Copy number variation analysis based on AluScan sequences

Jian Feng Yang; Xiao Fan Ding; Lei Chen; Wai Kin Mat; Michelle Zhi Xu; Jin Fei Chen; Jian Min Wang; Lin Xu; Wai Sang Poon; Ava Kwong; Gilberto Ka Kit Leung; Tze Ching Tan; Chi Hung Yu; Yue Bin Ke; Xin Yun Xu; Xiao Yan Ke; Ronald C.W. Ma; Juliana C.N. Chan; Wei Qing Wan; Li Wei Zhang; Yogesh Kumar; Shui Ying Tsang; Shao Li; Hong Yang Wang; Hong Xue

doi:10.1186/s13336-014-0015-z

Copy number variation analysis based on AluScan sequences

Jian Feng Yang
, Xiao Fan Ding
, Lei Chen
, Wai Kin Mat
, Michelle Zhi Xu
, Jin Fei Chen
, Jian Min Wang
, Lin Xu
, Wai Sang Poon
, Ava Kwong
, Gilberto Ka Kit Leung
, Tze Ching Tan
, Chi Hung Yu
, Yue Bin Ke
, Xin Yun Xu
, Xiao Yan Ke
, Ronald C.W. Ma
, Juliana C.N. Chan
, Wei Qing Wan
, Li Wei Zhang

Yogesh Kumar, Shui Ying Tsang, Shao Li, Hong Yang Wang^*, Hong Xue

^*Corresponding author for this work

Division of Life Science

Research output: Contribution to journal › Journal Article › peer-review

11 Citations (Scopus)

Abstract

Background: AluScan combines inter-Alu PCR using multiple Alu-based primers with opposite orientations and next-generation sequencing to capture a huge number of Alu-proximal genomic sequences for investigation. Its requirement of only sub-microgram quantities of DNA facilitates the examination of large numbers of samples. However, the special features of AluScan data rendered difficult the calling of copy number variation (CNV) directly using the calling algorithms designed for whole genome sequencing (WGS) or exome sequencing. Results: In this study, an AluScanCNV package has been assembled for efficient CNV calling from AluScan sequencing data employing a Geary-Hinkley transformation (GHT) of read-depth ratios between either paired test-control samples, or between test samples and a reference template constructed from reference samples, to call the localized CNVs, followed by use of a GISTIC-like algorithm to identify recurrent CNVs and circular binary segmentation (CBS) to reveal large extended CNVs. To evaluate the utility of CNVs called from AluScan data, the AluScans from 23 non-cancer and 38 cancer genomes were analyzed in this study. The glioma samples analyzed yielded the familiar extended copy-number losses on chromosomes 1p and 9. Also, the recurrent somatic CNVs identified from liver cancer samples were similar to those reported for liver cancer WGS with respect to a striking enrichment of copy-number gains in chromosomes 1q and 8q. When localized or recurrent CNV-features capable of distinguishing between liver and non-liver cancer samples were selected by correlation-based machine learning, a highly accurate separation of the liver and non-liver cancer classes was attained. Conclusions: The results obtained from non-cancer and cancerous tissues indicated that the AluScanCNV package can be employed to call localized, recurrent and extended CNVs from AluScan sequences. Moreover, both the localized and recurrent CNVs identified by this method could be subjected to machine-learning selection to yield distinguishing CNV-features that were capable of separating between liver cancers and other types of cancers. Since the method is applicable to any human DNA sample with or without the availability of a paired control, it can also be employed to analyze the constitutional CNVs of individuals.

Original language	English
Article number	15
Journal	Journal of Clinical Bioinformatics
Volume	4
Issue number	1
DOIs	https://doi.org/10.1186/s13336-014-0015-z
Publication status	Published - 2014

Bibliographical note

Publisher Copyright:
© 2014 Yang et al.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

AluScan sequencing
CNV calling
Cancer classification
Machine learning

Access to Document

10.1186/s13336-014-0015-z

Cite this

Yang, J. F., Ding, X. F., Chen, L., Mat, W. K., Xu, M. Z., Chen, J. F., Wang, J. M., Xu, L., Poon, W. S., Kwong, A., Leung, G. K. K., Tan, T. C., Yu, C. H., Ke, Y. B., Xu, X. Y., Ke, X. Y., Ma, R. C. W., Chan, J. C. N., Wan, W. Q., ... Xue, H. (2014). Copy number variation analysis based on AluScan sequences. Journal of Clinical Bioinformatics, 4(1), Article 15. https://doi.org/10.1186/s13336-014-0015-z

@article{da20e790313b4d4a9bca13f3d41a5181,

title = "Copy number variation analysis based on AluScan sequences",

abstract = "Background: AluScan combines inter-Alu PCR using multiple Alu-based primers with opposite orientations and next-generation sequencing to capture a huge number of Alu-proximal genomic sequences for investigation. Its requirement of only sub-microgram quantities of DNA facilitates the examination of large numbers of samples. However, the special features of AluScan data rendered difficult the calling of copy number variation (CNV) directly using the calling algorithms designed for whole genome sequencing (WGS) or exome sequencing. Results: In this study, an AluScanCNV package has been assembled for efficient CNV calling from AluScan sequencing data employing a Geary-Hinkley transformation (GHT) of read-depth ratios between either paired test-control samples, or between test samples and a reference template constructed from reference samples, to call the localized CNVs, followed by use of a GISTIC-like algorithm to identify recurrent CNVs and circular binary segmentation (CBS) to reveal large extended CNVs. To evaluate the utility of CNVs called from AluScan data, the AluScans from 23 non-cancer and 38 cancer genomes were analyzed in this study. The glioma samples analyzed yielded the familiar extended copy-number losses on chromosomes 1p and 9. Also, the recurrent somatic CNVs identified from liver cancer samples were similar to those reported for liver cancer WGS with respect to a striking enrichment of copy-number gains in chromosomes 1q and 8q. When localized or recurrent CNV-features capable of distinguishing between liver and non-liver cancer samples were selected by correlation-based machine learning, a highly accurate separation of the liver and non-liver cancer classes was attained. Conclusions: The results obtained from non-cancer and cancerous tissues indicated that the AluScanCNV package can be employed to call localized, recurrent and extended CNVs from AluScan sequences. Moreover, both the localized and recurrent CNVs identified by this method could be subjected to machine-learning selection to yield distinguishing CNV-features that were capable of separating between liver cancers and other types of cancers. Since the method is applicable to any human DNA sample with or without the availability of a paired control, it can also be employed to analyze the constitutional CNVs of individuals.",

keywords = "AluScan sequencing, CNV calling, Cancer classification, Machine learning",

author = "Yang, \{Jian Feng\} and Ding, \{Xiao Fan\} and Lei Chen and Mat, \{Wai Kin\} and Xu, \{Michelle Zhi\} and Chen, \{Jin Fei\} and Wang, \{Jian Min\} and Lin Xu and Poon, \{Wai Sang\} and Ava Kwong and Leung, \{Gilberto Ka Kit\} and Tan, \{Tze Ching\} and Yu, \{Chi Hung\} and Ke, \{Yue Bin\} and Xu, \{Xin Yun\} and Ke, \{Xiao Yan\} and Ma, \{Ronald C.W.\} and Chan, \{Juliana C.N.\} and Wan, \{Wei Qing\} and Zhang, \{Li Wei\} and Yogesh Kumar and Tsang, \{Shui Ying\} and Shao Li and Wang, \{Hong Yang\} and Hong Xue",

note = "Publisher Copyright: {\textcopyright} 2014 Yang et al.",

year = "2014",

doi = "10.1186/s13336-014-0015-z",

language = "English",

volume = "4",

journal = "Journal of Clinical Bioinformatics",

issn = "2043-9113",

publisher = "BioMed Central Ltd",

number = "1",

}

Yang, JF, Ding, XF, Chen, L, Mat, WK, Xu, MZ, Chen, JF, Wang, JM, Xu, L, Poon, WS, Kwong, A, Leung, GKK, Tan, TC, Yu, CH, Ke, YB, Xu, XY, Ke, XY, Ma, RCW, Chan, JCN, Wan, WQ, Zhang, LW, Kumar, Y, Tsang, SY, Li, S, Wang, HY & Xue, H 2014, 'Copy number variation analysis based on AluScan sequences', Journal of Clinical Bioinformatics, vol. 4, no. 1, 15. https://doi.org/10.1186/s13336-014-0015-z

TY - JOUR

T1 - Copy number variation analysis based on AluScan sequences

AU - Yang, Jian Feng

AU - Ding, Xiao Fan

AU - Chen, Lei

AU - Mat, Wai Kin

AU - Xu, Michelle Zhi

AU - Chen, Jin Fei

AU - Wang, Jian Min

AU - Xu, Lin

AU - Poon, Wai Sang

AU - Kwong, Ava

AU - Leung, Gilberto Ka Kit

AU - Tan, Tze Ching

AU - Yu, Chi Hung

AU - Ke, Yue Bin

AU - Xu, Xin Yun

AU - Ke, Xiao Yan

AU - Ma, Ronald C.W.

AU - Chan, Juliana C.N.

AU - Wan, Wei Qing

AU - Zhang, Li Wei

AU - Kumar, Yogesh

AU - Tsang, Shui Ying

AU - Li, Shao

AU - Wang, Hong Yang

AU - Xue, Hong

PY - 2014

Y1 - 2014

N2 - Background: AluScan combines inter-Alu PCR using multiple Alu-based primers with opposite orientations and next-generation sequencing to capture a huge number of Alu-proximal genomic sequences for investigation. Its requirement of only sub-microgram quantities of DNA facilitates the examination of large numbers of samples. However, the special features of AluScan data rendered difficult the calling of copy number variation (CNV) directly using the calling algorithms designed for whole genome sequencing (WGS) or exome sequencing. Results: In this study, an AluScanCNV package has been assembled for efficient CNV calling from AluScan sequencing data employing a Geary-Hinkley transformation (GHT) of read-depth ratios between either paired test-control samples, or between test samples and a reference template constructed from reference samples, to call the localized CNVs, followed by use of a GISTIC-like algorithm to identify recurrent CNVs and circular binary segmentation (CBS) to reveal large extended CNVs. To evaluate the utility of CNVs called from AluScan data, the AluScans from 23 non-cancer and 38 cancer genomes were analyzed in this study. The glioma samples analyzed yielded the familiar extended copy-number losses on chromosomes 1p and 9. Also, the recurrent somatic CNVs identified from liver cancer samples were similar to those reported for liver cancer WGS with respect to a striking enrichment of copy-number gains in chromosomes 1q and 8q. When localized or recurrent CNV-features capable of distinguishing between liver and non-liver cancer samples were selected by correlation-based machine learning, a highly accurate separation of the liver and non-liver cancer classes was attained. Conclusions: The results obtained from non-cancer and cancerous tissues indicated that the AluScanCNV package can be employed to call localized, recurrent and extended CNVs from AluScan sequences. Moreover, both the localized and recurrent CNVs identified by this method could be subjected to machine-learning selection to yield distinguishing CNV-features that were capable of separating between liver cancers and other types of cancers. Since the method is applicable to any human DNA sample with or without the availability of a paired control, it can also be employed to analyze the constitutional CNVs of individuals.

AB - Background: AluScan combines inter-Alu PCR using multiple Alu-based primers with opposite orientations and next-generation sequencing to capture a huge number of Alu-proximal genomic sequences for investigation. Its requirement of only sub-microgram quantities of DNA facilitates the examination of large numbers of samples. However, the special features of AluScan data rendered difficult the calling of copy number variation (CNV) directly using the calling algorithms designed for whole genome sequencing (WGS) or exome sequencing. Results: In this study, an AluScanCNV package has been assembled for efficient CNV calling from AluScan sequencing data employing a Geary-Hinkley transformation (GHT) of read-depth ratios between either paired test-control samples, or between test samples and a reference template constructed from reference samples, to call the localized CNVs, followed by use of a GISTIC-like algorithm to identify recurrent CNVs and circular binary segmentation (CBS) to reveal large extended CNVs. To evaluate the utility of CNVs called from AluScan data, the AluScans from 23 non-cancer and 38 cancer genomes were analyzed in this study. The glioma samples analyzed yielded the familiar extended copy-number losses on chromosomes 1p and 9. Also, the recurrent somatic CNVs identified from liver cancer samples were similar to those reported for liver cancer WGS with respect to a striking enrichment of copy-number gains in chromosomes 1q and 8q. When localized or recurrent CNV-features capable of distinguishing between liver and non-liver cancer samples were selected by correlation-based machine learning, a highly accurate separation of the liver and non-liver cancer classes was attained. Conclusions: The results obtained from non-cancer and cancerous tissues indicated that the AluScanCNV package can be employed to call localized, recurrent and extended CNVs from AluScan sequences. Moreover, both the localized and recurrent CNVs identified by this method could be subjected to machine-learning selection to yield distinguishing CNV-features that were capable of separating between liver cancers and other types of cancers. Since the method is applicable to any human DNA sample with or without the availability of a paired control, it can also be employed to analyze the constitutional CNVs of individuals.

KW - AluScan sequencing

KW - CNV calling

KW - Cancer classification

KW - Machine learning

UR - https://openalex.org/W2108910098

U2 - 10.1186/s13336-014-0015-z

DO - 10.1186/s13336-014-0015-z

M3 - Journal Article

SN - 2043-9113

VL - 4

JO - Journal of Clinical Bioinformatics

JF - Journal of Clinical Bioinformatics

IS - 1

M1 - 15

ER -

Copy number variation analysis based on AluScan sequences

Abstract

Bibliographical note

UN SDGs

Keywords

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