复杂基因组测序技术研究进展

复杂基因组指的是无法使用常规测序和组装手段直接解析的一类基因组,通常指包含高比例重复序列、高杂合度、极端GC含量、存在难消除异源DNA污染的基因组。为了解决复杂基因组的测序和组装问题,需要分别从基因组测序实验方法、测序技术平台、组装算法与策略3个方面进行深入研究。本文详细介绍了复杂基因组测序组装相关的现有技术与方法,并结合复杂基因组经典实例介绍了复杂基因组测序的技术解决途径和发展历程,可为制订合适的复杂基因组测序策略提供参考。     

后基因组时代的基因组功能注释

基因组功能注释是后基因组时代功能基因组学研究的热点领域.从基因组功能注释的研究内容与研究手段出发,重点综述了生物信息学在该领域方法学上的研究进展,并展望了今后的发展前景.     

Smoke without fire: most reported cases of intron gain in nematodes instead reflect intron losses

Identification of recently gained spliceosomal introns would provide crucial evidence in the continuing debate concerning the age and evolutionary significance of introns. A previously published genomic analysis reported to have identified 122 introns that had been gained since the divergence of the nematodes Caenorhabidits elegans and Caenorhabditis briggsae approximately 100 MYA. However, using newly available genomic sequence from additional Caenorhabditis species, we show that 74% (60/81) of the reported gains in C. elegans are present in a C. briggsae relative. This pattern indicates that these introns represent losses in C. briggsae, not gains in C. elegans. In addition, 61% (25/41) of the reported gains in C. briggsae are present in the more distant C. briggsae relative, in a pattern suggesting that additional reported gains in C. elegans and/or C. briggsae may in fact represent unrecognized losses. These results underscore the dominance of intron loss over intron gain in recent eukaryotic evolution, the pitfalls associated with parsimony in inferring intron gains, and the importance of genomic sequencing of clusters of closely related species for drawing accurate inferences about genome evolution.     

Plastid‐targeted forms of restriction endonucleases enhance the plastid genome rearrangement rate and trigger the reorganization of its genomic architecture

Plant cells have acquired chloroplasts (plastids) with a unique genome (ptDNA), which developed during the evolution of endosymbiosis. The gene content and genome structure of ptDNAs in land plants are considerably stable, although those of algal ptDNAs are highly varied. Plant cells seem, therefore, to be intolerant of any structural or organizational changes in the ptDNA. Genome rearrangement functions as a driver of genomic evolutionary divergence. Here, we aimed to create various types of rearrangements in the ptDNA of Arabidopsis genomes using plastid‐targeted forms of restriction endonucleases (pREs). Arabidopsis plants expressing each of the three specific pREs, i.e., pTaqI, pHinP1I, and pMseI, were generated; they showed the leaf variegation phenotypes associated with impaired chloroplast development. We confirmed that these pREs caused double‐stranded breaks (DSB) at their recognition sites in ptDNAs. Genome‐wide analysis of ptDNAs revealed that the transgenic lines exhibited a large number of rearrangements such as inversions and deletions/duplications, which were dominantly repaired by microhomology‐mediated recombination and microhomology‐mediated end‐joining, and less by non‐homologous end‐joining. Notably, pHinP1I, which recognized a small number of sites in ptDNA, induced drastic structural changes, including regional copy number variations throughout ptDNAs. In contrast, the transient expression of either pTaqI or pMseI, whose recognition site numbers were relatively larger, resulted in small‐scale changes at the whole genome level. These results indicated that DSB frequencies and their distribution are major determinants in shaping ptDNAs.     

人类基因组计划与后基因组时代

2003年4月14日生命科学诞生了一个新的重要里程碑,人类基因组计划完成,后基因组时代正式来临。着重介绍了人类基因组计划的提出、目标与任务、实施与进展等方面的基本情况,讨论了后基因组时代的时间界定,分析展望了后基因组时代与人类基因组计划密切相关的生物信息学、功能基因组学、蛋白质组学、药物基因组学等几个重要研究领域 。     

Unraveling the nuclear and chloroplast genomes of an agar producing red macroalga, Gracilaria changii (Rhodophyta,Gracilariales)

Agar and agarose have wide applications in food and pharmaceutical industries. Knowledge on the genome of red seaweeds that produce them is still lacking. To fill the gap in genome analyses of these red algae, we have sequenced the nuclear and organellar genomes of an agarophyte, Gracilaria changii. The partial nuclear genome sequence of G. changii has a total length of 35.8 Mb with 10,912 predicted protein coding sequences. Only 39.4% predicted proteins were found to have significant matches to protein sequences in SwissProt. The chloroplast genome of G. changii is 183,855 bp with a total of 201 open reading frames (ORFs), 29 tRNAs and 3 rRNAs predicted. Five genes: ssrA, leuC and leuD CP76_p173 (orf139) and pbsA were absent in the chloroplast genome of G. changii. The genome information is valuable in accelerating functional studies of individual genes and resolving evolutionary relationship of red seaweeds.     

单分子纳米孔测序技术及其应用研究进展

测序技术在通量和成本方面有了较大的改进,以单分子纳米孔测序技术为代表的第三代测序技术更是以其超长读长、实时检测和可以直接检测碱基甲基化修饰等优势在医学及生命科学等领域作出了较大贡献。文中就单分子纳米孔测序技术的原理进行了简要描述,并对其在临床、动物、植物、细菌及病毒等领域的应用和其未来的发展方向进行了讨论。     

基于Web的基因组浏览器研究现状

测序技术的发展促使人类基因组测序成本急剧降低,测序速度迅速增加,对这些数据的分析和可视化已成为生命科学领域最重要的课题之一.基因组浏览器技术在基因序列分析,遗传密码解读,复杂疾病研究等方面具有重要意义.本文综述了9种主要的基因组浏览器技术,并从可视化内容、可视化形式、软件系统架构等角度分析了它们的特点.最后,探讨了基因组浏览器发展所面临的挑战.     

Telomere-targeted retrotransposons in the rice blast fungus Magnaporthe oryzae: agents of telomere instability

The fungus Magnaporthe oryzae is a serious pathogen of rice and other grasses. Telomeric restriction fragments in Magnaporthe isolates that infect perennial ryegrass (prg) are hotspots for genomic rearrangement and undergo frequent, spontaneous alterations during fungal culture. The telomeres of rice-infecting isolates are very stable by comparison. Sequencing of chromosome ends from a number of prg-infecting isolates revealed two related non-LTR retrotransposons (M. oryzae Telomeric Retrotransposons or MoTeRs) inserted in the telomere repeats. This contrasts with rice pathogen telomeres that are uninterrupted by other sequences. Genetic evidence indicates that the MoTeR elements are responsible for the observed instability. MoTeRs represent a new family of telomere-targeted transposons whose members are found exclusively in fungi.     

马基因组研究进展

各种生物都具有其独特的遗传信息, 深入了解生物体的形成过程以及各种生命活动都离不开基因组的研究成果。由于在世界范围内马具有良好的健康情况记录和详细的系谱记录, 使得马成为生命科学研究中极具价值的模式动物。尽管起步较晚, 但在过去的几年中, 马基因组图谱经历了前所未有的发展。文章主要对近年来马基因组遗传图谱、物理图谱、基因组比较作图以及功能基因组学等研究进展进行了综述, 这些图谱也正是世界各地研究人员用以探寻与马的各种性状(包括全部的健康状况、抗病性能、生殖生育能力、运动性能以及诸如毛色这样的表型特征等)相关基因的重要工具。相信这些研究成果将为马匹疾病预防、诊断和治疗提供新的思路与方法, 并将为马遗传育种提供更好的选配依据。     

Novel nucleomorph genome architecture in the cryptomonad genus hemiselmis

Cryptomonads are ubiquitous aquatic unicellular eukaryotes that acquired photosynthesis through the uptake and retention of a red algal endosymbiont. The nuclear genome of the red alga persists in a highly reduced form termed a nucleomorph. The nucleomorph genome of the model cryptomonad Guillardia theta has been completely sequenced and is a mere 551 kilobases (kb) in size, spread over three chromosomes. The presence of three chromosomes appears to be a universal characteristic of nucleomorph genomes in cryptomonad algae as well as in the chlorarachniophytes, an unrelated algal lineage with a nucleomorph and plastid genome derived from a green algal endosymbiont. Another feature of nucleomorph genomes in all cryptomonads and chlorarachniophytes examined thus far is the presence of subtelomeric ribosomal DNA (rDNA) repeats at the ends of each chromosome. Here we describe the first exception to this canonical nucleomorph genome architecture in the cryptomonad Hemiselmis rufescens CCMP644. Using pulsed-field gel electrophoresis (PFGE), we estimate the size of the H. rufescens nucleomorph genome to be approximately 580 kb, slightly larger than the G. theta genome. Unlike the situation in G. theta and all other known cryptomonads, sub-telomeric repeats of the rDNA cistron appear to be absent on both ends of the second largest chromosome in H. rufescens and two other members of this genus. Southern hybridizations using a variety of nucleomorph protein gene probes against PFGE-separated H. rufescens chromosomes indicate that recombination has been a major factor in shaping the karyotype and genomic structure of cryptomonad nucleomorphs.     

水稻和其他禾本科植物基因组多倍体起源的证据

基因加倍(Gene duplication)被认为是进化的加速器。古老的基因组加倍事件已经在多个物种中被确定,包括酵母、脊椎动物以及拟南芥等。本研究发现水稻基因组同样存在全基因组加倍事件,大概发生在禾谷类作物分化之前,距今约7000万年。在水稻基因组中,共找到117个加倍区段(Duplicated block),分布在水稻的全部12条染色体,覆盖约60％的水稻基因组。在加倍区段,大约有20％的基因保留了加倍后的姊妹基因对(Duplicated pairs)。与此形成鲜明对照的是加倍区段的转录因子保留了60％的姊妹基因。禾本科植物全基因组加倍事件的确定对研究禾本科植物基因组的进化具有重要影响,暗示了多倍体化及随后的基因丢失、染色体重排等在禾谷类物种分化中扮演了重要角色。     

Genome evolution trend of common carp （Cyprinus carpio L.） as revealed by the analysis of microsatellite loci in a gynogentic family

Genome evolution arises from two main ways of duplication and reduction. Fish specific genome duplication （FSGD） may have occurred before the radiation of the teleosts. Common carp （Cyprinus carpio L.） has been considered to be a tetraploid species, because of its chromosome numbers （2n=100） and its high DNA content. Using 69 microsatellite primer pairs, the variations were studied to better understand the genome evolution （genome duplication and diploidization） of common carp from a gynogenetic family. About 48% of primer pairs were estimated to amplify duplicates based on the number of PCR amplification per individual. Segregation patterns in the family suggested a partially duplicated genome structure and disomic inheritance. This indicates that the common carp is tetraploid and polyploidy occurred by allotetraploidy. Two primer pairs （HLJ021 and HLJ332） were estimated to amplify reduction based on the number of PCR amplification per individual. One allele in HLJ002 locus and HLJ332 locus was clearly lost in the gynogenetic family and the same as in six wild populations. Segregation patterns in the family suggested a partially diplodization genome structure. A hypothesis transition （dynamic） and equilibrium （static） were proposed to explain the common carp genome evolution between genome duplication and diploidization.     

昆虫基因组及其大小

昆虫基因组大小是由于基因组各种重复序列在扩增、缺失和分化过程中所致的数量差异造成的。这些差异使得昆虫不同类群间、种间和同种的不同种群间表现出基因组大小的不同。目前有59种昆虫已经列入基因组测序计划, 其中6种昆虫（黑腹果蝇Drosophila melanogaster、冈比亚按蚊Anopheles gambiae、家蚕Bombyx mori、意大利蜜蜂Apis mellifera、埃及伊蚊Aedes aegypti和赤拟谷盗Tribolium castaneum）的全基因组序列已经报道。有725种昆虫的基因组大小得到了估计, 大小在0.09~16.93 pg （88~16 558 Mb）之间。本文还介绍了昆虫基因组大小的估计方法, 讨论了昆虫基因组大小的变化及其意义。     

The mutational hazard hypothesis of organelle genome evolution: 10 years on

Why is there such a large variation in size and noncoding DNA content among organelle genomes? One explanation is that this genomic variation results from differences in the rates of organelle mutation and random genetic drift, as opposed to being the direct product of natural selection. Along these lines, the mutational hazard hypothesis (MHH) holds that ‘excess’ DNA is a mutational liability (because it increases the potential for harmful mutations) and, thus, has a greater tendency to accumulate in an organelle system with a low mutation rate as opposed to one with a high rate of mutation. Various studies have explored this hypothesis and, more generally, the relationship between organelle genome architecture and the mode and efficiency of organelle DNA repair. Although some of these investigations are in agreement with the MHH, others have contradicted it; nevertheless, they support a central role of mutation, DNA maintenance pathways and random genetic drift in fashioning organelle chromosomes. Arguably, one of the most important contributions of the MHH is that it has sparked crucial, widespread discussions about the importance of nonadaptive processes in genome evolution.     

大肠杆菌最小基因组分析和删减进展

大肠杆菌是基础研究最透彻、应用广泛的微生物,构建含减小甚至是最小基因组的大肠杆菌将为合成生物学的研究和应用提供理想的底盘生物。介绍了大肠杆菌最小基因组的生长与繁殖必需基因的生物信息学分析和实验鉴定,基因组敲除技术,以及删减基因组的大肠杆菌菌株的构建和应用等方面的研究进展。     

The evolutionary demography of duplicate genes

Although gene duplication has generally been viewed as a necessary source of material for the origin of evolutionary novelties, the rates of origin, loss, and preservation of gene duplicates are not well understood. Applying steady-state demographic techniques to the age distributions of duplicate genes censused in seven completely sequenced genomes, we estimate the average rate of duplication of a eukaryotic gene to be on the order of 0.01/gene/million years, which is of the same order of magnitude as the mutation rate per nucleotide site. However, the average half-life of duplicate genes is relatively small, on the order of 4.0 million years. Significant interspecific variation in these rates appears to be responsible for differences in species-specific genome sizes that arise as a consequence of a quasi-equilibrium birth-death process. Most duplicated genes experience a brief period of relaxed selection early in their history and a minority exhibit the signature of directional selection, but those that survive more than a few million years eventually experience strong purifying selection. Thus, although most theoretical work on the gene-duplication process has focused on issues related to adaptive evolution, the origin of a new function appears to be a very rare fate for a duplicate gene. A more significant role of the duplication process may be the generation of microchromosomal rearrangements through reciprocal silencing of alternative copies, which can lead to the passive origin of post-zygotic reproductive barriers in descendant lineages of incipient species.