Improving mammalian genome scaffolding using large insert mate-pair next-generation sequencing

Sebastiaan van Heesch; Wigard P Kloosterman; Nico Lansu; Frans-Paul Ruzius; Elizabeth Levandowsky; Clarence C Lee; Shiguo Zhou; Steve Goldstein; David C Schwartz; Timothy T Harkins; Victor Guryev; Edwin Cuppen

doi:10.1186/1471-2164-14-257

Improving mammalian genome scaffolding using large insert mate-pair next-generation sequencing

Sebastiaan van Heesch
, Wigard P Kloosterman
, Nico Lansu
, Frans-Paul Ruzius
, Elizabeth Levandowsky
, Clarence C Lee
, Shiguo Zhou
, Steve Goldstein
, David C Schwartz
, Timothy T Harkins
, Victor Guryev
, Edwin Cuppen

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

31 Citations (Scopus)

Abstract

BACKGROUND: Paired-tag sequencing approaches are commonly used for the analysis of genome structure. However, mammalian genomes have a complex organization with a variety of repetitive elements that complicate comprehensive genome-wide analyses.

RESULTS: Here, we systematically assessed the utility of paired-end and mate-pair (MP) next-generation sequencing libraries with insert sizes ranging from 170 bp to 25 kb, for genome coverage and for improving scaffolding of a mammalian genome (Rattus norvegicus). Despite a lower library complexity, large insert MP libraries (20 or 25 kb) provided very high physical genome coverage and were found to efficiently span repeat elements in the genome. Medium-sized (5, 8 or 15 kb) MP libraries were much more efficient for genome structure analysis than the more commonly used shorter insert paired-end and 3 kb MP libraries. Furthermore, the combination of medium- and large insert libraries resulted in a 3-fold increase in N50 in scaffolding processes. Finally, we show that our data can be used to evaluate and improve contig order and orientation in the current rat reference genome assembly.

CONCLUSIONS: We conclude that applying combinations of mate-pair libraries with insert sizes that match the distributions of repetitive elements improves contig scaffolding and can contribute to the finishing of draft genomes.

Original language	English
Article number	257
Pages (from-to)	257
Journal	BMC genomics
Volume	14
Issue number	1
DOIs	https://doi.org/10.1186/1471-2164-14-257
Publication status	Published - 16 Apr 2013
Externally published	Yes

Keywords

Animals
Base Sequence
Contig Mapping/methods
Gene Library
Genome
Interspersed Repetitive Sequences/genetics
Rats/genetics
Sequence Analysis, DNA/methods

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10.1186/1471-2164-14-257

Cite this

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title = "Improving mammalian genome scaffolding using large insert mate-pair next-generation sequencing",

abstract = "BACKGROUND: Paired-tag sequencing approaches are commonly used for the analysis of genome structure. However, mammalian genomes have a complex organization with a variety of repetitive elements that complicate comprehensive genome-wide analyses.RESULTS: Here, we systematically assessed the utility of paired-end and mate-pair (MP) next-generation sequencing libraries with insert sizes ranging from 170 bp to 25 kb, for genome coverage and for improving scaffolding of a mammalian genome (Rattus norvegicus). Despite a lower library complexity, large insert MP libraries (20 or 25 kb) provided very high physical genome coverage and were found to efficiently span repeat elements in the genome. Medium-sized (5, 8 or 15 kb) MP libraries were much more efficient for genome structure analysis than the more commonly used shorter insert paired-end and 3 kb MP libraries. Furthermore, the combination of medium- and large insert libraries resulted in a 3-fold increase in N50 in scaffolding processes. Finally, we show that our data can be used to evaluate and improve contig order and orientation in the current rat reference genome assembly.CONCLUSIONS: We conclude that applying combinations of mate-pair libraries with insert sizes that match the distributions of repetitive elements improves contig scaffolding and can contribute to the finishing of draft genomes.",

keywords = "Animals, Base Sequence, Contig Mapping/methods, Gene Library, Genome, Interspersed Repetitive Sequences/genetics, Rats/genetics, Sequence Analysis, DNA/methods",

author = "\{van Heesch\}, Sebastiaan and Kloosterman, \{Wigard P\} and Nico Lansu and Frans-Paul Ruzius and Elizabeth Levandowsky and Lee, \{Clarence C\} and Shiguo Zhou and Steve Goldstein and Schwartz, \{David C\} and Harkins, \{Timothy T\} and Victor Guryev and Edwin Cuppen",

note = "Funding Information: This work was supported by funding from the European Union framework 7 integrated project EURATRANS (HEALTH-F4-2010–241504 to E.C.); the NWO-CW TOP grant (700.58.303 to EC); and the National Institutes of Health (R01 HG000225 to D.C.S). Funding for open access charge: primary funding from the Hubrecht Institute.",

year = "2013",

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doi = "10.1186/1471-2164-14-257",

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AU - van Heesch, Sebastiaan

AU - Kloosterman, Wigard P

AU - Lansu, Nico

AU - Ruzius, Frans-Paul

AU - Levandowsky, Elizabeth

AU - Lee, Clarence C

AU - Zhou, Shiguo

AU - Goldstein, Steve

AU - Schwartz, David C

AU - Harkins, Timothy T

AU - Guryev, Victor

AU - Cuppen, Edwin

N1 - Funding Information: This work was supported by funding from the European Union framework 7 integrated project EURATRANS (HEALTH-F4-2010–241504 to E.C.); the NWO-CW TOP grant (700.58.303 to EC); and the National Institutes of Health (R01 HG000225 to D.C.S). Funding for open access charge: primary funding from the Hubrecht Institute.

PY - 2013/4/16

Y1 - 2013/4/16

N2 - BACKGROUND: Paired-tag sequencing approaches are commonly used for the analysis of genome structure. However, mammalian genomes have a complex organization with a variety of repetitive elements that complicate comprehensive genome-wide analyses.RESULTS: Here, we systematically assessed the utility of paired-end and mate-pair (MP) next-generation sequencing libraries with insert sizes ranging from 170 bp to 25 kb, for genome coverage and for improving scaffolding of a mammalian genome (Rattus norvegicus). Despite a lower library complexity, large insert MP libraries (20 or 25 kb) provided very high physical genome coverage and were found to efficiently span repeat elements in the genome. Medium-sized (5, 8 or 15 kb) MP libraries were much more efficient for genome structure analysis than the more commonly used shorter insert paired-end and 3 kb MP libraries. Furthermore, the combination of medium- and large insert libraries resulted in a 3-fold increase in N50 in scaffolding processes. Finally, we show that our data can be used to evaluate and improve contig order and orientation in the current rat reference genome assembly.CONCLUSIONS: We conclude that applying combinations of mate-pair libraries with insert sizes that match the distributions of repetitive elements improves contig scaffolding and can contribute to the finishing of draft genomes.

AB - BACKGROUND: Paired-tag sequencing approaches are commonly used for the analysis of genome structure. However, mammalian genomes have a complex organization with a variety of repetitive elements that complicate comprehensive genome-wide analyses.RESULTS: Here, we systematically assessed the utility of paired-end and mate-pair (MP) next-generation sequencing libraries with insert sizes ranging from 170 bp to 25 kb, for genome coverage and for improving scaffolding of a mammalian genome (Rattus norvegicus). Despite a lower library complexity, large insert MP libraries (20 or 25 kb) provided very high physical genome coverage and were found to efficiently span repeat elements in the genome. Medium-sized (5, 8 or 15 kb) MP libraries were much more efficient for genome structure analysis than the more commonly used shorter insert paired-end and 3 kb MP libraries. Furthermore, the combination of medium- and large insert libraries resulted in a 3-fold increase in N50 in scaffolding processes. Finally, we show that our data can be used to evaluate and improve contig order and orientation in the current rat reference genome assembly.CONCLUSIONS: We conclude that applying combinations of mate-pair libraries with insert sizes that match the distributions of repetitive elements improves contig scaffolding and can contribute to the finishing of draft genomes.

KW - Animals

KW - Base Sequence

KW - Contig Mapping/methods

KW - Gene Library

KW - Genome

KW - Interspersed Repetitive Sequences/genetics

KW - Rats/genetics

KW - Sequence Analysis, DNA/methods

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DO - 10.1186/1471-2164-14-257

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SN - 1471-2164

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SP - 257

JO - BMC genomics

JF - BMC genomics

IS - 1

M1 - 257

ER -

Improving mammalian genome scaffolding using large insert mate-pair next-generation sequencing

Abstract

Keywords

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