入侵种的DNA条形码鉴定

生物安全研究的范畴涉及任何由生物威胁所造成的风险。随着害虫优先考虑级别的不断变化,以及国家和部门间相互协作的不断加强,对DNA分子鉴定技术的标准化提出了更迫切的要求,而DNA条形码的出现为此类问题的解决提供了很好的机遇。我们以前人对毒蛾和果蝇的研究为例,比较了DNA条形码技术与PCR-RFLP等传统方法的鉴定效果,在此基础上提出了建立一个可对不同入侵种进行快速和准确鉴定的条形码技术平台的构想。     

Towards a global barcode library for Lymantria (Lepidoptera: Lymantriinae) tussock moths of biosecurity concern

Background

Detecting and controlling the movements of invasive species, such as insect pests, relies upon rapid and accurate species identification in order to initiate containment procedures by the appropriate authorities. Many species in the tussock moth genus Lymantria are significant forestry pests, including the gypsy moth Lymantria dispar L., and consequently have been a focus for the development of molecular diagnostic tools to assist in identifying species and source populations. In this study we expand the taxonomic and geographic coverage of the DNA barcode reference library, and further test the utility of this diagnostic method, both for species/subspecies assignment and for determination of geographic provenance of populations.

Methodology/Principal Findings

Cytochrome oxidase I (COI) barcodes were obtained from 518 individuals and 36 species of Lymantria, including sequences assembled and generated from previous studies, vouchered material in public collections, and intercepted specimens obtained from surveillance programs in Canada. A maximum likelihood tree was constructed, revealing high bootstrap support for 90% of species clusters. Bayesian species assignment was also tested, and resulted in correct assignment to species and subspecies in all instances. The performance of barcoding was also compared against the commonly employed NB restriction digest system (also based on COI); while the latter is informative for discriminating gypsy moth subspecies, COI barcode sequences provide greater resolution and generality by encompassing a greater number of haplotypes across all Lymantria species, none shared between species.

Conclusions/Significance

This study demonstrates the efficacy of DNA barcodes for diagnosing species of Lymantria and reinforces the view that the approach is an under-utilized resource with substantial potential for biosecurity and surveillance. Biomonitoring agencies currently employing the NB restriction digest system would gather more information by transitioning to the use of DNA barcoding, a change which could be made relatively seamlessly as the same gene region underlies both protocols.     

A real‐time PCR toolbox for accurate identification of invasive fruit fly species

Significant plant pests such as fruit flies that travel with fresh produce between countries as eggs or larvae pose a great economic threat to the agriculture and fruit industry worldwide. Time‐limited and expensive quarantine decisions require accurate identification of such pests. Immature stages are often impossible to identify, making them a serious concern for biosecurity agencies. Use of COI barcoding PCR, often the only molecular identification resource, is time‐consuming. We assess the suitability of the COI barcoding region for real‐time PCR assays to identify four pest fruit fly species (Family: Tephritidae), in a diagnostic framework. These species, namely Mediterranean fruit fly (Ceratitis capitata), Queensland fruit fly (Bactrocera tryoni), African invader fly (Bactrocera invadens) and Island fly (Dirioxa pornia) each provide a different set of genetic species delimitation problems. We discuss the benefits and limitations of using a single‐gene TaqMan^? real‐time approach for such species. Our results indicate that COI‐based TaqMan^? real‐time PCR assays, in particular for genetically distinct species, provide an accurate, sensitive and rapid diagnostic tool.     

Comparative studies on species identification of Noctuoidea moths in two nature reserve conservation zones (Beijing,China) using DNA barcodes and thin‐film biosensor chips

Rapid and accurate identification of species is required for the biological control of pest Noctuoidea moths. DNA barcodes and thin‐film biosensor chips are two molecular approaches that have gained wide attention. Here, we compare these two methods for the identification of a limited number of Noctuoidea moth species. Based on the commonly used mitochondrial gene cytochrome c oxidase I (the standard DNA barcode for animal species), 14 probes were designed and synthesized for 14 species shared by two national nature reserves in Beijing and Hebei, China. Probes ranged in length from 18 to 27 bp and were designed as mismatch probes to guarantee that there were at least three base differences between the probe and nontarget sequences. The results on the chip could be detected by the naked eye without needing special equipment. No cross‐hybridizations were detected although we tested all probes on the 14 target and 24 nontarget Noctuoidea species. The neighbour‐joining tree of the 38 species based on COI sequences gave 38 highly supported independent groups. Both DNA barcoding and thin‐film biosensor chips, based on the COI gene, are able to accurately identify and discriminate the 14 targeted moth species in this study. Because of its speed, high accuracy and low cost, the thin‐film biosensor chip is a very practical means of species identification. Now, a more comprehensive chip will be developed for the identification of additional Noctuoidea moths for pest control and ecological protection.     

云南边境地区果实蝇属种类DNA条形码鉴定

【目的】果实蝇属Bactrocera中有国际上重要的检疫性害虫, 基于形态的物种鉴定有一定的局限性。另一方面, 云南边境地区为东南亚地区实蝇入侵我国的重要通道。因此, 对该地区实蝇分子鉴定方法的研究对于该属物种的快速准确鉴定具有重要意义。本研究旨在探讨DNA条形码技术在果实蝇属物种鉴定中的有效性。【方法】使用线粒体基因COI和COII序列的通用引物对果实蝇属20个物种60份样品进行PCR扩增、测序和序列分析; 采取距离方法和建树方法评价2种序列的鉴别能力。【结果】COI和COII序列平均长度分别为682 bp和339 bp, 种内和种间遗传差异较大, 有较明显的遗传距离间隔（barcoding gap）, 鉴定成功率分别为91.2%和90.7%。另外, 分子系统树表明华实蝇亚属Sinodacus不是单系群。【结论】COI和COII序列均能够将绝大多数果实蝇属物种进行准确鉴别, 应用COI或COII序列进行果实蝇属物种鉴定具有一定的可行性。     

Plant DNA barcoding: from gene to genome

DNA barcoding is currently a widely used and effective tool that enables rapid and accurate identification of plant species; however, none of the available loci work across all species. Because single‐locus DNA barcodes lack adequate variations in closely related taxa, recent barcoding studies have placed high emphasis on the use of whole‐chloroplast genome sequences which are now more readily available as a consequence of improving sequencing technologies. While chloroplast genome sequencing can already deliver a reliable barcode for accurate plant identification it is not yet resource‐effective and does not yet offer the speed of analysis provided by single‐locus barcodes to unspecialized laboratory facilities. Here, we review the development of candidate barcodes and discuss the feasibility of using the chloroplast genome as a super‐barcode. We advocate a new approach for DNA barcoding that, for selected groups of taxa, combines the best use of single‐locus barcodes and super‐barcodes for efficient plant identification. Specific barcodes might enhance our ability to distinguish closely related plants at the species and population levels.     

Rapid, one-step DNA extraction for insect pest identification by using DNA barcodes

Early detection of economically important insects is critical to preventing their establishment as serious pests. To accomplish this, tools for rapid and accurate species identification are needed. DNA barcoding, using short DNA sequences as species "genetic identification tags," has already shown large potential as a tool for rapid and accurate detection of economically important insects. DNA extraction is the critical first step in generating DNA barcodes and can be a rate-limiting step in very large barcoding studies. Consequently, a DNA extraction method that is rapid, easy to use, cost-effective, robust enough to cope with range of qualities and quantities of tissue, and can be adapted to robotic systems will provide the best method for high-throughput production of DNA barcodes. We tested the performance of a new commercial kit (prepGEM), which uses a novel, streamlined approach to DNA extraction, and we compared it with two other commercial kits (ChargeSwitch and Aquapure), which differ in their method of DNA extraction. We compared performance of these kits by measuring percentage of polymerase chain reaction (PCR) success and mean PCR product yield across a variety of arthropod taxa, whichincluded freshly collected, ethanol-preserved, and dried specimens of different ages. ChargeSwitch and prepGEM performed equally well, but they outperformed Aquapure. prepGEM was much faster, easier to use, and cheaper than ChargeSwitch, but ChargeSwitch performed slightly better for older (> 5-yr-old) dried insect specimens. Overall, prepGEM may provide a highly streamlined method of DNA extraction for fresh, ethanol-preserved, and young, dried specimens, especially when adapted for high-throughput, robotic systems.     

20 years since the introduction of DNA barcoding: from theory to application

Traditionally, taxonomic identification has relied upon morphological characters. In the last two decades, molecular tools based on DNA sequences of short standardised gene fragments, termed DNA barcodes, have been developed for species discrimination. The most common DNA barcode used in animals is a fragment of the cytochrome c oxidase (COI) mitochondrial gene, while for plants, two chloroplast gene fragments from the RuBisCo large subunit (rbcL) and maturase K (matK) genes are widely used. Information gathered from DNA barcodes can be used beyond taxonomic studies and will have far-reaching implications across many fields of biology, including ecology (rapid biodiversity assessment and food chain analysis), conservation biology (monitoring of protected species), biosecurity (early identification of invasive pest species), medicine (identification of medically important pathogens and their vectors) and pharmacology (identification of active compounds). However, it is important that the limitations of DNA barcoding are understood and techniques continually adapted and improved as this young science matures.     

桔小实蝇幼体及成虫残体DNA条形码识别技术的建立与应用

实蝇类害虫多为国内外检疫对象, 其鉴定识别方法主要依据成虫的外部形态特征, 而传统的形态学识别法对口岸经常截获的幼体及残缺的虫体, 则无能为力。本研究以桔小实蝇Bactrocera dorsalis的幼体（卵、 幼虫、 蛹）以及成虫残体（足、 翅、 头部、 胸部、 腹部）为对象, 利用 DNA 条形码技术, 构建实蝇类害虫快速鉴定技术体系, 并以其他4种常见实蝇（包括番石榴实蝇B. correcta、 瓜实蝇B. cucurbitae、 南亚果实蝇B. tau、 柑桔大实蝇B. minax）为对象对该技术体系进行应用验证。结果显示, 桔小实蝇幼体以及成虫残体的碱基序列与数据库中靶标种COⅠ基因碱基序列的一致性为99.51%~99.84%, 其他4种实蝇相应序列与数据库中靶标种COⅠ基因序列的一致性分别为100%, 100%, 99.81%~99.83%和100%; 以邻接法（NJ法）构建系统发育树, 靶标种实蝇均与数据库中对应种实蝇聚为一支, 且置信度均为100%。以K2-P模型计算种内及种间遗传距离得出, 5种实蝇的种间遗传距离为0.0597~0.2363, 平均为0.1693; 种内遗传距离为0.0000~0.0041, 平均为0.0019。这些结果表明, 基于DNA条形码的物种识别技术完全可用于口岸截获的实蝇类害虫幼体及残体的准确鉴定。     

Loop-Mediated Isothermal Amplification Combined with PCR for Rapid Identification of the Ethiopian Fruit Fly (Diptera: Tephritidae)

Nowadays, with increasing trend of trans-boundary transportation of agricultural products and higher probability of introduction of many invasive species into new areas, fast and precise species diagnosis is of great significance particularly at the port of entry, where morphological identification often requires adult insect specimens especially with specialist insects. The cucumber fruit fly, Dacus ciliatus Loew (Diptera: Tephritidae), ranks as one of the most destructive agricultural pests attacking mainly fruits of Cucurbitaceae. This pest is also widespread and highly invasive; thus, it is a high priority for pest detection and quarantine programs. Although cucumber fruit fly adults can usually be identified and distinguished from the other species by morphological keys, it is often difficult or impossible to distinguish this species from the other tephritids that share host plants by using material from other stages of development. In such situations, using a quick and robust alternative species diagnostic tool would be valuable. In this study, we assessed a technique combining loop-mediated isothermal amplification (LAMP) with PCR (PCR-LAMP) for the rapid detection and discrimination of cucumber fruit fly DNA from some other common tephritid species attacking Cucurbitaceae, using material from different stages of development. The described method was species-specific and sensitive and provided a rapid diagnostic tool to detect D. ciliaus even by non-experts.     

山西翅果油树上三种重要鳞翅目害虫的形态 和分子鉴定及生活史观察

【目的】明确山西翅果油树Elaeagnus mollis上发生危害的3种鳞翅目害虫形态鉴定特征及生活史特性,并基于mtDNA COI基因DNA条形码对这3个种进行快速物种识别鉴定。【方法】通过观察山西翅果油树上3种鳞翅目害虫成虫外部形态和解剖拍照雌、雄性外生殖器特征,利用PCR扩增对待测样本COI基因DNA条形码序列进行测定,与GenBank数据库中同源序列进行比对,基于COI基因DNA条形码序列构建邻接树 (neighborjoining, NJ),结合形态学研究结果对这3种鳞翅目害虫开展种类鉴定。【结果】形态学鉴定结果表明,危害山西翅果油树的3种鳞翅目害虫为榆兴透翅蛾Synanthedon ulmicola、兴透翅蛾Synanthedon sp.和斜纹小卷蛾Apotomis sp.。对这3个种的外部形态和雌、雄性外生殖器鉴别特征进行了描述和绘图。DNA条形码序列比对分析结果显示,榆兴透翅蛾与GenBank数据库中Synanthedon sequoiae的COI基因核苷酸序列一致性为90.7%,兴透翅蛾与GenBank数据库中Synanthedon spheciformis的COI基因核苷酸序列一致性为90.0%,斜纹小卷蛾与GenBank数据库中Apotomis capreana的COI基因核苷酸序列一致性为92.7%,NJ树聚类分析结果显示3个种分别形成明显的单系分支,与形态学和序列比对鉴定结果相吻合。【结论】本研究基于形态学鉴定和COI基因DNA条形码分子鉴定明确了危害山西翅果油树的3种鳞翅目害虫——榆兴透翅蛾、兴透翅蛾和斜纹小卷蛾,并提供了3个种的形态鉴定特征、生活史资料,为重要经济树种翅果油树的害虫防治提供了理论依据和科学资料。     

Barcoding aphids (Hemiptera: Aphididae) of the Korean Peninsula: updating the global data set

DNA barcode (mitochondrial COI) sequences are provided for species identification of aphids from the Korean Peninsula. Most (98%) of the 154 species had distinct COI sequences (average 0.05% intraspecific pairwise divergence) relative to the degree of sequence divergence among species (average value 5.84%). For species in common with other regions, barcodes for Korean samples fell near or within known levels of variation. Based on these results, we conclude that DNA barcodes can provide an effective tool for identifying aphid species in such applications as pest management, monitoring and plant quarantine.     

北京地区7种常见嗜尸性蝇类的COI基因序列分析及DNA条形码的建立

嗜尸性蝇类在命案死亡时间和现场推断方面有着十分重要的应用, 而DNA 条形编码技术能摆脱对虫卵和幼虫的饲养以及后续物种鉴定方面专业知识的依赖, 有助于实现现场采集蝇类样本的快速鉴定。本研究采集了北京地区7个嗜尸性蝇类优势种共77个个体的样本, 测定了所有个体线粒体DNA 上细胞色素C氧化酶亚基Ⅰ（COI）基因1 120 bp的序列。基于序列的系统发生分析显示, 同一物种不同个体的序列均以高达99%的支持值聚集在一起。序列间的分歧统计表明这些蝇类在物种内的个体分歧不超过1%, 而不同物种间的净分歧均超过7.74%, 最高可达14.85%。滑动窗口分析表明, 在整个序列区段种间差异位点存在较平均的分布。通过测定COI基因的序列, 建立了北京地区7个嗜尸性蝇类优势种的DNA条形码, 据此实现了对这些物种准确、快速、简单的区分和鉴定, 同时也为后续应用于物种鉴定的种属特异性位点之筛选提供了基础数据。     

Utility of GenBank and the Barcode of Life Data Systems (BOLD) for the identification of forensically important Diptera from Belgium and France

Fly larvae living on dead corpses can be used to estimate post-mortem intervals. The identification of these flies is decisive in forensic casework and can be facilitated by using DNA barcodes provided that a representative and comprehensive reference library of DNA barcodes is available.We constructed a local (Belgium and France) reference library of 85 sequences of the COI DNA barcode fragment (mitochondrial cytochrome c oxidase subunit I gene), from 16 fly species of forensic interest (Calliphoridae, Muscidae, Fanniidae). This library was then used to evaluate the ability of two public libraries (GenBank and the Barcode of Life Data Systems – BOLD) to identify specimens from Belgian and French forensic cases. The public libraries indeed allow a correct identification of most specimens. Yet, some of the identifications remain ambiguous and some forensically important fly species are not, or insufficiently, represented in the reference libraries. Several search options offered by GenBank and BOLD can be used to further improve the identifications obtained from both libraries using DNA barcodes.     

ITS2 sequences as barcodes for identifying and analyzing spider mites (Acari: Tetranychidae)

The use of DNA barcodes, short DNA sequences from a standardized region of the genome, has recently been proposed as a tool to facilitate species identification and discovery. Here we show that second internal transcribed spacer of nuclear ribosomal DNA (rDNA-ITS2) barcodes effectively discriminate among 16 species of spider mites (Acari: Tetranychidae) from Israel. The barcode sequences of each species were unambiguously distinguishable from all other species and formed distinct, nonoverlapping monophyletic groups in the maximum-parsimony tree. Sequence divergences were generally much greater between species than within them. Using a 0.02 (2%) threshold for species diagnosis in our data set, 14 out of 16 species recognized by morphological criteria would be accurately identified. The only exceptions involved the low divergence, 0.011–0.015 (1.1–1.5%), between Tetranychus urticae and Tetranychus turkestani, where speciation may have occurred only recently. Still, these species had fixed alternative rDNA-ITS2 variants, with five diagnostic nucleotide substitutions. As a result, we tentatively conclude that rDNA-ITS2 sequence barcodes may serve as an effective tool for the identification of spider mite species and can be applicable as a diagnostic tool for quarantine and other pest management activities and decision-making. We predict that our work, together with similar efforts, will provide in the future the platform for a uniform, accurate, practical and easy-to-use method of spider mite species identification.     

Design and applicability of DNA arrays and DNA barcodes in biodiversity monitoring

Background  

The rapid and accurate identification of species is a critical component of large-scale biodiversity monitoring programs. DNA arrays (micro and macro) and DNA barcodes are two molecular approaches that have recently garnered much attention. Here, we compare these two platforms for identification of an important group, the mammals.     

Differentiation between Aphis pomi and Aphis spiraecola using multiplex real‐time PCR based on DNA barcode sequences

The green apple aphid (Aphis pomi) and the spirea aphid (Aphis spiraecola) are pests of apples in North America. Although management regimes exist to effectively control these pests, they differ significantly because of varying susceptibility of each species to common pesticides and differences in their life cycles. Therefore, accurate identification of the species present is essential for pest control. However, the identification process is complicated because of the morphological similarity between these two species. As a result, confusion between A. pomi and A. spiraecola often occurs. DNA barcoding has been proven to accurately identify species of Aphididae. A further study demonstrated that DNA barcodes could be used to accurately differentiate A. pomi and A. spiraecola. DNA barcoding represents an important step towards rapid identification of these pests as distinctions can be easily made between morphologically similar species as well as from eggs and immature individuals in addition to adults. However, samples must still be sent to specially equipped facilities for sequence analysis, which can take between several hours and days. Real‐time PCR is emerging as a useful tool for more rapid pest identification. The purpose of this study was to develop a real‐time PCR assay for differentiation of A.pomi from A. spiraecola based on DNA barcode sequences from the Barcode of Life Data System. This assay was designed on the portable SmartCycler II platform and can be used in field settings to differentiate these species quickly and accurately. It has the potential to be a valuable tool to improve pest management of A. pomi and A. spiraecola.     

Promise and Challenge of DNA Barcoding in Venus Slipper (Paphiopedilum)

Orchidaceae are one of the largest families of flowering plants, with over 27,000 species described and all orchids are listed in CITES. Moreover, the seedlings of orchid species from the same genus are similar. The objective of DNA barcoding is rapid, accurate, and automated species identification, which may be used to identify illegally traded endangered species from vegetative specimens of Paphiopedilum (Venus slipper), a flagship group for plant conservation with high ornamental and commercial values. Here, we selected eight chloroplast barcodes and nrITS to evaluate their suitability in Venus slippers. The results indicate that all tested barcodes had no barcoding gap and the core plant barcodes showed low resolution for the identification of Venus slippers (18.86%). Of the single-locus barcodes, nrITS is the most efficient for the species identification of the genus (52.27%), whereas matK + atpF-atpH is the most efficient multi-locus combination (28.97%). Therefore, we recommend the combination of matK + atpF-atpH + ITS as a barcode for Venus slippers. Furthermore, there is an upper limit of resolution of the candidate barcodes, and only half of the taxa with multiple samples were identified successfully. The low efficiency of these candidate barcodes in Venus slippers may be caused by relatively recent speciation, the upper limit of the barcodes, and/or the sampling density. Although the discriminatory power is relatively low, DNA barcoding may be a promising tool to identify species involved in illegal trade, which has broad applications and is valuable for orchid conservation.     

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。     

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。