核糖体DNA的内转录间隔区序列标记在真菌分类鉴定中的应用

传统的真菌分类主要根据真菌菌株的形态特征、生长特性与生理生化指标进行,而分子生物学技术的发展提升了真菌分类鉴定研究的手段。真菌核糖体DNA内转录间隔区(ITS)在进化上比编码区快,种内的不同菌株之间高度保守,但在种间变化极大,故可为真菌学的研究提供丰富的遗传信息。简要综述了ITS序列分析技术在真菌分类鉴定中的应用现状、相关问题及前景。     

DNA序列在植物系统学研究中的应用

植物DNA序列由于进化速率上的差异而适用于不同分类阶元的系统发育研究,因此,针对某一特定的系统学问题选择相应合适的分子片段是分子系统学研究中最为关键的一步。在前人研究的基础上,主要讨论了目前分子系统发育和进化研究中一些常用的DNA序列的适用范围,包括nrDNA的18S基因及ITS等非编码区,cpDNA的编码基因（rbcI、matK、ndhF、atpB）及非编码区序列（rpL16、rpoC1、rps16、trnL-F和trnT-L）和应用较少的mtDNA。研究表明,18S、rbcI等编码基因及mtDNA一般适用于较高分类阶元甚至整个种子植物谱系间的系统发育的探讨,而ITS及cpDNA的非编码区序列等因其较快的进化速率多用于较低分类阶元的系统关系研究。     

DNA分析技术及其在植物系统学研究中的应用

ＤＮＡ分析技术及其在植物系统学研究中的应用贺新强,李法曾（山东师范大学生物系,济南２５００１４）ＤＮＡＡＮＡＬＹＺＩＮＧＴＥＣＨＮＩＱＵＥＳＡＮＤＩＴＳＡＰＰＬＩＣＡＴＩＯＮＩＮＰＬＡＮＴＳＹＳＴＥＭＡＴＩＣＳＲＥＳＥＡＲＣＨ￥ＨｅＸｉｎ－ｑｉａｎｇ...     

核糖体DNA ITS区序列在植物分子系统学研究中的价值

本文就近年来国内外有关被子植物核糖体ＤＮＡ中的内转录间隔区（ＩＴＳ）序列在植物属内,近缘属间乃至科内系统发育研究中的应用,结合作者在中国姜科山姜属（Ａｌｐｉｎｉａ Ｒｏｘｂ．）上的研究,对ＩＴＳ区序列在植物分子系统学研究中的价值作一简要综述,对其应用前景也进行了讨论。     

利用核核糖体DNA内转录间隔区(ITS)探讨广义羽藓科系统发育

利用核核糖体DNA ITS序列,探讨了苔藓植物广义羽藓科的系统发育,摸索出适于扩增ITS片段的最适反应条件。实验共得到广义羽藓科6个种的ITS序列,它们分别是：Abieti-nela abietina(AJ417494),Anomodon minar(AJ344145),Chaopodium aciculum(AJ315968),Tuidium pristocalyx(AJ416443),Thuidium assimile(AJ416442),Herpetineuron toccoae(AJ315967),其中后5个种是国际上首次得到的。本文利用ITS序列构建羽藓科7属、11种植物的系统发育树,据Bootstrap严格一致树表明：广义的羽藓科为并系发育,可分为两个主要的分支,牛舌藓属Anomodon,羊角藓属Herpetineuron和多枝藓属Happohymenium等为一支,而山羽藓属Abietinella,羽藓属Thuuidium,沼羽藓属Helodium和麻羽藓属Claopodium等为另一主要分支,从分子水平上支持了据形态特征把原牛舌藓亚科的牛舌藓属,羊角藓属,多枝藓属提升为牛舌藓科的结论。     

同工酶分析技术及其在植物研究中的应用

同工酶几乎存在于所有生物的所有组织中,是生物化学和分子生态学的重要研究内容。本文阐明了同工酶分析技术的特点,及其在植物系统学、植物生理生态学研究中的应用,并着重阐述了同工酶分析技术在云杉研究中的应用。     

rDNA ITS区序列分子标记技术在植物学研究中的应用

在植物学研究中,人们越来越多地采用核糖体DNA内转录间隔区（ITS）作为分子标记。本文对近10年来rDNA ITS序列在植物系统发育、分类与鉴定、种质资源以及病虫害的鉴定与防治中的应用等方面的研究进展进行了综述,并对ITS序列的应用前景进行了初步探讨。     

叶绿体DNA及其在植物系统学研究中的应用

叶绿体ＤＮＡ及其在植物系统学研究中的应用黄瑶,李朝銮,马诚,吴乃虎（中国科学院成都生物研究所,成都,６１００４１）（中国科学院发育生物学研究所,北京,１０００８０）ＣＨＬＯＨＯＰＬＡＳＴＤＮＡＡＮＤＩＴＳＡＰＰＬＩＣＡＴＩＯＮＴＯＰＬＡＮＴＳＹＳＴＥ...     

DNA分析与基因组序列和植物系统学研究

从DNA杂交、RFLP分析、DNA的限制酶图谱分析等方面描述DNA分析技术在植物学研究中的应用,讨论了DNA分析技术与植物系统学的关系及分子数据的分析方法。并以高等植物为对象,从核DNA、叶绿体DNA和线粒体DNA三方面对植物分子系统学进行了论述。     

DNA多态性及其在植物功能基因组学研究中的应用

DNA多态性是生物多样性的基础。本综述了DNA多态性的影响因素,并就DNA多态性应用于基因定位、基因克隆以及基因功能分析等领域进行了探讨,展示了DNA多态性在植物功能基因组学研究中的广阔应用前景。     

Morphological and molecular identification of the metacestode parasitizing the liver of rodent hosts in bamboo growing areas of mizoram, northeast India

In Mizoram (Northeast India), rodent outbreaks are known to occur periodically with the onset of bamboo flowering causing a tremendous destruction to food grains and as per the folk belief, often resulting in famine. In an exploratory survey of rodent pests in bamboo growing atreas for their helminth parasite spectrum, metacestodes of tapeworms were frequently encountered infecting the liver lobes and body cavity of the host. The morphological criteria were found to be closely consistent with the metacestode of Taenia species. In molecular characterization of the parasite, the ribosomal DNA (ITS1, ITS2) and mitochondrial COI were amplified and sequenced. Based upon both morphological data and molecular analysis using bioinformatic tools, the metacestode is identified as confirmed to be representing Cysticercus fasciolaris. The adult form of which (Taenia taeniaeformis) commonly occurs in felid and canid mammalian hosts.     

Extracting glycan motifs using a biochemicallyweighted kernel

Carbohydrates, or glycans, are one of the most abundant and structurally diverse biopolymers constitute the third major class of biomolecules, following DNA and proteins. However, the study of carbohydrate sugar chains has lagged behind compared to that of DNA and proteins, mainly due to their inherent structural complexity. However, their analysis is important because they serve various important roles in biological processes, including signaling transduction and cellular recognition. In order to glean some light into glycan function based on carbohydrate structure, kernel methods have been developed in the past, in particular to extract potential glycan biomarkers by classifying glycan structures found in different tissue samples. The recently developed weighted qgram method (LK-method) exhibits good performance on glycan structure classification while having limitations in feature selection. That is, it was unable to extract biologically meaningful features from the data. Therefore, we propose a biochemicallyweighted tree kernel (BioLK-method) which is based on a glycan similarity matrix and also incorporates biochemical information of individual q-grams in constructing the kernel matrix. We further applied our new method for the classification and recognition of motifs on publicly available glycan data. Our novel tree kernel (BioLK-method) using a Support Vector Machine (SVM) is capable of detecting biologically important motifs accurately while LK-method failed to do so. It was tested on three glycan data sets from the Consortium for Functional Glycomics (CFG) and Kyoto Encyclopedia of Genes and Genomes (KEGG) GLYCAN and showed that the results are consistent with the literature. The newly developed BioLK-method also maintains comparable classification performance with the LK-method. Our results obtained here indicate that the incorporation of biochemical information of q-grams further shows the flexibility and capability of the novel kernel in feature extraction, which may aid in the prediction of glycan biomarkers.     

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.     

Geographical diversification of the genus Cicer (Leguminosae: Papilionoideae) inferred from molecular phylogenetic analyses of chloroplast and nuclear DNA sequences

Cicer L. (Leguminosae: Papilionoideae) consists of 42 species of herbaceous or semi-shrubby annuals and perennials distributed throughout the temperate zones of the Northern Hemisphere. The origin and geographical relationships of the genus are poorly understood. We studied the geographical diversification and phylogenetic relationships of Cicer using DNA sequence data sampled from two plastid regions, trnK / matK and trnS - trnG , and two nuclear regions, the internal transcribed spacer (ITS) and external transcribed spacer (ETS) regions of nuclear ribosomal DNA, from 30 species. The results from the phylogenetic analyses of combined nuclear and chloroplast sequence data revealed four well-supported geographical groups: a Middle Eastern group, a West-Central Asian group, an Aegean–Mediterranean group, and an African group. Age estimates for Cicer based on methods that do not assume a molecular clock (for example, penalized likelihood) demonstrate that the genus has a Mediterranean origin with considerable diversification in the Miocene/Pliocene epochs. Geological events, such as mountain orogenesis and environmental changes, are major factors for the dispersal of Cicer species. The early divergence of African species and their geographically distinct region in the genus suggest a broader distribution pattern of the genus in the past than at present.  © 2007 The Linnean Society of London, Botanical Journal of the Linnean Society, 2007, 154 , 175–186.     

Microbial DNA diagnostic technology

The principle objectives when creating a robust DNA diagnostic assay system are sensitivity, specificity and minimal read-time. To meet these ends, depending on the specifically defined test, various aspects of molecular hybridization methodology must be optimized. In particular, among other things, attention has focused on (i) formulating highly specific probes; (ii) devising sensitive nonisotopic detection systems, (iii) minimizing the extent of preparing clinical samples for assaying, (iv) amplifying the target sequence to augment sensitivity and (v) enhancing hybridization kinetics to speed up the reaction period. In this article, some recent studies that are directed to the development of nucleic acid hybridization systems for clinical diagnosis of microorganisms are considered.     

Chip ligating human genomic DNA serves as storage material and template for polymerase chain reaction

A chip was developed to store DNA for medical research. The optional restriction site fixed on the chip can randomly ligate with whole human genomic DNA treated by the corresponding restriction enzyme. PCR can then use the chip as template DNA. Moreover, a chip fixing two restriction sites (e.g. EcoRI and HindIII) showed the amplification by PCR for any location of genomic DNA. Repetitive PCRs have confirmed that a DNA chip can be stored by at –4 °C for 2 years.