Resolution of the extracellular α-glucosidase system ofBacillus sp. NCIB 11203

Summary Two extracellular -glucosidases (EC 3.2.1.20, -D-glucoside glucohydrolase) of the alkalophilic bacterium,Bacillus sp. NCIB 11203, were separated, purified and partially characterised. Resolution of the system into two separate enzymes was achieved by fractionation with (NH₄)₂SO₄ and chromatography on DEAE-Biogel A. The first of these activities, an -glucosidase, hydrolysed p-nitrophenyl--D-glucopyranoside preferentially and had minor activity on isomaltose and isomaltotriose. The second enzyme was a maltase and displayed highest activity on maltose and maltotriose and some activity on p-nitrophenyl--D-glucopyranoside.     

Identification of new genes involved in disaccharide fermentation in yeast

Summary Maltose non-fermenting mutants were obtained from strains carrying a MAL4 allele which permits constitutive synthesis of maltase. Cells carrying this allele are able to utilize sucrose in the absence of the classical sucrose genes. All maltose non-fermenting mutants were also sucrose non-fermenters. Eight mutants had become maltase negative; 19 mutants could still form maltase constitutively.In crosses with segregational maltose and sucrose non-fermenting strains, enzyme negative mutants gave diploids unable to ferment maltose and sucrose. Enzyme positive, non-fermenting mutants gave diploids which readily fermented maltose and sucrose. This latter type of mutants was designated dsf (disaccharide fermentation) mutants.The diploids derived from crossing non-fermenting mutants with segregational non-fermenters were subjected to tetrad analysis. Enzyme negative non-fermenters gave only non-fermenting progeny. The dsf mutants segregated both fermenting and non-fermenting progeny, some of which showed the dsf phenotype. This indicated that none of the dsf mutants had a defect in a gene closely linked to MAL4. Crosses between dsf mutants and strains carrying the maltose genes MAL2 and MAL3 showed that the mutations affected maltose fermentation in general. Sucrose fermentation in the presence of the classical sucrose gene SUC3 was not affected, nor were fermentation of glucose, fructose and galactose.The uptake of radioactivity from uniformly labeled maltose appeared to be blocked in mutants of at least four of the dsf genes. Only one non-leaky and a leaky mutant showed a significant uptake.These results suggest that there is an extremely complex transport system for maltose and sucrose or that the utilization of these disaccharides requires a complex series of metabolic reactions.     

Formation of a raw starch-hydrolyzing alpha-amylase by Clostridium 2021: Effect of carbon sources

Summary Clostridium 2021 was found to produce -amylase effective at hydrolyzing raw starch. Of the carbohydrates examined, starch at 3 % concentration was found to be the best carbon source for enzyme production. The products of -amylase action on starch were: maltose. glucose and higher dextrins.     

Construction of industrial baker's yeast strains able to assimilate maltose under catabolite repression conditions

Spore progeny from an industrial baker's yeast strain were mutagenized with UV and mutants resistant to 2-deoxyglucose isolated. One of these mutants (10a12–13) showed high levels of maltase (-glucosidase) and external invertase, and assimilated maltose when growing under catabolite repression conditions. This mutant was not allelic to any of the catabolite repression mutants tested cat4, cat80, cid1, cyc8, hex2, hxk2 and tup1. Mutant 10a12–13 was crossed with appropriate strains to construct hybrids that were also able to assimilate maltose in the presence of glucose. These hybrids may be useful in fermentation processes where both glucose and maltose are present.     

Phosphate effects in the fermentation of α-amylase by Bacillus amyloliquefaciens

Summary The effects of phosphate on -amylase fermentation byBacillus amyloliquefaciens were investigated. It was observed through batch culture that optimal phosphate level which maximizes -amylase biosynthesis exists. High concentration of phosphate level promotes maltose uptake and growth of the microorganism, while high maltose uptake rate in the microorganism at the same time represses the enzyme biosynthesis presumably due to catabolite repression inside the microorganism. In continuous cultivation, a steady state of -amylase biosynthesis was obtained by maintaining phosphate level at a certain level. In fed-batch culture, by intermittant feeding of phosphate as well as maltose, higher activity of -amylase in the broth was obtained compared to the result from single nutrient feeding.     

A hybrid DNA sequence containing the replication origin of the multicopy yeast plasmid 2 micron circle and an additional repeated sequence can convert maltose-negative into maltose-positive strains

Summary Yeast DNA pools were prepared by ligating partial Sau3A genomic digests from strains carrying various MAL genes into the BamHI site of the yeast-Escherichia coli shuttle vector YRp7. They were used to transform recipient yeast strains that could not utilize maltose since they lacked a classical MAL gene. Transformants were obtained that could use maltose and also formed normal levels of maltase. They were unstable. They would lose the selective marker TRP1 of YRp7 alone, together with the ability to utilize maltose or only the ability to utilize maltose. The insertion of one of the plasmids was used as a hybridization probe for the others and found to share homologous sequences with all. They were then shown to contain the replication origin of the yeast 2 m circle plasmid and additional genomic digests of total yeast DNA. They hybridized at various degrees of efficiency with several bands, indicating that they were part of a family of repeated sequences. Apparently, it was the combination of the replication origin of the 2 m circles with the additional sequences that promoted maltose utilization.     

Organization of the MAL loci of Saccharomyces. Physical identification and functional characterization of three genes at the MAL6 locus

Summary We have physically and functionally identified three genes at the MAL6 locus of Saccharomyces carlsbergensis. Using multicopy yeast plasmid vectors, we have subcloned various segments of the entire MAL6 locus. The functional characterization of the MAL6 subcloned regions was determined by (1) analyzing biochemically the levels of MAL-encoded proteins (maltase [-D-glucosidase, E.C. 3.2.1.20] and maltose transport protein) in cells transformed with various MAL6 subclones, and (2) testing the ability of the subclones to complement the maltose fermentation defects of well characterized Mal^– mutants in the highly homologous MAL1 locus. The physical homology between MAL6 and MAL1 is in part demonstrated by the gene disruption of MAL1 using subcloned MAL6 DNA sequences. The results demonstrate that the MAL6 locus is a complex of at least three genes: MAL6R, MAL6T and MAL6S. These genes specify, respectively, a regulatory function, a maltose transport activity (presumably the maltose permease) and the structural gene for maltase. The functional organization of the MAL6 locus is thus identical to that which we had previously determined by mutational analysis for the MAL1 locus.     

Production of doubled haploid lines in frequencies sufficient for barley breeding programs

Winter barley (Hordeum vulgare L.) anthers were cultured on different liquid and on starch-solidified media. The optimal embryo and callus formation with different F₁-lines and the cv. Igri was obtained on a liquid medium with 20% Ficoll, 20 g/l maltose and barley starch. But the influence of the growth conditions of the donor plants and the genotypical differences are still enormous. The procedure has been optimized to such an extent that it can be used economically.     

A novel α-glucosidase produced by Bacillus amylolyticus

Bacillus amylolyticus produces -amylase, pullulanase and -glucosidase. By selection of carbon source in the growth medium, -glucosidase was produced preferentially and with exclusion of the other two activities. The -glucosidase was highly specific for maltose and to a lesser extent maltotriose but was inactive towards a range of other substrates including p-nitrophenyl -D-glucoside and isomaltose. Optima for activity were recorded at pH 7.0 and 40° C and the enzyme was insensitive to ethylenediaminetetraacetic acid.     

Characterization of two β-glucosidase genes fromClostridium thermocellum

Summary Two -glucosidase genes, designatedbglA andbglB, were isolated from a gene bank ofClostridium thermocellum DSM 1237. The coding sequences forbglA andbglB were located on non-homologous DNA fragments of 3.2– and 3.4-kb, respectively. Both genes direct inEscherichia coli the synthesis of cytoplasmic -glucosidases, which differ with respect to substrate specificity and temperature profile. The properties of thebglA-encoded -glucosidase A closely resemble that of a -glucosidase previously isolated fromC. thermocellum cultures.     

Glucose repression of maltase and methanol-oxidizing enzymes in the methylotrophic yeastHansenula polymorpha: Isolation and study of regulatory mutants

Regulation of the synthesis of maltase and methanol-oxidizing enzymes by the carbon source has been analyzed in the methylotrophic yeastHansenula polymorpha. Maltase was shown to be responsible for the growth ofH. polymorpha not only on maltose, but also on sucrose. The affinity of maltase towards maltase substrates decreased in the order: 4-nitrophenyl glucoside (pNPG) <sucrose <maltose. Mutants with glucose repression-insensitive synthesis of alcohol oxidase and maltase were obtained fromH. polymorpha by mutagenesis and subsequent selection on methanol medium in the presence of 2-deoxy-d-glucose. One of the isolated mutants, L63, was studied in more detail. Mutant L63 was recessive and monogenic and it was not deficient in hexokinase. Its analysis revealed thatH. polymorpha most probably has a repressor protein that in the presence of glucose can down-regulate expression of both maltase and enzymes of methanol oxidation.     

Isolation of aClostridium thermocellum gene encoding a thermostable β-1, 3-glucanase (laminarinase)

Summary AClostridium thermocellum gene directing the synthesis of a thermostable -glucanase was localized on a 1.9-kb DNA fragment by subcloning intoEscherichia coli plasmid vectors. The enzyme was highly efficient in degrading glucans with alternating -1, 3- and -1,4-linkages such as lichenan and barley glucan. It was also active towards the -1, 3-glucan laminarin, but lacked activity on cellulosic substrates and -glucans. The enzyme was therefore classified as -1, 3-glucanase (laminarinase) and the corresponding gene was designatedlicA. With barley -glucan as substrate the enzyme had a pH optimum around pH 6.5 and a temperature optimum at 65°C. It was stable for several hours at 60°C in the absence of substrate.     

The carbohydrases of Bacillus stearothermophilus NCIB 11412 and NCIB 10814

Summary Two strains (NCIB 11412 and NCIB 10814) of the thermophilic organism Bacillus stearothermophilus were found to produce complex carbohydrase systems. The enzyme activities in each system include -amylase as the major component, maltase, pullulanase, a minor amylase and cyclodextrinase. The latter three activities are produced in low yield in both strains. A crude enzyme preparation from each strain possessed maltogenic properties on hydrolysis of soluble starch. Following rigorous purification procedures, the purified major -amylase from either strain did not produce maltose as a major end-product of starch hydrolysis. However, a partially purified mixture of pullulanase, minor amylase and cyclodextrinase activities from NCIB 11412 and NCIB 10814 produced 56.4% and 62.0% maltose, respectively, from soluble starch.     

Enhancement of maltose utilisation by Saccharomyces cerevisiae in medium containing fermentable hexoses

Saccharomyces cerevisiae are unable to maintain high rates of fermentation during transition from catabolism of hexoses to maltose. This phenomenon, termed ‘maltose lag’, presents problems for the baking, brewing and distilling industries, which rely on yeast catabolism of mixtures of hexoses and maltose. Maltose utilisation requires the presence of maltose permease and α-glucosidase (maltase), encoded by MAL genes. Synthesis of these is induced by maltose and repressed by glucose. One strain of baker’s yeast used in this work exhibited a marked maltose lag, whereas a second strain exhibited a shorter lag during conversion from hexose to maltose metabolism. The extent of the lag was linked to the levels of maltose permease and maltase in cells at the time of inoculation into mixed sugar medium. This view is supported by results showing that pulsing yeast with maltose to induce expression of MAL genes prior to inoculation into mixed sugar medium, enhanced sugar fermentation. Maltose pulsing of yeasts could therefore be useful for enhancing some fermentations relevant to baking and other yeast industries. Received 24 December 1988/ Accepted in revised form 18 March 1999     

Production of active human interferon-β inE. coli I. Preferential production by lower culture temperature

Summary Unusually low culture temperature, such as 20°C, was shown to be preferable for the synthesis of active human interferon- (IFN-) inE. coli harboring a recombinant plasmid. TheE. coli cells cultured at 20°C gave 8.6-fold higher IFN- activity than those cultured at 37°C. However, almost the equal amounts of IFN- protein were accumulated in both cells cultured at 20°C and at temperature higher than 20°C, suggesting that IFN- might exist as an active form in the cells cultured at 20°C, while as a rather denatured form in the cells cultured at higher temperature.     

Photosynthetic ability in dark-grown Reboulia hemisphaerica and Barbula unguiculata cells in suspension culture

Suspension cultured cells of the liverwort, Reboulia hemisphaerica and of the moss, Barbula unguiculata were independently subcultured in the medium containing 2% glucose in the dark or in the light for more than one year, and the photosynthetic activities of the final cultures were determined. Throughout the culture period light-grown cells of both species contained high amount of chlorophyll (4 to 34 g mg^–1 dry weight) and showed a high photosynthetic activity (10 to 84 mol O₂ mg^–1 chlorophyll h^–1). Dark-grown cells of R. hemisphaerica showed the same level of chlorophyll content and photosynthetic O₂ evolving activity as light-grown cells. Although chlorophyll content in dark-grown B. unguiculata cells was ten-fold lower than that in light-grown cells, the photosynthetic activity of these dark-grown cells was higher than that of light-grown cells based on chlorophyll content.     

Production and localization of cellulases and β-glucosidase from the thermophilic fungusThielavia terrestris

Summary The enzyme production and localization ofThielavia terrestris strains C464 and NRRL 8126 were compared to determine their optimum temperature and pH for cellulase activity. High levels of intracellular -glucosidase activity were detected in the former strain. The intracellular -glucosidase of both strains were more thermostable than the extracellular enzyme; the half life ofT.terrestris (C464) endoglucanase activity at 60°C was greater than 96 hrs.     

A negative selection scheme for tobacco protoplast-derived cells expressing the T-DNA gene 2

The amido hydrolase encoded by the T-DNA gene 2 catalyzes the conversion of indole-acetamide, -naphthalene acetamide, and other substrate analogues into the corresponding auxins. As a result, only gene 2-expressing protoplast-derived tobacco cells can grow in medium containing low concentrations (0.2–1 M) of -naphthalene acetamide as auxin precursor. However, in a mixture of SR1 and SR1, gene 2 ⁺ protoplast-derived cells, cross-feeding occurs and consequently no positive selection for gene 2 is obtained. A 100-times higher concentration of -naphthalene acetamide (between 30 and 300 M) provides a negative selection scheme. Only the tobacco cells expressing gene 2 are sensitive to the high naphthalene acetamide concentration and cannot grow to colonies, while cells lacking the gene 2 product regenerate calli even in mixed gene 2 ⁺ and gene 2 ^– cell populations. Thus, gene 2 might provide a unique biochemically defined marker to investigate mutations and gene inactivation.     

Fermentation of starch to ethanol by a complementary mixture of an amylolytic yeast andSaccharomyces cerevisiae

Summary Synergistic coculture of an amylolytic yeast (Saccharomycopsis fibuligera) andS. cerevisiae, a non-amylolytic yeast, fermented unhydrolyzed starch to ethanol with conversion efficiencies over 90% of the theoretical maximum. Fermentation was optimal between pH 5.0 to 6.0. Using a starch concentration of 10% (w/v) and a 5% (v/v) inoculum ofS. fibuligera, increasingS. cerevisiae inoculum from 4% to 12% (w/v) resulted in 35–40% (w/v) increase in ethanol yields. Anaerobic or limited aerobic incubation almost doubled ethanol yields.     

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.