The impact of next-generation sequencing on genomics 被引量：25

The impact of next-generation sequencing on genomics

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摘要 This article reviews basic concepts, general applications, and the potential impact of next-generation sequencing （NGS） technologies on genomics, with particular reference to currently available and possible future platforms and bioinformatics. NGS technologies have demon- strated the capacity to sequence DNA at unprecedented speed, thereby enabling previously unimaginable scientific achievements and novel biological applications. But, the massive data produced by NGS also presents a significant challenge for data storage, analyses, and management solutions. Advanced bioinformatic tools are essential for the successful application of NGS technology. As evidenced throughout this review, NGS technologies will have a striking impact on genomic research and the entire biological field. With its ability to tackle the unsolved challenges unconquered by previous genomic technologies, NGS is likely to unravel the complexity of the human genome in terms of genetic variations, some of which may be confined to susceptible loci for some common human conditions. The impact of NGS technologies on genomics will be far reaching and likely change the field for years to come. This article reviews basic concepts, general applications, and the potential impact of next-generation sequencing （NGS） technologies on genomics, with particular reference to currently available and possible future platforms and bioinformatics. NGS technologies have demon- strated the capacity to sequence DNA at unprecedented speed, thereby enabling previously unimaginable scientific achievements and novel biological applications. But, the massive data produced by NGS also presents a significant challenge for data storage, analyses, and management solutions. Advanced bioinformatic tools are essential for the successful application of NGS technology. As evidenced throughout this review, NGS technologies will have a striking impact on genomic research and the entire biological field. With its ability to tackle the unsolved challenges unconquered by previous genomic technologies, NGS is likely to unravel the complexity of the human genome in terms of genetic variations, some of which may be confined to susceptible loci for some common human conditions. The impact of NGS technologies on genomics will be far reaching and likely change the field for years to come.

作者 Jun Zhang Rod Chiodini Ahmed Badr Genfa Zhang

机构地区 COEfor Neurosciences Department of Biomedical Sciences Internal Medicine College of Life Sciences

出处《Journal of Genetics and Genomics》 SCIE CAS CSCD 2011年第3期95-109,共15页 遗传学报（英文版）

基金 supported by NINDS/NIH(JZ),Coldwell Foundation(JZ) and TTUHSC(JZ)

关键词 Next-generation sequencing GENOMICS Genetic variation POLYMORPHISM Targeted sequence enrichment BIOINFORMATICS Next-generation sequencing Genomics Genetic variation Polymorphism Targeted sequence enrichment Bioinformatics

分类号 Q78 [生物学—分子生物学] Q811.4 [生物学—生物工程]

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参考文献98

1Ahn, S.M., Kim, T.H., Lee, S., Kim, D., Ghang, H., Kim, D.S., Kim, B.C. Kim, S.Y., Kim, W.Y., Kim, C., Park, D., Lee, Y.S., Kim, S., Reja, R. Jho, S., Kim, C.G., Cha, J.Y., Kim, K.H., Lee, B., Bhak, J., Kim, S.J.2009. The first Korean genome sequence and analysis: full genome sequencing for a socio-ethnic group. Genome Res. 19, 1622--1629.
2Ansorge, W.J., 2009. Next-generation DNA sequencing techniques. Nat. Biotechnol. 25, 195--203.
3Bainbridge, M.N., Wang, M., Burgess, D.L., Kovar, C., Rodesch, M.J., D'Ascenzo, M., Kitzman, J., Wu, Y.Q., Newsham, I., Richmond, T.A., Jeddeloh, J.A., Muzny, D., Albert, T.J., Gibbs, R.A., 2010. Whole exome capture in solution with 3 Gbp of data. Genome Biol. 11, R62.
4Bau, S., Schracke, N., Kranzle, M., Wu, H., Stabler, EE, Hoheisel, J.D., Beier, M., Summerer, D., 2009. Targeted next-generation sequencing by specific capture of multiple genomic loci using low-volume microfluidic DNA arrays. Anal. Bioanal. Chem. 393, 171--175.
5Bilguvar, K., Ozturk, A.K., Louvi, A., Kwan, K.Y., Choi, M., Tatli, B., Yalnizoglu, D., Tuysuz, B., Caglayan, A.O., Gokben, S., Kaymakcalan, H., Barak, T., Bakircioglu, M., Yasuno, K., Ho, W., Sanders, S., Zhu, Y., Yilmaz, S., Dincer, A., Johnson, M.H., Bronen, R.A., Kocer, N., Per, H., Mane, S., Pamir, M.N., Yalcinkaya, C., Kumandas, S., Topcu, M., Ozmen, M., Sestan, N., Lifton, R.P., State, M.W., Gunel, M., 2010. Whole- exome sequencing identifies recessive WDR62 mutations in severe brain malformations. Nature z~67. 2f17--21fl.
6Branton, D., Deamer, D.W., Marziali, A., Bayley, H., Benner, S.A., Buffer, T., Di Ventra, M., Garaj, S., Hibbs, A., Huang, X., Jovanovich, S.B., Krstic, P. S., Lindsay, S., Ling, X.S., Mastrangelo, C.H., Meller, A., Oliver, J.S., Pershin, Y.V., Ramsey, J.M., Riehn, R., Soni, G.V., Tabard-Cossa, V., Wanunu, M., Wiggin, M., Schloss, J.A., 2008. The potential and chal- lenges of nanopore sequencing. Nat. Biotechnol. 26, 1146-1153.
7Capriotti, E., Calabrese, R., Casadio, R., 2006. Predicting the insurgence of human genetic diseases associated to single point protein mutations with support vector machines and evolutionary information. Bioinformatics 22, 2729--2734.
8Chaisson, M.J., Brinza, D., Pevzner, EA., 2009. De novo fragment assembly with short mate-paired reads: does the read length matter? Genome Res. 19, 336--346.
9Chistoserdova, L., 2010. Recent progress and new challenges in metagenomics for biotechnology. Biotechnol. Lett. 32, 1351-1359.
10Daly, A.K., 2010a. Genome-wide association studies in pharmacogenomics. Nat. Rev. Genet. 11,241--246.

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9韩建萍,陈士林,张文生,王永炎.栀子道地性的分子生态学[J].应用生态学报,2006,17(12):2385-2388. 被引量：19
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1Thomas,F.Bumol,徐世淞,等.遗传信息、基因组技术和药物发展的未来[J].美国医学会杂志（中文版）,2001,20(6):275-278. 被引量：1
2Stephane Barge 朱琳(编译).“我在DNA里存了一本书”[J].新发现,2013(4):66-70.
3王克来.我国运用基因组技术破解对虾遗传密码[J].生物技术通报,2002,18(1):54-54.
4《自然-遗传学》：发现甲亢致病新机理[J].现代生物医学进展,2011,11(23).
5徐德昌.合成生物学与iGEM[J].生物信息学,2012,10(2):145-145. 被引量：6
6《自然-遗传学》：科学家发现胃癌驱动基因[J].现代生物医学进展,2012,12(2).
7生物工程[J].中国学术期刊文摘,2008,14(19):11-12.
8新系统可擦写DNA数据存储[J].硅谷,2012(10).
9Marc RIUS,Steve BOURNE,Harry Guy HORNSBY,Mark A. CHAPMAN.Applications of next-generation sequencing to the study of biological invasions[J].Current Zoology,2015,61(3):488-504. 被引量：5
10Jonathan Shoag,Christopher E Barbieri.Clinical variability and molecular heterogeneity inprostate cancer[J].Asian Journal of Andrology,2016,18(4):543-548. 被引量：4

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