Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology. / Cao, Hongzhi; Hastie, Alex R.; Cao, Dandan; Lam, Ernest T.; Sun, Yuhui; Huang, Haodong; Liu, Xiao; Lin, Liya; Andrews, Warren; Chan, Saki; Huang, Shujia; Tong, Xin; Requa, Michael; Anantharaman, Thomas; Krogh, Anders; Yang, Huanming; Cao, Han; Xu, Xun.

In: GigaScience, Vol. 3, 34, 2014.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Cao, H, Hastie, AR, Cao, D, Lam, ET, Sun, Y, Huang, H, Liu, X, Lin, L, Andrews, W, Chan, S, Huang, S, Tong, X, Requa, M, Anantharaman, T, Krogh, A, Yang, H, Cao, H & Xu, X 2014, 'Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology', GigaScience, vol. 3, 34. https://doi.org/10.1186/2047-217X-3-34

APA

Cao, H., Hastie, A. R., Cao, D., Lam, E. T., Sun, Y., Huang, H., Liu, X., Lin, L., Andrews, W., Chan, S., Huang, S., Tong, X., Requa, M., Anantharaman, T., Krogh, A., Yang, H., Cao, H., & Xu, X. (2014). Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology. GigaScience, 3, [34]. https://doi.org/10.1186/2047-217X-3-34

Vancouver

Cao H, Hastie AR, Cao D, Lam ET, Sun Y, Huang H et al. Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology. GigaScience. 2014;3. 34. https://doi.org/10.1186/2047-217X-3-34

Author

Cao, Hongzhi ; Hastie, Alex R. ; Cao, Dandan ; Lam, Ernest T. ; Sun, Yuhui ; Huang, Haodong ; Liu, Xiao ; Lin, Liya ; Andrews, Warren ; Chan, Saki ; Huang, Shujia ; Tong, Xin ; Requa, Michael ; Anantharaman, Thomas ; Krogh, Anders ; Yang, Huanming ; Cao, Han ; Xu, Xun. / Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology. In: GigaScience. 2014 ; Vol. 3.

Bibtex

@article{1d7781c5f2574338a033614e9c3151f7,
title = "Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology",
abstract = "BACKGROUND: Structural variants (SVs) are less common than single nucleotide polymorphisms and indels in the population, but collectively account for a significant fraction of genetic polymorphism and diseases. Base pair differences arising from SVs are on a much higher order (>100 fold) than point mutations; however, none of the current detection methods are comprehensive, and currently available methodologies are incapable of providing sufficient resolution and unambiguous information across complex regions in the human genome. To address these challenges, we applied a high-throughput, cost-effective genome mapping technology to comprehensively discover genome-wide SVs and characterize complex regions of the YH genome using long single molecules (>150 kb) in a global fashion.RESULTS: Utilizing nanochannel-based genome mapping technology, we obtained 708 insertions/deletions and 17 inversions larger than 1 kb. Excluding the 59 SVs (54 insertions/deletions, 5 inversions) that overlap with N-base gaps in the reference assembly hg19, 666 non-gap SVs remained, and 396 of them (60%) were verified by paired-end data from whole-genome sequencing-based re-sequencing or de novo assembly sequence from fosmid data. Of the remaining 270 SVs, 260 are insertions and 213 overlap known SVs in the Database of Genomic Variants. Overall, 609 out of 666 (90%) variants were supported by experimental orthogonal methods or historical evidence in public databases. At the same time, genome mapping also provides valuable information for complex regions with haplotypes in a straightforward fashion. In addition, with long single-molecule labeling patterns, exogenous viral sequences were mapped on a whole-genome scale, and sample heterogeneity was analyzed at a new level.CONCLUSION: Our study highlights genome mapping technology as a comprehensive and cost-effective method for detecting structural variation and studying complex regions in the human genome, as well as deciphering viral integration into the host genome.",
author = "Hongzhi Cao and Hastie, {Alex R.} and Dandan Cao and Lam, {Ernest T.} and Yuhui Sun and Haodong Huang and Xiao Liu and Liya Lin and Warren Andrews and Saki Chan and Shujia Huang and Xin Tong and Michael Requa and Thomas Anantharaman and Anders Krogh and Huanming Yang and Han Cao and Xun Xu",
year = "2014",
doi = "10.1186/2047-217X-3-34",
language = "English",
volume = "3",
journal = "GigaScience",
issn = "2047-217X",
publisher = "Oxford Academic",

}

RIS

TY - JOUR

T1 - Rapid detection of structural variation in a human genome using nanochannel-based genome mapping technology

AU - Cao, Hongzhi

AU - Hastie, Alex R.

AU - Cao, Dandan

AU - Lam, Ernest T.

AU - Sun, Yuhui

AU - Huang, Haodong

AU - Liu, Xiao

AU - Lin, Liya

AU - Andrews, Warren

AU - Chan, Saki

AU - Huang, Shujia

AU - Tong, Xin

AU - Requa, Michael

AU - Anantharaman, Thomas

AU - Krogh, Anders

AU - Yang, Huanming

AU - Cao, Han

AU - Xu, Xun

PY - 2014

Y1 - 2014

N2 - BACKGROUND: Structural variants (SVs) are less common than single nucleotide polymorphisms and indels in the population, but collectively account for a significant fraction of genetic polymorphism and diseases. Base pair differences arising from SVs are on a much higher order (>100 fold) than point mutations; however, none of the current detection methods are comprehensive, and currently available methodologies are incapable of providing sufficient resolution and unambiguous information across complex regions in the human genome. To address these challenges, we applied a high-throughput, cost-effective genome mapping technology to comprehensively discover genome-wide SVs and characterize complex regions of the YH genome using long single molecules (>150 kb) in a global fashion.RESULTS: Utilizing nanochannel-based genome mapping technology, we obtained 708 insertions/deletions and 17 inversions larger than 1 kb. Excluding the 59 SVs (54 insertions/deletions, 5 inversions) that overlap with N-base gaps in the reference assembly hg19, 666 non-gap SVs remained, and 396 of them (60%) were verified by paired-end data from whole-genome sequencing-based re-sequencing or de novo assembly sequence from fosmid data. Of the remaining 270 SVs, 260 are insertions and 213 overlap known SVs in the Database of Genomic Variants. Overall, 609 out of 666 (90%) variants were supported by experimental orthogonal methods or historical evidence in public databases. At the same time, genome mapping also provides valuable information for complex regions with haplotypes in a straightforward fashion. In addition, with long single-molecule labeling patterns, exogenous viral sequences were mapped on a whole-genome scale, and sample heterogeneity was analyzed at a new level.CONCLUSION: Our study highlights genome mapping technology as a comprehensive and cost-effective method for detecting structural variation and studying complex regions in the human genome, as well as deciphering viral integration into the host genome.

AB - BACKGROUND: Structural variants (SVs) are less common than single nucleotide polymorphisms and indels in the population, but collectively account for a significant fraction of genetic polymorphism and diseases. Base pair differences arising from SVs are on a much higher order (>100 fold) than point mutations; however, none of the current detection methods are comprehensive, and currently available methodologies are incapable of providing sufficient resolution and unambiguous information across complex regions in the human genome. To address these challenges, we applied a high-throughput, cost-effective genome mapping technology to comprehensively discover genome-wide SVs and characterize complex regions of the YH genome using long single molecules (>150 kb) in a global fashion.RESULTS: Utilizing nanochannel-based genome mapping technology, we obtained 708 insertions/deletions and 17 inversions larger than 1 kb. Excluding the 59 SVs (54 insertions/deletions, 5 inversions) that overlap with N-base gaps in the reference assembly hg19, 666 non-gap SVs remained, and 396 of them (60%) were verified by paired-end data from whole-genome sequencing-based re-sequencing or de novo assembly sequence from fosmid data. Of the remaining 270 SVs, 260 are insertions and 213 overlap known SVs in the Database of Genomic Variants. Overall, 609 out of 666 (90%) variants were supported by experimental orthogonal methods or historical evidence in public databases. At the same time, genome mapping also provides valuable information for complex regions with haplotypes in a straightforward fashion. In addition, with long single-molecule labeling patterns, exogenous viral sequences were mapped on a whole-genome scale, and sample heterogeneity was analyzed at a new level.CONCLUSION: Our study highlights genome mapping technology as a comprehensive and cost-effective method for detecting structural variation and studying complex regions in the human genome, as well as deciphering viral integration into the host genome.

U2 - 10.1186/2047-217X-3-34

DO - 10.1186/2047-217X-3-34

M3 - Journal article

C2 - 25671094

VL - 3

JO - GigaScience

JF - GigaScience

SN - 2047-217X

M1 - 34

ER -

ID: 136791524