3' Branch Ligation: a Novel Method to Ligate Non-complementary DNA to Recessed or Internal 3'OH Ends in DNA or RNA

Overview

Journal DNA Res

Publisher Oxford University Press

Specialties Genetics
Molecular Biology

Date 2018 Nov 15

PMID 30428014

Citations 6

Authors

Lin Wang

Yang Xi

Wenwei Zhang

Weimao Wang

Hanjie Shen

Xiaojue Wang

Xia Zhao

Andrei Alexeev

Brock A Peters

Alayna Albert

Xu Xu

Han Ren

Ou Wang

Killeen Kirkconnell

Helena Perazich

Sonya Clark

Evan Hurowitz

Ao Chen

Xun Xu

Radoje Drmanac

Yuan Jiang

Affiliations

Soon will be listed here.

Abstract

Nucleic acid ligases are crucial enzymes that repair breaks in DNA or RNA during synthesis, repair and recombination. Various genomic tools have been developed using the diverse activities of DNA/RNA ligases. Herein, we demonstrate a non-conventional ability of T4 DNA ligase to insert 5' phosphorylated blunt-end double-stranded DNA to DNA breaks at 3'-recessive ends, gaps, or nicks to form a Y-shaped 3'-branch structure. Therefore, this base pairing-independent ligation is termed 3'-branch ligation (3'BL). In an extensive study of optimal ligation conditions, the presence of 10% PEG-8000 in the ligation buffer significantly increased ligation efficiency to more than 80%. Ligation efficiency was slightly varied between different donor and acceptor sequences. More interestingly, we discovered that T4 DNA ligase efficiently ligated DNA to the 3'-recessed end of RNA, not to that of DNA, in a DNA/RNA hybrid, suggesting a ternary complex formation preference of T4 DNA ligase. These novel properties of T4 DNA ligase can be utilized as a broad molecular technique in many important genomic applications, such as 3'-end labelling by adding a universal sequence; directional tagmentation for NGS library construction that achieve theoretical 100% template usage; and targeted RNA NGS libraries with mitigated structure-based bias and adapter dimer problems.

Citing Articles

A New Specific and Sensitive RT-qPCR Method Based on Splinted 5' Ligation for the Quantitative Detection of RNA Species Shorter than microRNAs.

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Depletion of erythropoietic miR-486-5p and miR-451a improves detectability of rare microRNAs in peripheral blood-derived small RNA sequencing libraries.

Juzenas S, Lindqvist C, Ito G, Dolshanskaya Y, Halfvarson J, Franke A NAR Genom Bioinform. 2021; 2(1):lqaa008.

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Comparison of long-read methods for sequencing and assembly of a plant genome.

Murigneux V, Rai S, Furtado A, Bruxner T, Tian W, Harliwong I Gigascience. 2020; 9(12).

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Deciphering the complexity of simple chromosomal insertions by genome sequencing.

Dong Z, Chau M, Zhang Y, Dai P, Zhu X, Leung T Hum Genet. 2020; 140(2):361-380.

PMID: 32728808 DOI: 10.1007/s00439-020-02210-x.

Development of coupling controlled polymerizations by adapter-ligation in mate-pair sequencing for detection of various genomic variants in one single assay.

Dong Z, Zhao X, Li Q, Yang Z, Xi Y, Alexeev A DNA Res. 2019; 26(4):313-325.

PMID: 31173071 PMC: 6704401. DOI: 10.1093/dnares/dsz011.

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