974) ofAureobasidium pullulans produced a saccharifying -amylase and two forms of glucoamylase extracellularly when grown on starch at 28°C for 4 days. A sugar syrup containing DP1 (degree of polymerization) and DP2 (31) was made from maltodextrin DE (dextrose equivalent) 10 (35%, w/w) at 55°C and pH 4.5 using the amylase preparation (40 U g^–1 DS (dry substance). The syrup composition was highly dependent upon substrate concentration but nearly independent of enzyme dose. Glucose syrup containing 93% glucose was made from maltodextrin DE 10 (35%, w/w) at 65°C and pH 4.5 using the same enzyme preparation at 100 U g^–1 DS. The enzyme preparation (100 U g^–1 DS) produced 98–100% glucose from raw corn starch at pH 4.5 and 50°C.The mention of firm names or trade products does not imply that they are endorsed or recommended by the US Department of Agriculture over other firms or similar products not mentioned. Abbreviations: DE, dextrose equivalent (an indication of polymerization; reducing sugars as percentage glucose); DP, degree of polymerization; DP1, glucose; DP2, disaccharide; DP3, trisaccharide; DP4, tetrasaccharide; DS, dry substance.     

The raw starch-degrading alkaline amylase ofBacillus sp IMD 370

The amylase ofBacillus sp IMD 370 is the first report of an alkaline amylase with the ability to digest raw starch. The amylase could degrade raw corn and rice starches more effectively than raw potato starch. It showed no adsorb-ability to any type of raw starch at any pH value tested. The enzyme digested raw corn starch to glucose, maltose, maltotriose and maltotetraose. The maximum pH for raw starch hydrolysis was pH 8.0 compared to pH 10.0 for soluble starch hydrolysis. The metal chelator, ethylenediaminetetraacetic acid, strongly inhibited raw starch-digestion and its effect was reversed by the addition of divalent cations. Degradation of raw starch was stimulated six-fold in the presence of -cyclodextrin (17.5 mM).     

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

The -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 ionexchange chromatography. The enzyme exhibited maxima for activity at pH 6.0 and 65°C, had a relative molecular mass of 60900–62000 and an isoelecric 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 (K _m=7.7 × 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. Correspondence to: C. T. Kelly     

Purification and Some Properties of an Extracellular Amylase from a Moderate Halophile, Micrococcus halobius

A moderate halophile, Micrococcus halobius ATCC 21727, produced an extracellular dextrinogenic amylase when cultivated in media containing 1 to 3 M NaCl. The amylase was purified from the culture filtrate to an electrophoretically homogenous state by glycogen-complex formation, diethylaminoethyl-cellulose chromatography, and Bio-Gel P-200 gel filtration. The enzyme had maximal activity at pH 6 to 7 in 0.25 M NaCl or 0.75 M KCl at 50 to 55°C. The activity was lost by dialysis against distilled water. Molecular weight was estimated to be 89,000 by sodium dodecyl sulfate-gel electrophoresis. The action pattern on amylose, soluble starch, and glycogen showed that the products were maltose, maltotriose, and maltotetraose, with lesser amount of glucose.     

Production, purification and characterization of an α-amylase produced by Saccharomycopsis fibuligera

Saccharomycopsis fibuligera ST 2 produced high levels of extracellular amylase during the stationary phase of growth. Glucose or other low molecular weight metabolizable sugars did not repress the synthesis of the amylase, indicating the lack of catabolite repression in this organism. Of the nitrogen sources examined, yeast extract and corn steep liquor stimulated the highest yield of amylase. Ammonium sulphate inhibited α-amylase synthesis. The enzyme was purified 118-fold from the culture supernatant fluid by isopropanol precipitation and DEAE-Sephadex A50 chromatography. The purified enzyme was characterized as an α-amylase. The α-amylase had the following properties: molecular weight, 40900 ± 500; optimum temperature, 60°C; activation energy, 1600 cal/mol; optimum pH, 4·8–6·0; range of pH stability, pH 4·0–9·4; K_m (50°C, pH 5·5) for soluble starch, 0·572 mg/ml; final products of starch hydrolysis—glucose, maltose, maltotriose and maltotetraose.     

Molecular cloning and expression of an extracellular α-amylase gene from an Antarctic deep sea psychrotolerant <Emphasis Type="Italic">Pseudomonas stutzeri</Emphasis> strain 7193

Psychrotolerant Pseudomonas stutzeri strain 7193 capable of producing an extracellular α-amylase was isolated from deep sea sediments of Prydz Bay, Antarctic. The 59678-Da protein (AmyP) was encoded by 1665-bp gene (amyP). The deduced amino acid sequence was identified with four regions, which are conserved in amylolytic enzymes and form a catalytic domain, and was predicted to be maltotetraose forming extracellular amylase by using the I-TASSER online server. Purification of AmyP amylases from both the recombinant of Escherichia coli Top 10 F′ and strain 7193 was conducted. Biochemical characterization revealed that the optimal amylase activity was observed at pH 9.0 and temperature 40°C. The enzymes were unstable at temperatures above 30°C, and only retain half of their highest activity after incubation at 60°C for 5 min. Thin-layer chromatography analysis of the products of the amylolytic reaction showed the presence of maltotetraose, maltotriose, maltose and glucose in the starch hydrolysate.     

Induction of α-amylase by maltooligosaccharides in Thermomonospora curvata

The action pattern of the α-amylase produced by Thermomonospora curvata is unique. Maltooligosaccharides (maltose to maltopentaose) were tested individually for their ability to induce α-amylase in this thermophilic actinomycete. Maltotetraose was the most inductive followed by maltotriose. Maltose was a good inducer of amylase production when used as sole carbon source, but had relatively little inductive capacity in the presence of either glucose or cellobiose. When cellobiose was added during exponential growth on maltose, maltose utilization and extracellular α-amylase accumulation were transiently inhibited. With maltotriose as the initial carbon source, addition of cellobiose did not inhibit the utilization of the trisaccharide; however, cellobiose, whether added during exponential growth or stationary phase, resulted in the rapid degradation of amylase when maltotriose was depleted from the medium. This inactivation did not appear to be a growth phase-induced phenomenon because stationary phase cells in the absence of cellobiose maintained their peak extracellular amylase level. This cellobiose-mediated α-amylase inactivation would be particularly important during production of the enzyme on a complex lignocellulosic substrate.     

Production of an amylase-degrading raw starch by Gibberella pulicaris

An endophytic fungus, Gibberella pulicaris, produced an amylase which degraded raw starches from cereals and other crops including raw potato, sago, tapioca, corn, wheat and rice starch. In each case, glucose was the main product. Among the raw starches used, raw potato starch gave the highest enzyme activity (85 units mg^–1 protein) and raw wheat starch the lowest (49 units mg^–1 protein). The highest amylase production (260 units mg^–1 protein) was achieved when the concentration of raw potato starch was increased to 60 g l^–1. Optimum hydrolysis was at 40°C and pH 5.5.     

Bacterial diversity in thermophilic aerobic sewage sludge

Summary Using -amylase as an example, extremely thermophilic Bacilli isolated from heat-treated sewage sludge are shown to be a source for enzymes stable and active at high temperatures. The isolates which are classified as subspecies of Bacillus stearothermophilus differ from each other in protein composition indicating the heterogeneiety of that subspecies. Media are evaluated for good growth and high enzyme productivity. Best media are those composed of three or four different complex components like combinations of peptone, soy grist, and malt extract, -amylase production on simple carbon sources is negligible. From the cultivation supernatants crude -amylase extracts are prepared and their behaviour at high temperatures is described. The optimal temperature of all tested enzymes is 80°C. They are stable at suboptimal temperatures for over 20 h and at 95° C 50% of their activity is lost within 2 h. The activity at 95° C is however preserved for over 3 h in presence of starch. The products of the starch digestion are maltotriose, maltose, and some glucose. The amylases can therefore compete in activity and stability with commercially available -amylases from Bacillus licheniformis.     

A constitutive maltotetraose-producing amylase fromPseudomonas sp. IMD 353

Pseudomonas sp. IMD 353, secretes an extracellular maltotetraose-producing amylase. One of the most outstanding features of this enzyme is that it is produced constitutively (29 units/ml), using glucose (3%, w/v) as the carbon source. The amylase was purified to homogeneity and its enzymic properties examined. It had maxima for activity at pH 7.0 and 50°C, a relative molecular mass of 63,000 and an isoelectric point at pH 5.0. Specific amylase inhibitors, tendamistat and -amylase wheat inhibitor, activated the enzyme. Starch was hydrolysed from the non-reducing chain ends, by an endo-acting mechanism, producing maltotetraose in the -anomeric form. Yields of 65% (w/v), and 62% (w/v) were obtained on hydrolysis of starch (1%, w/v) and dextrin (15%, w/v), respectively. This enzyme failed to hydrolyse mmaltotetraose, even on prolonged incubation.     

Production and stabilization of amylase preparations from rice bran solid medium

A low-cost amylase preparation of dried fermented bran was developed from rice bran solid cultures of Aspergillus oryzae supplemented with soya bean flour (SBF) and cassava starch (3:1) and dried at 50 °C for 4 h. Storage stability of preparations at 4 °C or 30 °C was significantly enhanced (P 0.05) by adding SBF or partially hydrolyzed starch (PHS). While amylase preparations without stabilizer retained 59 and 48% of their activity after 12 weeks storage at 4 and 30 °C respectively, the same preparations fortified with SBF (5% w/v) retained 95 and 94% stability respectively, during the same period. PHS at 5% (w/v) also gave a maximum stability of 94 and 91.8% at 4 and 30 °C, respectively. The unstabilized preparation retained only 42% of its activity compared to the stabilized forms, which retained 82–90% activity after 15 min incubation at 100 °C.     

Characterization of d-Enzyme (4-alpha-Glucanotransferase) in Arabidopsis Leaf

Two major forms of d-enzyme (4-α-glucanotransferase, EC 2.4.1.25) were successfully separated from most of the amylase activity using FPLC-Mono Q column chromatography. Transfer of a maltosyl group was observed upon the incubation of d-enzyme with maltotriose and d-[U-¹⁴ C]glucose. About 4.5% of the radioactivity was transferred to maltotriose in 2 hours. End product analysis showed the accumulation of glucose and maltopentaose from maltotriose within the first 10 minutes of the reaction. Several other maltodextrins were also observed with longer incubation times, although maltose was never produced. A quantitative measurement of maltodextrin production from the reaction of [¹⁴ C]maltotriose with d-enzyme showed that the quantity of maltotriose decreased from 100% to 31% after 3 hours incubation, while glucose, maltotetraose, maltopentaose, maltohexaose, maltoheptaose, maltooctaose, and higher maltodextrins increased in amount. Glucose is the major product throughout the course of the reaction of d-enzyme with maltotriose. Maltotriose, in addition to glucose, are the major products in the reaction of d-enzyme with maltodextrins with a chain length greater than maltotriose. This study confirms the existence of a transglycosylase that disproportionates maltotriose and higher maltodextrins by transferring maltosyl or maltodextrinyl groups between maltodextrins resulting in the production of glucose and different maltodextrins, but not maltose, in leaf tissue with enzymic properties very similar to the previously reported d-enzyme in potato.     

Thermostable liquefying α-amylase fromBacillus amyloliquefaciens

Summary An extracellular -amylase is purified to homogeneity with 62 % recovery of the enzyme activity using heat treatment, ion-exchange and gel filtration chromatographies. The purified enzyme has a molecular weight of 68, 000, isoelectric point 6.25, optimal activity at pH 6 and temperature 65 °C, k_est 8.8×10⁸ s¹ liquefying amylase units, and K_m for starch 2.9 mg ml^–1. The enzyme is further characterized for its endo action on the starch and related polymers. Calcium stabilizes the active conformation of the enzyme during prolonged exposure to the extremes of pH and temperature. The enzyme retains 100 % activity for 24 h at 65°C and exhibits a half-life of 9, 3, and 0.5 h at 80°, 85° and 90°C, respectively.     

Purification and characterization of thermostable β-amylase and pullulanase from high-yielding Clostridium thermosulfurogenes SV2

Thermostable -amylase and pullulanase, secreted by the thermophilic anaerobic bacterium Clostridium thermosulfurogenes strain SV2, were purified by salting out with ammonium sulphate, DEAE-cellulose column chromatography, and gel filtration using Sephadex G-200. Maltose was identified as a major hydrolysis product of starch by -amylase, and maltotriose was identified as a major hydrolysis product of pullulan by pullulanase. The molecular masses of native -amylase and pullulanase were determined to be 180 and 100 kDa by gel filtration, and 210 and 80 kDa by SDS–PAGE, respectively. The temperature optima of purified -amylase and pullulanase were 70 and 75°C, respectively, and both enzymes were completely stable at 70°C for 2h. The presence of starch further increased the stability of both the enzymes to 80°C and both displayed a pH activity optimum of 6.0. The starch hydrolysis products formed by -amylase action had -anomeric form.     

Extracellular amylolytic system of the yeast Lipomyces kononenkoae

Summary A strain of the yeast Lipomyces kononenkoae which converted starch into SCP with a high yield, produced three extracellular amylases which were purified from the culture fluid by Ficoll concentration, dialysis, isopropanol precipitation and DE-cellulose chromatography: an -amylase, a glucoamylase and a debranching transferase. The latter transferred -1,6-glucosyl units from panose to glucose forming maltose and appeared to have some debranching activity on amylopectin. The -amylase had the following properties: MW 38000 daltons; no effect of added calcium ions on activity; optimum temperature and pH for activity around 40°C and pH 5.5; H and S of heat inactivation 24360 cal mol^–1 and 29.2 cal deg^–1 mol^–1; range of pH stability pH 4–6.5; pI=7.1; final low molecular weight products of starch hydrolysis, maltose and glucose; K_m (40°C, pH 5.5) for starch 2.7 gl^–1, for maltotriose 109 gl^–1; uncompetitive inhibition by maltose with K_i (40°C, pH 5.5) 29.5 gl^–1. The glucoamylase had the following properties: MW 81500 daltons; optimum temperature and pH for activity around 50°C and pH 4.5: H and S of heat inactivation 20400 cal mol^–1 and 17.7 cal deg^–1 mol^–1; range of pH stability pH 4–6.5; pI=6.1; K_m (30°C, pH 4.5) for soluble starch 16.2 gl^–1, for maltose 0.36 gl^–1, for p-nitrophenyl--D-glucoside 0.35 gl^–1; competitive inhibition by glucose with K_i (30°C, pH 4.5) 4.7 gl^–1.