锦葵科植物DNA条形码通用序列的筛选

对锦葵科植物样品的ITS、ITS2、rbcL、matK和psbA-trnH序列进行PCR扩增和测序,比较各序列的扩增效率、测序成功率、种内和种间变异的差异以及barcoding gap图,使用BLAST1和Nearest Distance方法评价不同序列的鉴定能力,进而从这些候选序列中筛选出较适合锦葵科植物鉴别的DNA条形码序列。结果表明,ITS序列在采集的锦葵科植物11个种26个样品中的扩增成功率较高,其种内、种间变异差异和barcoding gap较ITS2、psbA-trnH及rbcL序列具有更明显的优势,且纳入60个属316个种共1228个样品的网上数据后,其鉴定成功率可达89.9%。psbA-trnH序列的扩增和测序成功率最高,其鉴定成功率为63.2%,并能鉴别一些ITS序列无法鉴别的种。实验结果表明,ITS和psbA-trnH是较适合鉴别锦葵科植物的DNA条形码序列组合。     

锦葵科植物DNA条形码通用序列的筛选

对锦葵科植物样品的ITS、ITS2、rbcL、matK和psbA-trnH序列进行PCR扩增和测序, 比较各序列的扩增效率、测序成功率、种内和种间变异的差异以及barcoding gap图, 使用BLAST1和Nearest Distance方法评价不同序列的鉴定能力, 进而从这些候选序列中筛选出较适合锦葵科植物鉴别的DNA条形码序列。结果表明, ITS序列在采集的锦葵科植物11个种26个样品中的扩增成功率较高, 其种内、种间变异差异和barcoding gap较ITS2、psbA-trnH及rbcL序列具有更明显的优势, 且纳入60个属316个种共1 228个样品的网上数据后, 其鉴定成功率可达89.9%。psbA-trnH序列的扩增和测序成功率最高, 其鉴定成功率为63.2%, 并能鉴别一些ITS序列无法鉴别的种。实验结果表明, ITS和psbA-trnH是较适合鉴别锦葵科植物的DNA条形码序列组合。     

山葡萄种质资源DNA条形码通用序列的筛选

对山葡萄(Vitis amurensis)种质资源样品的ITS、ITS2、psb A-trn H、rbc L和mat K序列进行PCR扩增及测序,优化PCR反应的退火温度,比较各序列的扩增效率、测序成功率、品种间和品种内的差异及barcoding gap图,使用BLAST和NJ树法比较不同序列的鉴定能力,最终从5条DNA片段中筛选出可用于山葡萄种质资源鉴定的DNA条形码通用序列。结果表明,在采集的11份33个山葡萄样品中,psb A-trn H和ITS2序列的扩增与测序成功率较高,其品种间、品种内差异及barcoding gap较ITS、rbc L和mat K序列具有明显的优势,且ITS2序列能够鉴别psb A-trn H序列无法鉴别的品种。实验证明,ITS2和psb A-trn H序列是较适合鉴别山葡萄资源的DNA条形码序列组合。DNA条形码弥补了形态学鉴定的不足,可为山葡萄种质资源的准确鉴定提供科学依据。     

莪术基原植物DNA条形码序列的筛选与鉴定

为寻找适用于中药材莪术基原植物鉴定的DNA条形码序列,探索快速高效的莪术基原植物鉴定的新方法,该文首先利用扩增成功率和测序成功率对中药材莪术三种基原植物,9个样本的7种DNA条形码序列(ITS、ITS2、matK、psbA-trnH、trnL-trnF、rpoB和atpB-rbcL)进行评估,然后利用MEGA6.0软件...     

大型经济真菌的DNA条形码研究——以我国剧毒鹅膏为例

鹅膏属（Amanita）部分物种为重要食用真菌,而另外部分物种则是剧毒的,在我国及其他许多国家,每年都有因误食剧毒鹅膏而导致中毒甚至死亡的事件发生。DNA条形码是用一段或几段短的DNA序列来对物种进行快速、准确鉴定的方法。本研究选取三个候选片段,即核糖体大亚基（nLSU）、内转录间隔区（ITS）和翻译延长因子1-α（tef1-α）,使用真核生物通用引物,测试我国已知的7种剧毒鹅膏及2种易混的可食鹅膏,并将欧美分布的但与黄盖鹅膏（A.subjunquillea）亲缘关系密切的绿盖鹅膏（A.phalloides）纳入分析中。nLSU的PCR扩增和测序成功率均为100%,但种内和种间遗传变异偶有重叠。ITS的PCR扩增和测序成功率分别达到100%和85.7%,且具有高的种间变异和低的种内变异。tef1-α的PCR扩增和测序成功率分别达到85.7%和100%,种间和种内遗传分化均高于ITS和nLSU。三个片段的物种分辨率均较高,但与nLSU相比,ITS和tef1-α具有更为明显的barcode gap。鉴于ITS可能会成为真菌界的通用条码,故建议将ITS作为鹅膏属的核心条形码,tef1 α和nLSU作为该属的辅助条形码。     

COI基因作为丛赤壳科真菌DNA条形码的测试

以丛赤壳科33种76个菌株为材料,探讨COI基因作为该科DNA条形码的可能性。结果表明,该DNA片段存在较多内含子,为了获取某些种的短片段,需设计许多引物,PCR扩增与测序成功率低,难以达到便捷、快速的物种鉴定的目的。因此,COI不宜作为丛赤壳科的DNA条形码。对已获得的少数片段进行分析表明,该基因对丛赤壳科部分种具有较强的物种鉴别力。     

用于灵芝属10个物种快速鉴定的DNA条形码筛选与验证

灵芝栽培品种常出现同名异物或同物异名的现象,依赖于灵芝的形态学特征鉴定物种的传统分类方法不足以鉴定物种的种间和种内差异。为开发简便而准确的分子水平灵芝属物种鉴定方法,以常用于种属鉴定的核糖体内转录间隔区（ITS）、微管蛋白基因（β-tubulin）片段、大亚基核糖体DNA(LSU)片段和基因编码RNA聚合酶Ⅱ第二大亚基（RPB2）片段4个DNA条形码,对灵芝属10个物种的44份菌株进行PCR扩增和测序,比较4个条形码的扩增成功率和变异率,根据种内、种间遗传距离差异分析筛选特异性的DNA条形码间隔（DBG）,并利用单独及联合条形码构建系统发育树验证筛选的DBG鉴定灵芝属物种的准确性。研究结果表明：β-tubulin和LSU片段的PCR扩增成功率均达100%,ITS和RPB2片段分别为95.35%和90.91%;对比ITS和LSU片段,β-tubulin和RPB2片段的种内最大遗传距离分别小于各自的种间最小遗传距离,存在明显的DBG,有利于准确对物种进行种间鉴定;利用ITS、β-tubulin和RPB2片段分别构建的系统发育树均能使灵芝属10个物种的所有个体聚为1个单系分支,而LSU片段不...     

亚热带森林乔木树种DNA条形码研究——以哀牢山自然保护区为例

作为新一代植物志iFlora的重要组成部分,DNA条形码已经成为物种鉴定中重要且有效的方法。本研究以亚热带森林的乔木树种为研究对象,开展了DNA条形码的尝试性工作。为评估DNA条形码对鉴定亚热带森林树种的有效性,收集并研究了来自哀牢山自然保护区内5l科111属中204个树种的525个乔木个体。结果显示,所选4个DNA片段（rbcL,matK,trnH-psbA和ITS）的PCR扩增成功率都超过90％;测序成功率rbcL和matK最高,分别为90．7％和90．5％,trnH-psbA次之（83．6％）,ITS最低（73．5％）,表明4个片段在亚热带森林乔木中都具有较好的通用性。应用BLAST与NJ Tree两种方法,对物种和属水平的鉴别成功率进行统计,发现单片段中ITS最高,分别为68．4％-81．3％和99．0％～100％,核心条码rkL和matK组合的成功率是52．8％～60．2％和86．7％～90．5％,再与补充条码trnH-psbA和ITS联合,可以成功鉴别74．7％～79．6％哀牢山自然保护区亚热带森林中的乔木物种。由于ITS片段在亚热带森林部分重要树种类群（樟科和壳斗科等）中的测序成功率较差,所以对这些植物类群采用trnH-psbA作为DNA条形码是一个更好的选择。     

木霉属补充DNA条形码筛选

木霉属真菌是一类重要的生物资源,在工农业、环境保护等方面具有较高经济价值,对其进行快速、准确的物种鉴定兼具理论意义和应用前景。以木霉属35个概念清晰的种为材料,选择ITS、rpb2和 tef1作为候选基因序列,利用TaxonGap对231个序列片段进行分析,将种内与种间序列差异以及序列获取难易程度作为评价指标,筛选该属的补充条形码片段。结果表明,rpb2具有适宜的种内与种间序列差异,其最小的种间差异（2.48%）,大于最大种内差异（1.8%）,种内、种间遗传距离存在明显的间隔区,并且该基因序列具有较高的PCR扩增与测序成功率（94.4%）;ITS和tef1基因序列的种内与种间序列差异之间存在交叉重叠。因此建议rpb2作为木霉属的补充DNA条形码序列。     

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。     

DNA条形码(ITS2)在葫芦科鉴定中应用价值的评估

探讨在纳入分析数据时,数据信息的选择对ITS2序列作为DNA条形码在葫芦科植物中鉴定能力的影响。首先,建立由葫芦科植物ITS2序列组成的3个资料组,其中Dataset1为实验样本,Dataset2由实验样本及GenBank数据库样本组合,Dataset3为从Dataset2中去除部分序列后所得。通过比较3个资料组的种间、种内的变异、Barcoding Gap及鉴定成功率,评估纳入分析的数据选择差异对ITS2鉴定能力的影响。结果显示ITS2序列在3个资料组属水平上的鉴定成功率均达到100%;种水平上,用BLAST1法鉴定成功率分别为100%、 67.8%、 90.6%,Nearest Distance法鉴定成功率分别为100%、 52.5%、 66.5%。可见纳入分析的数据选择有差异时,会导致鉴定成功率的较大变化。3个资料组中,ITS2分析仅有Dataset2的Barcoding Gap不够显著。因此对于DNA条形码分析中的数据纳入标准,值得进一步研究。     

Identification of species within Tetrastigma (Miq.) Planch. (Vitaceae) based on DNA Barcoding Techniques

Many species of Tetrastigma (Miq.) Planch. (Vitaceae) have long been used as medicinal plants in China, and some are endangered due to overexploitation. Although adulterants are often added to traditional Chinese medicines, there is no reliable or practical method for identifying them. In this study, we used four markers (rbcL, matK, trnH-psbA, and internal transcribed spacer [ITS]) as DNA barcodes to test their ability to distinguish species of Tetrastigma. The results indicated that the best barcode was ITS, which showed significant inter-specific genetic variability, and thus its potential as a DNA barcode for identifying Tetrastigma. Multiple loci provided a greater ability to distinguish species than single loci. We recommend using the combined rbcL+matK+ITS barcode for the genus. Phylogenetic trees from each barcode were compared. Analyses using the unweighted pair group method with arithmetic mean discriminated an equal or greater percentage of resolvable species than did neighbor joining, maximum likelihood, or maximum parsimony analyses. Additionally, five medicinal species of Tetrastigma, especially T. hemsleyanum, could be identified precisely using DNA barcoding.     

Identification of species within Tetrastigma (Miq.) Planch.(Vitaceae) based on DNA barcoding techniques

Many species of Tetrastigma (Miq.) Planch. (Vitaceae) have long been used as medicinal plants in China, and some are endangered due to overexploitation. Although adulterants are often added to traditional Chinese medicines, there is no reliable or practical method for identifying them. In this study, we used four markers (rbcL, matK, trnH-psbA and internal transcribed spacer [ITS]) as DNA barcodes to test their ability to distinguish species of Tetrastigma. The results indicated that the best barcode was ITS, which showed significant inter-specific genetic variability, and thus its potential as a DNA barcode for identifying Tetrastigma. Multiple loci provided a greater ability to distinguish species than single loci. We recommend using the combined rbcL+matK+ITS barcode for the genus. Phylogenetic trees from each barcode were compared. Analyses using the unweighted pair group method with arithmetic mean discriminated an equal or greater percentage of resolvable species than did neighbor joining, maximum likelihood, or maximum parsimony analyses. Additionally, five medicinal species of Tetrastigma, especially T. Hemsleyanum, could be identified precisely using DNA barcoding.     

DNA barcoding of European Herbertus (Marchantiopsida, Herbertaceae) and the discovery and description of a new species

DNA barcoding of a group of European liverwort species from the genus Herbertus was undertaken using three plastid (matK, rbcL and trnH-psbA) and one nuclear (ITS) marker. The DNA barcode data were effective in discriminating among the sampled species of Herbertus and contributed towards the detection of a previously overlooked European Herbertus species, described here as H. norenus sp. nov. This species shows clear-cut differences in DNA sequence for multiple barcode regions and is also morphologically distinct. The DNA barcode data were also useful in clarifying taxonomic relationships of the European species with some species from Asia and North America. In terms of the discriminatory power of the different barcode markers, ITS was the most informative region, followed closely by matK. All species were distinguishable by ITS alone, rbcL + matK and various other multimarker combinations.     

Efficiency of DNA barcodes for species delimitation: A case in Pterygiella Oliv. (Orobanchaceae)

DNA barcoding is becoming an increasingly popular means to identify species. The obscure discrimination in the genus Pterygiella calls into question the re-assessment of the criterion for species delimitation. We collected 20 individuals, representing all five described species of this genus in its distributional range. The aim was to use three proposed barcode DNA regions (rbcL, matK, and ITS) to diagnose Pterygiella species, and examine which barcode is more suitable for discerning the congeneric and related species. The results showed that the core barcodes matK and rbcL were comparatively less effective. However, the ITS region, especially ITS-1 and ITS-2, successfully identified all species in the genus. Furthermore, the secondary structure of ITS-2 RNA, especially compensatory base changes, appears complementary to classical primary sequence analysis for DNA barcoding.     

DNA barcoding of the fungal genus <Emphasis Type="Italic">Neonectria</Emphasis> and the discovery of two new species

To determine a suitable DNA barcode for the genus Neonectria, the internal transcribed spacer rDNA, β-tubulin, EF-1α, and RPB2 genes were selected as candidate markers. A total of 205 sequences from 19 species of the genus were analyzed. Intra- and inter-specific divergences and the ease of nucleotide sequence acquisition were treated as criteria to evaluate the feasibility of a DNA barcode. Our results indicated that any single gene among the candidate markers failed to serve as a successful barcode, while the combination of the partial EF-1α, and RPB2 genes recognized all species tested. We tentatively propose the combined partial EF-1α and RPB2 genes as a DNA barcode for the genus. During this study, two cryptic species were discovered, based on the combined data of morphology and DNA barcode information. We described and named these two new species N. ditissimopsis and N. microconidia.     

Efficiency of DNA barcodes for species delimitation: A case in Pterygiella Oliv.(Orobanchaceae)

DNA barcoding is becoming an increasingly popular means to identify species. The obscure discrimination in the genus Pterygiella calls into question the re-assessment of the criterion for species delimitation. We collected 20 individuals, representing all five described species of this genus in its distributional range. The aim was to use three proposed barcode DNA regions (rbcL, matK, and ITS) to diagnose Pterygiella species, and examine which barcode is more suitable for discerning the congeneric and related species. The results showed that the core barcodes matK and rbcL were comparatively less effective. However, the ITS region, especially ITS-1and ITS-2, successfully identified all species in the genus. Furthermore, the secondary structure of ITS-2 RNA, especially compensatory base changes, appears complementary to classical primary sequence analysis for DNA barcoding.     

DNA Barcoding of Economically Important Mushrooms: A Case Study on Lethal Amanitas from China

Some species of the genus Amanita are economically important gourmet mushrooms, while others cause dramatic poisonings or even deaths every year in China and in many other countries. A DNA barcode is a short segment or a combination of short segments of DNA sequences that can distinguish species rapidly and accurately. To establish a standard DNA barcode for poisonous species of Amanita in China, three candidate markers, the large subunit nuclear ribosomal RNA (nLSU), the internal transcribed spacer (ITS), and the translation elongation factor 1 alpha (tef1 α) were tested using the eukaryotic general primers for their feasibility as barcodes to identify seven species of lethal fungi and two species of edible ones which can easily be confused with the lethal ones known from China. In addition, A.phalloides—a European and North American species closely related to one of the seven taxa, A.subjunquillea was also included. PCR amplification and sequencing success rate, intra and inter specific variation and rate of species identification were considered as main criteria for evaluation of the candidate DNA barcodes. Although the nLSU had high PCR and sequencing success rates (100% and 100% respectively), occasional overlapping occurred between the intra and inter specific variations. The PCR amplification and sequencing success rates of ITS were 100% and 85.7% respectively. ITS showed high sequence variation among species group and low variation within a given species. There was a relatively high PCR amplification and sequencing success rate for tef1 α (85.7% and 100% respectively), and its intra and inter specific variation was higher than that of ITS or nLSU. All three candidate markers showed hight species resolution. ITS and tef1 α had a more clearly defined barcode gap than nLSU. Our study showed that the tef1 α and nLSU can be proposed as supplementary barcodes for the genus Amanita, while ITS can be used as a primary barcode marker considering that the ITS region may become a universal barcode marker for the fungal kingdom.