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.     

Familial long-read sequencing increases yield of de novo mutations

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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。     

通往个性化医疗的新一代测序技术：Ion Torrent

自1977年第一代Sanger测序法诞生以来,测序技术经历了突飞猛进的发展,第二代和第三代测序技术相继出现。随着测序仪代次的更迭,实现测序目的的技术权重已逐渐由偏重生化反应转向偏重物理学、材料学等非生物学科。Life Technologies公司推出的Ion Torrent Personal Genomic Machine（PGM）就是这类技术转型的代表。我们对测序技术的发展和Ion TorrentPGM的特点及应用做简要综述。     

Kiloniella majae sp. nov., isolated from spider crab (Maja brachydactyla) and pullet carpet shell clam (Venerupis pullastra)

Ten Gram-negative, rod-shaped and motile bacterial strains were isolated from spider crab (M27.10, M27.11a, F36.1, F36.4, M56.1, F76.17b, M146.1, M166.3 and M166.6) and pullet carpet shell clam (SBRF 1.10) collected in the coast of Galicia. Analyses of the 16S rRNA genes showed that the strains belong to the genus Kiloniella and have high similarity with the species Kiloniella spongiae (99.44–99.86%) and Kiloniella litopenaei (99.0–99.5%). Strains M56.1^T (=CECT 9195, =LMG 29925), M146.1 (=CECT 9193, =LMG 29926) and SBRF 1.10 (=CECT 9194, =LMG 29927) were selected on the basis of genotyping by enterobacterial repetitive intergenic consensus PCR (ERIC-PCR). Phylogenetic analysis based on concatenated sequences of the genes gyrB, ftsZ, rpoD and mreB showed that the isolates form a differentiated branch within the genus Kiloniella. Moreover, the average nucleotide identity (ANIm, ANIb and OrthoANI) and in silico estimated DNA–DNA reassociation values between selected Galician isolates and Kiloniella species were below the established cut-off for species deliniation. The results obtained in the genetic and phenotypical analyses indicate that the isolates represent a new species of the genus Kiloniella, for which the name Kiloniella majae sp. nov. is proposed with strain M56.1^T (=CECT 9195^T, =LMG 29925^T) as the type strain.     

籼稻''''93-11''''一段基因组序列的完善及分析

超级杂交稻父本‘93-11＇的基因组序列测定的完成,为进行作物遗传改良和不同作物之间的比较基因组学研究提供了又一重要序列资源.但是,该基因组序列中还存在很多“缺口”,为使‘93-11＇的基因组序列更加精确,同时提供一些“缺口”填补策略和方法,本研究采用PCR扩增、回收克隆测序的方法对该基因组中一段长约160 kb、含有6个“缺口”的基因组序列进行了完善,并运用相关分子生物学和生物信息学软件进行了详细分析,结果表明：该6个“缺口”中,存在1个“缺口”估计错误,2个序列拼接错误;“缺口”主要位于非编码区,位于编码区的只有1个,其改变了对本处基因的注释,使此基因由原来的9个外显子增加为11个;填补“缺口”后,基因密度增加.     

Genome analysis of the domestic dog (Korean Jindo) by massively parallel sequencing

Although pioneering sequencing projects have shed light on the boxer and poodle genomes, a number of challenges need to be met before the sequencing and annotation of the dog genome can be considered complete. Here, we present the DNA sequence of the Jindo dog genome, sequenced to 45-fold average coverage using Illumina massively parallel sequencing technology. A comparison of the sequence to the reference boxer genome led to the identification of 4 675 437 single nucleotide polymorphisms (SNPs, including 3 346 058 novel SNPs), 71 642 indels and 8131 structural variations. Of these, 339 non-synonymous SNPs and 3 indels are located within coding sequences (CDS). In particular, 3 non-synonymous SNPs and a 26-bp deletion occur in the TCOF1 locus, implying that the difference observed in cranial facial morphology between Jindo and boxer dogs might be influenced by those variations. Through the annotation of the Jindo olfactory receptor gene family, we found 2 unique olfactory receptor genes and 236 olfactory receptor genes harbouring non-synonymous homozygous SNPs that are likely to affect smelling capability. In addition, we determined the DNA sequence of the Jindo dog mitochondrial genome and identified Jindo dog-specific mtDNA genotypes. This Jindo genome data upgrade our understanding of dog genomic architecture and will be a very valuable resource for investigating not only dog genetics and genomics but also human and dog disease genetics and comparative genomics.     

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。     

Sequencing of Camelina neglecta,a diploid progenitor of the hexaploid oilseed Camelina sativa

Camelina neglecta is a diploid species from the genus Camelina, which includes the versatile oilseed Camelina sativa. These species are closely related to Arabidopsis thaliana and the economically important Brassica crop species, making this genus a useful platform to dissect traits of agronomic importance while providing a tool to study the evolution of polyploids. A highly contiguous chromosome-level genome sequence of C. neglecta with an N50 size of 29.1 Mb was generated utilizing Pacific Biosciences (PacBio, Menlo Park, CA) long-read sequencing followed by chromosome conformation phasing. Comparison of the genome with that of C. sativa shows remarkable coincidence with subgenome 1 of the hexaploid, with only one major chromosomal rearrangement separating the two. Synonymous substitution rate analysis of the predicted 34 061 genes suggested subgenome 1 of C. sativa directly descended from C. neglecta around 1.2 mya. Higher functional divergence of genes in the hexaploid as evidenced by the greater number of unique orthogroups, and differential composition of resistant gene analogs, might suggest an immediate adaptation strategy after genome merger. The absence of genome bias in gene fractionation among the subgenomes of C. sativa in comparison with C. neglecta, and the complete lack of fractionation of meiosis-specific genes attests to the neopolyploid status of C. sativa. The assembled genome will provide a tool to further study genome evolution processes in the Camelina genus and potentially allow for the identification and exploitation of novel variation for Camelina crop improvement.     

Emerging tools for synthetic genome design

Synthetic biology is an emerging discipline for designing and synthesizing predictable, measurable, controllable, and transformable biological systems. These newly designed biological systems have great potential for the development of cheaper drugs, green fuels, biodegradable plastics, and targeted cancer therapies over the coming years. Fortunately, our ability to quickly and accurately engineer biological systems that behave predictably has been dramatically expanded by significant advances in DNA-sequencing, DNA-synthesis, and DNA-editing technologies. Here, we review emerging technologies and methodologies in the field of building designed biological systems, and we discuss their future perspectives.     

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.     

高通量测序技术在动植物研究领域中的应用

高通量测序是核酸测序研究的一次革命性技术创新, 该技术以极低的单碱基测序成本和超高的数据产出量为特征, 为基因组学和后基因组学研究带来了新的科研方法和解决方案. 在动植物研究领域, 高通量测序引领了一次具有里程碑意义的科学研究模式革新, 科研人员可利用该技术在基因组、转录组和表观基因组等领域展开多层次多方面多水平研究. 本文就高通量测序技术应用于动植物基因组学和功能基因组学研究进展进行了系统阐述, 并对当前高通量测序技术的现状和热点及未来的发展趋势作了深入剖析和讨论.     

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。     

蜜蜂全基因组出笼前后

在2006年10月26日,期待已久的蜜蜂的基因组序列在英国杂志《自然》上发表了。这一事件对于全世界蜜蜂生物学家来说,标志着蜜蜂研究“后基因组时代”的开始。这一重大项目由倍乐医学院完成,耗资800万美元,历时2年。而实际上对于基因组的注释又经过近2年的时间,由代表15个国家、来自64个实验室的170名科学家完成。这一等待是值得的基因组序列最终发表后,生物学家通过互联网能做他们自己的“数据采掘”,用这一可得的公共资源验证自己的假说。事实上,在蜜蜂基因组文章在《自然》上发表的当周,其姊妹刊上发表的约50篇相关论文中,有一半以上是基于生物信息学的研究,这些刊物包括《科学》、《基因组研究》、《美国国家科学院院报》及《昆虫分子生物学》。蜜蜂与人类享有一些共性劳动分工,复杂的通信系统包括语言,发达的保卫和防御系统,精妙的建筑以及为了共同利益自我牺牲的特点。由于有这些共性,蜜蜂基因组的发表将使科学家不仅能够深入研究蜜蜂生物学,而且能深入了解我们人类自身的生物学。     

点滴复膜酵母兔源分离株基因组测序及比较分析

点滴复膜酵母Cyniclomyces guttulatus是一种定殖及生长于犬、兔、豚鼠、龙猫、大鼠和小鼠等动物胃肠道内的真菌。与大多数传统酵母相比,点滴复膜酵母具有耐酸(pH 1.5-4.5)、耐高温(38-42 ℃)的独特生长特性,可在体外快速增殖。腹泻动物粪便中可见大量点滴复膜酵母,尽管没有直接证据表明感染点滴复膜酵母会引起明显病状,但其被认为是多种动物的机会性致病菌。本研究通过全基因组测序和转录组测序明确点滴复膜酵母的基因结构和注释信息,获得点滴复膜酵母的系统性基因组和转录组数据。结果显示基因组大小为29.71 Mb,包含11 307个基因,转录组大小为17.67 Mb,GC含量分别为43.02%和43.09%;mRNA、CDS、外显子和内含子的平均长度分别为1 476、1 447、1 374和540 bp;点滴复膜酵母存在517个独特的基因家族,共包括1 162个基因,该酵母的独特基因特点为后续研究奠定基础。比较分析结果表明,点滴复膜酵母的基因组大小和数量明显大于其他12种酵母,提示该酵母可能存在全基因组复制,这可能与其独特的胃肠道定殖、耐酸和耐高温生长特性密切相关。     

Distinct evolutionary patterns of Oryza glaberrima deciphered by genome sequencing and comparative analysis

Here we present the genomic sequence of the African cultivated rice, Oryza glaberrima, and compare these data with the genome sequence of Asian cultivated rice, Oryza sativa. We obtained gene‐enriched sequences of O. glaberrima that correspond to about 25% of the gene regions of the O. sativa (japonica) genome by methylation filtration and subtractive hybridization of repetitive sequences. While patterns of amino acid changes did not differ between the two species in terms of the biochemical properties, genes of O. glaberrima generally showed a larger synonymous–nonsynonymous substitution ratio, suggesting that O. glaberrima has undergone a genome‐wide relaxation of purifying selection. We further investigated nucleotide substitutions around splice sites and found that eight genes of O. sativa experienced changes at splice sites after the divergence from O. glaberrima. These changes produced novel introns that partially truncated functional domains, suggesting that these newly emerged introns affect gene function. We also identified 2451 simple sequence repeats (SSRs) from the genomes of O. glaberrima and O. sativa. Although tri‐nucleotide repeats were most common among the SSRs and were overrepresented in the protein‐coding sequences, we found that selection against indels of tri‐nucleotide repeats was relatively weak in both African and Asian rice. Our genome‐wide sequencing of O. glaberrima and in‐depth analyses provide rice researchers not only with useful genomic resources for future breeding but also with new insights into the genomic evolution of the African and Asian rice species.     

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。