植物物种的快速鉴定与iFlora: DNA条形码在马先蒿属中的应用

DNA条形码技术就是利用一段较短的标准DNA序列对物种进行快速鉴定。与基于植物外部形态特征的传统分类鉴定方法相比, DNA条形码具有高效、准确,且易于实现自动化和标准化的特点。马先蒿属（Pedicularis L.）植物具对生（轮生）叶的种类70%以上分布在中国,近缘种间形态上非常相似,鉴定较为困难。研究选取马先蒿属具对生（轮生）叶类群43种164份样品,利用叶绿体基因（rbcL、matK、trnH psbA）和核基因（ITS）条形码片段,采用建树法和距离法检验4个条形码对这些物种的鉴定效果。结果表明,ITS片段用于建树法和距离法的鉴别率分别为81.40%和89.57%,其鉴别率高于3个叶绿体基因片段和任一基因片段的组合条码。另外,利用ITS成功解决了一些疑难种的分类问题。DNA条形码在马先蒿属研究中的实用性为新一代植物志（iFlora）实现物种的快速和准确鉴定提供了有力支持,并能为分类学、生态学、进化生物学、居群遗传学和保护遗传学等分支学科的研究提供重要信息。     

植物物种的快速鉴定与iFlora：DNA条形码在马先蒿属中的应用

DNA条形码技术就是利用一段较短的标准DNA序列对物种进行快速鉴定。与基于植物外部形态特征的传统分类鉴定方法相比,DNA条形码具有高效、准确,且易于实现自动化和标准化的特点。马先蒿属（PedicularisL．）植物具对生（轮生）叶的种类70％以上分布在中国．近缘种间形态上非常相似,鉴定较为困难。研究选取马先蒿属具对生（轮生）叶类群43种164份样品,利用叶绿体基因（rbcL、matK、trnH-psbA）和核基因（ITS）条形码片段,采用建树法和距离法检验4个条形码对这些物种的鉴定效果。结果表明,ITS片段用于建树法和距离法的鉴别率分别为81．40％和89．57％,其鉴别率高于3个叶绿体基因片段和任一基因片段的组合条码。另外,利用ITS成功解决了一些疑难种的分类问题。DNA条形码在马先蒿属研究中的实用性为新一代植物志（iFlora）实现物种的快速和准确鉴定提供了有力支持,并能为分类学、生态学、进化生物学、居群遗传学和保护遗传学等分支学科的研究提供重要信息。     

蒟蒻薯属 (薯蓣科) 植物DNA条形码研究

蒟蒻薯属（Tacca）植物种间在形态上差别不大,导致分类上存在一定的困难。DNA条形码是一种利用短的DNA标准片段来鉴别和发现物种的方法。本研究利用核基因ITS片段和叶绿体基因trnH psbA, rbcL, matK片段对蒟蒻薯属6个种的DNA条形码进行研究,对4个DNA片段可用性,种内种间变异,barcode gap进行了分析,采用Tree based和BBA两种方法比较不同序列的鉴定能力。结果显示：单片段ITS正确鉴定率最高,片段组合rbcL+matK正确鉴定率最高。支持CBOL植物工作组推荐的条码组合rbcL+matK可作为蒟蒻薯属物种鉴定的标准条码,建议ITS片段作为候选条码。丝须蒟蒻薯Tacca integrifolia采自西藏的居群与马来西亚居群形成了2个不同的遗传分支,且两者在形态上也存在一定的差异,很可能是一个新种。     

DNA条形码分析方法研究进展

DNA条形码是一段短的、标准化的DNA序列,DNA条形码技术通过对DNA条形码序列分析实现物种的有效鉴定.随着生物DNA条形码序列的大量测定,DNA条形码分析方法得到迅速发展,推动了其在生物分子鉴定中的应用.2003年以来,DNA条形码技术已广泛应用于动物、植物和真菌等物种的鉴定,并有力地推动了生物分类学、生物多样性和生态学等学科的发展.本文在综述DNA条形码技术的基础上,总结了5类主要的DNA条形码分析方法,即基于遗传距离的分析、基于遗传相似度的分析、基于系统发育树的分析、基于序列特征的分析和基于统计分类法的分析,并进一步展望了DNA条形码技术的发展与应用.     

DNA条形码技术在植物中的研究现状

DNA条形码技术（DNA barcoding）是用短的DNA片段对物种进行识别和鉴定的分子生物学技术。在动物研究中该技术已经成功应用于利用线粒体细胞色素c氧化酶亚基I（COI）进行物种鉴定和发现隐种或新物种。相对于动物, COI基因在高等植物中进化速率较慢, 因此植物条形码研究以叶绿体基因组作为重点, 但目前还处于寻找合适的基因片段阶段。许多学者对此进行了积极的探索, 报道了多种植物条形码的候选片段或组合, 但还没有获得满足所有标准的特征位点片段。该文介绍了DNA条形码的标准、优点、工作流程及数据分析方法, 总结了DNA条形码在植物中的研究现状。     

植物DNA条形码在系统发育研究中的应用

<正>1常用植物DNA条形码物种的准确鉴定是开展科学研究和生物多样性保护的先决条件,但根据形态学特征进行物种鉴定对非专业人员而言比较困难。即使是专业人员,面对纷繁复杂的物种,要想逐一鉴定也难以实现。DNA条形码技术(DNA barcoding)为物种的快速、准确鉴定提供了可能(Hebert et al.,2003)。线粒体COI基因作为动物的DNA条形码已得到广泛应用。但对     

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。     

蒟蒻薯属(薯蓣科)植物DNA条形码研究

蒟蒻薯属(Tacca)植物种间在形态上差别不大,导致分类上存在一定的困难.DNA条形码是一种利用短的DNA标准片段来鉴别和发现物种的方法.本研究利用核基因ITS片段和叶绿体基因trn H-psbA,rbcL,matK片段对蒟蒻薯属6个种的DNA条形码进行研究,对4个DNA片段可用性,种内种间变异,barcode gap进行了分析,采用Tree-based和BBA两种方法比较不同序列的鉴定能力.结果显示:单片段ITS正确鉴定率最高,片段组合rbcL+matK正确鉴定率最高.支持CBOL植物工作组推荐的条码组合rbcL+matK可作为蒟蒻薯属物种鉴定的标准条码,建议ITS片段作为候选条码.丝须蒟蒻薯Tacca integrifolia采自西藏的居群与马来西亚居群形成了2个不同的遗传分支,且两者在形态上也存在一定的差异,很可能是一个新种.     

地黄属植物的DNA条形码研究

地黄属(Rehmannia)为玄参科(Scrophulariaceae)药用植物,广泛分布于中国中东部及北部地区。由于地黄属植物经历了快速成种,导致其属内物种间形态性状差异较小,运用传统的形态学分类方法已难以准确地鉴定物种,近年来迅速发展起来的DNA条形码技术为快速、准确地鉴别物种提供了新思路。本研究选用3个叶绿体DNA非编码区片段(trn L-trn F、trn M-trn V和trn S-trn G)及核基因ITS片段,运用PWG-distance和TreeBuilding两种方法对地黄属5个物种75个个体进行了DNA条形码分析。结果表明:单个叶绿体DNA片段或核基因ITS片段对地黄属物种的鉴别率较低(0%~20%),组合的叶绿体DNA片段分辨能力虽然高于单个DNA片段,但并不能将地黄属5个物种完全区分开;trn S-trn G+ITS片段组合的分辨率可达100%,能够将地黄属5个物种准确区分,与所有叶绿体DNA片段和核基因ITS片段组合(trn L-trn F+trn M-trn V+trn S-trn G+ITS)的辨别率相同,因此推荐trn S-trn G+ITS作为地黄属植物的标准条形码。此外,利用DNA条形码鉴别物种时,可采用叶绿体DNA片段和核DNA片段组合的方法来提高物种鉴定的成功率。     

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...     

Multilocus species identification and fungal DNA barcoding: insights from blue stain fungal symbionts of the mountain pine beetle

There is strong community-wide interest in applying molecular techniques to fungal species delimitation and identification, but selection of a standardized region or regions of the genome has not been finalized. A single marker, the ribosomal DNA internal transcribed spacer region, has frequently been suggested as the standard for fungi. We used a group of closely related blue stain fungi associated with the mountain pine beetle (Dendroctonus ponderosae Hopkins) to examine the success of such single-locus species identification, comparing the internal transcribed spacer with four other nuclear markers. We demonstrate that single loci varied in their utility for identifying the six fungal species examined, while use of multiple loci was consistently successful. In a literature survey of 21 similar studies, individual loci were also highly variable in their ability to provide consistent species identifications and were less successful than multilocus diagnostics. Accurate species identification is the essence of any molecular diagnostic system, and this consideration should be central to locus selection. Moreover, our study and the literature survey demonstrate the value of using closely related species as the proving ground for developing a molecular identification system. We advocate use of a multilocus barcode approach that is similar to the practice employed by the plant barcode community, rather than reliance on a single locus.     

Molecular analysis of the fungal microbiome associated with the olive fruit fly Bactrocera oleae

A molecular approach was used to investigate the fungal microbiome associated with Bactrocera oleae a major key pest of Olea europea, using the ITS2 region of the ribosomal DNA (rDNA) as barcode gene. Amplicons were cloned and a representative number of sequenced fragments were used as barcode genes for the identification of fungi. The analysis of the detected sequence types (STs) enabled the identification of a total of 34 phylotypes which were associated with 10 fungal species, 3 species complexes and 8 genera. Three phylotypes remained unresolved within the order Saccharomycetales and the phylum Ascomycota because of the lack of closely related sequences in GenBank. Cladosporium was the most abundantly detected genus, followed by Alternaria and Aureobasidium, well-known components of olive sooty moulds. Interestingly, Colletotrichum sp. and other fungal plant pathogens were also detected, leading to potential new insights into heir epidemiology.     

DNA barcoding to map the microbial communities: current advances and future directions

During the last two decades, the DNA barcode development towards microbial community has increased dramatically. DNA barcode development is related to error-free and quick species identification which aid in understanding the microbial biodiversity, as well as the diseases related to microbial species. Here, we seek to evaluate the so-called barcoding initiatives for the microbial communities and the emerging trends in this field. In this paper, we describe the development of DNA marker-based DNA barcoding system, comparison between routine species identification and DNA barcode, and microbial biodiversity and DNA barcode for microbial communities. Two major topics, such as the molecular diversity of viruses and barcode for viruses have been discussed at the same time. We demonstrate the current status and the maker of DNA barcode for bacteria, algae, fungi, and protozoa. Furthermore, we argue about the promises, limitations, and present and future challenges of microbial barcode development.     

A new promising phylogenetic marker to study the diversity of fungal communities: The Glycoside Hydrolase 63 gene

In molecular ecology, the development of efficient molecular markers for fungi remains an important research domain. Nuclear ribosomal internal transcribed spacer (ITS) region was proposed as universal DNA barcode marker for fungi, but this marker was criticized for Indel‐induced alignment problems and its potential lack of phylogenetic resolution. Our main aim was to develop a new phylogenetic gene and a putative functional marker, from single‐copy gene, to describe fungal diversity. Thus, we developed a series of primers to amplify a polymorphic region of the Glycoside Hydrolase GH63 gene, encoding exo‐acting α‐glucosidases, in basidiomycetes. These primers were validated on 125 different fungal genomic DNAs, and GH63 amplification yield was compared with that of already published functional markers targeting genes coding for laccases, N‐acetylhexosaminidases, cellobiohydrolases and class II peroxidases. Specific amplicons were recovered for 95% of the fungal species tested, and GH63 amplification success was strikingly higher than rates obtained with other functional genes. We downloaded the GH63 sequences from 483 fungal genomes publicly available at the JGI mycocosm database. GH63 was present in 461 fungal genomes belonging to all phyla, except Microsporidia and Neocallimastigomycota divisions. Moreover, the phylogenetic trees built with both GH63 and Rpb1 protein sequences revealed that GH63 is also a promising phylogenetic marker. Finally, a very high proportion of GH63 proteins was predicted to be secreted. This molecular tool could be a new phylogenetic marker of fungal species as well as potential indicator of functional diversity of basidiomycetes fungal communities in term of secretory capacities.     

Assessing the effect of varying sequence length on DNA barcoding of fungi

DNA barcoding shows enormous promise for the rapid identification of organisms at the species level. There has been much recent debate, however, about the need for longer barcode sequences, especially when these sequences are used to construct molecular phylogenies. Here, we have analysed a set of fungal mitochondrial sequences - of various lengths - and we have monitored the effect of reducing sequence length on the utility of the data for both species identification and phylogenetic reconstruction. Our results demonstrate that reducing sequence length has a profound effect on the accuracy of resulting phylogenetic trees, but surprisingly short sequences still yield accurate species identifications. We conclude that the standard short barcode sequences ( approximately 600 bp) are not suitable for inferring accurate phylogenetic relationships, but they are sufficient for species identification among the fungi.     

菌物DNA条形码技术原理与操作

DNA条形码技术是通过对1个较短目的基因的DNA序列进行分析从而进行物种鉴定的方法,它通过对1个或多个相关基因进行大范围的扫描,进而鉴定未知物种或者发现新种。当传统的分类学受到阻碍时,这种技术可以发挥其优势。相对于其他生物,菌物的生活史独特而复杂,这就使得对其进行的形态学鉴定要受到菌物自身生长发育时期的限制。国内外科学家对寻找适合于大多数菌物的标准DNA条码进行过探索,但还没有找到满足全部特征的基因片段。文中对DNA条形码技术的概念、原理依据、操作步骤和优缺点方面进行了介绍,并对DNA条形码技术在我国菌物研究方面的应用前景进行了展望。     

真菌DNA条形码技术研究进展

DNA条形码(DNA barcoding)技术作为一门新兴的物种鉴定方法以其灵敏、精确、方便和客观的优势,在动植物和微生物的分类鉴定中已经得到广泛应用.真菌鉴定中常用作标准条形码的是核核糖体DNA内转录间隔区(Internal transcribed spacer,ITS),如今也有一些新型条形码被发现和应用到实际操作中,如微条形码、ND6、EF3.本文对DNA条形码技术的产生和发展做出了总结,通过研究其在真菌中应用的实际案例分析了DNA条形码技术的优缺点及发展趋势,并指出DNA条形码技术将以全新的视角来弥补传统分类学的不足,最终实现生物自身的序列变异信息与现有形态分类学的结合.     

Recombinant DNA in filamentous fungi: progress and prospects

Recombinant DNA technology enables the creation of well-defined alterations in the genetic material of an organism. Methods to manipulate recombinant DNA in the filamentous fungi (a group of microorganisms that includes species of academic as well as commercial interest) have recently been developed. This has been the result of adaptation of procedures successfully employed in the manipulation of other microorganisms. There are a number of similarities in the behavior of recombinant DNA in different fungi, but a number of differences have also been observed between the filamentous and the nonfilamentous fungi. Such differences include the ability to identify DNA replication origins and the host range of expression of fungal genes.     

DNA barcoding in the rust genus Chrysomyxa and its implications for the phylogeny of the genus

Chrysomyxa rusts are fungal pathogens widely present in the boreal forest. Taxonomic delimitation and precise species identification are difficult within this genus because several species display similar morphological features. We applied a DNA barcode system based on the ribosomal internal transcribed spacer region (ITS), large subunit (28S) ribosomal RNA gene, mitochondrial cytochrome oxidase 1 (CO1) and mitochondrial NADH dehydrogenase subunit 6 (NAD6) in 86 strains from 16 different Chrysomyxa species, including members of the Chrysomyxa ledi species complex. The nuclear ITS and 28S loci revealed higher resolving power than the mitochondrial genes. Amplification of the full CO1 barcode region failed due to the presence of introns limiting the dataset obtained with this barcode. In most cases the ITS barcodes were in agreement with taxonomic species based on phenotypic characters. Nevertheless we observed genetically distinct (different DNA barcodes) lineages within Chrysomyxa pyrolae and Chrysomyxa rhododendri, providing some evidence for allopatric speciation within these morphologically defined species. This finding, together with the observed pattern of host specificities of the studied rust fungi, suggest that species diversification within the C. ledi species complex might be governed by a set of factors such as specialisation to certain Ericaceae species as telial hosts and to a lesser extent specialization to different spruce species as aecial hosts. Moreover allopatric speciation by geographic disruption of species also seems to take place. When our data were integrated into a broader phylogenetic framework the Chrysomyxa genus unexpectedly was not resolved as a monophyletic group. Indeed the spruce cone rusts C. pyrolae and C. monesis coalesced with the pine needle rusts belonging to the genus Coleosporium, whereas the microcyclic species Chrysomyxa weirii was embedded within a clade comprising the genus Melampsora.     

Selection of a DNA barcode for Nectriaceae from fungal whole-genomes

A DNA barcode is a short segment of sequence that is able to distinguish species. A barcode must ideally contain enough variation to distinguish every individual species and be easily obtained. Fungi of Nectriaceae are economically important and show high species diversity. To establish a standard DNA barcode for this group of fungi, the genomes of Neurospora crassa and 30 other filamentous fungi were compared. The expect value was treated as a criterion to recognize homologous sequences. Four candidate markers, Hsp90, AAC, CDC48, and EF3, were tested for their feasibility as barcodes in the identification of 34 well-established species belonging to 13 genera of Nectriaceae. Two hundred and fifteen sequences were analyzed. Intra- and inter-specific variations and the success rate of PCR amplification and sequencing were considered as important criteria for estimation of the candidate markers. Ultimately, the partial EF3 gene met the requirements for a good DNA barcode: No overlap was found between the intra- and inter-specific pairwise distances. The smallest inter-specific distance of EF3 gene was 3.19%, while the largest intra-specific distance was 1.79%. In addition, there was a high success rate in PCR and sequencing for this gene (96.3%). CDC48 showed sufficiently high sequence variation among species, but the PCR and sequencing success rate was 84% using a single pair of primers. Although the Hsp90 and AAC genes had higher PCR and sequencing success rates (96.3% and 97.5%, respectively), overlapping occurred between the intra- and inter-specific variations, which could lead to misidentification. Therefore, we propose the EF3 gene as a possible DNA barcode for the nectriaceous fungi.