云南程海湖酵母菌多样性及应用

【目的】针对云南丽江永胜县境内程海湖环境的特殊性,研究高原湖泊环境中酵母菌的多样性,初步探索程海湖环境中酵母菌的利用价值。【方法】对程海湖的湖水和其周边土壤样品中的酵母菌进行分离;应用26S rDNA的D1/D2区域序列分析,并结合形态及生理生化指标对分离获得的酵母菌进行鉴定;采用筛选培养基对已鉴定酵母菌进行产酶定性实验,分析高原湖泊中酵母菌的多样性及可应用性。【结果】分离得到酵母菌64株,对其中63株进行鉴定,归属于9个属22个种(包括4个疑似新种或新变种);地霉属Geotrichum和隐球酵母属Cryptococcus是2种环境中的共有属;在产酶活性筛选中发现有9株产胞外酶活性的菌株,其中YM24373既产蛋白酶又可产淀粉酶。【结论】研究结果显示程海湖中酵母菌组成具有较为丰富的多样性,其应用价值值得进一步研究。     

淀粉基高吸水树脂降解菌的筛选及初步鉴定*

以淀粉接枝丙烯酸高吸水树脂为唯一碳源,从土壤中筛选出4个菌株,纯化后进行菌种鉴定。经过表面观察和理化实验,初步鉴定出它们分别为两类放线菌(放线菌科,Actinomycetaceaes和固氮菌科,Azotobacteraceae)、酵母菌(隐球酵母科,红酵母属,Rhodotonda)和霉菌(毛霉科,根霉属,Rhizopus sp．),为深入研究高吸水树脂的降解性能提供参考。     

云南程海湖冬季酵母菌多样性及胞外酶活性研究

采用过滤涂皿的方法对云南程海湖冬季湖水样品中的酵母菌进行分离,通过26S r DNA D1/D2区域序列分析并结合形态观察和生理生化测试对分离获得的菌株进行鉴定,同时采用胞外酶定性筛选培养基进行产酶活性筛选,分析冬季程海湖酵母菌的多样性及胞外酶活性。结果从程海湖中分离获得171株酵母菌,鉴定为14个属22个种和2个潜在的新分类单元;优势属是红冬孢酵母属Rhodosporidium、红酵母属Rhodotorula和隐球酵母属Cryptococcus;优势种是红冬孢酵母Rhodosporidium kratochvilovae和斯鲁菲亚红酵母Rhodotorula slooffiae;湖北半部的样点CH2的多样性指数(H′=1.5945)和丰富度指数(R=2.7576)均最高,均匀度指数较高的是湖北部的样点CH1(J=0.8531);样点之间种群差异大,相似性低。大多数酵母菌株具有产1种以上的胞外酶。     

云南高原湖泊杞麓湖冬季可培养酵母菌多样性分析

【目的】探究云南杞麓湖酵母菌群落结构及其与环境因子的相互关系。【方法】采用原位培养方法对杞麓湖14个水样进行酵母菌分离,应用26S r DNA D1/D2区域序列分析,并结合形态及生理生化指标将对分离获得的酵母菌进行鉴定,运用软件bio-dap和Canoco分析酵母菌类群的丰富度及其与环境因子间的相互关系。【结果】从杞麓湖中分离得到321株酵母菌,鉴定为14个属27个种和1个潜在的新类群。Rhodosporidium kratochvilovae和出芽短梗霉(Aureobasidium pullulans)是优势种,分别为总菌株数的29.6%和16.8%。水体总磷含量是影响产色素红冬孢酵母属(Rhodosporidium)分布的重要环境因子,而p H为隐球酵母属(Cryptococcus)分布的一个重要选择条件。【结论】杞麓湖酵母菌具有较为丰富的群落多样性。     

云南星云湖酵母菌多样性及产类胡萝卜素的评价

【背景】星云湖属云南高原湖泊,对其酵母菌的多样性研究和产类胡萝卜素菌株的筛选有助于开发利用星云湖酵母菌资源。【目的】研究云南星云湖酵母菌群落结构多样性,筛选和评价产类胡萝卜素活性菌株。【方法】采用膜过滤平置培养对星云湖水样进行酵母菌分离;应用26S rRNA D1/D2区域序列分析和形态特征及生理生化指标相结合,对分离获得的酵母菌进行鉴定;运用软件BIO-DAP分析酵母菌类群的多样性;采用酸热法提取类胡萝卜素,紫外分光光度计测定类胡萝卜素含量。【结果】从星云湖湖水中分离得到797株酵母菌,鉴定为18个属37个种。胶红酵母(Rhodotorula mucilaginosa)和Naganishia albida是优势种,分别占总菌株数的36.64%和28.86%;有28株酵母菌类胡萝卜素产量可达200μg/g细胞干重以上;有4株类胡萝卜素产量可达300μg/g细胞干重以上;粘红酵母(Rhodotorula glutinis) 2株、胶红酵母(Rhodotorula mucilaginosa)和Rhodosporidiobolus fluviale各1株。【结论】云南高原湖泊星云湖的酵母菌具有丰富的多样性,湖泊的营养化程度以及地理差异影响酵母菌群落的结构;红冬孢酵母属(Rhodosporidiobolus)和红酵母属(Rhodotorula)是星云湖类胡萝卜素产量可达300μg/g细胞干重以上的主要类群。有进一步开发研究的价值。     

石河子不同树龄蟠桃土壤中可培养酵母多样性分析及功能酵母的筛选

为了探究新疆本土蟠桃园可培养酵母菌多样性,并挖掘功能酵母资源,本研究以新疆石河子蟠桃园3年、8年、15年树龄的根际和非根际土壤以及桃树叶片为材料,经过传统的分离培养方法获得可培养的酵母菌菌株,并进行形态学、生理生化以及26S r DNA的D1/D2区序列分析,共获得可培养酵母菌129株,从属于12个属17个种,其中子囊菌酵母为优势菌群,占分离属的88%,分布于威克汉姆酵母属(Wickerhamomyces),Vanrija属,Barnettozyma属和有孢圆酵母属(Torulaspora)等11个属的15个种。担子菌占分离属的12%,分布于隐球酵母属(Cryptococcus)的2个种。其中优势属威克汉姆酵母属,包括异常威克汉姆酵母(W. anomalus)和W. pijperi两个种,占总比例的33%,优势种异常威克汉姆酵母所占总株数比例为17%。从可培养酵母中共筛选出23株功能酵母,其中富硒酵母21株,优势种为白地霉(Galactomyces candidum),产蛋白酶酵母2株均属于隐球酵母属的Cryptococcus albidus。结果表明,新疆桃园中蕴含丰富的酵母菌资源,非根际土壤中的酵母多样性大于根际及叶片酵母多样性,且分离得到富硒酵母及产蛋白酶酵母。本研究挖掘了新疆本土可培养酵母菌资源,同时也为功能酵母的开发和利用提供理论指导。     

云南抚仙湖产类胡萝卜素酵母菌的资源调查

【目的】对分离自云南抚仙湖湖水的379株酵母菌进行产类胡萝卜素的筛选,以期获得具有开发应用价值的产类胡萝卜素酵母菌。【方法】采用酸热法提取类胡萝卜素,紫外分光光度计测定类胡萝卜素含量,SPSS软件分析产类胡萝卜素酵母的分布特征。【结果】318株酵母菌(占供试菌株的83.91%)具有产类胡萝卜素的能力,大多数菌株类胡萝卜素产量在10-300μg/g之间,最高达590.83μg/g。产类胡萝卜素酵母集中分布于红冬孢酵母属(Rhodosporidium)和红酵母属(Rhodotorula);担子菌酵母产类胡萝卜素的能力高于子囊菌酵母;筛选到9株产类胡萝卜素活性较强的菌株:双倒卵形红冬孢酵母(Rhodosporidium diobovatum)3株、沼泽生红冬孢酵母(Rhodosporidium paludigenum)2株、粘红酵母(Rhodotorula glutinis)、禾本红酵母(Rhodotorula graminis)、瑞纳锁掷孢酵母(Sporidiobolus ruineniae)及Cystofilobasidium macerans各1株。【结论】高原湖泊抚仙湖生存着大量产类胡萝卜素的酵母菌,"红色酵母"(Red yeasts)具有较强的产类胡萝卜素的能力,红冬孢酵母属(Rhodosporidium)和红酵母属(Rhodotorula)是抚仙湖产类胡萝卜素酵母菌的主要类群。     

云南阳宗海酵母菌种群结构及产胞外酶测试北大核心CSCD

【目的】研究阳宗海酵母菌种群结构,分析生物因子及非生物因子对酵母菌种群分布的影响;测试阳宗海酵母菌产胞外酶活性。【方法】水样用醋酸纤维素滤膜过滤,原位培养分离酵母菌;梯度稀释法分离土样和底泥样品;对分离得到的菌株进行DNA提取和测序,分析26S rDNA的D1/D2区域,并结合形态及生理生化指标进行鉴定;用产酶筛选培养基对分离得到的酵母菌进行产胞外酶活性测试。【结果】共分离得到201株酵母菌,鉴定分属于15个属48个种,其中包括10个潜在的新种;普鲁兰类酵母(Aureobasidium pullulans),库德里阿兹威氏毕赤酵母(Pichia kudriavzevii),胶红酵母(Rhodotorula mucilaginosa),Cryptococcus podzolicus是优势种;15.9%的酵母菌具有产胞外酶活性,主要是脂肪酶和淀粉酶。【结论】阳宗海酵母菌有较为丰富的多样性,人为活动对阳宗海酵母菌分布影响较大,其次浊度、电导率也是影响酵母菌种群分布的重要因素;阳宗海产胞外酶酵母菌可能参与湖泊生态系统的自然循环。     

异龙湖湿地修复后可培养酵母菌的多样性及其与理化因子的相关性

【目的】研究湿地修复后异龙湖中可培养酵母菌多样性及其与理化因子的相关性。【方法】对异龙湖湖水中可培养酵母菌进行DNA提取和测序,通过分析26SrRNA基因的D1/D2区域和形态以及生理生化特征对酵母菌进行鉴定,测定各个水样点的总有机碳(TOC)、总氮(TN)、总磷(TP)、总硬度(TH)和电导率(Cond),运用R 4.0.5、Canoco 5软件来分析异龙湖湖水中可培养酵母菌多样性和与理化因子的相关性。【结果】从湿地修复后的异龙湖湖水中分离获得519株可培养酵母菌,鉴定为24个属42个种和1个潜在的新种,胶红酵母(Rhodotorula mucilaginosa)、皮肤皮状新丝孢酵母(Cutaneotrichosporon dermatis)以及产黑色素短梗霉(Aureobasidium melanogenum)是异龙湖中的优势种,分别分离到了320株(52.29%)、40株(7.71%)和37株(7.13%)。【结论】湿地修复后的异龙湖具有丰富的可培养酵母菌资源,其群落结构较湿地修复前有了明显的变化,湖区西北部的可培养酵母菌多样性要比湖区东南部丰富。TN与异龙湖中可培养酵母菌多样性...     

渤海海水中酵母菌的种类

本文报道了渤海海水中酵母菌种类的调查结果,从31个站位中,共分离鉴定了228株酵母菌,这些酵母菌分别属于8属40种:红酵母属(Rhodotorula)5个种,隐球酵母属(Cryptococcus)8个种,德巴利酵母属(Debaryomyces)2个种,毕赤酵母属(Pichia)8个种,酵母属(Saccharomyces)2个种,短梗霉属(Aureobasidium)1个种,球孢酵母属(Torulaspora)1个种,假丝酵母属(candida)13个种。40个种中,有13种是中国新记录,即:黑隐球酵母(Cryptococcus ater),大型隐球酵母(Cr.magnus),多型德巴利酵母(Debaryomyces polymorphus),克鲁维酵母(Saccharomyces kluyveri),伯顿毕赤酵母(Pichia burtonii),卡森毕赤酵母(P.carsonii),埃切毕赤酵母(P.etchellsii),季也蒙毕赤酵母(P.guilliermondii),海梅尔毕赤酵母(P.heimii),嗜土毕赤酵母(P.philogaea),奥默毕赤酵母(P.ohmeri),棘胫小蠹毕赤酵母(P.scolyti),和戴尔有孢圆酵母(Torulaspora delbrueckii),在这13种中,除埃切毕赤酵母和奥默毕赤酵母外,其余11种在海水里也是首次报道。     

Yeasts and Yeast-Like Fungi Associated with Tree Bark: Diversity and Identification of Yeasts Producing Extracellular Endoxylanases

A total of 239 yeast strains was isolated from 52 tree bark samples of the Medaram and Srisailam forest areas of Andhra Pradesh, India. Based on analysis of D1/D2 domain sequence of 26S rRNA gene, 114 strains were identified as ascomycetous; 107 strains were identified as basidiomycetous yeasts; and 18 strains were identified as yeast-like fungi. Among the ascomycetous yeasts, 51% were identified as members of the genus Pichia, and the remaining 49% included species belonging to the genera Clavispora, Debaryomyces, Kluyveromyces, Hanseniaspora, Issatchenkia, Lodderomyces, Kodamaea, Metschnikowia, and Torulaspora. The predominant genera in the basidiomycetous yeasts were Cryptococcus (48.6%), Rhodotorula (29%), and Rhodosporidium (12.1%). The yeast-like fungi were represented by Aureobasidium pullulans (6.7%) and Lecythophora hoffmanii (0.8%). Of the 239 yeast strains tested for Xylanase, only five strains of Aureobasidium sp. produced xylanase on xylan-agar medium. Matrix-assisted laser desorption ionization-time of flight analysis and N-terminal amino-acid sequence of the xylanase of isolate YS67 showed high similarity with endo-1-4-β-xylanase (EC 3.2.1.8) of Aureobasidium pullulans var. melanigenum. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Yeasts in an industrial malting ecosystem

The malting ecosystem consists of two components: the germinating cereal grains and the complex microbial community. Yeasts and yeast-like fungi are an important part of this ecosystem, but the composition and the effects of this microbial group have been largely unknown. In this study we surveyed the development of yeasts and yeast-like fungi in four industrial scale malting processes. A total of 136 malting process samples were collected and examined for the presence of yeasts growing at 15, 25 and 37°C. More than 700 colonies were isolated and characterized. The isolates were discriminated by PCR-fingerprinting with microsatellite primer (M13). Yeasts representing different fingerprint types were identified by sequence analysis of the D1/D2 domain of the 26S rRNA gene. Furthermore, identified yeasts were screened for the production of α-amylase, β-glucanase, cellulase and xylanase. A numerous and diverse yeast community consisting of both ascomycetous (25) and basidiomycetous (18) species was detected in the various stages of the malting process. The most frequently isolated ascomycetous yeasts belonged to the genera Candida, Clavispora, Galactomyces, Hanseniaspora, Issatchenkia, Pichia, Saccharomyces and Williopsis and the basidiomycetous yeasts to Bulleromyces, Filobasidium, Cryptococcus, Rhodotorula, Sporobolomyces and Trichosporon. In addition, two ascomycetous yeast-like fungi (black yeasts) belonging to the genera Aureobasidium and Exophiala were commonly detected. Yeasts and yeast-like fungi produced extracellular hydrolytic enzymes with a potentially positive contribution to the malt enzyme spectrum. Knowledge of the microbial diversity provides a basis for microflora management and understanding of the role of microbes in the cereal germination process.     

红富士苹果园酵母多样性研究

从北京顺义和山东泰安红富士苹果园采集果实、叶片、树皮和土壤等不同基物,分离酵母菌,利用26S rDNA的D1/D2区域序列分析并结合形态学特征和SSCP分析对这些菌株进行了分类学研究,探讨了苹果园酵母的物种多样性及其分布。北京苹果园共分离酵母菌129株,鉴定为13属21种,优势属为Pichia（4个种）,Cryptococcus（3个种）,Pseudozyma（3个种）,子囊菌占较大优势,分布于8属12种,占总种数的57.1%。山东苹果园共分离酵母291株,鉴定为13属26种,优势属为假丝酵母Candida（6个种）,毕赤酵母Pichia（4个种）和隐球酵母Cryptococcus（3个种）,并且子囊菌占较大优势,分布于7属17种,占总种数的65.4%。     

西藏曲拉和云南乳饼中酵母菌的鉴定及其生物多样性

【目的】探讨西藏曲拉和云南乳饼中酵母菌的生物多样性及其分布特征,为我国传统乳制品中酵母菌资源的利用提供基础数据。【方法】从西藏和云南分别采集的5份曲拉样品和8份乳饼样品中分离出41株酵母菌,利用26SrDNAD1/D2区域序列分析对这些菌株进行了分类鉴定。【结果】曲拉和乳饼样品中酵母菌的总数分别在106-107cfu/g和102-106cfu/g之间,曲拉样品的酵母菌平均数比乳饼样品中的高34倍。共鉴定出10属12种,其中西藏曲拉的优势菌株为发酵毕赤氏酵母(Pichia fermentans)和酿酒酵母(Saccharomyces cerevisiae);云南乳饼的优势菌株为类筒假丝酵母(Candida zeylanoides)和喜仙人掌毕赤氏酵母(Pichia cactophila)。毕赤氏酵母属(Pichia)是曲拉和乳饼的共同优势属。【结论】西藏曲拉和云南乳饼中的酵母菌都具有丰富的生物多样性,但其差异性很大。     

Production of alditols fromd-xylose by yeasts

Production of glycerol, tetritols, pentitols, hexitols and heptitols was tested with 193 strains of yeasts and yeast-like microorganisms belonging to 13 genera. According to the production of alditols, the yeast species were divided into four groups. The largest group consisted of pentitol-producing yeasts. Only few species produced glycerol, tetritol and hexitol. Production of heptitols was found mainly in sporulating yeasts. Translated by Č. Novotny     

Extracellular enzymatic activity profiles in yeast and yeast-like strains isolated from tropical environments

AIMS: The objective of this study was to investigate the extracellular enzymatic activity (EEA) profile of yeasts isolated from tropical environments of the Brazilian rain forest. This screening survey could constitute the first approach in selecting yeast strains of environmental origin potentially exploitable as enzyme producers. METHODS AND RESULTS: In this study, 348 yeast (193 ascomycetes and 155 basidiomycetes) and 46 yeast-like strains (Aureobasidium pullulans) were screened for their EEA profile. The spread occurrence of extracellular amylases, esterases, lipases, proteases, pectinases and chitinases appeared to be a strain-related character. CONCLUSIONS: Yeasts isolated from tropical environments could represent a promising source of EEA. Selected strains showed maximum levels of EEA under acidic or neutral conditions. SIGNIFICANCE AND IMPACT OF THE STUDY: This study demonstrated the potential for yeasts isolated from extreme environments as sources of industrially relevant enzymes for biotechnological purposes.     

Yeasts from phylloplane and their capability to produce indole-3-acetic acid

Yeasts were isolated from the phylloplane of various plant species collected from seven provinces in Thailand. A total of 114 yeast strains and 10 strains of a yeast-like fungus were obtained by enrichment isolation from 91 out of 97 leaf samples (93.8?%). On the basis of the D1/D2 domain of the large subunit rRNA gene sequence similarity, 98 strains were identified to be of 36 yeast species in 18 genera belonging to Ascomycota viz. Candida, Clavispora, Cyberlindnera, Debaryomyces, Hanseniaspora, Hyphopichia, Kazachstania, Kluyveromyces, Kodamaea, Lachancea, Metschnikowia, Meyrozyma, Pichia, Starmerella, Torulaspora and Wickerhamomyces, and to Basidiomycota viz. Sporidiobolus and Trichosporon. Three strains were found to represent two novels Candida species which were previously described as C. sirachaensis and C. sakaeoensis. Ten strains of yeast-like fungus were identified as Aureobasidium pullulans of the phylum Ascomycota. Ascomycetous yeast species accounted altogether for 98.0?% of the 98 strains. The prevalent species was Candida tropicalis with a low frequency of isolation (14.3?%). Diversity of yeasts other than ballistoconidium-forming yeast in phylloplane in a tropical country in Asia has been reported for the first time. All strains obtained were accessed for the capability to produce IAA and result revealed that 39 strains in 20 species, one strain each of an undescribed and a novel species, and two unidentified strains showed the capability of producing IAA when cultivated in yeast extract peptone dextrose broth supplemented with 0.1?% l-tryptophan. All five strains of Candida maltosa produced relatively high concentrations of IAA.     

Yeasts in malting,with special emphasis on <Emphasis Type="Italic">Wickerhamomyces anomalus</Emphasis> (synonym <Emphasis Type="Italic">Pichia anomala</Emphasis>)

Malted barley is a major raw material of beer, as well as distilled spirits and several food products. The production of malt (malting) exploits the biochemical reactions of a natural process, grain germination. In addition to germinating grain, the malting process includes another metabolically active component: a diverse microbial community that includes various types of bacteria and fungi. Therefore, malting can be considered as a complex ecosystem involving two metabolically active groups. Yeasts and yeast-like fungi are an important part of this ecosystem, but previously the significance of yeasts in malting has been largely underestimated. Characterization and identification of yeasts in industrial processes revealed 25 ascomycetous yeasts belonging to 10 genera, and 18 basidiomycetous yeasts belonging to 7 genera. In addition, two ascomycetous yeast-like fungi belonging to the genera Aureobasidium and Exophiala were commonly detected. Yeasts and yeast-like fungi produced extracellular hydrolytic enzymes with a potentially positive contribution to the malt enzyme spectrum. Several ascomycetous yeast strains showed strong antagonistic activity against field and storage moulds, Wickerhamomyces anomalus (synonym Pichia anomala) being the most effective species. Malting studies revealed that W. anomalus VTT C-04565 effectively restricted Fusarium growth and hydrophobin production during malting and prevented beer gushing. In order to broaden the antimicrobial spectrum and to improve malt brewhouse performance, W. anomalus could be combined with other starter cultures such as Lactobacillus plantarum. Well-characterized microbial mixtures consisting of barley and malt-derived microbes open up several possibilities to improve malt properties and to ensure the safety of the malting process.