An Efficient Strategy for Large-scale High-throughput Transposon-mediated Sequencing of CDNA Clones

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2002 May 30

PMID 12034834

Citations 17

Authors

Yaron S N Butterfield

Marco A Marra

Jennifer K Asano

Susanna Y Chan

Ranabir Guin

Martin I Krzywinski

Soo Sen Lee

Kim W K MacDonald

Carrie A Mathewson

Teika E Olson

Pawan K Pandoh

Anna-Liisa Prabhu

Angelique Schnerch

Ursula Skalska

Duane E Smailus

Jeff M Stott

Miranda I Tsai

George S Yang

Scott D Zuyderduyn

Jacqueline E Schein

Steven J M Jones

Affiliations

Soon will be listed here.

Abstract

We describe an efficient high-throughput method for accurate DNA sequencing of entire cDNA clones. Developed as part of our involvement in the Mammalian Gene Collection full-length cDNA sequencing initiative, the method has been used and refined in our laboratory since September 2000. Amenable to large scale projects, we have used the method to generate >7 Mb of accurate sequence from 3695 candidate full-length cDNAs. Sequencing is accomplished through the insertion of Mu transposon into cDNAs, followed by sequencing reactions primed with Mu-specific sequencing primers. Transposon insertion reactions are not performed with individual cDNAs but rather on pools of up to 96 clones. This pooling strategy reduces the number of transposon insertion sequencing libraries that would otherwise be required, reducing the costs and enhancing the efficiency of the transposon library construction procedure. Sequences generated using transposon-specific sequencing primers are assembled to yield the full-length cDNA sequence, with sequence editing and other sequence finishing activities performed as required to resolve sequence ambiguities. Although analysis of the many thousands (22 785) of sequenced Mu transposon insertion events revealed a weak sequence preference for Mu insertion, we observed insertion of the Mu transposon into 1015 of the possible 1024 5mer candidate insertion sites.

Citing Articles

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Extensive libraries of gene truncation variants generated by in vitro transposition.

Morelli A, Cabezas Y, Mills L, Seelig B Nucleic Acids Res. 2017; 45(10):e78.

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MuA-mediated in vitro cloning of circular DNA: transpositional autointegration and the effect of MuB.

Pulkkinen E, Haapa-Paananen S, Savilahti H Mol Genet Genomics. 2016; 291(3):1181-91.

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An assay to monitor the activity of DNA transposition complexes yields a general quality control measure for transpositional recombination reactions.

Pulkkinen E, Haapa-Paananen S, Savilahti H Mob Genet Elements. 2015; 4(5):1-8.

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Large-scale sequencing based on full-length-enriched cDNA libraries in pigs: contribution to annotation of the pig genome draft sequence.

Uenishi H, Morozumi T, Toki D, Eguchi-Ogawa T, Rund L, Schook L BMC Genomics. 2012; 13:581.

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