美洲大蠊基因组重复序列分析

重复序列是真核生物基因组的重要组成部分。一些重复序列,如自主型的逆转录转座子LINE,在昆虫的系统进化和遗传多样性研究方面得到了广泛的应用。de novo从头预测和基于同源比对预测相结合的方法被用来搜索美洲大蠊Periplaneta americana基因组,共鉴定出大约占全基因组62%的重复序列。研究发现,散在重复序列中,DNA转座子占美洲大蠊基因组的16.18%;逆转座元件中LINE最多,占基因组的13.64%,SINE和LTR分别占基因组的3.52%和1.32%。LINEs中的Bov Bs亚家族在所有转座子亚家族中比例最高(约6.73%)。美洲大蠊与德国小蠊Blattella germanica相比,除LTR外,其他类型的转座子占基因组的比例均高于德国小蠊。通过分析逆转录转座子反转录酶完整度、氨基酸序列相似度及遗传距离,从美洲大蠊基因组中鉴定出一类BovBs:RTE-1_PAm。BovBs的反转录酶氨基酸序列的系统树表明,美洲大蠊与内华达古白蚁Zootermopsis nevadensis的进化关系比与其同属蜚蠊科Blattidae的德国小蠊的关系更近。昆虫中BovBs的进化关系与传统核基因进化关系的不同,表明转座子的进化相对宿主基因的进化具有一定的独立性。     

基因组中重复序列的意义

从原核生物到真核生物,其基因组中的重复序列呈递增趋势.重复序列的作用也被各种实验所揭示.各种重复序列的类型与它在染色体上的分布密切相关.重复序列不是垃圾,而是影响着生命的进化、遗传、变异;同时它对基因表达、转录调控、染色体的构建以及生理代谢都起着不可或缺的作用.它们的功能及演化也正在被逐步阐明.     

基因组中的重复DNA序列

综述了基因组中常见的重复DNA序列,介绍了其可能的产生机理、分布情况和生物学功能。     

毛竹微型颠倒重复序列的鉴定及分子标记开发

MITEs(miniature inverted-repeat transposable elements)又称颠倒重复序列,是缺少转座酶序列的非自主型转座子,在真核生物基因组含量丰富,是基因组多态性形成的重要驱动力之一.该研究利用MITE Tracker软件,在毛竹(Phyllostachys edulis)新版基因...     

一种快速有效的识别DNA重复序列的方法

按统计的相应分析方法设计和编制了基因组重复序列的识别软件。经众多Ａｌｕ序列的回顾性分析,错报率为４．８％,漏报率为５．８％,又地剪入编码区的Ａｌｕ序列的细致检查和对Ｔ细胞受体基因组的Ａｌｕ序列的大尺度搜索,证实本程序是一种快束速和良好的识别ＤＮＡ重复序列的工具。     

细菌基因组重复序列PCR技术及其应用

细菌中散在分布的DNA重复序列近年来不断被报道,基因外重复回文序列和肠细菌基因间共有重复序列是两个典型的原核细胞基因组散在重复序列。重复序列在染色体上的分布和拷贝数具种间特异性,用它们的互补序列作为引物,以细菌基因组DNA为模板进行PCR扩增反应,反应产物的琼脂糖电泳可以提供非常清晰的DNA指纹图谱,使用此图谱既可对各种微生物进行快速分型及鉴定,又可对它们进行DNA水平上的遗传多样性分析。细菌基因组重复序列PCR技术具有简捷、快速、结果稳定等特点,可对细菌进行分子标记,用于菌株分型、分类鉴定和亲缘关系等方面的研究。     

小麦及其近缘种中基因组特异性DNA重复序列的研究进展

本文对小麦族植物中基因组特异性DNA重复序列的分类、基本特征、分离和鉴定方法、在小麦遗传改良中的应用以及未来研究的发展趋势进行了简述。综合已有的研究结果可以看出基因组特异性DNA重复序列是小麦族植物基因组特异性形成的重要构成部分。对基因组特异性DNA重复序列的研究是认识小麦族植物基因组的有效途径之一,基因组特异性DNA重复序列的应用将进一步促进小麦族植物分子细胞遗传学和普通小麦遗传改良研究的进展。 Advances in Studies of Genome-Specific Repetitive DNA Sequences in Wheat and Related Species BAI Jian-rong1,2,JIA Xu1,WANG Dao-wen1 1.The State Key Laboratory of Plant Cell and Chromosome Engineering,Institute of Genetics and Developmental Biology,The Chinese Academy of Sciences,Beijing 100101,China; 2.Crop Genetics Institute,Shanxi Academy of Agricultural Sciences,Taiyuan 030031,China Abstract:In this paper we review recent advances in studies of several aspects of genome specific repetitive DNA sequences in wheat and related species.The available results demonstrate that genome specific repetitive DNA sequences are important components of genome specificity in wheat and related species.Research on genome specific repetitive DNA sequences is essential to the elucidation of genome function.The application of genome specific repetitive DNA sequences will aid molecular cytogenetic studies in wheat and related species and contributes to genetic improvement of common wheat. Key words：wheat;genome specific repetitive DNA sequence;chromosome     

用实时定量PCR解决基因组序列组装中的重复序列问题

目的:探寻一种简单、经济的方法,解决基因组序列拼接中的重复序列问题。方法:选取序列拼接中遇到重复序列问题的质粒NDM-BTR,在其与重复序列相关的contigs两端设计引物,进行实时定量PCR,通过观察临界循环数来判断contig之间的位置关系。结果:成功判断出质粒contig之间的位置关系,得到了质粒基因组完成图。结论:实时定量PCR法可用于解决基因组序列拼接中的重复序列问题,相比较传统建立大片段文库更加简单、快速、经济。     

植物基因组中微型反向重复转座元件研究进展

微型反向重复转座元件(miniature inverted repeat transposable element,MITE)是一类特殊的转座元件,在结构上与有缺失的DNA转座子相似,但具有反转录转座子高拷贝数的特点.MITE时常与基因相伴,对基因调控可能起重要作用,因此,MITE正逐渐成为基因和基因组进化及生物多样性研究的一种重要工具.本文综述了植物基因组MITE的结构、分类、活性及其应用研究进展.     

Identification of Repetitive Elements in the Genome of Oreochromis niloticus: Tilapia Repeat Masker

The large-scale bacterial artificial chromosome-end sequencing project of Nile tilapia (Oreochromis niloticus) has generated extensive sequence data that allowed the examination of the repeat content in this fish genome and building of a repeat library specific for this species. This library was established based on Tilapiini repeat sequences from GenBank, sequences orthologous to the repeat library of zebrafish in Repbase, and novel repeats detected by genome analysis using MIRA assembler. We estimate that repeats constitute about 14% of the tilapia genome and also give estimates for the occurrence of the different repeats based on the Basic Local Alignment Search Tool searches within the database of known tilapia sequences. The frequent occurrence of novel repeats in the tilapia genome indicates the importance of using the species-specific repeat masker prior to sequence analyses. A web tool based on the RepeatMasker software was designed to assist tilapia genomics.     

玉米基因组的简单重复序列遗传研究进展

前言在真核生物基因组中重复序列占有很大比重,它的绝大部分存在于诸如间隔序列和调控序列非编码序列中,但它也分布在有些结构基因的序列中,它多为轻度重复序列。植物的基因组重复序列一般占80%左右,基因组较大其重复序列所占比重较大,如玉米基因组(ｈａｐｌｏｉｄｇｅｎｏｍｅ)大约有3×109,其中几乎80%以上是重复序列[12]。重复序列对维持染色体的空间结构、基因的表达、遗传重组都具有重要作用。重复序列单...     

GEMINI: Integrative Exploration of Genetic Variation and Genome Annotations

Modern DNA sequencing technologies enable geneticists to rapidly identify genetic variation among many human genomes. However, isolating the minority of variants underlying disease remains an important, yet formidable challenge for medical genetics. We have developed GEMINI (GEnome MINIng), a flexible software package for exploring all forms of human genetic variation. Unlike existing tools, GEMINI integrates genetic variation with a diverse and adaptable set of genome annotations (e.g., dbSNP, ENCODE, UCSC, ClinVar, KEGG) into a unified database to facilitate interpretation and data exploration. Whereas other methods provide an inflexible set of variant filters or prioritization methods, GEMINI allows researchers to compose complex queries based on sample genotypes, inheritance patterns, and both pre-installed and custom genome annotations. GEMINI also provides methods for ad hoc queries and data exploration, a simple programming interface for custom analyses that leverage the underlying database, and both command line and graphical tools for common analyses. We demonstrate GEMINI''s utility for exploring variation in personal genomes and family based genetic studies, and illustrate its ability to scale to studies involving thousands of human samples. GEMINI is designed for reproducibility and flexibility and our goal is to provide researchers with a standard framework for medical genomics.This is a PLOS Computational Biology Software Article.     

Identification of Two Penelope-Like Elements with Different Structures and Chromosome Localization in Kuruma Shrimp Genome

Penelope, originally found as a key element responsible for the hybrid dysgenesis in Drosophila virilis, has been widely conserved throughout eukaryotic genomes. In other organisms, they are often referred to as Penelope-like elements or PLEs. In this study, we found two types of PLEs, designated MjPLE01 and MjPLE02, from kuruma shrimp, Marsupenaeus japonicus. There was no observed nucleotide similarity between MjPLE01 and 02, and both elements differed from each other in terms of their structure; MjPLE02 has a distinctive endonuclease (EN) domain at the C-terminus while MjPLE01 do not. A phylogenetic tree that includes publicly available PLEs and TERTs showed that MjPLE01 and 02 were closely related to Coprina elements, which have been reported as an EN-deficient PLE, and to Penelope–Poseidon group, which possess an EN domain, respectively. Genomic Southern blot analysis using MjPLE01 as a probe showed several multiple bands that differ among individual shrimps. On the other hand, two major identical bands were observed when MjPLE02 was used. Colony hybridization showed co-localization of MjPLE01 and GGTTA repeats, suggesting that MjPLE01 might be prevalent in subtelomeric regions of kuruma shrimp genome. These results suggest that the kuruma shrimp genome has at least two types of PLEs with different domain compositions, phylogenetic positions, and probably chromosomeal localization. Such distinctive types of PLEs in an organism have never been described and hence could be a potential source to understand how multiple PLE types evolved.     

Glider and Vision: Two New Families of Miniature Inverted-Repeat Transposable Elements in Xenopus Laevis Genome

We have characterised from Xenopus laevis two new short interspersed repetitive elements, we have named Glider and Vision, that belong to the family of miniature inverted-repeat transposable elements (MITEs). Glider was first characterised in an intronic region of the α-tropomyosin (α-TM) gene and database search has revealed the presence of this element in 10 other Xenopus laevis genes. Glider elements are about 150 bp long and for some of them, their terminal inverted repeats are flanked by potential target-site duplications. Evidence for the mobility of Glider element has been provided by the presence/absence of one element at corresponding location in duplicated α-TM genes. Vision element has been identified in the promoter region of the cyclin dependant kinase 2 gene (cdk2) where it is boxed in a Glider element. Vision is 284 bp long and is framed by 14-bp terminal inverted repeats that are flanked by 7-bp direct repeats. We have estimated that there are about 20,000 and 300 copies of Glider and Vision respectively scattered throughout the laevis genome. Every MITEs elements but two described in our study are found either in 5′ or in 3′ regulatory regions of genes suggesting a potential role in gene regulation. This revised version was published online in August 2006 with corrections to the Cover Date.     

Evaluation of Three Automated Genome Annotations for Halorhabdus utahensis

Genome annotations are accumulating rapidly and depend heavily on automated annotation systems. Many genome centers offer annotation systems but no one has compared their output in a systematic way to determine accuracy and inherent errors. Errors in the annotations are routinely deposited in databases such as NCBI and used to validate subsequent annotation errors. We submitted the genome sequence of halophilic archaeon Halorhabdus utahensis to be analyzed by three genome annotation services. We have examined the output from each service in a variety of ways in order to compare the methodology and effectiveness of the annotations, as well as to explore the genes, pathways, and physiology of the previously unannotated genome. The annotation services differ considerably in gene calls, features, and ease of use. We had to manually identify the origin of replication and the species-specific consensus ribosome-binding site. Additionally, we conducted laboratory experiments to test H. utahensis growth and enzyme activity. Current annotation practices need to improve in order to more accurately reflect a genome''s biological potential. We make specific recommendations that could improve the quality of microbial annotation projects.