一株甲基对硫磷降解菌-布朗克假丝酵母JMUPMD-1的分离与鉴定

对一株新分离的、能以甲基对硫磷为唯一磷源生长的菌株JMUPMD-1,利用形态特征观察和生理生化特性,及结合rDNA ITS分子序列分析对JMUPMD-1进行鉴定;采用气相色谱法检测培养过程中甲基对硫磷浓度的变化,确定甲基对硫磷降解速率。该菌株的rDNA ITS序列与布朗克假丝酵母（Candida blankii）的同源性为99％。形态特征和生理生化特性与布朗克假丝酵母相符合,因此鉴定为布朗克假丝酵母。以350μg／L甲基对硫磷为唯一磷源和350μg／L甲基对硫磷及1g／L K2HPO4组成的混合磷源培养该菌株,测得该菌株的降解率为48．6％。该菌株的胞内提取液具有明显的甲基对硫磷降解酶活性。     

山茶属植物ITS的扩增及其序列特征分析

以山茶属(Camellia)植物为实验材料,通过在PCR反应液中加入二甲基亚砜(DMSO)来改进ITS区的扩增效果,并对获得的序列进行了相关的比较分析以及系统发育分析。分析结果表明:(1)PCR反应液中添加4%的DMSO能明显提高ITS的扩增效率,并能有效防止ITS假基因的扩增;(2)与功能拷贝相比,ITS假基因序列的ITS1和ITS2区存在多处碱基缺失,GC含量明显偏低,5.8S区二级结构稳定性降低;(3)应用ITS假基因进行种水平的系统发育分析会对其真实的系统关系造成影响,提示进行系统进化研究时应警惕假基因的干扰。     

基于ITS 序列探讨沙棘属植物的系统发育关系

对分布于青海境内的中国沙棘、肋果沙棘和西藏沙棘的ITS区进行扩增和序列分析,并以胡颓子科胡颓子属沙枣为外类群,对胡颓子科沙棘属15种植物的ITS序列进行聚类分析, 探讨沙棘属各植物的亲缘关系.结果表明： 3种沙棘属植物的ITS区长度为600～605 bp,其中,ITS-1区为201～203 bp,5.8S为166～167 bp,ITS-2区为232～236 bp.核苷酸分析显示,3种沙棘属植物的ITS区存在丰富的变异位点.聚类分析表明,棱果沙棘种的2个亚种——棱果沙棘和理塘沙棘为2个不同种,江孜沙棘与柳叶沙棘之间的亲缘关系较近,而与中国沙棘亲缘关系较远;沙棘种下9个亚种间的聚类结果与形态学分类差异较大.
     

衣藻属的系统发育分析——基于形态形状和nrDNA ITS序列

通过实验分析莱茵衣藻 ( Chlamydomonas reinhardtii) 1个种和互连网获得衣藻属 1 5个种及丝藻属 1个种 ( Ulothrix zonata) ,共 1 7个种的 nr DNA ITS序列 ,并以 U.zonata为外类群 ,采用计算机分析软件包对其进行分析及构建分子系统发育树图。同时以 1 2个传统分类性状 ,对此 1 6种衣藻构建数据矩阵 ;以 U.zonata动孢子的相应性状为外类群原始性状 ,用Wagner法在计算机上对其进行分枝分析 ;然后比较并分析分子系统树和表征性状分支分析树的异同。初步尝试以 ITS分子序列系统发育分析作为传统性状分析的补充来研究衣藻种间的亲缘关系。     

药用野生稻复合体ITS1和ITS2序列变异及其系统进化分析

通过PCR扩增并测序分析稻属药用野生稻复合体5个野生稻种基因组完整的ITS区及5.8S区,并与栽培稻ITS序列进行比较,构建分子系统进化树,探讨了稻属药用野生稻复合体内不同种间的亲缘关系和系统进化.结果表明,ITS1和ITS2均有较高的G/C含量,ITS1序列的长度多态性相对较高,ITS2序列的碱基突变频率较高.药用野生稻和高秆野生稻亲缘关系很近,而与栽培稻亲缘关系较远;短药野生稻、斑点野生稻、澳洲野生稻与药用野生稻亲缘关系渐近.处于进化的过渡阶段.     

降香黄檀的DNA条形码鉴定研究

DNA条形码技术是利用基因组中一段短的标准序列进行物种的鉴定并探索其亲缘进化关系。本研究对采自海南不同地区降香黄檀五个居群24份样品的psbA-trnH,rbcL,核ITS及ITS2序列进行PCR扩增和测序,比较各序列扩增和测序效率。种间和种内变异,采用BLAST1和邻接 (NJ) 法构建系统聚类树方法评价不同序列的鉴定能力。结果表明ITS2在所研究的材料中具有最高的扩增和测序效率,而ITS扩增效率较低。ITS2完整序列在区分黄檀属不同种间差异具有较大优势。因此可利用ITS2从分子水平区分降香黄檀与其他混伪种。     

金耳与其近似种的rDNA-ITS序列分析

对金耳(Tremella aurantialba)的担子果、酵母状分生孢子培养物和菌丝培养物的核糖体DNA内部转录间隔区(ITS)序列进行PCR扩增和测序。结果表明金耳担子果的ITS区PCR产物均为碱基数不同的两条带,片段长度和序列与酵母状分生孢子培养物、菌丝培养物一致。通过对ITS1和ITS2联合进行系统发育分析表明金耳酵母状分生孢子培养物归属于银耳属的金耳,参与组成担子果的寄主菌丝为毛韧革菌(Stereum hirsutum)。结合GenBank中登录的金黄银耳、脑状银耳、橙黄银耳等近似种构建了的系统发育树,结果支持形态学证据,表明金耳是一个独立种。     

IGS基因及RAPD标记分析在加特隐球酵母基因分类中的应用

根据ITS1-5.8S-ITS2区域的特异核酸序列变化,加特隐球酵母Cryptococcus gattii(≡新型隐球酵母加特变种Cryptococcu neoformans var.gattii)可分为6种基因型。本研究通过检测加特隐球酵母的IGS基因,发现其IGS序列有着更丰富的变异和信息位点。通过结合加特隐球酵母RAPD(随机扩增的多态性DNA)图谱比较研究,与IGS和ITS的序列分析结果大体一致,说明新近发现的加特隐球酵母ITS8型确实有别于以前报道过的其他加特隐球酵母ITS基因型。研究证明IGS1及IGS2基因片段分析可以作为加特隐球酵母基因分类鉴定中有效的辅助鉴别的分子生物学方法,联合多种基因分类鉴定的方法可以更有效地揭示新型隐球酵母加特变种种内不同基因亚型间的遗传进化关系。     

口腔黏膜真菌鉴定方法的比较

比较常见用于黏膜真菌菌种鉴别的多种方法,探寻最佳的鉴别方法。采集230例普通人群口腔黏膜样本,分别用玉米吐温-80培养观察厚膜孢子法、糖发酵生化反应法、CHROMagar假丝酵母菌显色培养基法、ITS基因的PCR-RFLP(聚合酶链反应-限制性片段长度多态性)法、ITS测序菌种鉴定法,鉴别真菌各菌株。结果显示:有56例菌株至少通过1种方法检出真菌;玉米吐温-80分离培养假丝酵母菌37株;50例菌株ITS基因测序共鉴定出8个菌种,白假丝酵母菌(C.albicans)29株,近平滑假丝酵母菌(C.parapsilosis)10株,热带假丝酵母菌(C.tropicalis)5株,Candida metapsilosis 1株,Lodderomyces elongisporus 1株,克柔假丝酵母菌(Candida krusei)1株,乙醇假丝酵母菌(C.ethanolica)1株,季也蒙毕赤酵母菌(Pichia guilliermondii)2株;CHROMagar假丝酵母菌显色培养基法鉴定出3种菌株,分别是白假丝酵母菌、热带假丝酵母菌、近平滑假丝酵母菌;PCR-RFLP法检出5种菌株,分别是白假丝酵母菌、热带假丝酵母菌、近平滑假丝酵母菌、季也蒙毕赤酵母菌、克柔假丝酵母菌,与基因的测序鉴定一致率为91%;糖发酵生化反应法阳性标本占被检出真菌例数的46.4%(26/56)。结果表明:ITS基因的测序法可以准确鉴定真菌各个菌种;PCR-RFLP法能鉴定常见的菌种,但操作繁琐;CHROMagar假丝酵母菌显色培养基法能快速准确鉴别3种常见假丝酵母菌菌种;玉米吐温-80可以准确培养鉴别白假丝酵母菌;糖发酵生化反应法,缺乏足够的敏感度和特异性,难以准确鉴别各个菌种。     

枇杷属内栽培种和部分野生种ITS序列分析

对不同栽培区的25种普通枇杷品种以及7种枇杷属野生种的ITS序列进行扩增并测序,采用邻接法和最大简约法进行系统发育树的构建并对枇杷属内不同种间的遗传关系进行了分析。结果表明:枇杷属植物ITS序列ITS1+5.8S rDNA+ITS2总长度为592 bp或594 bp,长度变化发生在ITS2。所有样本的ITS1和5.8S rDNA长度一样,都是223 bp和168 bp;而ITS2为201 bp或203 bp。5种枇杷属野生种的ITS序列长度为594 bp,包括栎叶枇杷、大渡河枇杷、南亚枇杷、南亚枇杷窄叶变种和大瑶山枇杷;其余2种枇杷属野生种(麻栗坡枇杷、小叶枇杷)和普通枇杷栽培种的ITS序列长度都为592 bp。所有样本ITS序列的GC含量为64.2%~64.5%,其中ITS1为64.1%~65.5%,ITS2为68.1%~72.6%。对所有样本的ITS序列比对产生44个可变位点,其中38个为简约信息位点,其中11个位于ITS1,5个位于5.8S rDNA,22个位于ITS2。最大的种间序列差异为7.7%,最小的种间差异发生在麻栗坡枇杷和小叶枇杷之间,仅为0.2%。普通枇杷种内的ITS序列差异很低,25种普通枇杷栽培种之间的序列差异为0~1.5%。所研究的枇杷属植物可分为3个分支。分支Ⅰ包括所有普通枇杷品种,分支Ⅱ包含5种野生枇杷种,包括栎叶枇杷、大渡河枇杷、南亚枇杷、南亚枇杷窄叶变种和大瑶山枇杷;分支Ⅲ由2个野生枇杷种(麻栗坡枇杷、小叶枇杷)组成。该研究结果表明ITS序列对枇杷种间鉴定和系统发育分析具有一定意义,但对普通枇杷栽培种间的鉴定作用不大。     

口腔念珠菌基因多态性检测

目的检测正常人群口腔念珠菌基因型,以了解口腔念珠菌基因多态性。方法采集162例正常人群口腔样本,用念珠菌显色培养基(CHROM agar)进行菌种分离培养鉴定,用玉米Tween80培养基进行真菌孢子形态学检查鉴定,随机抽取45个菌株样本进行内含子转录间隔区(internal transcribed spacer region,ITS)序列检测,并比对同源性,建立进化树,观察菌株进化分支情况。结果分离培养出念珠菌菌株57株(57/162,35.2%),其中白色念珠菌(Candida albicans)36株(36/57,63.1%)。进行ITS序列检测的45个菌株申请GenBank序列注册号为FJ697166-GQ280292。结论正常人群口腔念珠菌基因具有多态性。     

PCR amplification of the rDNA internal transcribed spacer region for differentiation of Saccharomyces cultures

Abstract The size of the internal transcribed spacer (ITS) region as measured by gel electrophoresis of PCR products, amplified by primers ITS1 and ITS4, was over 800 bp for all Saccharomyces sensu stricto species, but yeasts belonging to other Saccharomyces species had a shorter ITS region, making this characteristic potentially useful in the identification of Saccharomyces isolates. The ITS product length was homogeneous within the species Saccharomyces cerevisiae .     

Rapid differentiation of phenotypically similar yeast species by single-strand conformation polymorphism analysis of ribosomal DNA

Single-strand conformation polymorphism (SSCP) analysis of ribosomal DNA (rDNA) was investigated for rapid differentiation of phenotypically similar yeast species. Sensitive tests indicated that some yeast strains with one, most strains with two, and all strains with three or more nucleotide differences in the internal transcribed spacer 1 (ITS1) or ITS2 region could be distinguished by PCR SSCP analysis. The discriminative power of SSCP in yeast species differentiation was demonstrated by comparative studies of representative groups of yeast species from ascomycetes and basidiomycetes, including Saccharomyces species, medically important Candida species, and phylloplane basidiomycetous yeast species. Though the species within each group selected are closely related and have relatively similar rDNA sequences, they were clearly differentiated by PCR-SSCP analysis of the ITS1 region, given the amplified fragments were less than 350 bp in sizes. By using SSCP analysis for rapid screening of yeast strains with different rDNA sequences, species diversity existing in a large collection of yeast strains from natural sources was effectively and thoroughly investigated with substantially reduced time and cost in subsequent DNA sequencing.     

Sequencing of the internal transcribed spacer region ITS1 as a molecular tool detecting variation in the Stylosanthes guianensis species complex

 The internal transcribed spacer (ITS) regions 1 and 2 of the ribosomal DNA from Stylosanthes guianensis CIAT 1283 and cv ‘Schofield’ were amplified by polymerase chain reaction using conserved ITS primers from the 18S, 5.8S and 26S ribosomal genes flanking those regions. The entire region of 683 bp long was cloned, and seven clones were sequenced. Comparison of the ITS spacer regions with published DNA sequences of other plant species revealed limited homology only; this was in contrast to their comparison with the 5.8S rDNA sequences. The ITS1 region of 45 S. guianensis accessions was amplified by PCR and sequenced on both strands using the conserved primers ITS2-ITS5. These sequences, ranging from 201 to 204 bp, were aligned to each other to assess intra-specific polymorphism. Within the S. guianensis (Aubl.) Sw. species complex, 11 DNA sequence types could be distinguished based on an insertion/deletion (indel) event and 15 single base-pair substitutions. In 1 of the S. guianensis types, two kinds of ITS1 sequence were observed in each individual, reminiscent of an incomplete homogenization of the repeat structure in this type. Polymorphisms in the sequence of the ITS1 region were used to define molecular markers for S. guianensis on the basis of PCR-restriction fragment length polymorphism and selective PCR. Received: 24 June 1997 / Accepted: 31 October 1997     

ITS1: a DNA barcode better than ITS2 in eukaryotes?

A DNA barcode is a short piece of DNA sequence used for species determination and discovery. The internal transcribed spacer (ITS/ITS2) region has been proposed as the standard DNA barcode for fungi and seed plants and has been widely used in DNA barcoding analyses for other biological groups, for example algae, protists and animals. The ITS region consists of both ITS1 and ITS2 regions. Here, a large‐scale meta‐analysis was carried out to compare ITS1 and ITS2 from three aspects: PCR amplification, DNA sequencing and species discrimination, in terms of the presence of DNA barcoding gaps, species discrimination efficiency, sequence length distribution, GC content distribution and primer universality. In total, 85 345 sequence pairs in 10 major groups of eukaryotes, including ascomycetes, basidiomycetes, liverworts, mosses, ferns, gymnosperms, monocotyledons, eudicotyledons, insects and fishes, covering 611 families, 3694 genera, and 19 060 species, were analysed. Using similarity‐based methods, we calculated species discrimination efficiencies for ITS1 and ITS2 in all major groups, families and genera. Using Fisher's exact test, we found that ITS1 has significantly higher efficiencies than ITS2 in 17 of the 47 families and 20 of the 49 genera, which are sample‐rich. By in silico PCR amplification evaluation, primer universality of the extensively applied ITS1 primers was found superior to that of ITS2 primers. Additionally, shorter length of amplification product and lower GC content was discovered to be two other advantages of ITS1 for sequencing. In summary, ITS1 represents a better DNA barcode than ITS2 for eukaryotic species.     

New species Micractinium kostikovii (Chlorellaceae,Trebouxiophyceae) from Russia

Correctly identifying species of Chlorella-like microalgae is difficult because of their morphological simplicity and high phenotypic plasticity. The use of molecular tools has revolutionized research on algal diversity, enabling such advances as the discovery of numerous new taxa. This article presents the results of a study of strains that are newly isolated from a freshwater Lake Prudovikov (Samara region, Russian Federation). These strains had the typical Chlorella morphology, exhibiting spherical cells and a cup-shaped parietal chloroplast. The chloroplast contained a single pyrenoid enveloped by starch grains. However, 18S–ITS1–5.8S–ITS2 sequence analyses indicated that the studied strains are strongly allied with the well-supported genus Micractinium. Based on the results of a comparative analysis of the morphological, molecular and environmental characteristics of the studied strains (employing a polyphasic approach), we propose that they are new species of Micractinium: Micractinium kostikovii sp. nov.     

Confirmation of cultivated Porphyra tenera (Bangiales, Rhodophyta) by polymerase chain reaction restriction fragment length polymorphism analyses of the plastid and nuclear DNA

Polymerase chain reaction restriction fragment length polymorphism (PCR‐RFLP) analysis of the plastid ribulose‐1,5‐bisphosphate carboxylase (RuBisCo) spacer region was developed for a more reliable and rapid species identification of cultivated Porphyra in combination with PCR‐RFLP analysis of the nuclear internal transcribed spacer (ITS) region. From the PCR‐RFLP analyses of the plastid and nuclear DNA, we examined seven strains of conchocelis that were used for cultivation as Porphyra tenera Kjellman but without strict species identification. The PCR‐RFLP analyses suggested that two strains, C‐32 and 90‐02, were cultivated P. tenera and that the other five strains, C‐24, C‐28, C‐29, C‐30 and M‐1, were Porphyra yezoensis f. narawaensis Miura. To identify species more accurately and to reveal additional genetic variation, the two strains C‐32 and 90‐02 were further studied by sequencing their RuBisCo spacer and ITS‐1 regions. Although RuBisCo spacer sequences of the two strains were identical to each other, each of their ITS‐1 sequences showed a single substitution. The sequence data again confirmed that the two strains (C‐32 and 90‐02) were cultivated P. tenera, and suggested that the two strains showed some genetic variation. We concluded that PCR‐RFLP analysis of the plastid and nuclear DNA is a powerful tool for reliable and rapid species identification of many strains of cultivated Porphyra in Japan and for the collection of genetically variable breeding material of Porphyra.     

Discrimination of <Emphasis Type="Italic">Tricholoma</Emphasis> species by species-specific ITS primers

The ITS region of ectomycorrhizal fungi was analyzed, and species-specific PCR primers were designed for 8 ectomycorrhizal Tricholoma species. Although a high degree of intraspecific homology was observed, interspecific variation was sufficient to design species-specific primers based on sequence of the ITS region. PCR amplification with the specific primers generated fragments of the expected sizes from DNA extracted from the strains of each species but gave no amplified products from the strains of the other 16 species in eight genera. These results suggest that sequence of the ITS region is appropriate to be used for species-level identification of ectomycorrhizal fungi.     

CONSPECIFICITY AND INDO-PACIFIC DISTRIBUTION OF SYMBIODINIUM GENOTYPES (DINOPHYCEAE) FROM GIANT CLAMS

We previously reported the occurrence of genetically‐diverse symbiotic dinoflagellates (zooxanthellae) within and between 7 giant clam species (Tridacnidae) from the Philippines based on the algal isolates' allozyme and random amplified polymorphic DNA (RAPD) patterns. We also reported that these isolates all belong to clade A of the Symbiodinium phylogeny with identical 18S rDNA sequences. Here we extend the genetic characterization of Symbiodinium isolates from giant clams and propose that they are conspecific. We used the combined DNA sequences of the internal transcribed spacer (ITS)1, 5.8S rDNA, and ITS2 regions (rDNA‐ITS region) because the ITS1 and ITS2 regions evolve faster than 18S rDNA and have been shown to be useful in distinguishing strains of other dinoflagellates. DGGE of the most variable segment of the rDNA‐ITS region, ITS1, from clonal representatives of clades A, B, and C showed minimal intragenomic variation. The rDNA‐ITS region shows similar phylogenetic relationships between Symbiodinium isolates from symbiotic bivalves and some cnidarians as does 18S rDNA, and that there are not many different clade A species or strains among cultured zooxanthellae (CZ) from giant clams. The CZ from giant clams had virtually identical sequences, with only a single nucleotide difference in the ITS2 region separating two groups of isolates. These data suggest that there is one CZ species and perhaps two CZ strains, each CZ strain containing individuals that have diverse allozyme and RAPD genotypes. The CZ isolated from giant clams from different areas in the Philippines (21 isolates, 7 clam species), the Australian Great Barrier Reef (1 isolate, 1 clam species), Palau (8 isolates, 7 clam species), and Okinawa, Japan (1 isolate, 1 clam species) shared the same rDNA‐ITS sequences. Furthermore, analysis of fresh isolates from giant clams collected from these geographical areas shows that these bivalves also host indistinguishable clade C symbionts. These data demonstrate that conspecific Symbiodinium genotypes, particularly clade A symbionts, are distributed in giant clams throughout the Indo‐Pacific.     

Genotyping of a Miso and Soy Sauce Fermentation Yeast,Zygosaccharomyces rouxii,Based on Sequence Analysis of the Partial 26S Ribosomal RNA Gene and Two Internal Transcribed Spacers

We analyzed sequences of the D1D2 domain of the 26S ribosomal RNA gene (26S rDNA sequence), the internal transcribed spacer 1, the 5.8S ribosomal RNA gene, and the internal transcribed spacer 2 (the ITS sequence) from 46 strains of miso and soy sauce fermentation yeast, Zygosaccharomyces rouxii and a closely related species, Z. mellis, for typing. Based on the 26S rDNA sequence analysis, the Z. rouxii strains were of two types, and the extent of sequence divergence between them was 2.6%. Based on the ITS sequence analysis, they were divided into seven types (I–VII). Between the type strain (type I) and type VI, in particular, a 12% difference was detected. The occurrence of these nine genotypes with a divergence of more than 1% in these two sequences suggests that Z. rouxii is a species complex including novel species and hybrids. Z. mellis strains were of two types (type α and type β) based on the ITS sequence. Z. rouxii could clearly be distinguished from Z. mellis by 26S rDNA and ITS sequence analyses, but not by the 16% NaCl tolerance, when used as the sole key characteristic for differentiation between the two species.