用于Illumina测序平台不同试剂盒制备RNA-seq文库的方法比较

RNA-seq是利用深度测序进行转录组分析的技术,并且在新一代测序的主流平台Illumina上运用广泛。针对Illumina平台的RNA-Seq建库,目前有多个不同类型的建库方法支持该技术,但是在操作步骤和成本上有很大差距。本研究分别试验了Tru Seq RNA文库制备、NEBNext RNA文库制备以及KAPA RNA文库制备3种方法,首次系统地对这3种建库方法得到的片段长度,浓度和建库流程进行了比较分析。研究显示,3种文库的片段长度都集中在300~1 000 bp之间,KAPA RNA文库制备得到的文库浓度最高,该制备方法只需要进行一次磁珠纯化,操作简便,成本低,所需要的起始量低,适用于进行大规模的建库实验。     

利用高效的大片段DNA回收方法改良Fosmid文库的构建

外源DNA插入片段为40 kb左右的Fosmid文库在基因组学研究中有广泛的应用,但长期以来,40 kb外源片段的分离与纯化依赖于传统的切胶并电洗脱至透析袋的方法,难以得到足够量的DNA片段,极大降低Fosmid文库构建的成功率。通过改进全自动核酸/蛋白质回收系统SageELF的操作流程,建立一种简单、便捷、高效地回收40 kb左右DNA片段的方法,并用其成功地构建高质量的Fosmid文库。从文库中随机挑选的25个单克隆,经过测序及酶切分析,发现该文库中插入的DNA片段大小为37.9±5.2 kb。以上结果表明,利用改良的操作方法回收40 kb基因组DNA,操作简捷、高效,片段大小精准;另外,用该DNA片段构建的Fosmid文库,插入片段比较集中,有利于后续的基因组学分析。     

RAD-seq技术及其在昆虫学研究中的应用

限制性酶切位点关联DNA测序技术(restriction-site-associated DNA sequencing,RAD-seq)是在二代测序技术基础上发展起来的一种简化基因组技术(reduced-representation genome sequencing,RRGS)。RAD-seq利用限性核酸内切酶使基因组片段化,经过修饰后连接含标记的接头构建文库并进行测序。因其具有操作简单、实验成本低、通量高等优点,在分子生态学、进化基因组学、保护遗传学等领域得到应用。目前发展起来的RAD-seq技术主要包括利用稀有酶和物理打断方式进行基因组片段化的mbRAD、利用稀有酶和常见酶组合酶切的方式进行基因组片段化的ddRAD、利用IIB型限制性内切酶得到短片段文库的2bRAD、利用同裂酶和Illumina试剂盒建库的ezRAD和完全利用Nextera试剂盒建库的nextRAD。本文对每种RAD-seq技术的特点及其在昆虫种群遗传学、群落生态学、物种界定、系统发育和遗传连锁图谱构建等研究领域的应用进行了综述。     

一种用于构建红色红曲霉基因组Cosmid文库的大片段DNA制备方法

摘要：【目的】制备用于构建红色红曲霉cosmid文库的大片段基因组DNA。【方法】采用优化的酚氯仿抽提法制备DNA,并利用Sau3AI切割至平均大小为40 kb,然后使用Stratagene包装蛋白构建cosmid文库。基于PCR法使用同源探针从该文库中进行了目的基因的筛选。【结果】制备了浓度为5 μg/μL,平均片段大小大于48 kb的红色红曲霉大片段基因组DNA。利用该DNA构建的cosmid文库基因组覆盖倍数为10,并筛选到了含有目的片段的cosmid。【结论】通过该方法制备红色红曲霉大片段基因组D     

甲基营养菌MP681基因组测序文库的构建

目的:建立甲基营养菌MP681基因组文库,用于鸟枪法测序。方法:提取MP681基因组DNA,经超声随机片段化及T4 DNA聚合酶末端修平处理后,与经SmaⅠ酶切、小牛肠碱性磷酸酶(CIP)去磷酸化处理的pUC19载体连接,电击转化大肠杆菌DH5α感受态,并通过末端双向测序对文库质量进行评价。结果:分别构建了2～4 kb和4～6 kb基因组文库,电泳结果显示插入片段长度与预期符合,文库库容均在10万以上。结论:构建了插入片段大小和库容符合要求的甲基营养菌MP681全基因组鸟枪法2～4 kb、4～6 kb测序文库。     

水稻二化螟和三化螟基因组ddRADseq文库的构建

本文介绍了构建水稻二化螟和三化螟"双酶切限制性酶切位点关联DNA测序"(Double digest restrictionsite associated DNA sequencing,ddRADseq)文库的方法。利用安捷伦2100生物分析仪对4种单酶切及2种双酶切的酶切产物片段大小及分布范围进行分析,筛选出Mlu C I和Nla III两种限制性内切酶组合对螟虫基因组DNA进行酶切。酶切后的DNA片段两端连接上特定的P1、P2接头后,用Pippin Prep回收大小为285-435 bp的DNA片段。通过PCR扩增进行文库的富集并引入index序列。构建好的ddRADseq文库用琼脂糖凝胶电泳和生物分析仪进行质量检测。本方法所构建的文库DNA片段长度、分布和摩尔浓度能够达到Illumina平台测序的技术要求。本研究证实了利用Mlu C I和Nla III组合酶切构建水稻螟虫基因组ddRADseq文库的可行性,为在水稻螟虫中利用ddRADseq技术开展生物地理学、种群遗传学和系统发育重建等方面的研究奠定基础。     

甜菜碱增强长片段PCR的扩增

聚合酶链式反应 (PCR)作为一项非常成熟的技术可以用于基因组序列的扩增。普通的PCR技术只适合于短片段DNA的扩增 ,一般在 6kb以下。对于 6kb至十几kb甚至几十kb以上的DNA片段的扩增就非常困难。通过添加不同化学物质 ,发现甜菜碱对长片段PCR的扩增有非常有效的增强作用。通过对玉米总DNA以及质粒DNA的扩增 ,发现 1mol L到 25mol L甜菜碱对改进PCR扩增效果明显。通过添加甜菜碱 ,可以从玉米基因组中扩增出 9kb以上的单拷贝片段 ,从质粒中扩增出 16kb以上片段。经过试验 ,发现不同GC含量的引物需要使用不同浓度的甜菜碱。甜菜碱可以减少甚至消除长片段PCR中的非特异性扩增。同时 ,我们发现其它的添加物 ,如DMSO ,甘油 ,甲酰胺对长片段PCR的作用不明显     

甜菜碱增强长片段PCR的扩增

聚合酶链式反应(PCR)作为一项非常成熟的技术可以用于基因组序列的扩增。普通的PCR技术只适合于短片段DNA的扩增,一般在6kb以下。对于6kb至十几kb甚至几十kb以上的DNA片段的扩增就非常困难。通过添加不同化学物质,发现甜菜碱对长片段PCR的扩增有非常有效的增强作用。通过对玉米总DNA以及质粒DNA的扩增,发现1mol／L到2．5mol／L甜菜碱对改进PCR扩增效果明显。通过添加甜菜碱,可以从玉米基因组中扩增出9kb以上的单拷贝片段,从质粒中扩增出16kb以上片段。经过试验,发现不同GC含量的引物需要使用不同浓度的甜菜碱。甜菜碱可以减少甚至消除长片段PCR中的非特异性扩增。同时,我们发现其它的添加物,如DMSO,甘油,甲酰胺对长片段PCR的作用不明显。     

药用美洲大蠊全基因组测序分析

以美洲大蠊Periplaneta americana为原料生产的康复新液等药品临床疗效显著,得到了广泛应用。本文以四川好医生攀西药业有限责任公司饲养的药用美洲大蠊为材料,首次采用Illumina Hi Seq 2000和Pac Bio SMRT测序平台开展了全基因组测序,并进行基因组组装、注释和分析。原始测序数据经过滤后得到1.4 Tb的二代测序数据和33.81 Gb的三代测序数据。组装结果表明,美洲大蠊基因组大小为3.26 Gb,这在已报道的昆虫基因组中仅次于东亚飞蝗Locusta migratoria。基因组重复序列含量为62.38%,杂合度为0.635%,表明其为复杂基因组。组装的Contig N50和scaffold N50长度分别为28.2 kb、315 kb,单拷贝基因完整性为88.1%,小片段文库测序数据平均比对率为99.8%,测序和组装质量满足后续分析要求。采用De novo预测、同源预测和基于转录本预测3种方法共注释到14 568个基因,其中92.4%的基因获得了功能注释。本研究首次完成了美洲大蠊的全基因组测序,也是大蠊属Periplaneta昆虫的第一个基因组,为美洲大蠊遗传进化分析和药用基因资源挖掘打下了重要基础。     

古DNA单链测序文库的建立与检测北大核心CSCD

2005年问世的第二代测序技术在古DNA领域的应用,突破了第一代测序技术在绝灭或死亡生物全基因组获取手段上的局限。借助古基因组信息,研究者能够从更为系统的实时分子证据角度,解读诸如人类起源、大型绝灭哺乳动物迁移演化、动植物家养驯化以及早期人类社会生活模式等古生物学、遗传学与演化生物学问题。引入第二代测序技术之后,传统的古DNA研究方法及流程得以改变,剔除了原有的实验流程中耗时的分子克隆步骤,引入了与第二代测序技术紧密相关的古DNA单链测序文库构建环节。古DNA单链测序文库的构建,是将古DNA双链模板变性成单链后,通过向单链古DNA两端添加人工DNA片段,将古DNA分子转变成能被测序仪识别的文库分子。针对古DNA分子微量、高度片段化以及普遍存在碱基损伤的特点,古DNA单链测序文库,能够高效获取古DNA材料中的遗传信息。本文系统介绍古DNA单链测序文库建立流程,以及对文库质量进行检测的方法,为研究者运用第二代测序技术测定绝灭或死亡生物全基因组提供方法借鉴。     

Illumina mate-paired DNA sequencing-library preparation using Cre-Lox recombination

Standard Illumina mate-paired libraries are constructed from 3- to 5-kb DNA fragments by a blunt-end circularization. Sequencing reads that pass through the junction of the two joined ends of a 3-5-kb DNA fragment are not easy to identify and pose problems during mapping and de novo assembly. Longer read lengths increase the possibility that a read will cross the junction. To solve this problem, we developed a mate-paired protocol for use with Illumina sequencing technology that uses Cre-Lox recombination instead of blunt end circularization. In this method, a LoxP sequence is incorporated at the junction site. This sequence allows screening reads for junctions without using a reference genome. Junction reads can be trimmed or split at the junction. Moreover, the location of the LoxP sequence in the reads distinguishes mate-paired reads from spurious paired-end reads. We tested this new method by preparing and sequencing a mate-paired library with an insert size of 3 kb from Saccharomyces cerevisiae. We present an analysis of the library quality statistics and a new bio-informatics tool called DeLoxer that can be used to analyze an IlluminaCre-Lox mate-paired data set. We also demonstrate how the resulting data significantly improves a de novo assembly of the S. cerevisiae genome.     

Pseudo-Sanger sequencing: massively parallel production of long and near error-free reads using NGS technology

Background

Usually, next generation sequencing (NGS) technology has the property of ultra-high throughput but the read length is remarkably short compared to conventional Sanger sequencing. Paired-end NGS could computationally extend the read length but with a lot of practical inconvenience because of the inherent gaps. Now that Illumina paired-end sequencing has the ability of read both ends from 600 bp or even 800 bp DNA fragments, how to fill in the gaps between paired ends to produce accurate long reads is intriguing but challenging.

Results

We have developed a new technology, referred to as pseudo-Sanger (PS) sequencing. It tries to fill in the gaps between paired ends and could generate near error-free sequences equivalent to the conventional Sanger reads in length but with the high throughput of the Next Generation Sequencing. The major novelty of PS method lies on that the gap filling is based on local assembly of paired-end reads which have overlaps with at either end. Thus, we are able to fill in the gaps in repetitive genomic region correctly. The PS sequencing starts with short reads from NGS platforms, using a series of paired-end libraries of stepwise decreasing insert sizes. A computational method is introduced to transform these special paired-end reads into long and near error-free PS sequences, which correspond in length to those with the largest insert sizes. The PS construction has 3 advantages over untransformed reads: gap filling, error correction and heterozygote tolerance. Among the many applications of the PS construction is de novo genome assembly, which we tested in this study. Assembly of PS reads from a non-isogenic strain of Drosophila melanogaster yields an N50 contig of 190 kb, a 5 fold improvement over the existing de novo assembly methods and a 3 fold advantage over the assembly of long reads from 454 sequencing.

Conclusions

Our method generated near error-free long reads from NGS paired-end sequencing. We demonstrated that de novo assembly could benefit a lot from these Sanger-like reads. Besides, the characteristic of the long reads could be applied to such applications as structural variations detection and metagenomics.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-14-711) contains supplementary material, which is available to authorized users.     

Paired-End Sequencing of Long-Range DNA Fragments for De Novo Assembly of Large,Complex Mammalian Genomes by Direct Intra-Molecule Ligation

Background

The relatively short read lengths from next generation sequencing (NGS) technologies still pose a challenge for de novo assembly of complex mammal genomes. One important solution is to use paired-end (PE) sequence information experimentally obtained from long-range DNA fragments (>1 kb). Here, we characterize and extend a long-range PE library construction method based on direct intra-molecule ligation (or molecular linker-free circularization) for NGS.

Results

We found that the method performs stably for PE sequencing of 2- to 5- kb DNA fragments, and can be extended to 10–20 kb (and even in extremes, up to ∼35 kb). We also characterized the impact of low quality input DNA on the method, and develop a whole-genome amplification (WGA) based protocol using limited input DNA (<1 µg). Using this PE dataset, we accurately assembled the YanHuang (YH) genome, the first sequenced Asian genome, into a scaffold N50 size of >2 Mb, which is over100-times greater than the initial size produced with only small insert PE reads(17 kb). In addition, we mapped two 7- to 8- kb insertions in the YH genome using the larger insert sizes of the long-range PE data.

Conclusions

In conclusion, we demonstrate here the effectiveness of this long-range PE sequencing method and its use for the de novo assembly of a large, complex genome using NGS short reads.     

Sequencing,annotation and comparative analysis of nine BACs of the giant panda(Ailuropoda melanoleuca)

A 10-fold BAC library for the giant panda was constructed and nine BACs were selected to generate finish sequences.These BACs could be used as a validation resource for the de novo assembly accuracy of the whole genome shotgun sequencing reads of the giant panda newly generated by Illumina GA sequencing technology.Complete Sanger sequencing,assembly,annotation and comparative analysis were carried out on the selected BACs of a joint length 878 kb.Homologue search and de novo prediction methods were used to ...     

A viral discovery methodology for clinical biopsy samples utilising massively parallel next generation sequencing

Here we describe a virus discovery protocol for a range of different virus genera, that can be applied to biopsy-sized tissue samples. Our viral enrichment procedure, validated using canine and human liver samples, significantly improves viral read copy number and increases the length of viral contigs that can be generated by de novo assembly. This in turn enables the Illumina next generation sequencing (NGS) platform to be used as an effective tool for viral discovery from tissue samples.     

A Microfluidic DNA Library Preparation Platform for Next-Generation Sequencing

Next-generation sequencing (NGS) is emerging as a powerful tool for elucidating genetic information for a wide range of applications. Unfortunately, the surging popularity of NGS has not yet been accompanied by an improvement in automated techniques for preparing formatted sequencing libraries. To address this challenge, we have developed a prototype microfluidic system for preparing sequencer-ready DNA libraries for analysis by Illumina sequencing. Our system combines droplet-based digital microfluidic (DMF) sample handling with peripheral modules to create a fully-integrated, sample-in library-out platform. In this report, we use our automated system to prepare NGS libraries from samples of human and bacterial genomic DNA. E. coli libraries prepared on-device from 5 ng of total DNA yielded excellent sequence coverage over the entire bacterial genome, with >99% alignment to the reference genome, even genome coverage, and good quality scores. Furthermore, we produced a de novo assembly on a previously unsequenced multi-drug resistant Klebsiella pneumoniae strain BAA-2146 (KpnNDM). The new method described here is fast, robust, scalable, and automated. Our device for library preparation will assist in the integration of NGS technology into a wide variety of laboratories, including small research laboratories and clinical laboratories.     

基于短序列测序数据的四倍体拟南芥转录组研究

为了促进对四倍体拟南芥(A.suecica)的研究,阐明多倍体植物在染色体加倍过程中遗传物质的变化,从而在分子层面上解释多倍体植物的环境适应和进化机制,描述了一套基于第二代测序技术的转录组短序列组装和生物信息学分析方法.通过对23 000 000条来至于Illumina测序平台的序列数据进行SOAPdenovo组装,以...     

Method for quick DNA barcode reference library construction

DNA barcoding has become one of the most important techniques in plant species identification. Successful application of this technology is dependent on the availability of reference database of high species coverage. Unfortunately, there are experimental and data processing challenges to construct such a library within a short time. Here, we present our solutions to these challenges. We sequenced six conventional DNA barcode fragments (ITS1, ITS2, matK1, matK2, rbcL1, and rbcL2) of 380 flowering plants on next‐generation sequencing (NGS) platforms (Illumina Hiseq 2500 and Ion Torrent S5) and the Sanger sequencing platform. After comparing the sequencing depths, read lengths, base qualities, and base accuracies, we conclude that Illumina Hiseq2500 PE250 run is suitable for conventional DNA barcoding. We developed a new “Cotu” method to create consensus sequences from NGS reads for longer output sequences and more reliable bases than the other three methods. Step‐by‐step instructions to our method are provided. By using high‐throughput machines (PCR and NGS), labeling PCR, and the Cotu method, it is possible to significantly reduce the cost and labor investments for DNA barcoding. A regional or even global DNA barcoding reference library with high species coverage is likely to be constructed in a few years.     

Cross‐platform compatibility of de novo‐aligned SNPs in a nonmodel butterfly genus

High‐throughput sequencing methods for genotyping genome‐wide markers are being rapidly adopted for phylogenetics of nonmodel organisms in conservation and biodiversity studies. However, the reproducibility of SNP genotyping and degree of marker overlap or compatibility between datasets from different methodologies have not been tested in nonmodel systems. Using double‐digest restriction site‐associated DNA sequencing, we sequenced a common set of 22 specimens from the butterfly genus Speyeria on two different Illumina platforms, using two variations of library preparation. We then used a de novo approach to bioinformatic locus assembly and SNP discovery for subsequent phylogenetic analyses. We found a high rate of locus recovery despite differences in library preparation and sequencing platforms, as well as overall high levels of data compatibility after data processing and filtering. These results provide the first application of NGS methods for phylogenetic reconstruction in Speyeria and support the use and long‐term viability of SNP genotyping applications in nonmodel systems.