Studies on the Amylolytic System of the Black-koji Molds

Saccharogenic and dextrinogenic amylase fractions were prepared from Black-koji amylase system and their actions investigated with a number of different substrates.

It was found that saccharogenic amylase fraction completely hydrolyzes glutinous rice starch and glycogen to glucose, without leaving any limit dextrin. On the other hand, this enzyme fraction converts potato starch to an extent of about 90% theoretical glucose, the remainder being left as limit dextrin, which is colored purple by iodine. The complete hydrolysis of the branched substrates except potato starch shows that the saccharogenic amylase fraction is capable of hydrolyzing the l,6-α-d-glucosidic linkage besides the 1,4-linkage, while the branched fraction of potato starch may contain some sort of anomaly to the enzyme. Dextrinogenic amylase fraction hydrolyzes starch and glycogen just as malt α-amylase.     

Studies on the Amylolytic System of the Black-koji Molds

The amylase system of black-koji molds was fractionated, in respect to its activity, into two fractions, the dextrinogenic and saccharogenic. Their separate and combined activities to digest raw starch were investigated. Contrary to the knowledge established so far, the dextrinogenic amylase fraction was found to be capable of digesting the raw starch though only weakly, while the saccharogenic amylase fraction much more strongly. When the two fractions were combined, digestion proceeded with twice or thrice the velocity of the, sum of each component. This accelerating interaction, which never occurs in cooked-starch digestion, is worthy to be stressed as a characteristic of raw starch digestion by this amylase system. The raw starches of corn, wheat and glutinous rice are in this way, digested completely to glucose. Among them, glutinous rice starch displays peculiar facility in the digestion.     

The Composition of Saccharogenic Amylase from Rhizopus javanicus and the Isolation of Glycopeptides

Saccharogenic amylase from Rhizopus javanicus sp. 3–46 was known to be a glycoprotein which contained 27 residues of mannose and 4 residues of N-acetylglucosamine per mole of the saccharogenic amylase. Attempts have been made to obtain glycopeptides from the saccharogenic amylase. Three glycopeptides, GP-I-a, GP-I-b and GP-II, were separated from a Pronase digest of heat-denatured saccharogenic amylase by gel filtration on Sephadex G-50 and chromatography on DEAE-Sephadex A-25. GP-I-a contained asparagine, glycine, mannose and N-acetylglucosamine in a molar ratio of 1: 1: 6: 2. GP-I-b contained asparagine, threonine, mannose and N-acetylglucosamine in a molar ratio of 1: 1: 9:2. GP-II consisted of threonine, serine, proline, alanine and mannose in a molar ratio of 6: 2: 2: 2: 12.     

Production of saccharogenic and dextrinogenic amylases by Rhizomucor pusillus A 13.36

A newly-isolated thermophilic strain of the zygomycete fungus Rhizomucor pusillus 13.36 produced highly active dextrinogenic and saccharogenic enzymes. Cassava pulp was a good alternative substrate for amylase production. Dextrinogenic and saccharogenic amylases exhibited optimum activities at a pH of 4.0-4.5 and 5.0 respectively and at a temperature of 75 degrees C. The enzymes were highly thermostable, with no detectable loss of saccharogenic or dextrinogenic activity after 1 h and 6 h at 60 degrees C, respectively. The saccharogenic activity was inhibited by Ca(2+) while the dextrinogenic was indifferent to this ion. Both activities were inhibited by Fe(2+) and Cu(2+) Hydrolysis of soluble starch by the crude enzyme yielded 66% glucose, 19.5% maltose, 7.7% maltotriose and 6.6% oligosaccharides.     

Starch debranching enzyme (R-enzyme or pullulanase) from developing rice endosperm: purification, cDNA and chromosomal localization of the gene

Starch debranching enzyme (R-enzyme or pullulanase) was purified to homogeneity from developing endosperm of rice (Oryza sativa L. cv. Fujihikari) using a variety of high-performance liquid chromatography columns, and characterized. A cDNA clone encoding the full length of the rice endosperm debranching enzyme was isolated and its nucleotide sequence was determined. The cDNA contains an open reading frame of 2958 bp. The mature debranching enzyme of rice appears to be composed of 912 amino acids with a predicted relative molecular mass (M_r) of 102069 Da, similar in size to its M_r of about 100 000 Da estimated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The amino acid sequence of rice debranching enzyme is substantially similar to that of bacterial pullulanase, while it bears little similarity to that of bacterial isoamylase or to glycogen debranching enzymes from human muscle and rabbit muscle. Southern blot analyses strongly suggest that the debranching enzyme gene is present as a single copy in the rice genome. Analysis by restriction fragment length polymorphism with a probe including the 3′-untranslated region of cDNA for rice debranching enzyme confirmed that the debranching enzyme gene is located on chromosome 4.     

Structural Analysis of Sydowic Acid by X-ray Diffraction

Streptomyces sp. No. 280 produced several kinds of amylase inhibitors (amylase inhibitor A, B, B' and C). Two amylase inhibitors (designated as AI-A₁ and AI-A₂) were obtained from an amylase inhibitor A fraction by paper chromatography. AI-A₁ inhibited muscle phosphorylase a much more than AI-A₂ and was hydrolyzed by sweet potato β-amylase whereas AI-A₂ was not. Both amylase inhibitors had a carbohydrate and were hydrolyzed by some kinds of amylases or acids. They lost their inhibitory activity against phosphorylase a after treatment with acids or hog pancreatic α-amylase, but they showed increased inhibitory activity toward porcine small intestinal sucrase.

Both AI-A₁ and AI-A₂ were composed of glucose and a basic moiety which gave a positive ninhydrin reaction. The molecular weights of AI-A₁ and AI-A₂ were estimated to be approximately 1300 ? 1500 by gel filtration on a Sephadex G-15 column. The nitrogen content of the amylase inhibitors was found to be about 1.3% by elementary analysis     

An improved assay method for amylase activity using an amylodextrin fraction as substrate

A rapid and simple method for determination of amylase activity, by using a fraction of an amylo-oligosaccharide (amylodextrin, 1) as substrate, is described. The sample solution is incubated with a solution of 1 and the substrate consumed is estimated by measuring the difference in absorbance at 460 nm. The K_m value of 1 is about half that of starch. The homogeneity of 1 in its chemical structure and molecular weight facilitated the specification of amylase units according to the international definition. This procedure was applied for assay of human-serum amylase with excellent reproducibility. This method did not require a large dilution factor, as the standard curve showed a linear relationship over a wide range of amylase concentrations.     

Subcellular localization of the starch degradative and biosynthetic enzymes of spinach leaves

The subcellular localization of the starch biosynthetic and degradative enzymes of spinach leaves was carried out by measuring the distribution of the enzymes in a crude chloroplast pellet and soluble protein fraction, and by the separation on sucrose density gradients of intact organelles, chloroplasts, peroxisomes, and mitochondria of a protoplast lysate. ADP-Glucose pyrophosphorylase, starch synthase, and starch-branching enzymes are quantitatively associated with the chloroplasts. The starch degradative enzymes amylase, R-enzyme (debranching activity), phosphorylase, and D-enzyme (transglycosylase) are observed both in the chloroplast and soluble protein fractions, the bulk of the degradative enzyme activities reside in the latter fraction. Chromatography of a chloroplast extract on diethylaminoethyl-cellulose resolves the R- and D-enzymes from amylase and phosphorylase activities although the two latter enzyme activities coeluted. The digestion pattern of amylase with amylopectin as a substrate indicates an endolytic activity but displays properties unlike the typical α-amylase as isolated from endosperm tissue.     

Glycosylated salivary α-amylases are capable of maltotriose hydrolysis and glucose formation

The physiological and/or clinical significance of sugar chains in human salivary αamylase was investigated in terms of substrate-specificity for synthesized malto-oligosaccharides. Glycosylated and non-glycosylated α-amylases were prepared on a Sephacryl S-200 column, in which the amylases were separated into four fractions from the different affinities for Sephacryl: fraction I, amylases bearing sugar chains with sialic acid; fraction II, amylases bearing sugar chains without sialic acid; fractions III and IV, non-glycosylated amylases. These were classified according to the differences in their affinities for lectins, molecular sizes and isoelectric points. The inhibitory effect of maltotriose (G₃) on starch hydrolysis of the amylase fraction, suggests that starch and G₃ can be the substrate for glycosylated amylase, and that the glycosylated amylases are capable of G₃ hydrolysis for conversion into maltose and glucose. Using malto-oligosaccharides, G₃, G₄, G₅ and G₇, as substrates, the substrate-specificities and G₃/G₅ ratio of amylase activities in the four fractions were examined. Maltopentaose, G₅, is routinely used as a substrate for α-amylase, and then we assumed that both glycosylated and non-glycosylated amylases react with G₅. Moreover, the results indicate that the glycosylated amylases clearly had a higher capacity for G₃ hydrolysis than the non-glycosylated amylases, although no substrate preference of either type of amylase was observed among G₄, G₅ and G₇. Glycosylated amylases have the capacity for glucose formation from malto-oligosaccharides.     

Dual production of amylase and δ-endotoxin by Bacillus thuringiensis subsp. kurstaki during biphasic fermentation

This study examined the efficacy of a Bacillus thuringiensis (Bt) strain in producing amylase (EC 3.2.1.1) as a by-product without affecting its unique ability for producing δ-endotoxin, thus to establish a cultivation strategy for the dual production and recovery of both δ-endotoxin and amylase from the fermented medium with an industrial perspective. LB medium was individually supplemented (5 to 100%, wt/vol) with flour from six naturally available starchy stored foods (banana, Bengal gram, jack seed, potato, taro or tapioca); after initial fermentation (12 h), the supernatant in the medium obtained by centrifugation (1000 g, 10 min) was used for harvesting amylase and the resultant pellet was further incubated aseptically for the production of endospores and δ-endotoxin by solid-state fermentation. Maximum crude amylase activity (867 U/gram dry substrate, 12 h) was observed in potato flour-supplemented medium (10% wt/vol, 12 h), while the activity in LB control was only 4.36 U/mL. SDS-PAGE profile of the crude (supernatant), as well as partially purified (40–60% (NH₄)₂SO₄ fractionation) amylase showed that its apparent molecular mass was 51 kDa, which was further confirmed by native PAGE. The harvest of industrially significant extracellular amylase (probably α-amylase) produced as a byproduct during early growth phase would boost the economics of the Bt-based bio-industry engaged in δ-endotoxin production.     

Characteristics of the amylase of Arthrobacter psychrolactophilus

Properties of the extracellular amylase produced by the psychrotrophic bacterium, Arthrobacter psychrolactophilus, were determined for crude preparations and purified enzyme. The hydrolysis of soluble starch by concentrated crude preparations was found to be a nonlinear function of time at 30 and 40 °C. Concentrates of supernatant fractions incubated without substrate exhibited poor stability at 30, 40, or 50 °C, with 87% inactivation after 21 h at 30 °C, 45% inactivation after 40 min at 40 °C and 90% inactivation after 10 min at 50 °C. Proteases known to be present in crude preparations had a temperature optimum of 50 °C, but accounted for a small fraction of thermal instability. Inactivation at 30, 40, or 50 °C was not slowed by adding 20 mg/ml bovine serum albumin or protease inhibitor cocktail to the preparations or the assays to protect against proteases. Purified amylase preparations were almost as thermally sensitive in the absence of substrate as crude preparations. The temperature optimum of the amylase in short incubations with Sigma Infinity Amylase Reagent was about 50 °C, and the amylase required Ca⁺² for activity. The optimal pH for activity was 5.0–9.0 on soluble starch (30 °C), and the amylase exhibited a K _m with 4-nitrophenyl-α-D-maltoheptaoside-4,6-O-ethylidene of 120 μM at 22 °C. The amylase in crude concentrates initially hydrolyzed raw starch at 30 °C at about the same rate as an equal number of units of barley α-amylase, but lost most of its activity after only a few hours.     

Effects of drought on primary photosynthetic processes of cotton leaves

The localization of enzymes involved in the flow of carbon into and out of starch was determined in guard cells of Commelina communis. The guard cell chloroplasts were separated from the rest of the cellular components by a modification of published microfuge methods. The enzymes of interest were then assayed in the supernatant and chloroplast fractions. The chloroplast yield averaged 75% with 10% cytoplasmic contamination. The enzymes involved in starch biosynthesis, ADPglucose pyrophosphorylase, starch synthase, and branching enzyme, are located exclusively in the chloroplast fraction. The enzymes involved in starch degradation show a more complex distribution. Phosphorylase is located in both the supernatant and chloroplast fraction, 50% in each fraction. Most of the amylase and debranching enzyme activity is present in the supernatant (70%) fraction. The majority of the rest of the enzymes involved in the degradation of starch to malate and synthesis of starch from a hexose precursor were also investigated. All of the enzymes were present in the chloroplast except for hexokinase and phosphofructokinase. The inability to assay these enzymes could possibly have been due to the lack of or low activity of the enzymes or to nonoptimal assay conditions.     

Separation and partial purification of extracellular amylase and protease from Bacillus caldolyticus

Summary The extracellular amylase and protease from Bacillus caldolyticus can be concentrated by ammonium sulfate precipitation after growth on either solid or in liquid media containing starch, glucose, and brain-heart infusion. Using the Diaflo ultrafiltration system with membranes of various permeability, the enzymes could be separated from each other by extensive flushing with buffer. Best results were obtained with the 50–70% ammonium sulfate fraction as starting material, yielding 72% of the total amylase activity in the low molecular weight fraction (UM-10 fraction: 10000–30000), while 54 and 25% respectively of the protease were retained in the two high molecular weight fractions (50000–100000, and more than 100000). Similar results were obtained with the 20–50% ammonium sulfate fraction, while the fraction of 0–20% saturation contained a low molecular weight protease. The native amylase seems to consist of a number of sub-units, which after extensive flushing accumulate in the fraction with an approximate molecular weight between 10000 and 30000. The enzyme could also be precipitated from cell-free liquid media with ammonium sulfate, followed by separation and purification on ultra-filtration cells. According to the specific activity of the UM-10 fractions a 400-fold purification was obtained compared to the amylase activity of the cell-free medium.Direct concentration and separation from liquid media, omitting ammonium sulfate treatment, was also found to be possible, although prolonged flushing with buffer was necessary to obtain satisfactory separation.During purification from the ammonium sulfate fractions, amylase activity was found to decrease but could be restored by Ca-ions. At 70°C, a final concentration of 0.5 mM CaCl₂, was sufficient for full restoration, while three times that amount was necessary at 80°C. Determination of the K _m-values for Ca at different temperatures resulted in an asymptotically increasing curve at temperatures beyond 75°C. Addition of Ca had a pronounced effect on the stability of the amylase at 80°C but not at 90°C. Protease activity and stability was not affected by Ca-ions.     

Effect of iso-osmotic levels of salts and PEG-6000 on enzymes in germinating pea seeds

Effects of iso-osmotic levels of salts (NaCl, CaCl₂, Na₂SO₄) and PEG-6000 on the activity of hydrolytic and nitrogen assimilatory enzymes in pea embryo axis and coty ledon were studied. The activity of nitrate reductase and nitrite reductase in embryo axis and cotyledon and the activity of protease and α-amylase in cotyledon decreased with decreasing medium osmotic potential as compared to control at all the stages of seedling growth. The activity of protease and amylase increases with increasing levels of stress in embryo axis. Sodium chloride induced, stress had more deleterious effects on the activity of nitrate reductase, nitrite reductase and αamylase followed by other salts and PEG-6000. On the other hand, CaCl₂ induced salt stress was more depressive for protease activity. The maximum increase in the activity of protease and amylase was observed in embryo axis at higher concentration of salts and PEG-6000.     

Some Properties of Amylase Inhibitor Produced by Streptomyces sp. No. 280

A strain of Streptomyces produces a new substance capable of inactivating some amylases. This has not been reported by previous workers.

This amylase inhibitor was purified by means of acetone treatment, active carbon adsorption and column chromatography on DEAE-cellulose.

It was dialyzable through a cellophane membrane and soluble in water and methyl alcohol. The inhibitor had a small molecular weight and was a peptide-like substance. The inhibiting substance was resistant to the temperatures, and acted as inhibitor of glucoamylase, bacterial saccharogenic α-amylase, salivary and pancreatic α-amylases.     

Growth and glucoamylase production by the thermophilic fungusThermomyces lanuginosus in a synthetic medium

Summary The production of glucogenic amylase from the thermophilic fungus Thermomyces lanuginosus was studied in shake flasks and laboratory fermentors. As conidia were not able to germinate in media without yeast extract, pregerminated conidia were applied as inoculum. By this procedure it was possible to use different NH _inf4 ^sup+ salts as the sole source of nitrogen for growth and amylase formation in a synthetic medium. In pH-controlled fermentors a fourfold increase in the extracellular glucogenic amylase activity was obtained with (NH₄)H₂PO₄ as the nitrogen source as compared with yeast extract. However, by fractionation of these activities, comparable yields of partially purified glucoamylases were obtained. The glucoamylase preparation from fermentations with either of the nitrogen sources had a temperature optimum at 70° C and showed similar thermal stability. By incubation without substrate at 60° C. 90% of the activity was still present after 5 h. At 70° C, 50% of the activity was retained after 30 min incubation. Offprint requests to: I. Hassum     

Immobilization of α-amylase from mung beans (Vigna radiata) on Amberlite MB 150 and chitosan beads: A comparative study

α-Amylase from mung beans (Vigna radiata) was immobilized on two different matrices, Amberlite MB 150 and chitosan beads. Maximum immobilization obtained was 72% and 69% in case of Amberlite and chitosan beads, respectively. The pH optima of soluble α-amylase were 5.6, whereas that for immobilized amylase on chitosan and Amberlite was 7.0. Soluble amylase and Amberlite immobilized amylase showed maximum activity at 65 °C, whereas chitosan immobilized amylase showed maximum activity at 75 °C. α-Amylase immobilized on Amberlite showed apparent K_m of 2.77 mg/ml, whereas α-amylase immobilized on chitosan showed an apparent K_m of 5 mg/ml. The Amberlite-amylase and chitosan-amylase showed a residual activity of 43% and 27%, respectively, after 10 uses. The loss of activity for free amylase after 100 days of storage at 4 °C was 70%, whereas that for Amberlite- and chitosan-amylases, under the same experimental conditions, the losses were 45% and 55%, respectively. The easy availability of mung bean α-amylase, the ease of its immobilization on low-cost matrices and good stability upon immobilization in the present study makes it a suitable product for further use in industrial applications.     

Behaviour of Endomycopsis fibuligera glucoamylase towards raw starch

An extracellular glucoamylase [exo-1,4-α-d-glucosidase, 1,4-α-d-glucan glucohydrolase, EC 3.2.1.3] of Endomycopsis fibuligera has been purified and some of its properties studied. It had a very high debranching activity (0.63). The enzyme was completely adsorbed onto raw starch at all the pH values tested (pH 2.0–7.6). Amylase inhibitor from Streptomyces sp. did not prevent the adsorption of glucoamylase onto raw starch although the enzyme did not digest raw starch in the presence of amylase inhibitor. Sodium borate (0.1 m) eluted only 35% of the adsorbed enzyme from raw starch. The optimum pH for raw starch digestion was 4.5 whereas that of boiled soluble starch hydrolysis was 5.5. Waxy starches were more easily digested than non-waxy starches, and root starches were slowly digested by this enzyme.     

Adipokinetic hormones control amylase activity in the cockroach (Periplaneta americana) gut

This study examined the biochemical characteristics of α‐amylase and hormonal (adipokinetic hormone: AKH) stimulation of α‐amylase activity in the cockroach (Periplaneta americana) midgut. We applied two AKHs in vivo and in vitro, then measured resultant amylase activity and gene expression, as well as the expression of AKH receptor (AKHR). The results revealed that optimal amylase activity is characterized by the following: pH: 5.7, temperature: 38.4 °C, K_m (Michaelis–Menten constant): 2.54 mg starch/mL, and V_max (maximum reaction velocity): 0.185 μmol maltose/mL/min. In vivo application of AKHs resulted in significant increase of amylase activity: by two‐fold in the gastric caeca and 4–7 fold in the rest of the midgut. In vitro experiments supported results seen in vivo: a 24‐h incubation with the hormones resulted in the increase of amylase activity by 1.4 times in the caeca and 4–9 times in the midgut. Further, gene expression analyses reveal that AKHR is expressed in both the caeca and the rest of the midgut, although expression levels in the former were 23 times higher than levels in the latter. A similar pattern was found for the amylase (AMY) gene. Hormonal treatment did not affect the expression of either gene. This study is the first to provide evidence indicating direct AKH stimulation of digestive enzyme activity in the insect midgut, supported by specific AKHR gene expression in this organ.     

Relationships between plasma composition and parotid salivary composition and secretion rates in the potoroine marsupials,Aepyprymnus rufescens and Potorous tridactylus

Summary Parotid salivation was investigated in two species of potoroine marsupial, Aepyprymnus rufescens and Potorous tridactylus to ascertain flow rates and composition, the buffer capacity of the saliva with respect to possible dependence of these animals on foregut fermentation, and the similarity of anion excretion patterns to those of the kangaroo parotid. Under anaesthesia neither species secreted spontaneously and secretion was stimulated by intravenous infusion of carbachol, bethanechol and isoprenaline. Under cholinergic stimulation in Aepyprymnus, the concentrations of Na, Cl, HCO₃ and osmolality were positively correlated with flow rate, whereas K, Mg, PO₄, H⁺ and urea were negatively correlated with flow. Amylase activity and the concentrations of protein and Ca showed no consistent relation to flow. Relative to Aepyprymnus, saliva of Potorous had much lower amylase activity and amylase activity per gram protein, lower concentrations of urea and Ca, and higher Na. Protein, K and HCO₃ concentrations were similar in both species. The plasma of both species had similar electrolyte concentrations, but Potorous had lower protein, urea, osmolality and amylase activity. Plasma amylase activity in Aepyprymnus rose during cholinergic stimulation to levels in excess of rodent plasma. Isoprenaline infusion in Aepyprymnus increased salivary amylase activity and concentrations of protein, Ca, HCO₃ and PO₄, and reduced the concentrations of Cl and H⁺. The patterns of anion excretion in the two potoroine marsupials were dissimilar to those of the kangaroo parotid suggesting that parotid fluid secretion is not HCO₃ driven to the same extent as that of kangaroos. Buffer anion concentrations and secretion rates were similar to koalas and low relative to kangaroos, indicating that these potoroines do not rely on foregut fermentation.Abbreviations bw body weight - SEM standard error of mean - VFA volatile fatty acids