Development of Coupling Controlled Polymerizations by Adapter-ligation in Mate-pair Sequencing for Detection of Various Genomic Variants in One Single Assay

Overview

Journal DNA Res

Publisher Oxford University Press

Specialties Genetics
Molecular Biology

Date 2019 Jun 8

PMID 31173071

Citations 11

Authors

Zirui Dong

Xia Zhao

Qiaoling Li

Zhenjun Yang

Yang Xi

Andrei Alexeev

Hanjie Shen

Ou Wang

Jie Ruan

Han Ren

Hanmin Wei

Xiaojuan Qi

Jiguang Li

Xiaofan Zhu

Yanyan Zhang

Peng Dai

Xiangdong Kong

Killeen Kirkconnell

Oleg Alferov

Shane Giles

Jennifer Yamtich

Bahram G Kermani

Chao Dong

Pengjuan Liu

Zilan Mi

Wenwei Zhang

Xun Xu

Radoje Drmanac

Kwong Wai Choy

Yuan Jiang

Affiliations

Soon will be listed here.

Abstract

The diversity of disease presentations warrants one single assay for detection and delineation of various genomic disorders. Herein, we describe a gel-free and biotin-capture-free mate-pair method through coupling Controlled Polymerizations by Adapter-Ligation (CP-AL). We first demonstrated the feasibility and ease-of-use in monitoring DNA nick translation and primer extension by limiting the nucleotide input. By coupling these two controlled polymerizations by a reported non-conventional adapter-ligation reaction 3' branch ligation, we evidenced that CP-AL significantly increased DNA circularization efficiency (by 4-fold) and was applicable for different sequencing methods but at a faction of current cost. Its advantages were further demonstrated by fully elimination of small-insert-contaminated (by 39.3-fold) with a ∼50% increment of physical coverage, and producing uniform genome/exome coverage and the lowest chimeric rate. It achieved single-nucleotide variants detection with sensitivity and specificity up to 97.3 and 99.7%, respectively, compared with data from small-insert libraries. In addition, this method can provide a comprehensive delineation of structural rearrangements, evidenced by a potential diagnosis in a patient with oligo-atheno-terato-spermia. Moreover, it enables accurate mutation identification by integration of genomic variants from different aberration types. Overall, it provides a potential single-integrated solution for detecting various genomic variants, facilitating a genetic diagnosis in human diseases.

Citing Articles

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Evaluation of genetic risk of apparently balanced chromosomal rearrangement carriers by breakpoint characterization.

Xiao Y, Cheng D, Luo K, Li M, Tan Y, Lin G J Assist Reprod Genet. 2023; 41(1):147-159.

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High-resolution single-molecule long-fragment rRNA gene amplicon sequencing of bacterial and eukaryotic microbial communities.

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Mate-pair genome sequencing reveals structural variants for idiopathic male infertility.

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