Extracellular Isoamylase Produced by the Yeast Lipomyces kononenkoae

A strain of the starch-converting yeast Lipomyces kononenkoae produced, when grown on starch, a debranching enzyme that proved to be an isoamylase (glycogen 6-glucanohydrolase; E.C. 3.2.1.68). So far, only bacteria have been found to produce extracellular isoamylases. The yeast isoamylase enhanced β-amylolysis of amylopectin and glycogen and completely hydrolyzed these substrates into maltose when combined with a β-amylase but had no action on dextran or pullulan. By isopropanol precipitation and carboxymethyl cellulose chromatography, L. kononenkoae isoamylase was partially purified from the supernatant of cultures grown on a mineral medium with soluble starch. Optimum temperature and pH for activity of the isoamylase were 30°C and 5.6. The molecular weight was around 65,000, and the pI was at pH 4.7 to 4.8. The K_m (30°C, pH 5.5) for soluble starch was 9 g liter⁻¹.     

Glycogen in the Marine Protozoon Parauronema acutum*

SYNOPSIS. The carbohydrate which accumulates in the cytoplasm of the marine protozoon, Parauronema acutum, during normal growth was isolated, purified and characterized chemically. The highly purified material yielded only glucose residues following hydrolysis in 0.6 N HCl for 3 h at 100 C; measurement of total carbohydrate by the phenol-sulfuric acid method and by treatment with amylo-glucosidase and glucose oxidase gave similar values. Aqueous solutions of the purified material reacted with iodine to form a complex which exhibited an absorption peak at 456 nm with a shift to 484 nm in the presence of 50% saturated (NH₄)₂SO₄. Digestion with α-amylase, β-amylase, and isoamylase yielded 71%, 45% and 8.3% hydrolysis, respectively. Treatment sequentially with both isoamylase and β-amylase gave complete hydrolysis of the polymer. The average chain length (CL) determined by the isoamylase procedure was 12. These observations are consistent with the view that the carbohydrate isolated from the protozoan is a polymer consisting of α-D-glucose residues arranged in chains containing α-(1→4) linkages with branch points containing α-(1→6) linkages occurring once on the average of ～ 12 glucose residues and, as such, is indistinguishable from glycogen isolated from mammalian sources.     

Purification and Substrate Specificity of Yeast Isoamylase

Yeast isoamylase was highly purified by means of salting-out with ammonium sulfate, chromatography on DEAE-cellulose, and gel filtration on Sephadex G-100. More than 200-fold purification was achieved through these procedures from crude yeast extract. While the purified enzyme did not attack α-1, 6-glucosidic linkages in panose, isopanose (6-malto-sylglucose), branched triose (4,6-diglucosylglucose), and isomaltosylmaltose (6³-α-glucosylmaltotriose), it acted on α,β-limit dextrin to liberate glucose as well as maltose and higher oligosaccharides. Substrate specificity of the yeast isoamylase was discussed in comparison with that of plant and bacterial isoamylases (R-enzvme and pullulanase), and the mechanism of debranching of glycogen by yeast enzymes was also discussed.     

Purifications and Enzymatic Properties of β-Amylase and Pullulanase from Bacillus cereus var. mycoides

A β-amylase and a pullulanase produced by Bacillus cereus var. mycoides were purified by means of ammonium sulfate fractionation, adsorption on starch and celite and Sephadex G–100 column chromatography. The purified enzymes were homogeneous in disc electrophoresis.

The β-amylase released only maltose from amylose, amylopectin, starch and glycogen, and the released maltose was in β-form. The pullulanase released maltose, maltotriose and maltotetraose from β-limit dextrin and maltotriose from pullulan, but not amylose-like substance from amylopectin.

The optimum pHs of β-amylase and pullulanase were about 7 and 6~6.5, respectively. The optimum temperatures of the enzymes were about 50°C. The enzymes were inhibited by the sulfhydryl reagents such as mercuric chloride and p-chloromercuribenzoate, and the inhibitions with p-chloromercuribenzoate were restored by the addition of cysteine. The molecular weights of β-amylase and pullulanase were estimated to be 35,000±5,000 and 110,000±20,000, respectively.     

On the Inducers of α-Amylase Formation In Aspergillus oryzae

In a previous paper it has been described that α-amylase formation in Aspergillus oryzae is stimulated by soluble starch, glycogen and maltose, whereas it is inhibited by glucose, which is added into a growing medium or a secondary incubation medium as the carbon source. The present paper reports that isomaltose and panose are the most effective inducers among a large number of sugars examined here, and suggests the importance of transglucosidase action demonstrated in view of α-amylase formation. The initial action of inducers in this system is also discussed.     

Characterization of an alpha-glucan from chick embryo sternum whose synthesis is stimulated by L-3,5,3'-triiodothyronine and human serum.

Incorporation of [³H]glucose into macromolecular components of 12-day chick embryo sternum incubated in vitro was stimulated by both human serum and l-3,5,3′-triiodothyronine. Under all conditions, 65–70% of the radioactivity was incorporated into glycosaminoglycans. About 10% of the radioactivity was incorporated into a fraction separable by ion-exchange chromatography which was stimulated two- to sixfold by addition of 2–10 nm triiodothyronine and 5–20% ($\text{v}\text{v}$) human serum. Further characterization of this fraction by paper electrophoresis at pH 3.5 showed the presence of two components, one apparently anionic and one neutral. All of the increase in incorporation of [³H]glucose was into the former species. Acid hydrolysis of this material showed that it contained only glucose. Treatment with α-amylase released 78% of the label as maltotriose and maltose; digestion with crystalline β-amylase released 75% as maltose; and treatment with glucoamylase and α-amylase released 93% as glucose. There was no incorporation of any amino acid into this fraction, nor could any incorporation of [³²P]phosphate, [³⁵S]sulfate, [³H]uridine, or [³H]acetate be demonstrated. Mild acid hydrolysis (0.1 N HC1, 100 °C, 10–20 min) converted the material to a neutral species with a much lower molecular weight. The results indicate that chick embryo sternum contains a species of glycogen whose synthesis is stimulated by thyroid hormones and other serum factors.     

Purification of pullulanase from <Emphasis Type="Italic">Aureobasidium pullulan</Emphasis>s

Purification and characterization of pullulanase from Aureobasidium pullulans. Pullulanase was purified by using gel—filtration column then on ion exchange using Q-sepharose column yielding a single peak. Purification was further carried out on SP-sepharose column. Molecular weight of pullulanase from A. pullulans was found to be about 73 KDa on the SDS-PAGE 10%. Native-PAGE 10% showed the activity of pullulanase, using polyacrylamide gel containing pullulan. Hydrolysis products from pullulanase activity with soluble starch, glycogen and pullulan on thin layer chromatography appeared as one band which is maltotriose, while α-amylase with soluble starch and glycogen showed two bands which are maltose and maltotriose but α-amylase gave negative result with pullulan on TLC chromatography only. Pullulanase could degrade α-1,6 glycosidic linkage of the previous substrates, while amylase could degrade α-1,4 glycosidic linkage of glycogen, soluble starch and pullulan. MALDI-Ms was employed to deduce protein sequence of pullulanase.     

Studies on the Metabolism of Aspergilli

Studies were made on the effect of water level of culture medium on the mycelial compositions and enzyme production in Aspergillus sojae K. S. The mold was grown on the media of various water levels made of powder of defatted soybean and wheat granule. The mycelia grown on the medium of low water level produced more protease and α-amylase, consumed more oxygen, formed less ammonia, and were richer in 2 n H₂SO₄-soluble glycogen, 60% H₂SO₄-soluble carbohydrates, protein and RNA per mg dry weight than the mycelia grown on the medium of high water level. Chromatographic analyses were carried out for nucleotides, sugar phosphates and free carbohydrates in cold TCA-soluble fraction of the mycelia.     

Kinetics of α-amylase production in a continuous culture ofBacillus licheniformis

As found during continuous cultivation ofBacillus licheniformis on a semisynthetic medium (glucose or maltose as C source), the specific rate of α-amylase production is proportional to growth rate but is repressed by higher substrate concentrations. Besides glucose or maltose, peptone was also used as an alternative carbon source during cultivation. The specific rate of production of the enzyme on maltose is half that found with glucose.     

Amino Acid Sequence of an Active Center Peptide Containing Serine Isolated from Alkaline Protease of Bacillus No. 221

The substrate specificity of pig liver acid α-glucosidase was investigated. The enzyme showed a wide specificity on various substrates. The Km values for maltose, malto-triose, -tetraose, -pentaose, -hexaose and -heptaose, and maltodextrin (mean degree of polymerization, 13) were 6.7 mm, 4.4 mm, 5.9 mm, ll mm, 4.0 mm, 5.6 mm and 7.1 mm, respectively. The relative maximum velocities for maltooligosaccharides consisting of three or more glucose units were 82.6 to 92.3% of the maximum velocity for maltose. For disaccharides, the rates of hydrolysis decreased in the following order: maltose > nigerose > kojibiose > isomaltose. The acid α-glucosidase also hydrolyzed several α-glucans, such as glycogen, soluble starch, β-limit dextrin and amylopectin. The Km value for β-limit dextrin was the lowest of those for α-glucans.

The nature of the active site catalyzing the hydrolyses of maltose and glycogen was investigated by kinetic methods. In experiments with mixed substrates, maltose and glycogen, the kinetic features agreed very closely with those theoretically predicted for a single active site catalyzing the hydrolyses of both substrates. Cations, Na⁺, K⁺ and Mg⁺⁺, were about equally effective in the activation of the enzyme action on maltose and glycogen. The inhibitor constants of tris(hydroxymethyl)aminomethane (Tris) and turanose were nearly the same for maltase activity as those for glucoamylase activity. From these results, the enzyme was concluded to attack maltose and glycogen by a single active site mechanism.     

Characterization of Lipid A,A Component of Lipopolysaccharides from Selenomonas ruminantium

Lipid components of a glycolipid, formerly designated as spot A, from the cells of Selenomonas ruminantium were investigated. The basic structure of this material had been previously shown to be β-glucosaminyl-l,6-glucosamine. The major component of O- and N-acyl side chains was β-OH C_13:0 acid when the cells were grown with added valerate. Approximately 85 % of the total amide linked fatty acids was this compound. A considerable amount of C_13:2 acid was also present as a component of O-acyl fatty acids. When the cells were grown in a glucose medium containing caproate, the major fatty acid component of the spot A compound was β-OH myristic and β-OH C_13:0: acids. ¹⁴C-Valerate or ¹⁴C-caproate, supplemented to the glucose medium, was incorporated into O- and N-acyl linked fatty acid moieties of the spot A compound. It was also shown that the spot A compound was the lipid A component of lipopolysaccharides of this organism.     

Improved culture conditions forCowdria ruminantium (Rickettsiales), the agent of heartwater disease of domestic ruminants

The causal agent of heartwater disease of domestic ruminants,Cowdria ruminantium, can, with difficulty, be isolated and passaged in lines of bovine endothelial cells grown in the presence of the Glasgow modification of Eagle's minimal essential medium. However, when Leibovitz's L-15 medium supplemented with 0.45% glucose at pH 6.0–6.5 is used as maintenance medium for these cells, isolation and serial passage may routinely be achieved.     

Derepression of a baker's yeast strain for maltose utilization is associated with severe deregulation of HXT gene expression

Aims: We undertook to improve an industrial Saccharomyces cerevisiae strain by derepressing it for maltose utilization in the presence of high glucose concentrations. Methods and Results: A mutant was obtained from an industrial S. cerevisiae strain following random UV mutagenesis and selection on maltose/5‐thioglucose medium. The mutant acquired the ability to utilize glucose simultaneously with maltose and possibly also sucrose and galactose. Aerobic sugar metabolism was still largely fermentative, but an enhanced respirative metabolism resulted in a 31% higher biomass yield on glucose. Kinetic characterization of glucose transport in the mutant revealed the predominance of the high‐affinity component. Northern blot analysis showed that the mutant strain expresses only the HXT6/7 gene irrespective of the glucose concentration in the medium, indicating a severe deregulation in the induction/repression pathways modulating HXT gene expression. Interestingly, maltose‐grown cells of the mutant display inverse diauxy in a glucose/maltose mixture, preferring maltose to glucose. Conclusion: In the mutant here reported, the glucose transport step seems to be uncoupled from downstream regulation, because it seems to be unable to sense abundant glucose, via both repression and induction pathways. Significance and Impact of the Study: We report here the isolation of a S. cerevisiae mutant with a novel derepressed phenotype, potentially interesting for the industrial fermentation of mixed sugar substrates.     

Expression of α-amylase in cultured callus of french bean

α-Amylase (EC 3.2.1.1) expression was found in calli of French bean (Phaseolus vulgaris L. cv Goldstar). We examined enzyme activity in the calli to investigate influence of gibberellin and sugars on enzyme expression. After subculture of the calli, α-amylase activity decreased, and then increased at a stationary phase of callus growth. Exogenous application of gibberellin and an inhibitor of gibberellin synthesis, uniconazole, did not have any significant effects on the enzyme expression. Sugar starvation increased the activity, while addition of metabolizable sugars, such as sucrose, glucose and maltose, to the medium repressed expression. Addition of 6% mannitol, a non-metabolizable sugar, to the medium induced higher α-amylase expression as compared to addition of 3% mannitol. This result suggests that osmotic stress enhances α-amylase activity in the calli. Furthermore, high concentrations of agar in the medium increased α-amylase activity in the calli. It is probable that high concentrations of agar prevented incorporation of nutrient into the calli and induced the α-amylase activity in the calli.     

GROWTH OF EXCISED PEA EMBRYONIC AXES ON DIFFERENT SUGARS

Excised pea embryonic axes were cultured on mineral salts plus various carbon sources. Growth continued for at least 3 wk, as measured by increased length, fresh and dry wt, sugar content, and β-amylase activity. The optimum sucrose concentration for elongation and fresh wt accumulation was 5% (w/v), although dry wt and sugar content increased in cultures containing 10 to 20%. Comparable growth was observed for axes cultured on 2% sucrose, glucose, fructose, or maltose.     

Effect of pH on isoamylase production by Pseudomonas amyloderamosa WU 5315

The isoamylase activity of Pseudomonas amyloderamosa WU 5315 was stable over the pH range from 5.5 to 6.25 while only about 30% of the activity remained at pH 6.5. Low isoamylase activity (418 U ml^-1) was produced by the cells grown at high pH. Activity reached almost 3000 U ml^-1 when pH was kept below 6.0 during the fermentation. With 1% glucose plus 2% maltose instead of 3% maltose as carbon source, however, no pH control was required and the isoamylase activity of Ps. amyloderamosa WU 5315 increased to 3400 U ml^-1.     

Characterization of an exo-acting intracellular α-amylase from the hyperthermophilic bacterium Thermotoga neapolitana

We cloned and expressed the gene for an intracellular α-amylase, designated AmyB, from the hyperthermophilic bacterium Thermotoga neapolitana in Escherichia coli. The putative intracellular amylolytic enzyme contained four regions that are highly conserved among glycoside hydrolase family (GH) 13 α-amylases. AmyB exhibited maximum activity at pH 6.5 and 75°C, and its thermostability was slightly enhanced by Ca²⁺. However, Ca²⁺ was not required for the activity of AmyB as EDTA had no effect on enzyme activity. AmyB hydrolyzed the typical substrates for α-amylase, including soluble starch, amylose, amylopectin, and glycogen, to liberate maltose and minor amount of glucose. The hydrolytic pattern of AmyB is most similar to those of maltogenic amylases (EC 3.2.1.133) among GH 13 α-amylases; however, it can be distinguished by its inability to hydrolyze pullulan and β-cyclodextrin. AmyB enzymatic activity was negligible when acarbose, a maltotetraose analog in which a maltose residue at the nonreducing end was replaced by acarviosine, was present, indicating that AmyB cleaves maltose units from the nonreducing end of maltooligosaccharides. These results indicate that AmyB is a new type exo-acting intracellular α-amylase possessing distinct characteristics that distinguish it from typical α-amylase and cyclodextrin-/pullulan-hydrolyzing enzymes.     

Growth Inhibition of Lactobacillus casei Phage J1 by Dehydroacetate

The fine structures of amylopectin and intermediate material characteristic of amylomaize starch were investigated by chemical and enzymatic means. In comparison with waxy-maize amylopectin, that of amylomaize starch was found to possess a img/ approximately 10 glucose units longer. Unit-chain profiles of waxy and amylomaize amylopectins revealed that the clear difference lay simply in the relative amounts of two unit-chain fractions. By fractionations of debranched β-limit dextrins, it was demonstrated that the img/ of the internal chains in amylomaize amylopectin was 9 glucose units longer than that in waxy-maize amylopectin. In addition, the proportion of maltose and maltotriose fractions in the debranched dextrin for amylomaize amylopectin was noticeably smaller than found for waxy-maize amylopectin. These data suggest a lesser branching frequency of outer branches in amylomaize amylopectin, confirming the previous proposal that this amylopectin has longer inner and outer branches than those of normal amylopectin.

As for amylomaize intermediate material, the average degree of polymerization was estimated to be 250 to 300 glucose units per molecule. It was also indicated that there were 5 or 6 glucose residues corresponding to the non-reducing end in the molecule. The unit-chain profile of the intermediate material implied that this molecule was mainly composed of branches with img/ around 50. Moreover, the presence of only small amounts of maltose and maltotriose fractions was demonstrated by the unit-chain distribution of this β-limit dextrin. These findings indicate that amylomaize intermediate material is totally consistent with a branched glucan having a low molecular weight, proposing that this anomalous glucan has such a fine structure that four or five branches with img/ around 50 are linked to a main linear chain of 100 to 150 glucose units.     

Quantitative Study of Anomeric Forms of Maltose Produced by α- and βAmylases

Anomeric forms of glucose and maltose produced from phenyl, p-nitrophenyl, p-tert-butylphenyl, p-ethylphenyl and p-chlorophenyl α-maltosides and maltopentaose by α- and β-amylases were determined quantitatively by a gas-liquid chromatographic method. All of the three kinds of α-amylases tested, B. subtilis saccharifying α-amylase, Taka-amylase A, and porcine pancreas α-amylase, were found to produce only α-maltose from the maltosides. Sweet potato and barley β-amylases produced β-maltose from maltopentaose.

Saccharifying α-amylase from B. subtilis also released α-maltose from all the maltosides mentioned above, contrary to the report by Shibaoka et al. that the enzyme released β-maltose from maltosides other than phenyl α-maltoside: FEBS Lett., 16, 33 (1971); J. Biochem., 77, 1215 (1975). It appears unlikely that the α-amylase releases β-maltose, depending on the kind of substrate.