高通量筛选诱变菌株降低黄酒发酵氨基甲酸乙酯前体积累

【目的】氨基甲酸乙酯是发酵食品中普遍存在的一种潜在危害物。黄酒中氨基甲酸乙酯的前体主要是尿素和乙醇。本研究通过高通量筛选策略降低黄酒发酵过程中尿素的积累,从而降低氨基甲酸乙酯积累。【方法】以一株黄酒生产工业菌株酿酒酵母XZ-11为研究对象,采用ARTP诱变和高通量筛选策略,获得尿素积累量较低菌株。使用实时定量PCR技术检测氮代谢中尿素代谢和转运相关基因(DUR1,2和DUR3)的变化。【结果】筛选得到一株尿素高效稳定性利用菌株5-11C。其尿素积累量比酿酒酵母XZ-11降低了50.6%。实时定量荧光PCR结果表明,与尿素代谢和转运相关的基因(DUR1,2和DUR3)表达量分别提高了3.3和2.2倍。【结论】高通量筛选策略可以用于降低黄酒生产过程中氨基甲酸乙酯前体尿素的含量。由于未采用基因工程手段,避免了可能的法规问题,消费者易于接受,在发酵食品行业具有较好的应用前景。     

Metabolic Engineering of the Regulators in Nitrogen Catabolite Repression To Reduce the Production of Ethyl Carbamate in a Model Rice Wine System

Rice wine has been one of the most popular traditional alcoholic drinks in China. However, the presence of potentially carcinogenic ethyl carbamate (EC) in rice wine has raised a series of food safety issues. During rice wine production, the key reason for EC formation is urea accumulation, which occurs because of nitrogen catabolite repression (NCR) in Saccharomyces cerevisiae. NCR represses urea utilization by retaining Gln3p in the cytoplasm when preferred nitrogen sources are present. In order to increase the nuclear localization of Gln3p, some possible phosphorylation sites on the nuclear localization signal were mutated and the nuclear localization regulation signal was truncated, and the disruption of URE2 provided an additional method of reducing urea accumulation. By combining these strategies, the genes involved in urea utilization (DUR1,2 and DUR3) could be significantly activated in the presence of glutamine. During shake flask fermentations of the genetically modified strains, very little urea accumulated in the medium. Furthermore, the concentrations of urea and EC were reduced by 63% and 72%, respectively, in a model rice wine system. Examination of the normal nutrients in rice wine indicated that there were few differences in fermentation characteristics between the wild-type strain and the genetically modified strain. These results show that metabolic engineering of the NCR regulators has great potential as a method for eliminating EC during rice wine production.     

Optimization production of acid urease by <Emphasis Type="Italic">Enterobacter</Emphasis> sp. in an approach to reduce urea in Chinese rice wine

Urea in alcoholic beverages is a precursor of ethyl carbamate, which is carcinogenic. Acid urease (EC 3.5.1.5) is regarded as a good approach to scavenge the urea. The acid urease of Enterobacter sp. R-SYB082, with lower optimum pH than the widely used commercial acid urease, exhibited a urea removal rate of 66.5% in Chinese rice wine, which was higher than that of the commercial acid urease (58.9%). The production of the acid urease was optimized from 1,100 to 2,504 U L⁻¹ by an approach which includes the optimization of initial glucose concentration, the elevation of anaerobic level of the reactor by charging CO₂ and in vitro natural activation of the target enzyme by simple cold storage (4°C). These would open up the possibility for developing industrial application of this acid urease for producing high-quality Chinese rice wine.     

Analysis of volatile aroma constituents of wine produced from Indian mango (<Emphasis Type="Italic">Mangifera indica</Emphasis> L.) by GC-MS

Volatile aroma compounds are synthesized by wine yeast during wine fermentation. In this study the volatile aroma composition of two varieties of mango wine were determined to differentiate and characterize the wines. The wine was produced from the fruits of two varieties of mango cultivars namely Banginapalli and Alphonso. The volatile compounds formed in mango wine were analyzed by gas chromatography coupled with mass spectrometry (GC-MS). Thirty-two volatile compounds in wines were determined of which four were new and unidentified present in lower concentration. Apart from the ethanol (8.5 ± 0.28 and 7.2 ± 0.28% v/v), 1-propanol (54.11 ± 0.33 and 42.32 ± 0.57 mg/l), isobutyl alcohol (102 ± 1.57 and 115.14 ± 2.88 mg/l) and isoamyl alcohol (123 ± 2.88 and 108.40 ± 0.23 mg/1) were found to be the major flavouring higher alcohols in the mango wines produced from the fruits of Banginapalli and Alphonso respectively. Ethyl acetate (35 ± 0.57 and 30.42 ±1.15 mg/l) was the major ester component in both wines produced. Besides, other esters like ethyl octonoate, ethyl hexanoate and ethyl decanoate were also present in the wines. Cyclohexane methanol (1.45 ± 0.11 mg/l) was present only in wine made from Banginapalli and β-phenylethyl butanoate (0.62 ± 0.01 mg/1) was found only in Alphonso wine. The results demonstrate that the wine prepared from Banginapalli variety had better aroma composition and good taste than that from the Alphonso variety.     

The Concentration of Ethyl Carbamate in Commercial Ume (Prunus mume) Liqueur Products and a Method of Reducing It

The ethyl carbamate concentration of commercial ume liqueur products was studied, and a method of reducing it was examined from the viewpoint of antioxidation. The average ethyl carbamate concentration across 38 ume liqueur products was 0.12 mg/l (0.02–0.33 mg/l). When potassium metabisulfite was added to a concentration of 0–1,000 ppm during production, the generation of ethyl carbamate was reduced in a concentration-dependent manner, but when the amount of potassium metabisulfite added was below the maximum level allowed under the Japanese Food Sanitation Act, the reduction was only 27%. When ume liqueurs were produced under deoxygenated conditions created using an oxygen absorber, the ethyl carbamate concentration was reduced by up to 47% as compared with the control group, probably due mainly to a reduction in free hydrogen cyanide. When ume liqueur was produced in an oxygen atmosphere, the ethyl carbamate concentration increased by up to 50% as compared with the control group. Thus, oxygen may be involved in the generation of ethyl carbamate in ume liqueur production.     

Mutant isolation of non-urea producing sake yeast by positive selection

Urea is reported to be a main precursor in wine and sake (Japanese rice wine) of ethyl carbamate (ECA), a suspected carcinogen. We constructed an arginase-deficient mutant (Δcar1/Δcar1) from a diploid sake yeast, Kyokai no. 9, using a gene disruption method (Kitamoto, K. et al., Appl. Environ. Microbiol., 57, 301, 1991). The car1 mutant thus constructed enabled us to brew sake containing no urea or ECA. In spite of their superior characteristics, industrial use of mutants for sake brewing has so far been difficult because guidelines for recombinant DNA utilization in the food and beverages industry have not yet been established. Using the genetically engineered car1 mutant, we have developed a new medium for the positive selection of car1 mutants. Many arginase-deficient mutants could be easily isolated from not only a laboratory haploid strain (X2180-1A), but also sake yeasts (Kyokai no. 9 and Kyokai no 10) and wine yeasts (Geisenheim 74 and Eperney). Sake with no urea could be brewed using the car1 mutants, and no ECA was detected in the resulting sake even after heat treatment (hi-ire) and storage.     

Degradation of malic acid in wine by immobilized Issatchenkia orientalis cells with oriental oak charcoal and alginate

Aims: To test degradation of malic acid content in wine by immobilized Issatchenkia orientalis KMBL 5774 cells recently isolated from Korean wine pomace as a malic acid‐degrading yeast. Methods and Results: I. orientalis KMBL 5774 cells were immobilized using a mixture of oriental oak (Quercus variabilis) charcoal with sodium alginate. When the immobilized yeast cells were observed on a scanning electron microscope, cells were efficiently immobilized on the surface area of the charcoal. A Korean wine containing a high level of malic acid was treated with the immobilized yeast cells. The HPLC analysis of the malic acid content in the treated wine showed the malic acid content was reduced to 0·75 mg ml^?1 after treatment from the original content of 8·96 mg ml^?1, representing 91·6% of the malic acid was degraded during the treatment. Conclusions: The immobilization of the malic acid‐degrading yeasts with oriental oak charcoal and sodium alginate is useful for degradation of malic acid in wines containing a high level of malic acid with no significant increase in other acids. Significance and Impact of the study: Malic acid is sometimes detrimental to the quality of wines when present at high concentrations in some varieties. The immobilized I. orientalis KMBL5774 cells appear to be a promising candidate in view of developing biotechnological methods for reduction of malic acid contents in wine.     

Yeast strain effect on the concentration of major volatile compounds and sensory profile of wines from Vitis vinifera var. Treixadura

The fermentative ability of five Saccharomyces cerevisiae strains and their influence on the aroma and sensory properties of wine from Treixadura were evaluated to determine the most suitable yeast that produces a high quality wine from this grapevine variety. The results indicated that all strains, except T2, were able to lead the vinification process and have good fermentative powers. The chemical composition of wines obtained with resident cellar yeasts consisted of a significant amount of glycerol, a compound that contributes to the structure and smoothness in taste of the wine. In addition, these strains were good producers of acetates, ethyl esters and fatty acids, compounds that positively influence wine aroma. Compounds with a direct contribution to the aroma of Treixadura wines (Odour Activity Value >1) included 2-methyl-1-butanol, 3-methyl-1-butanol, 2-phenylethanol, isoamyl and ethyl acetate and the ethyl esters, ethyl butyrate, ethyl hexanoate, ethyl octanoate and ethyl decanoate. Sensory analysis supported the fact that cellar strains produced more fruity and floral wines than commercial or spontaneous fermentations. We conclude that resident cellar yeasts enhanced sensory quality of wines from Treixadura.     

Effects of acetic acid, ethanol, and SO2 on the removal of volatile acidity from acidic wines by two Saccharomyces cerevisiae commercial strains

Herein, we report the influence of different combinations of initial concentration of acetic acid and ethanol on the removal of acetic acid from acidic wines by two commercial Saccharomyces cerevisiae strains S26 and S29. Both strains reduced the volatile acidity of an acidic wine (1.0 g l⁻¹ acetic acid and 11% (v/v) ethanol) by 78% and 48%, respectively. Acetic acid removal by strains S26 and S29 was associated with a decrease in ethanol concentration of 0.7 and 1.2% (v/v), respectively. Strain S26 revealed better removal efficiency due to its higher tolerance to stress factors imposed by acidic wines. Sulfur dioxide (SO₂) in the concentration range 95–170 mg l⁻¹ inhibits the ability of both strains to reduce the volatile acidity of the acidic wine used under our experimental conditions. Therefore, deacidification should be carried out either in wines stabilized by filtration or in wines with SO₂ concentrations up to 70 mg l⁻¹. Deacidification of wines with the better performing strain S26 was associated with changes in the concentration of volatile compounds. The most pronounced increase was observed for isoamyl acetate (banana) and ethyl hexanoate (apple, pineapple), with an 18- and 25-fold increment, respectively, to values above the detection threshold. The acetaldehyde concentration of the deacidified wine was 2.3 times higher, and may have a detrimental effect on the wine aroma. Moreover, deacidification led to increased fatty acids concentration, but still within the range of values described for spontaneous fermentations, and with apparently no negative impact on the organoleptical properties.     

Brettanomyces bruxellensis evolution and volatile phenols production in red wines during storage in bottles

Aims: The presence of Brettanomyces bruxellensis is an important issue during winemaking because of its volatile phenols production capacities. The aim of this study is to provide information on the ability of residual B. bruxellensis populations to multiply and spoil finished wines during storage in bottles. Methods and Results: Several finished wines were studied. Brettanomyces bruxellensis populations were monitored during two and a half months, and volatile phenols as well as chemical parameters regularly determined. Variable growth and volatile phenols synthesis capacities were evidenced, in particularly when cells are in a noncultivable state. In addition, the volatile phenol production was clearly shown to be a two‐step procedure that could strongly be correlated to the physiological state of the yeast population. Conclusions: This study underlines the importance of minimizing B. bruxellensis populations at the end of wine ageing to reduce volatile phenols production risk once the wine in bottle. Moreover, the physiological state of the yeast seems to have an important impact on ethyl‐phenols production, hence demonstrating the importance of taking into account this parameter when analysing wine spoilage risks. Significance and Impact of the Study: Little data exist about the survival of B. bruxellensis once the wine in bottle. This study provides information on the alteration risks encountered during wine storage in bottle and reveals the importance of carrying on further studies to increase the knowledge on B. bruxellensis physiology.     

鲁氏接合酵母对酱油中氨基甲酸乙酯前体物的代谢

【目的】研究鲁氏接合酵母氮源代谢特性,确定鲁氏接合酵母氮源代谢与酱油中氨基甲酸乙酯前体物瓜氨酸和尿素积累的关系。【方法】通过单一氮源培养、偏好型氮源培养和盐胁迫培养,检测不同条件下鲁氏接合酵母对精氨酸、瓜氨酸和尿素的代谢能力。【结果】通过对鲁氏接合酵母氨基酸利用能力的分析,确定了甘氨酸、丙氨酸和天冬酰胺3种氨基酸为鲁氏接合酵母的偏好型氮源。在偏好型氮源存在时,鲁氏接合酵母对尿素和瓜氨酸的利用并不受到抑制,丙氨酸和甘氨酸还能够促进对二者的利用。鲁氏接合酵母在单一氮源培养条件下不会降解精氨酸而积累尿素和瓜氨酸,反而可以大量利用氨基甲酸乙酯的前体物尿素和瓜氨酸。但在盐胁迫下,鲁氏接合酵母利用尿素和瓜氨酸受到阻遏,从而造成酱油中氨基甲酸乙酯前体物不能被充分利用而积累。【结论】盐胁迫阻遏了鲁氏接合酵母对瓜氨酸和尿素的利用,从而造成酱油发酵过程中耐盐细菌所产生的氨基甲酸乙酯前体物的积累。     

STUDY ON SENSORY AND COMPOSITION CHANGES IN ITALIAN AMARONE VALPOLICELLA RED WINE DURING AGING

Amarone is a red wine produced with a technique already known to the ancient Romans, based on withered grapes and a slow fermentation. Amarone is now considered to be one of the great Italian wines and it is exported all over the world. Sensory and compositional analyses were carried out to describe the profile of the Amarone over four vintages (1998–2001) at different stages of aging. All wines were analyzed for titratable and volatile acidity, pH, alcohol content, residual sugars, t‐resveratrol, antioxidant power, color, tonality, total polyphenols and anthocyans. Twelve trained people evaluated aroma and flavor attributes of all the wines in triplicate in a sensory session. Principal component analysis (PCA) of chemical, physical and sensory data for Amarone wine allowed us to highlight the differences between the wines. In general, the 1998 and 1999 vintages had higher aroma and flavor of Wood and Alcohol than the 2000 vintage, which, on the other hand, had higher aroma and flavor of Liquor and Cherry in alcohol. In contrast, the younger wine (2001 vintage) was the more Astringent and had many polyphenols and anthocyans, distinctive features for a red wine that has been in the cask for a short time.     

Characterization of yakju brewed from glutinous rice and wild-type yeast strains isolated from nuruks

Korean traditional rice wines yakju and takju are generally brewed with nuruk as the source of the saccharogenic enzymes by natural fermentation. To improve the quality of Korean rice wine, the microorganisms in the nuruk need to be studied. The objective of this research was to improve the quality of Korean wine with the wild-type yeast strains isolated from the fermentation starter, nuruk. Only strain YA-6 showed high activity in 20% ethanol. Precipitation of Y89-5-3 was similar to that of very flocculent yeast (?80%) at 75.95%. Using 18S rRNA sequencing, all 10 strains were identified as Saccharomyces cerevisiae. Volatile compounds present in yakju were analyzed by gas chromatography-mass selective detector. The principal component analysis (PCA) of the volatile compounds grouped long-chain esters on the right side of the first principal component, PC1; these compounds were found in yakju that was made with strains YA-6, Y89-5-3, Y89-5- 2, Y90-9, and Y89-1-1. On the other side of PC1 were short-chain esters; these compounds were found in wines that were brewed with strains Y183-2, Y268-3, Y54-3, Y98-4, and Y88-4. Overall, the results indicated that using different wild-type yeast strains in the fermentation process significantly affects the chemical characteristics of the glutinous rice wine.     

Reduced production of ethyl carbamate for wine fermentation by deleting <Emphasis Type="Italic">CAR1</Emphasis> in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Ethyl carbamate (EC), a pluripotent carcinogen, is mainly formed by a spontaneous chemical reaction of ethanol with urea in wine. The arginine, one of the major amino acids in grape musts, is metabolized by arginase (encoded by CAR1) to ornithine and urea. To reduce the production of urea and EC, an arginase-deficient recombinant strain YZ22 (Δcarl/Δcarl) was constructed from a diploid wine yeast, WY1, by successive deletion of two CAR1 alleles to block the pathway of urea production. The RT-qPCR results indicated that the YZ22 almost did not express CAR1 gene and the specific arginase activity of strain YZ22 was 12.64 times lower than that of parent strain WY1. The fermentation results showed that the content of urea and EC in wine decreased by 77.89 and 73.78 %, respectively. Furthermore, EC was forming in a much lower speed with the lower urea during wine storage. Moreover, the two CAR1 allele deletion strain YZ22 was substantially equivalent to parental strain in terms of growth and fermentation characteristics. Our research also suggested that EC in wine originates mainly from urea that is produced by the arginine.     

Effect of fermentation, aging and thermal storage on total glycosides, phenol-free glycosides and volatile compounds of White Riesling (Vitis vinifera L.) wines

There is growing recognition of the significance of the products of glycoside hydrolysis to varietal wine aroma. White Riesling wines were produced from four strains of Saccharomyces cerevisiae. Wines underwent conventional aging or anaerobic thermal storage (20 days at 45°C) either 2 or 40 months post-fermentation to quantify influences on total glycosides, phenol-free glycosides and selected volatiles. Glycoside and free volatile concentrations were estimated by analysis of glycosyl-glucose and gas chromatography/mass spectrometry, respectively. Thermal storage of wines 2 months post-fermentation reduced the total glycosides by an average of 33% for all yeasts and increased the concentration of free benzyl alcohol while decreasing the concentration of free linalool and geraniol. Conventional aging for 40 months reduced the total and phenol-free glycosides equally among yeasts by an average of 60%, with phenol-free glycosides averaging 80% of the total. Thermal storage of aged wines reduced the total glycoside concentration by an additional 29%. The effect of thermal storage on selected volatile phenols, higher alcohols, esters, acids, terpenes, carbonyl compounds, C-13 norisoprenoids and six-carbon alcohols was variable depending upon the component. Received 29 September 1998/ Accepted in revised form 16 January 1999     

Typing of human and bovine Staphylococcus aureus by RAPD-PCR and ribotyping-PCR

AIMS : The aim of this study was to investigate the production of ethyl carbamate (EC) precursors by Lactobacillus hilgardii in model and Douro fortified wines and to determine the relationship between these compounds and EC levels in this type of wine. METHODS AND RESULTS: Several model fortified wines and fortified wine inoculated with L. hilgardii were analysed for citrulline and EC formation. A good correlation (R > 0.9) was obtained between citrulline and potential EC (that EC which is formed during heating of sample at 80 degrees C for 48 h). CONCLUSIONS: This correlation allowed us to calculate the potential EC formed during lactic acid bacteria activity in fortified wine. SIGNIFICANCE AND IMPACT OF THE STUDY: A good correlation was obtained (R=0.92) between measured and calculated EC in spoiled fortified wines, citrulline apparently being the main EC precursor produced by Lact. hilgardii thus contributing to the potential EC in this type of wine.     

Determination of free sulphite in wine using a microbial sensor

Summary A microbial sensor of immobilized Thiobacillus thiooxidans S3 cells was assembled to determine free sulphite in wine. Sulphite oxidation activity of the immobilized cells was sufficiently high for use even after 3 months storage at 4° C. The sensitivity of this sensor was 116 nA·1·mg^-1 for sulphur dioxide. The relationship between the current decrease and the sulphur dioxide concentration was linear up to 17 mg·1^-1. The sampling rate achieved was 10 min per sample including washing time. This sensor method needed no pretreatment of wine samples, and wines diluted with 5 mM sulphuric acid solution could be directly introduced in the computer-aided analysis system. The pigments in red wine did not disturbed the analysis.     

Conservation of urea-N by immobilization-remobilization in a rice-Azolla intercrop

Nitrogen losses are notoriously high in flooded rice fertilized with urea. An Azolla intercrop can reduce such losses by immobilizing urea-N during periods of potentially high N-loss. The reduction in N loss linked with the absorption and remobilization of urea-N by Azolla, was studied in two greenhouse experiments conducted in Goettingen (Germany). Grain yield and N recovery were positively influenced by Azolla more than doubling grain yield and N uptake as compared to the split application of 300 mg N pot^–1 alone (Exp. 1). In the second experiment, the yield increase was 78.3% with single applications of 97.5 and 68.4% after a split-application of a total of 195 mg N pot^–1. In both years the effect of urea and Azolla combined exceeded that of the sum of the factors alone, a clear positive synergistic effect on yield and N uptake by rice. Azolla effectively competed with the young rice plants for applied urea, capturing nearly twice the urea-N than the rice plants up to tillering in experiment 1. In the second experiment, 64.6 mg N of the 97.5 mg applied early in the season was immobilized by Azolla within 2 weeks. This represented 63.1% of the total N accumulated in the Azolla. The fraction of Azolla-N derived from urea sank to 36.4 mg within 4 weeks and only 27.2 mg at maximum tillering as a result of Azolla senescence and N-release. Of this 64.6 mg urea N immobilized 28.7% is eventually taken up by the standing rice plant, representing 43.1% of the remineralized, urea-derived Azolla N. Following the second urea application, only 17.9 mg N were immobilized in the Azolla biomass during the 2 weeks, of which 6.9 mg pot^–1 were still retained in the Azolla at maturity. At this stage, rice is the more effective competitor for applied N. As much as 42.1% of this immobilized N finds its way into the rice by maturity. Thus, Azolla contributed to the conservation of N in the system, particularly of the urea applied early in the season. Loss of N from the system amounted to no more than 15%. Although the early-applied N directly recovered by the rice plant was low (20%), 2/3 of the N captured by Azolla following this first urea application was released to the system by the time of rice harvest, over 40% of which was available to the rice plant. Azolla thus appears to act as a slow release fertilizer.     

Establishment of stable NaCl-resistant rice plant lines from anther culture: distribution pattern of K+/Na+ in callus and plant cells

 Soil salinity markedly suppresses the growth of rice (Oryza sativa L.). We established rice anther culture to select for rice callus lines adapted to NaCl stress and regenerated plant progenies resistant to a NaCl stress of E.C. 16–18 mS. When exposed to NaCl, NaCl-adapted rice calli lost K⁺ and accumulated little Na⁺. Conversely, plant cells lost relatively little K⁺ and accumulated Na⁺. It is plausible that, NaCl-resistant mechanisms are different at callus and plant level. The stable NaCl-resistant lines produced have potential use in elucidating the molecular mechanisms behind NaCl resistance in rice and in rice breeding. Received: 27 February 1997 / Accepted: 4 April 1997