Rapid and Accurate Sequencing of Enterovirus Genomes Using MinION Nanopore Sequencer

Objective Knowledge of an enterovirus genome sequence is very important in epidemiological investigation to identify transmission patterns and ascertain the extent of an outbreak. The MinION sequencer is increasingly used to sequence various viral pathogens in many clinical situations because of its long reads, portability, real-time accessibility of sequenced data, and very low initial costs. However, information is lacking on MinION sequencing of enterovirus genomes. Methods In this proof-of-concept study using Enterovirus 71 （EV71） and Coxsackievirus A16 （CA16） strains as examples, we established an amplicon-based whole genome sequencing method using MinION. We explored the accuracy, minimum sequencing time, discrimination and high-throughput sequencing ability of MinION, and compared its performance with Sanger sequencing. Results Within the first minute （min） of sequencing, the accuracy of MinION was 98.5% for the single EV71 strain and 94.12%-97.33% for 10 genetically-related CA16 strains. In as little as 14 min, 99% identity was reached for the single EV71 strain, and in 17 min （on average）, 99% identity was achieved for 10 CA16 strains in a single run. Conclusion MinION is suitable for whole genome sequencing of enteroviruses with sufficient accuracy and fine discrimination and has the potential as a fast, reliable and convenient method for routine use.

基于纳米孔靶向全基因测序技术的新冠肺炎病例快速鉴定研究

目的探索快速识别新型冠状病毒的方法,为新冠肺炎防控提供技术支撑。方法分别运用基于三代纳米孔测序技术平台MinION Mk1C和基于二代测序技术平台Ion Torrent S5的新型冠状病毒(SARS-CoV-2)靶向全基因组测序技术对1例境外输入新冠肺炎确诊病例进行基因组测序。使用artic-ncov2019软件、CLC Genomics Workbench(Version 21.0)软件和DNAstar软件等进行数据处理和分析。结果基于三代纳米孔测序技术平台MinION Mk1C和基于二代测序技术平台Ion Torrent S5分别在7 h和30 h左右获得SARS-CoV-2全基因组数据,分别为29848bp和29801bp,两者共同29801bp数据部分同源性100%,经分析为新冠病毒B.1.1.7变异株。结论在对该病例样本的全基因测序中,基于三代纳米孔测序技术平台MinION Mk1C的SARS-CoV-2靶向全基因组测序技术将检测周期缩短至7 h左右,能够实现快速、准确地对SARS-CoV-2进行实时测序。

Oxford Nanopore MinION Sequencing and Genome Assembly

The revolution of genome sequencing is continuing after the successful secondgeneration sequencing （SGS） technology. The third-generation sequencing （TGS） technology, led by Pacific Biosciences （PacBio）, is progressing rapidly, moving from a technology once only capable of providing data for small genome analysis, or for performing targeted screening, to one that promises high quality de novo assembly and structural variation detection for human-sized genomes. In 2014, the MinION, the first commercial sequencer using nanopore technology, was released by Oxford Nanopore Technologies （ONT）. MiniON identifies DNA bases by measuring the changes in electrical conductivity generated as DNA strands pass through a biological pore. Its portability, affordability, and speed in data production makes it suitable for real-time applications, the release of the long read sequencer MiniON has thus generated much excitement and interest in the genomics community. While de novo genome assemblies can be cheaply produced from SGS data, assem- bly continuity is often relatively poor, due to the limited ability of short reads to handle long repeats. Assembly quality can be greatly improved by using TGS long reads, since repetitive regions can be easily expanded into using longer sequencing lengths, despite having higher error rates at the base level. The potential of nanopore sequencing has been demonstrated by various studies in genome surveillance at locations where rapid and reliable sequencing is needed, but where resources are limited.

Determining antimicrobial resistance profiles and identifying novel mutations of Neisseria gonorrhoeae genomes obtained by multiplexed MinION sequencing

Gonorrhea is one of the most common sexually transmitted diseases worldwide. To cure infection and prevent transmission,timely and appropriate antimicrobial therapy is necessary. Unfortunately, Neisseria gonorrhoeae, the etiological agent of gonorrhea, has acquired nearly all known mechanisms of antimicrobial resistance(AMR), thereby compromising the efficacy of antimicrobial therapy. Treatment failure resulting from AMR has become a global public health concern. Whole-genome sequencing is an effective method to determine the AMR characteristics of N. gonorrhoeae. Compared with next-generation sequencing, the MinION sequencer(Oxford Nanopore Technologies(ONT)) has the advantages of long read length and portability. Based on a pilot study using MinION to sequence the genome of N. gonorrhoeae, we optimized the workflow of sequencing and data analysis in the current study. Here we sequenced nine isolates within one flow cell using a multiplexed sequencing strategy. After hybrid assembly with Illumina reads, nine integral circular chromosomes were obtained. By using the online tool Pathogenwatch and a BLAST-based workflow, we acquired complete AMR profiles related to seven classes of antibiotics. We also evaluated the performance of ONT-only assemblies. Most AMR determinants identified by ONT-only assemblies were the same as those identified by hybrid assemblies. Moreover, one of the nine assemblies indicated a potentially novel antimicrobial-related mutation located in mtrR which results in a frame-shift, premature stop codon, and truncated peptide.In addition, this is the first study using the MinION sequencer to obtain complete genome sequences of N. gonorrhoeae strains which are epidemic in China. This study shows that complete genome sequences and antimicrobial characteristics of N.gonorrhoeae can be obtained using the MinION sequencer in a simple and cost-effective manner, with hardly any knowledge of bioinformatics required. More importantly, this strategy provides us with a potential approach to discover new AMR determinants.

纳米孔测序技术在核酸修饰检测中的应用

DNA和RNA上广泛存在着多种化学修饰.这些核酸修饰参与基因表达的调控,影响生长发育等生理过程,并可能会引发癌症等疾病.对核酸修饰的精准识别与定位有助于理解其功能机制,帮助相关疾病的诊断与治疗.纳米孔测序是一种新兴的单分子测序技术,可以根据修饰碱基与天然碱基之间阻孔信号的差异实现核酸序列中多种修饰的同时检测,是目前检测核酸修饰最直接的方法.本文简要介绍了纳米孔测序技术的发展和原理以及识别核酸修饰的算法工具,总结了纳米孔测序技术在核酸修饰检测中的应用,并对其发展前景进行了展望.

论公共视野下大学与大学人的使命

大学是过去时代的遗迹,以造就人格化的知识分子为核心。而如今的知识分子大都身处学院之中,教育成了一种公共的实践。伴随现代市场化的发展,使得甘心长年坐冷板凳的专业学者的学术生活受到冲击。在公共视野下,大学及大学人是用公共性服务来回避专业化工作,还是用专业化工作来消解大学及大学人的社会关怀与公共参与?本文试图以此为背景来探究公共视野下大学及大学人是否还能够"诗意地栖居",是否还能够以富有批判的精神和理想主义的情怀去终身坚守追求真理、做社会良知和砥砺学术道德的使命。

基于纳米孔测序技术的柑橘黄龙病检测方法建立

柑橘黄龙病(Huanglongbing)是柑橘生产上最具毁灭性的病害,及时快速地进行早期检测和诊断是防控黄龙病的关键措施之一。本文利用掌上纳米孔测序仪MinION对携带黄龙病菌Candidatus Liberibacter asiaticus的DNA样品进行测序,并利用Blast、GraphMap、minimap2以及两种bwa的比对方法将测序结果比对到黄龙病菌基因组上,比对结果均匀的比对到黄龙病菌基因组上,并未发现严重的偏倚现象,验证了其测序结果的可靠性。本技术可弥补因柑橘木虱Diaphorina citri(Kuwayama)虫体过小或损坏难以进行光学识别的不足,并可同时检测虫体是否携带有黄龙病菌,对有黄龙病发生风险但尚未有黄龙病实际发生的柑橘种植区提供实时实地的监控与预警。

民勤绿洲生态气候资源及其利用

民勤绿洲边缘 ,光照丰富、温差大 ,有利于农产品质量的提高。但是水资源缺乏 ,地下水位急剧下降和土地沙化是民勤绿洲农业生产的首要问题。如何充分利用现有生态资源 ,并充分提高其利用率是摆在我们面前的一个主要课题。只有通过引进优良品种 ,调整农业种植结构 ,大力推广节水灌溉技术 。

纳米孔测序技术在病原体现场快速确认中的应用与挑战

国外暴发的埃博拉出血热、寨卡病毒病和拉萨热疫情表明,我们亟需一种快速、有效的病原体现场检测技术来应对新发和烈性传染病。现有的二代测序平台能实现病原体快速鉴别,但对运行环境要求比较苛刻,样本制备过程相对复杂,测序运行时间较长,数据分析也依赖高性能计算设备,限制了其在非实验室环境下的现场检测应用。而作为三代测序技术代表之一的Oxford Nanopore Technologies(ONT)纳米孔测序平台具有实时、长读长、测序通量高、流转时间短、文库制备流程简易等优势,而ONT测序平台MinION更是以便携、低成本的特性而独具病原体现场快速确认的能力。本文主要对纳米孔测序技术在病原体现场快速确认中的应用与挑战进行综述。

关于拟常曲率空间中2-调和子流形

该文研究拟常曲率空间中的紧致2-调和子流形,得到了这类子流形成为极小子流形的关于第二基本形式模长的Pinching定理及推广的J．Simons型积分不等式:

利用纳米孔测序鉴定蓖麻蚕病害

蓖麻蚕Samia ricini为大蚕蛾科樗蚕属的绢丝与食用的非滞育型经济昆虫,且是少数可以室内大量圈养的绢丝昆虫,全年可累代饲养。在蓖麻蚕室内大批量圈养的生产过程可能遭受毁灭性病害的侵害,包括蓖麻蚕微粒子病、脓病、软化病等,且随着累代对病原物的不停积累蚕病会呈现愈发严重的趋势,病原愈发难以清除。因此,对蚕病的监测是防控蚕病爆发的重要手段之一。掌上纳米孔测序仪MinION是一款便携式高通量测序平台,便于实地进行DNA测序并对病原物进行检测。本文通过MinION测序仪对蓖麻蚕病蚕DNA进行测序,并对未知病原物DNA序列进行分析,探讨了利用MinION测序仪鉴定蓖麻蚕病原的可行性,对蚕病的监测提供了保障。

基于纳米孔测序技术的呼吸道病原体快速确认

目的验证纳米孔测序技术在呼吸道病原体应急检测中的可行性。方法对某上呼吸道感染患者的咽拭子标本进行总核酸抽提并定量,接着进行cDNA的逆转录合成和测序文库构建,在便携式三代测序仪MinION上进行测序,然后对测序数据进行病原分类学分析,最后使用实时荧光定量PCR验证测序结果。结果MinION在15 h内共计产生188063条有效序列。测序数据分析表明,在咽拭子样本中同时检测到人呼吸道腺病毒7型和甲型流感病毒H3N2亚型,分别有19和4条序列匹配到参考基因组。测序开始9 h内,MinION已分别产出78.95%的7型腺病毒序列和100%的H3N2序列。从取样到初步获得鉴定结果,流转时间为18.6 h。实时荧光定量PCR与测序结果一致。结论MinION用于呼吸道病原体的快速检测具有可行性,且具备同时检测多种病原体并对病原分型的能力,在暴发疫情和呼吸道病毒应急检测方面具有应用价值。

关于局部对称空间中2-调和子流形

本文研究局部对称完备黎曼流形中的紧致 2 调和子流形 ,得到了这类子流形第二基本形式模长平方的Pinching定理及推广的J .

Nanopore测序技术在临床中的应用进展

基因测序技术是生命科学和生物科技的核心技术之一,目前正处于从主流的二代测序技术向三代技术升级的过渡阶段。纳米孔(Nanopore)测序技术已被应用于微生物种群鉴定、全基因组测序、新物种发现等方面,更以其超长读长、实时检测和可以直接检测碱基甲基化修饰等优势在医学领域作出了较大贡献。本文描述了纳米孔测序仪(MinION)的技术特征,主要关注该技术在临床应用中的最新进展,并探讨了其发展前景。

4-十四烷基酚的合成及条件优化

以十四酰氯与苯酚反应得到苯酚酯,再与无水三氯化铝进行Fries重排生成烷基酮,后经黄鸣龙还原反应得到烷基酚。通过对Fries重排反应的反应时间、催化剂用量、是否添加溶剂进行研究得到较好的合成条件,合成出了烷基酚中间体。

洛马公司透露新的隐身无人机

洛马公司的Skunk工厂的研究人员最近掀开了新的隐身无人机的神秘面纱。从公司展出的图片可见，该隐身无人机的外形很像一枚巡航导弹，弹体光滑，弹翼较小。该隐身无人机由F／A-22猛禽多用途战斗机发射，可飞临载机不能到达的地方，用于执行侦察或打击任务。

关于局部对称共形平坦空间中2-调和子流形

通过研究局部对称共形平坦空间中2-调和子流形,得到了这类子流形的第二基本形式的模长平方的一个拼挤定理及推广了的J.Simons型积分不等式.

浅析大采高综放开采技术与应用现状

大采高综放工作面生产能力大、采出率高、安全条件和经济效益好,是目前厚煤层开采技术的主要发展方向之一,是实现厚及特厚煤层安全高产高效、实现年产千万吨级工作面的必要保障。通过对同忻、塔山、平朔一号井等矿井工作面地质条件、生产条件、产量及采出率、设备使用情况和矿压显现及安全可靠性等5个方面的调研,分析了目前大采高综放开采技术与应用现状,并提出了针对"三机"配套和开采工艺的建议,对大采高综放开采技术的发展有一定的借鉴意义。

论成仿吾对“文学本身的使命”的批判

成仿吾在《新文学之使命》一文中谈到了文学对于"文学本身的使命",他所理解的"文学本身的使命"是要以情感为本体,以"表现"为手法,创作出具有艺术性的既"全"而"美"的文学作品来。

纳米孔测序技术在病毒基因组研究中的应用

Oxford Nanopore Technologies （ONT）公司开发出了商业化的纳米孔测序仪-MinION。相对于二代测序技术平台，MinION的主要特点是读长长、简单快速、便携性高且可以实时分析测序数据。各国的研究人员也已经逐步将MinION应用于病毒检测、病毒全基因组测序、新病毒的发现、病毒准种与进化研究等领域。本文回顾了近几年纳米孔测序技术在病毒基因组研究中的应用，讨论了病毒基因组测序目前存在的问题，并展望了纳米孔测序技术未来的发展前景。