Production of catalytic cells for formaldehyde production and alcohol oxidase by a catabolite repression-insensitive mutant of a methanol yeast Candida boidinii A5

A catabolite repression-insensitive mutant of Candida boidinii A5, strain ADU-15, was investigated as to alcohol oxidase production and the production of cells exhibiting the maximum catalytic activity for formaldehyde production. The mutant strain ADU-15 showed higher cell productivity and higher alcohol oxidase activity when grown on mixed substrates (glucose-methanol), especially with a high concentration of glucose in the medium. Thus, even under substrate (glucose-methanol)-limited chemostat conditions, where the glucose concentration was low, partial derepression of alcohol oxidase by glucose in mutant strain ADU-15 was detected. The chemostat culture conditions with the glucose-methanol medium were optimized for alcohol oxidase production and the production of cells exhibiting the maximum catalytic activity for formaldehyde production, respectively. By means of chemostat culturing on mixed substrates, we improved the alcohol oxidase productivity 5.0-fold and the productivity of cells exhibiting the maximum catalytic activity for formaldehyde production 3.8-fold, in comparison with the parent strain chemostat cultured with methanol as the single substrate.     

Isolation and Characterization of a Catabolite Repression-Insensitive Mutant of a Methanol Yeast, Candida boidinii A5, Producing Alcohol Oxidase in Glucose-Containing Medium

Mutants exhibiting alcohol oxidase (EC 1.1.3.13) activity when grown on glucose in the presence of methanol were found among 2-deoxyglucose-resistant mutants derived from a methanol yeast, Candida boidinii A5. One of these mutants, strain ADU-15, showed the highest alcohol oxidase activity in glucose-containing medium. The growth characteristics and also the induction and degradation of alcohol oxidase were compared with the parent strain and mutant strain ADU-15. In the parent strain, initiation of alcohol oxidase synthesis was delayed by the addition of 0.5% glucose to the methanol medium, whereas it was not delayed in mutant strain ADU-15. This showed that alcohol oxidase underwent repression by glucose. On the other hand, degradation of alcohol oxidase after transfer of the cells from methanol to glucose medium (catabolite inactivation) was observed to proceed at similar rates in parent and mutant strains. The results of immunochemical titration experiments suggest that catabolite inactivation of alcohol oxidase is coupled with a quantitative change in the enzyme. Mutant strain ADU-15 was proved to be a catabolite repression-insensitive mutant and to produce alcohol oxidase in the presence of glucose. However, it was not an overproducer of alcohol oxidase and, in both the parent and mutant strains, alcohol oxidase was completely repressed by ethanol.     

Formaldehyde Production by Cells of a Mutant of Candida boidinii S2 Grown in Methanol-limited Chemostat Culture

Formaldehyde production was investigated with cells of a mutant, AOU-1, of a methanol yeast, Candida boidinii S2 grown in methanol-limited chemostat culture. The highest productivity was shown with cells from the culture at a dilution rate of 0.075 hr^-1, when cells had the highest activity of alcohol oxidase and almost minimum activity of formaldehyde dehydrogenase. Under optimal reaction conditions, 950 mm formaldehyde was produced in 10-hr reaction with the cells. By the chemostat culture, not only formaldehyde productivity but also cell productivity was improved in comparison with batch culture. A maximum cell productivity of 0.2 g · liter^-1 · hr^-1 and a cell yield of 47% were obtained.     

Production of catalase-free alcohol oxidase by Hansenula polymorpha

Summary Many of the potential technical applications of alcohol oxidase (MOX; EC 1.1.3.13) are limited by the presence of high activities of catalase in the enzyme preparations. In order to circumvent laborious and costly purification or inactivation procedures, the induction of MOX in a catalase-negative mutant of Hansenula polymorpha has been studied. Emphasis was laid on the induction of activities of MOX and the dissimilatory enzymes in continuous cultures grown on various mixtures of formate/glucose and formaldehyde/glucose. In continuous cultures of the catalase-negative mutant grown on these mixtures, MOX can be induced efficiently. To obtain a stable and productive process, the ratio of the substrates is of critical importance. The optimal ratios of the mixtures for the catalase-negative strain for formate/glucose and formaldehyde/glucose were 3:1 and 1–2:1, respectively. Under identical cultivation conditions the wild-type strain showed similar induction patterns for MOX and the dissimilatory enzymes formaldehyde dehydrogenase (FaDH) and formate dehydrogenase (FoDH). The MOX levels in the catalase-negative strain were approx. 50% of those in the wild-type strain.     

A comparative study of the inhibitory effect of ethanol and substrates on the fermentation rate of parent and a respiratory-deficient mutant

The inhibitory effect of alcohol and substrates on the fermentation rate of one strain of Candida pseudotropicalis and of a respiratory-deficient mutant of this strain is investigated. For the parent strain maximum fermentative activity is identical in the presence of glucose or lactose. For a respiratory-deficient mutant, the fermentation rate is always higher than that of the parent strain. The inhibitory effect of alcohol and substrate is always less with the respiratory-deficient mutant than with the parent strain.     

Strain improvement and metabolic flux analysis in the wild-type and a mutant Lactobacillus lactis strain for L(+)-lactic acid production

The effects of initial glucose concentration and calcium lactate concentration on the lactic acid production by the parent strain, Lactobacillus lactis BME5-18, were studied. The results of the experiments indicated that glucose and lactate repressed the cell growth and the lactic acid production by Lactobacillus lactis BME5-18. A L(+)-lactic acid overproducing strain, Lactobacillus lactis BME5-18M, was screened by mutagenizing the parent strain with ultraviolet (UV) light irradiation and selecting the high glucose and lactate calcium concentration repression resistant mutant. Starting with a concentration of 100g L(-1) glucose, the mutant produced 98.6 g L(-1) lactic acid after 60 h in flasks, 73.9% higher than that of the parent strain. The L(+)-lactic acid purity was 98.1% by weight based on the amount of total lactic acid. The culture of the parent strain could not be analyzed well by conventional metabolic flux analysis techniques, since some pyruvate were accumulated intracellularly. Therefore, a revised flux analysis method was proposed by introducing intracellular pyruvate pool. Further studies demonstrate that there is a high level of NADH oxidase activity (12.11 mmol mg(-1) min(-1)) in the parent strain. The molecular mechanisms of the strain improvement were proposed, i.e., the high level of NADH oxidase activity was eliminated and the uptake rate of glucose was increased from 82.1 C-mmol (g DW h)(-1) to 98.9 C-mmol (g DW h)(-1) by mutagenizing the parent strain with UV, and therefore the mutant strain converts mostly pyruvate to lactic acid with a higher productivity (1.76 g L(-1) h(-1)) than the parent strain (0.95 g L(-1) h(-1)).     

A Proposal for the Expression of the Foamability of Protein Solutions

Mutants exhibiting high catalase activity were derived from Candida boidinii S2 strain AOU-1, from among mutants resistant to H₂O₂, NaN₃ or 3-amino-1,2,4-triazole (ATA). The catalase activity of an ATA-resistant strain was improved by means of a methanol-limited chemostat culture with H₂O₂ supplementation. The catalase activity increased with increasing H₂O₂ concentration in the feed medium in the range where methanol did not remain. Alcohol oxidase activity increased after adaptation of the cells to H₂O₂. Cells of mutant strain SA051 grown under the optimal culture conditions produced 1200 mm formaldehyde in the reaction mixture.     

Regulation of alcohol oxidase synthesis in Hansenula polymorpha: Oversynthesis during growth on mixed substrates and induction by methanol

The regulation of the synthesis of alcohol oxidase, catalase, formaldehyde dehydrogenase and formate dehydrogenase was investigated in the methanol-utilizing yeast Hansenula polymorpha. The organism was found to synthesize immunologically identical alcohol oxidases during growth on glycerol and methanol. Growth on glycerol, however, was not dependent on the alcohol oxidase, as was shown with a mutant without alcohol oxidase protein. Similarly it was shown with a catalase activity negative mutant that high catalase activity during growth on glycerol was not a prerequisite for the utilization of this substrate, though absolutely required for growth on methanol.Experiments were conducted with mixed substrates to study the influence of methanol on alcohol oxidase synthesis. In batch cultures, growth on ribose plus methanol resulted in an enhanced rate of alcohol oxidase synthesis as compared to ribose alone. In continuous cultures, (D=0.1 h^-1) addition of methanol to glycerol-, glucose-, or sorbose-limited cultures gave rise to increased alcohol oxidase activity of up to 20 U/mg, which is about by 2 times higher than the specific activity used for growth on methanol alone. The increase in specific activity of the dissimilatory enzymes on the mixed substrates is partly due to methanol per se, as was shown by a mutant unable to dissimilate or assimilate methanol.     

Dismutation and cross-dismutation of aldehydes, and alcohol: aldehyde oxidoreduction by resting-cells of Pseudomonas putida F61-a

Pseudomonas putida F61-a defective in formaldehyde dehydrogenase was derived from the parent strain (F61). The bacterial strain grown on a nutrient broth supplemented with 1% glucose exhibited high formaldehyde dismutase activity. The dismutation and cross-dismutation of aldehydes occurred stoichiometrically in the resting-cells reaction. Many kinds of aliphatic and aromatic aldehydes that are scarcely soluble in water were utilized in these reactions as well as soluble ones. Formaldehyde at an extremely high concentration (0.5 M) was almost completely converted to equimolar amounts of methanol and formic acid by the resting-cells, which could be used three times without a loss of activity. The cross-dismutation between acrolein and formaldehyde occurred efficiently in the resting-cells reaction with 0.1 M each substrate. The alcohol: aldehyde oxidoreduction of the short-chain substrates was also shown by the resting-cells of a mutant (M6) unable to grow on n-propanol.     

Utilization of methanol by a catalase-negative mutant of Hansenula polymorpha

Summary In methanol-utilizing yeasts, catalase is an essential enzyme for the destruction of hydrogen peroxide generated by methanol oxidase (E.C. 1.1.3.13). It was found however that a catalase-negative mutant of Hansenula polymorpha is able to consume methanol in the presence of glucose in continuous cultures. At a dilution rate of 0.1 h^-1, stable continuous cultures could be obtained during growth on methanol/glucose mixtures with a molar ratio of methanol/glucose between 0 to 2.4. In these cultures methanol oxidase was induced up to a level of 40% of that obtained in the wild-type strain. The hydrogen peroxide-decomposition activity of the mutant was studied in more detail by pulsing methanol to samples of steady-state cultures. Only after the addition of excess methanol the hydrogen peroxide-decomposing system became saturated, and the cells excreted hydrogen peroxide. This was accompanied by excretion of formaldehyde and a rapid loss of viability. The presence of extracellular catalase during a methanol pulse prevented the loss of viability. The nature of the alternative hydrogen peroxide-decomposing enzyme system remains to be elucidated. Its capacity strongly depended on the cultivation conditions and pretreatment of the cells. Cells grown on formaldehyde/glucose mixtures showed a lower methanol tolerance than those grown on the methanol/glucose mixtures. Freeze-drying of cells drastically enhanced the excretion of hydrogen peroxide, probably as a result of an inactivation of the decomposing system.     

Metabolism associated with raised metabolic flux to sugar nucleotide precursors of exopolysaccharides in Lactobacillus delbrueckii subsp. bulgaricus

Exopolysaccharide (EPS) metabolism was studied in a galactose-negative strain of Lactobacillus delbrueckii subsp. bulgaricus, using two different approaches. Firstly, using both the parent strain and a chemically induced mutant with higher yield and specific productivity of EPS than the parent, comparative information was obtained relating to enzyme activities and metabolite levels associated with EPS formation when grown on lactose. Under continuous culture conditions (D=0.10 h⁻¹), the higher metabolic flux towards EPS formation in the mutant strain relative to the parent appeared to be mediated by raised levels of UDP-glucose pyrophosphorylase (UGP). Marginally raised UDP-galactose 4-epimerase (UGE) activity in the mutant strain suggested that this enzyme could also play a role in EPS overproduction. The second approach involved investigating the effect of growth rate on sugar nucleotide metabolism in the parent, as it is known that EPS production is growth-associated in this strain. UGE activity in the parent strain appeared to increase when the growth rate was elevated from 0.05 to 0.10 h⁻¹, and further to 0.35 h⁻¹, conditions that can be associated with higher levels of metabolic flux to EPS formation. Concurrent with these increments, intracellular ATP levels in the cell were raised. In both investigations glucose-6-phosphate accumulated pointing to a constriction at this branch-point, and a limitation in the flow of carbon towards fructose-6-phosphate or glucose-1-phosphate. The changes in metabolism associated with enhanced flux to EPS provide guidance as to how the yield of Lactobacillus delbrueckii subsp. bulgaricus EPS can be improved.     

复合诱变法选育香兰素高转化率菌株

通过紫外线照射和He-Ne激光修复对香兰素生产菌链霉菌Streptomyces sp.L1936进行复合诱变,得到香兰素高产菌株Streptomyces sp.L1936-8。结果表明:出发菌株经过诱变处理后,脱乙酰酶酶活提高了75%,香兰素氧化酶酶活降低了37.5%,香兰素产量提高了33%。     

Characterization of a citrate-negative mutant ofLeuconostoc mesenteroides subsp.mesenteroides: metabolic and plasmidic properties

Summary Comparison of the parental strain of the Leuconostoc mesenteroides subsp. mesenteroides (19D) and its citrate-negative mutant, which has lost a 22-kb plasmid, has confirmed the energetic role of citrate. Fermentation balance analysis showed that citrate led to a change in heterolactic fermentation from glucose. High levels of enzyme activity in both mutant and parental strains were found for NADH oxidase, lactate dehydrogenase, acetate kinase, alcohol dehydrogenase, diacetyl reductase and acetoin reductase, although NADH oxidase, alcohol dehydrogenase, diacetyl reductase and acetoin reductase were partly repressed by citrate. All these enzymes studied were not plasmid linked. In the parental strain, citrate lyase was induced by citrate. No citrate lyase activity was found in the citrate-negative mutant grown in presence of citrate, but this does not provide evidence that citrate lyase is linked to the 22-kb plasmid. Offprint requests to: C. Diviès     

Oxidation of formaldehyde by alcohol oxidase of Candida boidinii

A formaldehyde oxidase activity was found in cell-free extracts of methanol-grown yeast Candida boidinii. Loss of alcohol oxidase activity in a mutant, 4₈, led to loss of the formaldehyde oxidase activity, indicating that the same enzyme is probably responsible for both activities. This could be demonstrated with the purified alcohol oxidase which oxidizes, besides lower primary alcohols, formaldehyde to formate. The K _m value for formaldehyde is 5.7 mM. It seems that alcohol oxidase is not implicated in formaldehyde oxidation in vivo.     

Characteristics of Methylobacillus flagellatum KT mutants, deficient for phosphoglucoisomerase, an enzyme of the ribulose monophosphate cycle of obligate methylotrophic bacteria

The activities of the key enzymes of ribulose monophosphate cycle for formaldehyde oxidation and assimilation were tested in crude extracts from temperature sensitive mutants of obligatemethylotroph M. flagellatum KT. Two mutants deficient in phosphoglucoisomerase activity were identified during this screening. Phosphoglucoisomerase of T525 pgi-1 mutant was active both at permissive (30 degrees C) and nonpermissive (42 degrees C) temperatures. Complete inactivation of the enzyme at 42 degrees C occurred in 2 h in vitro, while in vivo incubation at nonpermissive temperature for more than 10 h was required for the enzyme inactivation. Phosphoglucoisomerase activity of T566 pgi-2 was 5-fold lower as compared with the one from the parent strain incubated at 30 degrees C. The enzyme was inactivated in 2 min. in crude extract at nonpermissive temperature.     

Oxidation of formaldehyde by alcohol oxidase of Candida boidinii.

A fromaldehyde oxidase activity was found in cellfree extracts of methanol-grown yeast Candida boidinii. Loss of alcohol oxidase activity in a mutant, 48, led to loss of the formaldehyde oxidase activity, indicating that the same enzyme is probably responsible for both activities. This could be demonstrated with the purified alcohol oxidase which oxidizes, besides lower primary alcohols, formaldehyde to formate. The Km value for formaldehyde is 5.7 mM. It seems that alcohol oxidase is not implicated in formaldehyde oxidation in vivo.     

Induction and selection of formaldehyde-based resistance inPseudomonas aeruginosa

Summary A formaldehyde resistant (R) phenotype ofPseudomonas aeruginosa was isolated from a formaldehydesensitive (S) parent by sequential treatment with 1,3,5-tris-(ethyl)hexahydro-s-triazine (ET). The resistance of the (R) strain to treatment with ET was approximately 3-fold higher than the parental (S) strain. Two modes of resistance to ET, and simultaneous resistance to formaldehyde, are demonstrated: (1) transient or induced resistance is expressed during shor-term exposure to ET, and this resistance is gradually lost during subsequent growth in the absence of ET, and (2) resistance that results from a stable phenotypic change in the (S) strain following sequential treatment with ET ((R) strain phenotype). The observed activities of three forms of the formaldehyde oxidizing enzyme, formaldehyde dehydrogenase, are strongly correlated with the relative response of the (S) and (R) strains to treatment with ET. The observed resistance of the (R) strain appears to be due to high levels of an NAD⁺-linked, glutathione-dependent form of formaldehyde dehydrogenase as well as a dye-linked formaldehyde dehydrogenase. The transient or induced response of the (R) strain involves an increase in activity of the dye-linked formaldehyde dehydrogenase. The induced response of the (S) strain and an ATCC strain ofP. aeruginosa, however, is correlated with the two forms of the NAD⁺-linked enzyme (glutathione-dependent (EC 1.2.1.1) and independent (EC 1.2.1.46)) with no contribution from the dye-linked enzyme.     

Degradation of microbodies in relation of activities of alcohol oxidase and catalase inCandida boidinii

Degradation of microbiodies in the methanolutilizing yeastCandida boidinii was mainly studies by electron microscopical observation. The yeast cells precultured on methanol medium contained five to six microbodies per section and showed high activities of alcohol oxidase, catalase, formaldehyde dehydrogenase and formate dehydrogenase. When the precultured cells were transferred into an ethanol medium the number of microbodies and concomitantly the activities of alcohol oxidase and catalase decreased. After 6 h of cultivation microbodies were hardly detected. Also the activity of alcohol oxidase was not measurable and catalase activity was reduced to one tenth, whereas the activities of formaldehyde dehydrogenase and formate dehydrogenase decreased only to about 70%. Experiments with methanol-grown cells transferred into an ethanol medium without nitrogen source indicated that the inactivation of alcohol oxidase and catalase does not require protein synthesis. However, the reappearance of these enzymes is presumably due to de novo protein synthesis as shown by experiments with cycloheximide.     

异源表达NADH选择性氧化酶提高光滑球拟酵母酵解速率及丙酮酸生产强度

摘要：【目的】为进一步提高光滑球拟酵母(Torulopsis glabrata)葡萄糖代谢速率及丙酮酸生产强度。【方法】将源于荚膜胞浆菌(Histoplasma capsulatum)的编码选择性氧化酶的AOX1基因过量表达于T. glabrata中,获得了一株线粒体内NADH氧化途径发生改变且胞内总NADH 氧化酶活性提高1.8倍的重组菌株AOX。【结果】与出发菌株CON比较,细胞浓度以及发酵周期降低了20.3%和10.7%,而平均比葡萄糖消耗速率和丙酮酸合成速率分别提高了34.7%和54.1%。其原因     

Microbial oxidation of methanol: Properties of crystallized alcohol oxidase from a yeast, Pichia sp

Alcohol oxidase (alcohol:oxygen oxidoreductase) was crystallized from a methanolgrown yeast, Pichia sp. The crystalline enzyme is homogenous as judged from polyacrylamide gel electrophoresis. Alcohol oxidase catalyzed the oxidation of short-chain primary alcohols (C₁ to C₆), substituted primary alcohols (2-chloroethanol, 3-chloro-1-propanol, 4-chlorobutanol, isobutanol), and formaldehyde. The general reaction with an oxidizable substrate is as follows: Primary alcohol + O₂ → aldehyde + H₂O₂ Formaldehyde + O₂ → formate + H₂O₂. Secondary alcohols, tertiary alcohols, cyclic alcohols, aromatic alcohols, and aldehydes (except formaldehyde) were not oxidized. The K_m values for methanol and formaldehyde are 0.5 and 3.5 mm, respectively. The stoichiometry of substrate oxidized (alcohol or formaldehyde), oxygen consumed, and product formed (aldehyde or formate) is 1:1:1. The purified enzyme has a molecular weight of 300,000 as determined by gel filtration and a subunit size of 76,000 as determined by sodium dodecyl sulfate-gel electrophoresis, indicating that alcohol oxidase consists of four identical subunits. The purified alcohol oxidase has absorption maxima at 460 and 380 nm which were bleached by the addition of methanol. The prosthetic group of the enzyme was identified as a flavin adenine dinucleotide. Alcohol oxidase activity was inhibited by sulfhydryl reagents (p-chloromercuribenzoate, mercuric chloride, 5,5′-dithiobis-2-nitrobenzoate, iodoacetate) indicating the involvement of sulfhydryl groups(s) in the oxidation of alcohols by alcohol oxidase. Hydrogen peroxide (product of the reaction), 2-aminoethanol (substrate analogue), and cupric sulfate also inhibited alcohol oxidase activity.