不同氯化钠浓度对Candida etchellsii CICIM Y0600生长和生物特性的影响研究

在酱油发酵过程中增香酵母的代谢产物能显著提高酱油产品的风味和品质.为了提高增香酵母菌在酱醪中的适应性,通过逐步提高氯化钠浓度的方法对酵母菌的耐盐度进行驯化培养.通过分析表明,经过5个批次的驯化,增香酵母菌的耐氯化钠浓度由180 g/L提高到240 g/L.对驯化后的三株耐不同氯化钠浓度的增香酵母菌株进行生物特性研究.结果表明,在200 g/L氯化钠浓度的培养基中,Candida etchellsii CICIM Y0600产游离氨基酸和酸解氨基酸总量分别达到2.01g/L和7.00 g/L.和其他不同氯化钠浓度条件下比较,其产有机酸种类没有变化,挥发性酯类物质含量最高,为0.80 g/L.耐盐度的提高使增香酵母菌更好地适应了在酱油发酵中的高盐度环境.     

酱醪细菌菌株的分离及功能分析

【目的】分离获得来源于酱醪的细菌,考察菌株与酱油品质相关的特性,初步评价其应用于酱油发酵的潜力。【方法】从日式酱油发酵的酱醪体系中分离和筛选优势或特征细菌菌株,比较它们的耐盐性及其在高盐条件下产蛋白酶、有机酸、挥发性物质和氨基酸等的能力。【结果】从日式酱油酱醪中共分离得到9株细菌,分别属于魏斯氏菌(Weissella)、乳酸足球菌(Pediococcus)、乳酸杆菌(Lactobacillus)、芽孢杆菌(Bacillus)、四联球菌(Tetragenococcus)和葡萄球菌(Staphylococcus)属。其中耐盐的细菌有类肠膜魏斯氏菌(Weissella paramesenteroides)CQ03、嗜酸乳酸足球菌(Pediococcus acidilactici)JY07、戊糖乳酸足球菌(Pediococcus pentosaceus)JY08、葡萄球菌(Staphylococcus sp.)JY09和嗜盐四联球菌(Tetragenococcus halophilus)MRS1。在高盐条件下,对它们的特性分析表明:解淀粉芽孢杆菌(Bacillus amyloliquefaciens)B2产蛋白酶和糖化酶的能力较强,W.paramesenteroides CQ03可水解原料产生较多鲜味氨基酸,T.halophilus MRS1产有机酸能力较强,它和S.sp.JY09代谢产生的挥发性物质较多。【结论】筛选得到9株在促进原料水解和提高风味物质合成方面有潜力的菌株,如果应用到酱油工业生产中,将有利于缩短发酵周期,提高酱油品质。     

酱醪中魏斯氏菌的分离及特性分析

【背景】魏斯氏菌广泛存在于发酵食品中,它们与食品发酵进程和风味物质的形成密切相关。酱油发酵过程酱醪中细菌的优势菌属是魏斯氏菌,研究魏斯氏菌的生理和代谢特性对于揭示菌株对环境的适应性和与酱油发酵相关的功能具有重要意义。【目的】从酱油酱醪中分离获得魏斯氏菌属中主要种的菌株,研究它们在酱油发酵过程的数量变化以及菌株的生理和生化特性,阐明菌株对酱油发酵体系的适应性和与酱油发酵相关的特性。【方法】通过菌株绝对数量的定量分析和耐受性比较,以及考察高盐条件下魏斯氏菌合成短链脂肪酸、胞外多糖、生物胺和氨基甲酸乙酯或其前体等特性,研究各类魏斯氏菌对酱油发酵和其安全性的影响。【结果】从高盐稀态酱油的酱醪中共分离得到16株魏斯氏菌,分别属于融合魏斯氏菌(Weissella confusa)、类肠膜魏斯氏菌(Weissellaparamesenteroides)和食窦魏斯氏菌(Weissellacibaria)。其中类肠膜魏斯氏菌可耐受高盐条件,是酱醪中魏斯氏菌属的主要菌种。它们合成短链脂肪酸的能力高于融合魏斯氏菌和食窦魏斯氏菌。酱醪来源的魏斯氏菌合成氨(胺)类危害物的特性区别较大,类肠膜魏斯氏菌的部分菌株产生物胺并可利用精氨酸积累瓜氨酸,食窦魏斯氏菌则能够降解多种生物胺。【结论】揭示了酱醪中主要魏斯氏菌的耐盐特性、在较低温度下生长情况和物质代谢规律,对于阐明魏斯氏菌与酱油发酵相关的功能和特性以及对酱油加工过程安全控制具有重要意义。     

Comparative Volatile Profiles in Soy Sauce According to Inoculated Microorganisms

We compared the volatile profiles in soy sauce according to inoculation with Tetragenococcus halophilus and/or Zygosaccharomyces rouxii. Totals of 107 and 81 volatiles were respectively identified by using solid-phase microextraction and solvent extraction. The various volatile compounds identified included acids, aldehydes, esters, ketones, furans and furan derivatives, and phenols. The major volatiles in the samples treated with T. halophilus were acetic acid, formic acid, benzaldehyde, methyl acetate, ethyl 2-hydroxypropanoate, 2-hydroxy-3-methyl-2-cyclopenten-1-one, and 4-hydroxy-3-methoxybenzaldehyde, while those in the samples inoculated with Z. rouxii were mainly ethanol, acetaldehyde, ethyl propanoate, 2/3-methylbutanol, 1-butanol, 2-phenylethanol, ethyl 2-methylpropanoate, and 4-hydroxy-2-ethyl-5-methyl-3(2H)-furanone. The results indicate that T. halophilus produced significant acid compounds and could affect the Z. rouxii activity, supporting the notion that yeasts and lactic acid bacteria respectively have different metabolic pathways of alcoholic fermentation and lactic acid fermentation, and produce different dominant volatile compounds in soy sauce.     

Bioconversion of ferulic acid to 4-vinylguaiacol and 4-ethylguaiacol and of 4-vinylguaiacol to 4-ethylguaiacol by halotolerant yeasts belonging to the genus Candida

In order to examine the genesis of the characteristic flavors of soy sauce and miso, seven novel halotolerant yeast strains of two types, which showed convertibility of ferulic acid (FA) to 4-vinylguaiacol (4-VG) and to 4-ethylguaiacol (4-EG), were isolated from miso-koji and miso pastes. Two of these strains were identified as Candida guilliermondii (anamorph of Pichia guilliermondii), and Candida fermentati (anamorph of Pichia caribbica), based on sequence analyses of a partial 26S ribosomal RNA gene and the region of internal transcribed spacers 1 and 2, and the 5.8S ribosomal RNA gene. Moreover, we also found three Candida etchellsii strains which showed convertibility of FA to 4-VG, but not to 4-EG, and two atypical strains of Candida versatilis which showed no convertibility of FA to 4-VG, but did show convertibility of 4-VG to 4-EG from soy sauce mashes. The bioconversion pathway from FA to 4-EG via 4-VG in halotolerant yeasts and bacteria is discussed.     

An unstructured kinetic model to study NaCl effect on volatile ester fermentation by <Emphasis Type="Italic">Candida etchellsii</Emphasis> for soy sauce production

Salt-tolerant aromatic yeast is an important microorganism arising from the solid state fermentation of soy sauce. The fermentation kinetics of volatile esters by Candida etchellsii was studied in a batch system. The data obtained from the fermentation were used for determining the kinetic parameters of the model. Batch experimental results at four NaCl levels (180, 200, 220, and 240 g/L) were used to formulate the parameter estimation model. The kinetic parameters of the model were optimized by specifically designed Runge-Kutta Genetic Algorithms (GA). The resulting mathematical model for volatile ester production, cell growth and glucose consumption simulates the experimental data well. The resulting new model was capable of explaining the behavior of volatile ester fermentation. The optimized parameters (μ_o, X _max, K _i, α, β, Y _X/S, m, and Y _P/S) were characterized by a correlation of functions assuming salinity dependence. The kinetic models optimized by GA describe the batch fermentation process adequately, as demonstrated by our experimental results.     

Isolation and characterization of Halomonas sp. strain IMPC, a p-coumaric acid-metabolizing bacterium that decarboxylates other cinnamic acids under hypersaline conditions

A moderately halophilic, mesophilic, Gram-negative, motile, nonsporulating bacterium, designated strain IMPC, was isolated from a table-olive fermentation rich in aromatic compounds, after enrichment on p-coumaric acid under halophilic conditions. Strain IMPC was able to degrade p-coumaric acid. p-hydroxybenzaldehyde and p-hydroxybenzoic acid were detected as breakdown products from p-coumaric acid. Protocatechuic acid was identified as the final aromatic product of p-coumaric acid catabolism before ring fission. Strain IMPC transformed various cinnamic acids with substituent H, OH, CH(3) or OCH(3) in the para- and/or meta-position of the aromatic ring to the corresponding benzoic acids, indicating a specific selection. A beta-oxidation pathway was proposed for these transformations. Phylogenetic analysis of the 16S rRNA gene revealed that this isolate was a member of the genus Halomonas. Strain IMPC was closely related to Halomonas elongata ATCC 33173(T)and Halomonas eurihalina ATCC 49336(T).     

Identification and typing of miso and soy sauce fermentation yeasts, Candida etchellsii and C. versatilis, based on sequence analyses of the D1D2 domain of the 26S ribosomal RNA gene, and the region of internal transcribed spacer 1, 5.8S ribosomal RNA gene and internal transcribed spacer 2

We analyzed sequences of the D1D2 domain of the 26S ribosomal RNA gene (26S rDNA sequence), and the region of internal transcribed spacer 1, 5.8S ribosomal RNA gene and internal transcribed spacer 2 (ITS sequence) of the miso and soy sauce fermentation yeasts, Candida etchellsii and Candida versatilis, in order to evaluate the usefulness of this sequence analysis for identification and typing of these two species. In the 26S rDNA sequence method, the numbers of base substitutions among C. etchellsii strains were up to 2 in 482 bp (99.6% similarity), and they were divided into three types (types A, B, and C). Those of C. versatilis strains were also up to 2 in 521 bp (99.6% similarity) and they were divided into three types (types 1, 2, and 3). In the ITS sequence method, those of C. etchellsii strains were zero in 433 bp (type a, 100% similarity). Those of C. versatilis were 5 in 409 bp (98.8% similarity), divided into 4 types (types I, II, III and IV). It was found that molecular methods based on the sequences of the 26S rDNA D1D2 domain and the ITS region were rapid and precise compared with the physiological method for the identification and typing of these two species.     

Development of a glutathione production process from proteinaceous biomass resources using protease-displaying <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Glutathione is a valuable tri-peptide that is widely used in the pharmaceutical, food, and cosmetic industries. Glutathione is produced industrially by fermentation using Saccharomyces cerevisiae, and supplementation of fermentation with several amino acids can increase intracellular GSH content. More recently, however, focus has been given to protein as a resource for biofuel and fine chemical production. We demonstrate that expression of a protease on the cell surface of S. cerevisiae enables the direct use of keratin and soy protein as a source of amino acids and that these substrates enhanced intracellular GSH content. Furthermore, fermentation using soy protein also enhanced cell concentration. GSH fermentation from keratin and to a greater extent from soy protein using protease-displaying yeast yielded greater GSH productivity compared to GSH fermentation with amino acid supplementation. This protease-displaying yeast is potentially applicable to a variety of processes for the bio-production of value-added chemicals from proteinaceous biomass resources.     

采用代谢组学分析技术分析工业啤酒发酵过程中风味物质生成规律

啤酒风味是保证啤酒品质的关键因素之一。运用代谢组学的方法,分析工业啤酒发酵过程中酵母胞内代谢物和啤酒风味物质的对应关系,从代谢水平上研究风味物质形成过程中的关键影响因素。在啤酒发酵过程中,同时检测风味物质的含量变化和酵母胞内代谢物的变化,对得到海量的、多维的代谢数据采用主成分分析（PCA）和偏最小二乘分析（PLS）的多元统计分析方法进行处理。由PCA分析结果可知：磷酸、海藻糖、琥珀酸、谷氨酸、天冬氨酸、丙氨酸对主成分贡献比较大,说明这些代谢物在不同发酵阶段含量变化显著。由PLS分析结果可知：对啤酒风味影响最大的物质主要为氨基酸,包括丝氨酸、缬氨酸、苏氨酸、赖氨酸、丙氨酸、亮氨酸和天冬酰胺等,这为啤酒中风味物质的调控提供了一定的理论指导。     

Halobacterium sp. SP1(1) as a starter culture for accelerating fish sauce fermentation

Aims: Application of Halobacterium sp. SP1(1) for the acceleration of fish sauce fermentation. Methods and Results: Traditional fish sauce fermentation was mimicked using Halobacterium sp. SP1(1) as starter culture. Protease activity, peptide release and α‐amino content (parameters used to monitor the progress of the fermentation) were high at day 10 in tests and day 20 in un‐inoculated controls. The total protein and nitrogen contents were also high in tests compared with controls. The amino acid profile observed at the end of fermentation in experimental samples, when compared with the commercial sauce preparation, was found to be better with respect to flavour and aroma contributing amino acids as well as essential amino acid lysine. Microflora analysis of the final fish sauce revealed the absence of any nonhalophilic or halotolerant micro‐organisms. The protease‐producing halophilic isolates obtained from the fish sauce of eviscerated and uneviscerated controls were identified as Halobacterium sp. F1 and F2, respectively, by 16S rDNA sequence analysis. Conclusions: Exogenous augmentation of Halobacterium sp. SP1(1) accelerated the fish sauce fermentation process with an additive effect on the existing natural microflora present in the fish during fermentation. Halobacterium sp SP1(1), therefore, can be used as an important starter culture for accelerating the fish fermentation process, which is attributed to its extracellular protease. Significance and Impact of the Study: The present study is the first report on use of Halobacterium species as a starter culture for accelerating fish sauce fermentation. Use of halobacterial starter cultures may revolutionize the process in fish sauce industries by reducing the fermentation time and making the process more economical with improved nutritive value of product.     

Characterization of ethanol fermentation waste and its application to lactic acid production by Lactobacillus paracasei

In this study, an ethanol fermentation waste (EFW) was characterized for use as an alternative to yeast extract for bulk fermentation processes. EFW generated from a commercial plant in which ethanol is produced from cassava/rice/wheat/barley starch mixtures using Saccharomyces cerevisiae was used for lactic acid production by Lactobacillus paracasei. The effects of temperature, pH, and duration on the autolysis of an ethanol fermentation broth (EFB) were also investigated. The distilled EFW (DEFW) contained significant amounts of soluble proteins (2.91 g/l), nitrogen (0.47 g/l), and amino acids (24.1 mg/l). The autolysis of the EFB under optimum conditions released twice as much amino acids than in the DEFW. Batch fermentation in the DEFW increased the final lactic acid concentration, overall lactic acid productivity, and lactic acid yield on glucose by 17, 41, and 14 %, respectively, in comparison with those from comparable fermentation in a lactobacillus growth medium (LGM) that contained 2 g/l yeast extract. Furthermore, the overall lactic acid productivity in the autolyzed then distilled EFW (ADEFW) was 80 and 27 % higher than in the LGM and DEFW, respectively.     

Isolation and Characterization of Neutral Peptides in Soy Sauce

A soy sauce sample was fractionated by gel filtration on a Sephadex G–15 column, then the fractions were subfractionated on the basis of acidity by ion exchange chromatography on a QAE-Sephadex A–25 column. After preliminary fractionation, the components in the neutral subfractions were transformed to copper salts, and the salts were chromatographed on a DEAE-Sephadex A–25 column with a borate buffer and aqueous acetic acid to separate neutral peptide substances from a large amount of free amino acids. The peptide fractions were further fractionated on a preparative amino acid analyzer and by paper chromatography to separate the peptide substances.

Three glycodipeptides and eight dipeptides were isolated and characterized as the major neutral peptide components in soy sauce. However, it was difficult to anticipate any direct contribution of these peptides to the flavor construction in soy sauce on the basis of their taste intensities and contents.     

Effect of threonine, cystathionine, and the branched-chain amino acids on the metabolism of Zygosaccharomyces rouxii*

Zygosaccharomyces rouxii is an important yeast in the formation of flavor in soy sauce. In this study, we investigated the separate effects of exogenous threonine, cystathionine, and the branched-chain amino acids on the metabolism of Z. rouxii. The addition of these amino acids had significant effects on both Z. rouxii growth and glycerol and higher alcohol production. It also seemed that Z. rouxii displayed the Crabtree effect, which was independent of the added amino acids. Furthermore, we investigated the regulation of the metabolism of alpha-ketobutyrate, which is a key-intermediate in Z. rouxii amino acid metabolism. Threonine and cystathionine were introduced separately to stimulate the formation rate of alpha-ketobutyrate and the branched-chain amino acids to inhibit its conversion rate. Enzyme activities showed that these amino acids had a significant effect on the formation and conversion rate of alpha-ketobutyrate but that the alpha-ketobutyrate pool size in Z. rouxii was in balance all the time. The latter was confirmed by the absence of alpha-ketobutyrate accumulation.     

Esterase activity in soy sauce Moromi as a factor hydrolyzing flavor esters

In order to elucidate the reason for the meager occurrence of volatile esters in soy sauce, the ester-decomposing activities of microorganisms concerned in soy sauce fermentation were examined. Soy yeasts showed at least 10 times higher esterase activity than the other yeasts used for fermented beverages. The yeast esterase was not greatly affected by the pH or NaCl concentration. Soy koji cultured with Aspergillus sojae or A. oryzae showed very high ester-splitting activity. By gel-filtration of koji esterase, the i-amylacetate (i-AmAc) decomposing fraction was obtained. This fraction showed a decrease of activity at lower pH or higher NaCl concentration. Koji esterase decreased its activity in moromi but remained over the entire moromi period. Koji esterase exhibited a higher activity than yeast esterase in fermenting moromi. These strong esterase activities are thought to be one of the causes of the low concentration of ester flavor in soy sauce.     

Potential inhibitors from wet oxidation of wheat straw and their effect on growth and ethanol production by Thermoanaerobacter mathranii

Alkaline wet oxidation (WO) (using water, 6.5 g/l sodium carbonate, and 12 bar oxygen at 195 degrees C) was used for pre-treating wheat straw (60 g/l), resulting in a hemicellulose-rich hydrolysate and a cellulose-rich solid fraction. The hydrolysate consisted of soluble hemicellulose (9 g/l), aliphatic carboxylic acids (6 g/l), phenols (0.27 g/l or 1.7 mM), and 2-furoic acid (0.007 g/l). The wet-oxidized wheat straw hydrolysate caused no inhibition of ethanol yield by the anaerobic thermophilic bacterium Thermoanaerobacter mathranii. Nine phenols and 2-furoic acid, identified to be present in the hydrolysate, were each tested in concentrations of 10-100x the concentration found in the hydrolysate for their effect on fermentation by T. mathranii. At 2 mM, these aromatic compounds were not inhibitory to growth or ethanol yield in T. mathranii. When the concentration of aromatics was increased to 10 mM, the fermentation was severely inhibited by the phenol aldehydes and to a lesser extent by the phenol ketones. By adding the same aromatic compounds to WO hydrolysate (10 mM), synergistic inhibitory effects of all tested compounds with hydrolysate components were shown. When the hydrolysate was concentrated three- and six-fold, growth and fermentation with T. mathranii were inhibited. At a six-fold hydrolysate concentration, the total concentration of phenolic monomers was 17 mM; hence aromatic monomers are an important co-factor in hydrolysate inhibition.     

Effects of the addition of different nitrogen sources in the tequila fermentation process at high sugar concentration

AIMS: To study the effect of the addition of different nitrogen sources at high sugar concentration in the tequila fermentation process. METHODS AND RESULTS: Fermentations were performed at high sugar concentration (170 g l(-1)) using Agave tequilana Weber blue variety with and without added nitrogen from different sources (ammonium sulfate; glutamic acid; a mixture of ammonium sulfate and amino acids) during the exponential phase of growth. All the additions increased the fermentation rate and alcohol efficiency. The level of synthesis of volatile compounds depended on the source added. The concentration of amyl alcohols and isobutanol were decreased while propanol and acetaldehyde concentration increased. CONCLUSIONS: The most efficient nitrogen sources for fermentation rate were ammonium sulfate and the mixture of ammonium sulfate and amino acids. The level of volatile compounds produced depended upon types of nitrogen. The synthesis of some volatile compounds increased while others decreased with nitrogen addition. SIGNIFICANCE AND IMPACT OF THE STUDY: The addition of nitrogen could be a strategy for improving the fermentation rate and efficiency in the tequila fermentation process at high sugar Agave tequilana concentration. Furthermore, the sensory quality of the final product may change because the synthesis of the volatile compounds is modified.     

Conversion of amino acids into aroma compounds by cell-free extracts of Lactobacillus helveticus

AIMS: Lactobacillus helveticus is an essential starter in Swiss-type cheeses such as Emmental. This study was to determine whether cell-free extracts of Lact. helveticus were able to convert free amino acids into neutral volatile aroma compounds at the pH and temperature occurring in cheese. METHODS AND RESULTS: A mix of branched-chain (Leu, Ile, Val), aromatic (Tyr, Phe) and sulphur (Met) amino acids was incubated for 7 days, at pH 5.7 and 24 degrees C, with cell-free extracts of six strains. The amino acids were all transaminated into the corresponding keto acids when an amino group acceptor (alpha-ketoglutaric acid) was provided. Phe and Tyr were transaminated the most efficiently, followed by Leu, Met, Ile and Val. Three major volatile compounds were detected by GC-MS: benzaldehyde, dimethyl disulphide and 2-methyl propanol. Whatever the strain, benzaldehyde was produced in the highest quantity (0.25-1 micromol l(-1) mg(-1) protein). CONCLUSIONS, SIGNIFICANCE AND IMPACT OF THE STUDY: Lactobacillus helveticus intracellular enzymes could significantly contribute to the production of aroma compounds from amino acid catabolism.     

An aminotransferase from Lactococcus lactis initiates conversion of amino acids to cheese flavor compounds.

The enzymatic degradation of amino acids in cheese is believed to generate aroma compounds and therefore to be involved in the complex process of cheese flavor development. In lactococci, transamination is the first step in the degradation of aromatic and branched-chain amino acids which are precursors of aroma compounds. Here, the major aromatic amino acid aminotransferase of a Lactococcus lactis subsp. cremoris strain was purified and characterized. The enzyme transaminates the aromatic amino acids, leucine, and methionine. It uses the ketoacids corresponding to these amino acids and alpha-ketoglutarate as amino group acceptors. In contrast to most bacterial aromatic aminotransferases, it does not act on aspartate and does not use oxaloacetate as second substrate. It is essential for the transformation of aromatic amino acids to flavor compounds. It is a pyridoxal 5'-phosphate-dependent enzyme and is composed of two identical subunits of 43.5 kDa. The activity of the enzyme is optimal between pH 6.5 and 8 and between 35 and 45 degrees C, but it is still active under cheese-ripening conditions.     

Parameters Affecting Ethyl Ester Production by Saccharomyces cerevisiae during Fermentation

Volatile esters are responsible for the fruity character of fermented beverages and thus constitute a vital group of aromatic compounds in beer and wine. Many fermentation parameters are known to affect volatile ester production. In order to obtain insight into the production of ethyl esters during fermentation, we investigated the influence of several fermentation variables. A higher level of unsaturated fatty acids in the fermentation medium resulted in a general decrease in ethyl ester production. On the other hand, a higher fermentation temperature resulted in greater ethyl octanoate and decanoate production, while a higher carbon or nitrogen content of the fermentation medium resulted in only moderate changes in ethyl ester production. Analysis of the expression of the ethyl ester biosynthesis genes EEB1 and EHT1 after addition of medium-chain fatty acid precursors suggested that the expression level is not the limiting factor for ethyl ester production, as opposed to acetate ester production. Together with the previous demonstration that provision of medium-chain fatty acids, which are the substrates for ethyl ester formation, to the fermentation medium causes a strong increase in the formation of the corresponding ethyl esters, this result further supports the hypothesis that precursor availability has an important role in ethyl ester production. We concluded that, at least in our fermentation conditions and with our yeast strain, the fatty acid precursor level rather than the activity of the biosynthetic enzymes is the major limiting factor for ethyl ester production. The expression level and activity of the fatty acid biosynthetic enzymes therefore appear to be prime targets for flavor modification by alteration of process parameters or through strain selection.