中条山野生葡萄产香酵母的筛选及其混菌发酵对葡萄酒香气成分的影响

【背景】产香酵母可赋予葡萄酒独特的香气,因此,分离筛选优良产香酵母对酿造具有地域风味的特色葡萄酒具有重要意义。【目的】从中条山野生葡萄中筛选产香酵母,进行种群鉴定和生理生化特性研究,并将其应用于葡萄酒发酵过程,研究其对葡萄酒香气成分的影响。【方法】采用稀释涂布平板法从中条山野葡萄中分离筛选酵母菌,对其进行分子生物学鉴定。优选其中具有显著香气的产香酵母,与酿酒酵母F15进行混合发酵,采用气相色谱质谱联用(gas chromatograph-mass spectrometer,GC-MS)对香气成分进行分析,采用半定量法测定香气成分含量。【结果】共分离获得各种菌株13株,26S rRNA基因D1/D2区序列分析表明它们分布于Issatchenkia、Torulaspora、Pichia、Saccharomyces和Rhodotorula等5个不同属内。优选其中一株香气较为浓郁的酵母菌株Issatchenkia orientalis strain XS-6开展研究,结果发现该菌株最高耐受乙醇浓度为8%,最高耐受NaCl浓度为6%,最适生长温度为38℃。与酿酒酵母F15混菌发酵的葡萄酒中共检测出31种香气成分。香气物质总含量较单菌发酵增加19.8%,其中11种香气成分含量增加明显,尤其是具有玫瑰香气的苯乙醇。醇类与酯类物质含量较单菌发酵增加19.6%,并发现了香草酸乙酯(ethyl vanillate)、邻苯二甲酸二丁酯(dibutyl phthalate)等7种新的酯类物质。【结论】产香酵母XS-6对乙醇、NaCl、温度等具有良好的耐受性,而且与酿酒酵母F15混菌发酵对西拉葡萄酒香气成分具有明显的影响,可能在改善葡萄酒风味方面具有潜在的应用价值。     

酒醅来源酵母菌合成异戊醇能力与途径解析

【背景】异戊醇是酵母菌在白酒发酵过程中通过氨基酸合成代谢途径和氨基酸分解代谢途径合成的主要高级醇,其含量影响白酒饮用的舒适度。【目的】分析和比较分离自浓香型白酒酒醅中的酵母菌合成异戊醇的能力,揭示酵母菌合成异戊醇的途径。【方法】从酒醅中分离具有异戊醇合成能力的酵母菌株,比较不同生长时期酵母菌合成异戊醇的能力,通过前体物代谢分析它们合成异戊醇的途径。【结果】分离自酒醅的5株酵母的异戊醇合成能力从强到弱依次为Naumovozyma castellii JP3-1、Saccharomyces cerevisiae JP3、Pichia fermentans JP22、Pichia kudriavzevii JP1和Naumovozyma dairenensis CBS421。这些酵母合成异戊醇的时期主要在对数生长期,N. castellii JP3-1、P. fermentans JP22和N. dairenensis CBS421在稳定生长期也合成异戊醇。S. cerevisiae JP3、N. castellii JP3-1和N. dairenensis CBS421在整个生长时期主要通过Harris途径合成异戊醇;P. kudriavzevii JP1在整个时期主要通过Ehrlich途径合成异戊醇;P. fermentans JP22在对数生长期通过Harris途径和Ehrlich途径合成异戊醇的能力接近,在稳定生长期主要通过Harris途径合成异戊醇。【结论】本研究揭示了酒醅来源5个属种酵母合成异戊醇的途径、能力与其生长时期的关系,研究结果可为解析浓香型白酒发酵过程异戊醇合成、积累机制及实施白酒发酵过程异戊醇合成的精准调控提供理论依据。     

宁夏贺兰山东麓葡萄酒酵母菌的筛选及应用

【背景】宁夏贺兰山东麓是中国生态最佳、酿酒葡萄质量最优产区之一,也是中国“葡萄酒地理标志产品”保护区域之一。【目的】筛选宁夏本土优良酵母菌株,比较分析各个酿酒酵母菌株对赤霞珠葡萄酒香气质量的影响,并结合感官评价筛选对葡萄酒风味影响较大的酿酒酵母菌株。【方法】将筛选出的11株起酵速度快,而且对高浓度酒精、SO₂和葡萄糖及低酸环境有较强耐受力的酵母菌株进行26S rDNA鉴定,确定酵母种类。不同酿酒酵母发酵的赤霞珠葡萄酒通过顶空固相微萃取和气相色谱-质谱联用技术测定其香气化合物。【结果】筛选出11株可在15%酒精度、500 g/L葡萄糖、350 mg/L SO₂和pH 3.0环境下生长的酵母菌株,对其进行26S rDNA鉴定,确定10株酵母菌株H5、G9、G3、X8、G14、L10、H3、X11、Z17、Z24为酿酒酵母(Saccharomyces cerevisiae),一株酵母菌L1为发酵毕赤酵母(Pichia fermentans)。测定的所有香气化合物中,酯类物质是赤霞珠葡萄酒香气物质的主要组分,其次是醇类。其中,乙酸乙酯、乙酸异戊酯、正...     

贺兰山东麓优良本土酿酒酵母筛选及发酵特性分析

【背景】商业酵母的使用造成葡萄酒同质化问题严重,发掘优良本土酿酒酵母具有十分重要的意义。【目的】从168株宁夏本土酿酒酵母菌株中筛选出性能优良、具有出色葡萄酒发酵能力的菌株。【方法】基于杜氏管发酵试验和乙醇、高糖等耐受性试验分析产H2S能力及生长曲线测定的方法,筛选出发酵力好、耐受性强、低产H2S的本土酿酒酵母进行赤霞珠葡萄酒发酵试验,测定葡萄酒样基础理化指标、酚类物质和挥发性成分,探究筛选出的酿酒酵母发酵特性。【结果】初步筛选出发酵快速,能适应13%乙醇、350 g/L葡萄糖、250 mg/L SO2、pH 1.0的生存环境且低产H2S的4株本土酿酒酵母YC-E8、QTX-D17、QTX-D7、YQY-E18。菌株YC-E8产甘油能力强,所发酵酒样香气与商业酵母XR、F33最为接近,适用于赤霞珠葡萄酒的发酵。菌株QTX-D17发酵酒样中酒精、单宁、总酚和花色苷含量最高,表现出本土酿酒酵母优良的发酵特性。菌株QTX-D7所发酵酒样香气中乙酸乙酯、辛酸乙酯、1-壬醇等物质含量较高,赋予了葡萄酒香蕉味、苹果味、菠萝味、椰子味等愉悦花果香。【结论】最终筛选出3株优良本土酿酒酵母QTX-D17...     

四川甘孜州高山葡萄酒产区酵母菌多样性分析

【背景】西南高山葡萄酒产区的甘孜州产区,具有生产优质葡萄酒的自然禀赋。【目的】研究四川甘孜州葡萄酒产区真核微生物种类多样性、本土酿酒酵母遗传多样性,以及商业酵母对本土酵母多样性的影响。【方法】利用ITS高通量测序技术对赤霞珠接种发酵和自然发酵过程中的微生物进行多样性分析,并利用Interdelta指纹图谱分析法,对经过26S rRNA基因鉴定的野生酿酒酵母基因型进行分类。【结果】ITS测序结果显示,接种发酵和自然发酵各时期均注释到7个科7个属的酵母,通过Interdelta指纹图谱分析发现甘孜州产区的酿酒酵母共有5种基因型。该产区酿酒酵母的6株代表菌株与我国其他产区109株酿酒酵母的进化树分析结果显示,均与来自北京产区的酿酒酵母菌株亲缘关系更近。【结论】甘孜州葡萄酒子产区酵母资源丰富,表现出较高的微生物多样性和中等程度的本土酿酒酵母基因型多样性,为后续优良本土酵母菌株的筛选奠定基础。     

高耐酸酒酒球菌常压室温等离子体诱变选育及其苹果酸-乳酸发酵研究

【目的】为选育出高度耐酸性酒酒球菌（Oenococcus oeni）突变菌株,研究其胁迫耐受性能及苹果酸-乳酸发酵（malolactic fermentation,MLF）能力。【方法】以酒酒球菌SD-2a为出发菌株,通过常压室温等离子体（atmospheric and room temperature plasma,ARTP）诱变技术,筛选高耐酸性酒酒球菌突变菌株,并探究其乙醇耐受性及在模拟酒和葡萄酒条件下的MLF能力。【结果】经过ARTP诱变处理后,利用pH 3.0的胁迫传代培养和分离纯化等,获得了5株β-葡萄糖苷酶活性较好的耐酸突变菌株,且在高乙醇浓度下表现出了较好的耐乙醇性。其中突变菌株ARTP-2在模拟酒中的β-葡萄糖苷酶活性和l-苹果酸累积降解量最高,且其在葡萄酒中l-苹果酸降解速率快于出发菌株,在第18天完成MLF,发酵后的葡萄酒香气成分的含量显著高于接种SD-2a的酒样。【结论】突变菌株ARTP-2具有良好的胁迫耐受性和MLF能力,对葡萄酒的香气起到积极的作用,为进一步开发优质的MLF商业发酵剂奠定基础。     

汾酒酿造车间和车间外环境中酵母菌多样性研究

为解析汾酒厂区酵母菌资源的多样性，采用分离培养方法，从汾酒酿造车间和车间外环境中的微生物中分离纯化到300株酵母菌，经26S rDNA序列比对分析，检测到酵母菌包括6科15属21种。系统发育树结果表明，汾酒酿造车间和车间外环境中的酵母菌包括担子菌门（Basidiomycota）和子囊菌门（Ascomycota）两个分支。尽管汾酒酿造车间和车间外环境中各有特异的酵母菌，但是两者都存在与白酒酿造相关的酵母菌如酿酒酵母（Saccharomyces cerevisiae）、毕赤酵母（Pichia kudriavzevii）和扣囊复膜酵母（Saccharomycopsis fibuligera）等。汾酒环境中含有丰富的酵母菌资源，可能是大曲和酒醅发酵过程中酵母菌的主要来源。这些都为进一步研究指明了方向。     

代谢工程改造热带假丝酵母生产1,2,4-丁三醇

【背景】 1,2,4-丁三醇属于手性多羟基醇,是一种重要的有机合成的化学中间体,以木糖为原料经四步酶反应是目前研究最多的生物合成路线。然而大肠杆菌的鲁棒性较弱,对发酵液中一些抑制剂的耐受性不是很好,同时存在严重的碳代谢抑制。近年来,鲁棒性较好的酵母菌成为更有吸引力的宿主,其中热带假丝酵母具有天然的木糖代谢途径,可以更好地利用木糖。【目的】在热带假丝酵母中构建从木糖到1,2,4-丁三醇的代谢途径。【方法】在热带假丝酵母中敲除木糖还原酶基因GRE3,从而阻断自身的木糖代谢途径。将来源于Caulobacter crescentus的木糖脱氢酶基因(xylB)和木糖酸脱水酶基因(xylD)及来源于Lactococcus lactis的酮酸脱羧酶基因(kdcA)克隆至C. tropicalis 207中,得到重组菌C. tropicalis BT,在此基础上考察重组菌代谢木糖合成1,2,4-丁三醇的能力,确定限速步骤,并通过增加关键基因xylD与kdcA的拷贝数提高1,2,4-丁三醇产量。【结果】在30℃、200 r/min、接种量1%、以30 g/L木糖为底物的情况下,重组菌的1,2,4-丁三醇的产量达到了1.2 g/L,在5 L发酵罐中的产量达到了3.7 g/L。【结论】在热带假丝酵母中实现以木糖为底物的1,2,4-丁三醇代谢途径,并通过在基因组上增加关键基因xylD与kdcA的拷贝数,获得了一株高产1,2,4-丁三醇的重组酵母菌株,这为后续在热带假丝酵母中进一步提高1,2,4-丁三醇产量奠定了基础。     

添加芦荟汁对红葡萄酒发酵的抑菌效果

二氧化硫（SO₂）危害人体健康。为了寻找用于葡萄酒酿造的SO₂替代品,在赤霞珠葡萄酒自然发酵和接种发酵中比较了添加芦荟汁（80 g/L）与SO₂（60 mg/L）的抑菌和发酵效果。结果表明,添加芦荟汁促进接种酵母和内源酵母生长,SO₂抑制内源酵母生长,接种酵母、添加芦荟汁和添加SO₂显著抑制细菌和霉菌生长,SO₂比芦荟汁对细菌和霉菌生长的抑制作用大。添加芦荟汁和添加SO₂同样提高乙醇产量和减小酸度下降,降低葡萄酒的残糖量和褐变度。添加芦荟汁提高了挥发性酸度和高级醇产量,降低了接种发酵的葡萄酒色度和提高乙酸产量,降低了自然发酵的乙醛产量,而SO₂作用相反。添加芦荟汁具有减少SO₂用量的可能性。     

油菜素内酯与美极梅奇酵母复配对葡萄灰霉病的抑制作用

【背景】生防酵母具有繁殖速度快、抗逆性强和不产生抗生素等特点,但其对病害的防控效果易受环境影响,油菜素内酯(brassinosteroid,BR)能调控植物生长发育与逆境响应平衡,可有效抑制葡萄果实灰霉病的发生。【目的】本研究旨在明确BR与生防酵母复配对葡萄果实灰霉病的抑制效果及作用机制,为新型生防制剂的研制和应用提供理论依据。【方法】采用美极梅奇酵母P01C004 (Y)、酵母和BR (YBR)、酵母和BR抑制剂(YBZ)处理“红地球”葡萄果实,处理6 h后人工接种灰霉菌孢子悬液。灰霉菌接种7 d后评价BR与生防酵母复配对灰霉菌的防治效果,并检测其抗氧化酶活性和13种酚类物质含量,利用qRT-PCR检测不同处理对葡萄BR、白藜芦醇和抗病相关基因表达水平的影响。【结果】7 d时,与Y处理相比,YBR对葡萄果实灰霉病防治效率提高了23.64%,显著提高了“红地球”葡萄果实中PPO酶活。YBR显著提高了2 d时果实中绿原酸、原儿茶酸、咖啡酸、表儿茶素和芹菜素等酚类物质含量,激活了果实内多种酚类物质的快速合成。YBR在48 h时激活了果实BR信号转导途径,显著上调VvBZR1和VvPR1基因的表达水平,更好地维持植物免疫反应,提高果实对病原菌的防御力。【结论】BR与美极梅奇酵母复配能触发果实多种抗病防御机制,提高葡萄果实灰霉病的防治效率,在采后病害防控方面表现出良好的应用前景。     

Functional interaction of yeast elongation factor 3 with yeast ribosomes

Elongation factor 3 (EF-3) is a unique and essential requirement of the fungal translational apparatus. EF-3 is a monomeric protein with a molecular mass of 116,000. EF-3 is required by yeast ribosomes for in vitro translation and for in vivo growth. The protein stimulates the binding of EF-1 alpha :GTP:aa-tRNA ternary complex to the ribosomal A-site by facilitating release of deacylated-tRNA from the E-site. The reaction requires ATP hydrolysis. EF-3 contains two ATP-binding sequence motifs (NBS). NBSI is sufficient for the intrinsic ATPase function. NBSII is essential for ribosome-stimulated activity. By limited proteolysis, EF-3 was divided into two distinct functional domains. The N-terminal domain lacking the highly charged lysine blocks failed to bind ribosomes and was inactive in the ribosome-stimulated ATPase activity. The C-terminally derived lysine-rich fragment showed strong binding to yeast ribosomes. The purported S5 homology region of EF-3 at the N-terminal end has been reported to interact with 18S ribosomal RNA. We postulate that EF-3 contacts rRNA and/or protein(s) through the C-terminal end. Removal of these residues severely weakens its interaction mediated possibly through the N-terminal domain of the protein.     

Phospholipases in yeast

The central role that different phospholipases play in many signal transduction pathways has been intensively studied by classical biochemical and molecular approaches. One approach not extensively pursued, has been the use of yeast as a model system for functional analysis of different aspects of phospholipase signalling. This review concentrates on attempts to establish yeast in this role and aims to demonstrate the potential offered by this approach.     

Medicinal yeast extracts

Alcoholic extracts of bakers' yeast (Saccharomyces cerevisiae) have been used for over 60 years in over-the-counter medications for the treatment of hemorrhoids, burns, and wounds. Although previous studies suggested that small peptides were responsible for the medical observations, the peptides were never resolved into separate fractions and identified. In the present report, a protein fraction was prepared by RPC18 chromatography of the extract which enhances wound closure in both diabetic and non-diabetic littermates. The peptides are active in nanomolar amounts and are 600 times more active than the initial extract. SDS-PAGE and N-terminal amino acid sequencing identified 4 polypeptides in the extract. Three of the proteins were small molecular weight stress-associated proteins: copper, zinc superoxide-dismutase, ubiquitin, and glucose lipid regulated protein (HSP 12). The fourth protein, acyl-CoA binding protein II, has not been previously associated with stress proteins.     

Making magnetic yeast

This study demonstrates that normal yeast cells can be magnetized, and identifies local redox control via carbon metabolism and iron supply as key factors involved in magnetization.     

Riboneogenesis in yeast

Glucose is catabolized in yeast via two fundamental routes, glycolysis and the oxidative pentose phosphate pathway, which produces NADPH and the essential nucleotide component ribose-5-phosphate. Here, we describe riboneogenesis, a thermodynamically driven pathway that converts glycolytic intermediates into ribose-5-phosphate without production of NADPH. Riboneogenesis begins with synthesis, by the combined action of transketolase and aldolase, of the seven-carbon bisphosphorylated sugar sedoheptulose-1,7-bisphosphate. In the pathway's committed step, sedoheptulose bisphosphate is hydrolyzed to sedoheptulose-7-phosphate by the enzyme sedoheptulose-1,7-bisphosphatase (SHB17), whose activity we identified based on metabolomic analysis of the corresponding knockout strain. The crystal structure of Shb17 in complex with sedoheptulose-1,7-bisphosphate reveals that the substrate binds in the closed furan form in the active site. Sedoheptulose-7-phosphate is ultimately converted by known enzymes of the nonoxidative pentose phosphate pathway to ribose-5-phosphate. Flux through SHB17 increases when ribose demand is high relative to demand for NADPH, including during ribosome biogenesis in metabolically synchronized yeast cells.