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.     

DNA条形码及其在生物多样性研究中的应用

DNA条形码是利用生物体内标准的、有足够变异的、易扩增且相对较短的DNA片段对物种进行快速准确鉴定的技术。自2003年DNA条形码相关概念提出以来广受关注,国内外相继开展了DNA条形码及信息系统建设研究,为DNA条形码技术的发展提供了坚实的研究基础和生物信息学分析平台。DNA条形码技术弥补了传统分类学的不足,为生物多样性研究提供了新的思路和方法。本文介绍了DNA条形码的产生与发展过程,国内外DNA条形码技术与信息系统建设研究进展,重点阐述了DNA条形码技术在物种鉴定、濒危物种保护、隐存种发现、生物多样性评估等研究领域中的应用。最后结合DNA条形码技术目前存在的问题,对其在相关研究领域的应用前景进行了展望。     

应用DNA条形码对植物标本的核查

DNA条形码主要目的是物种鉴定和新物种或隐存种的发现,而DNA条形码参考数据库是物种快速鉴定的重要基础。目前中国维管植物DNA条形码参考数据库正在建设之中,借助于公共数据库（NCBI）和初步建立的中国植物DNA条形码参考数据库,运用DNA条形码数据开展了植物标本鉴定的核查工作：（1）比较DNA序列信息与标本鉴定信息,从科、属、种级水平查找鉴定错误的标本;（2）基于有较好研究基础的DNA条形码参考数据库,开展未知标本的鉴定;（3）通过对标本核查的总结,提出DNA条形码参考数据库建设过程中的几点建议。     

关于植物DNA条形码研究技术规范

DNA条形码是利用标准的基因片段对物种进行快速鉴定的技术,已经成功用于生物物种分类和鉴定、生态学调查和生物多样性评估等研究领域。尽管生命条形码数据（BOLD）系统提供了主要针对动物类群DNA条形码研究的技术规范,但由于植物本身的生物学特性与所使用的条形码不同,因此已有技术规范并不完全适用于植物DNA条形码的研究。本文根据植物DNA条形码研究的特点与我国的实际情况,编写了植物DNA条形码研究技术标准和规范指南,具体包括十个方面的内容,即植物DNA条形码研究的样品采集策略;植物标本和野外数据的采集规范;植物标本图像信息的采集规范;植物DNA材料的采集规范;植物DNA材料的干燥与保存规范;植物总DNA的质量标准及保存规范;植物标准DNA条形码的选择与通用引物;DNA条形码的扩增与测序;DNA条形码数据的命名、编辑和提交规范;以及DNA条形码数据分析。我们期望通过这些标准规范的实施和在实践中的不断修订和完善,能为我国学者开展植物DNA条形码和iFlora研究提供参考和借鉴。
关键词：植物DNA条形码;技术规范;物种鉴定;标准;新一代植物志     

线粒体COⅠ基因在昆虫DNA条形码中的研究与应用

自2003年DNA条形码(DNA barcodes)概念出现以来,DNA条形码技术(DNA barcoding)受到生物分类学领域普遍关注,线粒体细胞色素氧化酶亚基I(mtDNACOⅠ)被用作动物类群的主要条形码序列,基于该基因片段的昆虫条形码研究在国内外广泛开展。本文在概述DNA条形码、条形码技术及已开展的昆虫条形码研究计划的基础上,总结了昆虫mtDNACOⅠ条形码及其技术在发现和描述隐种、种类分子鉴定以及系统发育等方面的研究进展,分析了细胞核线粒体假基因(Numts)对mtDNACOⅠ条形码扩增的影响,提出检测和避免Numts的方法,并对DNA条形码技术的进一步研究和应用进行了讨论和展望。     

藻类DNA条形码研究进展

DNA barcode,又称为DNA条形码,是指利用短的标准DNA序列的核苷酸多样性进行物种的鉴定和快速识别.目前该方法在动物分类研究中应用广泛,其中线粒体的细胞色素c氧化酶亚基1(cytochrome c oxidase subunit 1,COI或cox 1)基因中的约700bp长度的一段被用来作为标准DNA片段.在陆地植物条形码研究中,生命-植物条形码联盟会(Consortium for the Barcode of Life-Plant Working Group,CBOL-Plant Working Group)近期推荐将植物叶绿体中的两个基因片段rbcL+ matK作为初步的陆生植物条形码,此组合能在70％的程度上进行植物物种的鉴别.在海藻的分类研究中,DNA条形码的应用较少,已有的研究主要集中在硅藻、红藻和褐藻,尚没有学者明确提出适合藻类的DNA条形码.总结了能够作为藻类DNA条形码的序列特点、应用流程及分析方法,综述了DNA条形码在藻类中的研究现状和存在的问题,展望了藻类DNA条形码的应用前景.     

DNA条形码在鞘翅目昆虫分子系统学研究中的应用

近年来,DNA条形码(DNA Barcoding)技术已经成为生物分类学研究中备受关注的新型技术,并在鞘翅目昆虫系统发育研究中得到广泛应用。本文总结了鞘翅目昆虫DNA条形码研究所用COⅠ基因序列,概述了DNA条形码在鞘翅目昆虫的物种分类鉴定、发现新种和隐存种、系统发育关系研究等方面的应用,并对DNA条形码研究技术新进展和标准序列筛选需要注意的问题进行了讨论。     

DNA条形码的应用进展及讨论

DNA条形码(DNA Barcoding)是近几年来国际生物学研究的热点之一.但是在国内,相关概念还存在不同程度的模糊,不利于研究工作的进一步开展.本文在对DNA条形码与DNA分类（DNA Taxonomy）两个不同概念进行辨析的基础上,回顾与总结了DNA条形码的产生背景与应用进展,并对DNA条形码目前所面临的基因交流...     

基于DNA条形码的物种丰富度估计: 以宿迁地区鳞翅目蛾类为例

为了探究基于DNA条形码方法量化物种多样性指标的可行性, 本研究以江苏省宿迁地区蛾类群落为例, 基于DNA条形码方法估计群落物种丰富度并绘制等级多度分布曲线(rank-abundance curves), 同时与基于传统形态学的对应指标进行比较。结果表明: (1)基于DNA条形码的物种丰富度估计与基于形态的物种丰富度估计之间没有显著差异; (2)基于形态和DNA条形码的等级多度分布曲线趋势一致, 通过K-S检测发现二者之间没有显著性差异(P > 0.05)。结果显示, 基于DNA条形码的物种丰富度估计能够在一定程度上补充基于形态学的方法, 可以尝试将其应用于蛾类群落生态学调查研究中。     

药用植物DNA条形码鉴定研究进展

DNA条形码是利用相对较短的标准DNA片段对物种进行快速准确鉴定的一门技术。DNA条形码技术可以从分子水平弥补传统鉴定方法的一些不足。该技术具有良好的通用性,使得物种鉴定过程更加快速,已经广泛应用于动物物种的鉴定研究中。近年来,随着药用植物DNA条形码鉴定研究的快速发展,逐渐形成了药用植物和植物源中药材鉴定的完善体系。本文综述了DNA条形码技术鉴定药用植物的原理,介绍了中草药传统鉴定方法及其缺陷、使用DNA条形码技术鉴定植物源药材的意义以及DNA条形码在药用植物鉴定中的应用,对其应用前景进行了展望。     

Ancient plant DNA: review and prospects

Ancient DNA has received much attention since the mid-1980s, when the first sequence of an extinct animal species was recovered from a museum specimen. Since then, the majority of ancient DNA studies have focused predominantly on animal species, while studies in plant palaeogenetics have been rather limited, with the notable exception of cultivated species found in archaeological sites. Here, we outline the recent developments in the analysis of plant ancient DNA. We emphasize the trend from species identification to population-level investigation and highlight the potential and the difficulties in this field, related to DNA preservation and to risks of contamination. Further efforts towards the analysis of ancient DNA from the abundant store of fossil plant remains should provide new research opportunities in palaeoecology and phylogeography. In particular, intraspecific variation should be considered not only in cultivated plants but also in wild taxa if palaeogenetics is to become a fully emancipated field of plant research.     

Forensic DNA analysis for animal protection and biodiversity conservation: A review

The use of DNA analysis in forensic investigations into animal persecution and biodiversity conservation is now commonplace and crimes such as illegal collection/smuggling, poaching, and illegal trade of protected species are increasingly being investigated using DNA based evidence in many countries. Using DNA analysis, it is possible to identify the species and geographical origin (i.e. population) of a forensic sample, and to also individualise the sample with high levels of probability. Despite extensive literature in animal species, there is unfortunately a serious lack of information on plant species, with only a handful of recent studies. In this review, I detail the applications and diverse forensic investigations that have been carried out to date whilst also highlighting recent developmental studies which offer forensic potential for many species in the future.     

Plant histones. Relevance to the evolution of prokaryotes to eukaryotes

There are many procaryotic and eucaryotic organisms in plant kingdom. It is hoped that the study of plant histones will be useful in evolutionary studies. The histones of great variety of animal species have been studied and well characterized. Less information is available concerning plant histones. The general conclusion drawn from these investigations is that most organisms of eucaryotic plant and animal species contain the same five major histone fractions. Recently the histone-like proteins were found in some primitive eucaryotes and procaryotes. Data on histones from higher and lower eucaryotes and histone-like proteins of procaryotes are reviewed. Evolution of histones and their appearance prior to that of eucaryotic cell is postulated. The role of histones in evolution of nucleosomes is discussed.     

A comparative study of distant hybridization in plants and animals

Distant hybridization refers to crosses between two different species, genera, or higher-ranking taxa, which can break species limits, increase genetic variation, and combine the biological characteristics of existing species. It is an important way of creating genetic variation, fertile strains, and excellent characteristics in new strains and populations. Combining analyses and summaries from many inter-related documents in plants and animals, both domestic and international, including examples and long-standing research on distant hybridization in fish from our laboratory, we summarize and compare the similarities and differences in plant and animal distant hybridization. In addition, we analyze and review the biological characteristics of their different ploidy progenies and the possible causes of disparity in survival rates. Mechanisms of sterility in animal and plant distant hybrids are also discussed, and research methods for the study of biological characteristics of hybrids, including morphology, cytology,and molecular cytogenetics are presented. This paper aims to provide comprehensive research materials and to systematically compare the general and specific characteristics of plant and animal hybrids with regards to reproduction, genetics, growth traits,and other biological characteristics. It is hoped that this paper will have great theoretical and practical significance for the study of genetic breeding and biological evolution of plant and animal distant hybridization.     

Death by proteases in plants: whodunit

Several studies have shown that protease inhibitors can suppress programmed cell death in various plant species and plant tissues. This is especially true of caspase inhibitors that can block programmed cell death and its marker DNA laddering. There are up to six different caspase-like activities that can be measured in plant extracts, the most prominent being caspase1-like and caspase3-like. These activities can be located in vacuoles and also in the nucleus or the cytoplasm. This represents a striking apparent similarity with animal programmed cell death. Because there are no caspase orthologue in plant genomes, a major challenge is to identify these proteases. Recently two proteases with caspase-like activities have been recognized as belonging to two different protease families that are not closely related to animal caspases. Various other protease families have been implicated and this suggests that complex protease networks have been recruited for the plant cell demise.     

Molecular biomarkers for chronological age in animal ecology

The chronological age of an individual animal predicts many of its biological characteristics, and these in turn influence population‐level ecological processes. Animal age information can therefore be valuable in ecological research, but many species have no external features that allow age to be reliably determined. Molecular age biomarkers provide a potential solution to this problem. Research in this area of molecular ecology has so far focused on a limited range of age biomarkers. The most commonly tested molecular age biomarker is change in average telomere length, which predicts age well in a small number of species and tissues, but performs poorly in many other situations. Epigenetic regulation of gene expression has recently been shown to cause age‐related modifications to DNA and to cause changes in abundance of several RNA types throughout animal lifespans. Age biomarkers based on these epigenetic changes, and other new DNA‐based assays, have already been applied to model organisms, humans and a limited number of wild animals. There is clear potential to apply these marker types more widely in ecological studies. For many species, these new approaches will produce age estimates where this was previously impractical. They will also enable age information to be gathered in cross‐sectional studies and expand the range of demographic characteristics that can be quantified with molecular methods. We describe the range of molecular age biomarkers that have been investigated to date and suggest approaches for developing the newer marker types as age assays in nonmodel animal species.     

Flavonoids:New Roles for Old Molecules

Flavonoids are ubiquitous in the plant kingdom and have many diverse functions including defense, UV protection, auxin transport inhibition, allelopathy, and flower coloring. Interestingly, these compounds also have considerable biological activity in plant, animal and bacterial systems – such broad activity is accomplished by few compounds. Yet, for all the research over the last three decades, many of the cellular targets of these secondary metabolites are unknown. The many mutants available in model plant species such as Arabidopsis thaliana and Medicago truncatula are enabling the intricacies of the physiology of these compounds to be deduced. In the present review, we cover recent advances in flavonoid research, discuss deficiencies in our understanding of the physiological processes, and suggest approaches to identify the cellular targets of flavonoids.     

Application of TILLING and EcoTILLING as Reverse Genetic Approaches to Elucidate the Function of Genes in Plants and Animals

With the fairly recent advent of inexpensive, rapid sequencing technologies that continue to improve sequencing efficiency and accuracy, many species of animals, plants, and microbes have annotated genomic information publicly available. The focus on genomics has thus been shifting from the collection of whole sequenced genomes to the study of functional genomics. Reverse genetic approaches have been used for many years to advance from sequence data to the resulting phenotype in an effort to deduce the function of a gene in the species of interest. Many of the currently used approaches (RNAi, gene knockout, site-directed mutagenesis, transposon tagging) rely on the creation of transgenic material, the development of which is not always feasible for many plant or animal species. TILLING is a non-transgenic reverse genetics approach that is applicable to all animal and plant species which can be mutagenized, regardless of its mating / pollinating system, ploidy level, or genome size. This approach requires prior DNA sequence information and takes advantage of a mismatch endonuclease to locate and detect induced mutations. Ultimately, it can provide an allelic series of silent, missense, nonsense, and splice site mutations to examine the effect of various mutations in a gene. TILLING has proven to be a practical, efficient, and an effective approach for functional genomic studies in numerous plant and animal species. EcoTILLING, which is a variant of TILLING, examines natural genetic variation in populations and has been successfully utilized in animals and plants to discover SNPs including rare ones. In this review, TILLING and EcoTILLING techniques, beneficial applications and limitations from plant and animal studies are discussed.Key Words: Reverse genetics, functional genomics, TILLING (target induced local lesions in genomes), EcoTILLING (Ecotype TILLING), sequencing, SNP (single nucleotide polymorphism), genetic stocks.     

Plant Chromatin Structure and Post-Translational Modifications

Although a majority of the key works on chromatin structure and function have been carried out using animal tissues, studies of plant chromatin and the characterization of the histones and nonhistone chromosomal proteins are now developing well. There are clear functional differences between plant and animal genomes, including the percentage of total DNA transcribed, levels of ploidy, and the pathways of morphogenesis and cell differentiation. It is therefore not surprising that differences are appearing between animal and plant chromatin, for example, the consensus amino acid sequence for the plant H3 globular domain; the extensions to the basic domain regions of some plant histones such as H2A, which have specific interactions with linker DNA; the larger molecular weight of the plant H1 molecule with its extended basic domains correlated with short lengths of linker DNA, and the absence of the five residue binding segment in the globular part of plant H1, which suggests differences in the organization of higher order structure in plant chromatin. There are also unifying features between plant and animal chromatin, and the nature of plant material makes its study particularly advantageous in several areas. The regular nucleosome repeat and short lengths of linker DNA in some plants should provide more regular order structures for study, in which in the near absence of linker DNA, nucleosome position is the main, if not sole, determining factor in model building. However, the improved characterization and isolation of plant chromatin and associated molecules, for example, the isolation of the SPKK kinase gene in pea, are essential if major progress is to be made in our understanding of functional activities.     

分子标记技术在蛛形学研究中的应用

DNA分子标记作为新发展起来的一种遗传标记形式,凭借其可靠有效等优点,在动植物研究中的应用已越来越广泛。简述了DNA分子标记技术的种类、原理和特点,并综述了分子标记技术在蜘蛛亲缘关系界定和系统进化等方面的研究进展,对有关问题进行了初步讨论和展望。