Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing

Henrik Christiansen; Franz M. Heindler; Bart Hellemans; Quentin Jossart; Francesca Pasotti; Henri Robert; Marie Verheye; Bruno Danis; Marc Kochzius; Frederik Leliaert; Camille Moreau; Tasnim Patel; Anton P. Van de Putte; Ann Vanreusel; Filip A. M. Volckaert; Isa Schon

doi:10.1186/s12864-021-07917-3

Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing

Henrik Christiansen, Franz M. Heindler, Bart Hellemans, Quentin Jossart, Francesca Pasotti, Henri Robert, Marie Verheye, Bruno Danis, Marc Kochzius, Frederik Leliaert, Camille Moreau, Tasnim Patel, Anton P. Van de Putte, Ann Vanreusel, Filip A. M. Volckaert, Isa Schon

Biologie

Onderzoeksoutput: Article › peer review

13 Citaten (Scopus)

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Background: Genome-wide data are invaluable to characterize differentiation and adaptation of natural populations. Reduced representation sequencing (RRS) subsamples a genome repeatedly across many individuals. However, RRS requires careful optimization and fine-tuning to deliver high marker density while being cost-efficient. The number of genomic fragments created through restriction enzyme digestion and the sequencing library setup must match to achieve sufficient sequencing coverage per locus. Here, we present a workflow based on published information and computational and experimental procedures to investigate and streamline the applicability of RRS.
Results: In an iterative process genome size estimates, restriction enzymes and size selection windows were tested and scaled in six classes of Antarctic animals (Ostracoda, Malacostraca, Bivalvia, Asteroidea, Actinopterygii, Aves). Achieving high marker density would be expensive in amphipods, the malacostracan target taxon, due to the large genome size. We propose alternative approaches such as mitogenome or target capture sequencing for this group. Pilot libraries were sequenced for all other target taxa. Ostracods, bivalves, sea stars, and fish showed overall good coverage and marker numbers for downstream population genomic analyses. In contrast, the bird test library produced low coverage and few polymorphic loci, likely due to degraded DNA.
Conclusions: Prior testing and optimization are important to identify which groups are amenable for RRS and where alternative methods may currently offer better cost-benefit ratios. The steps outlined here are easy to follow for other non-model taxa with little genomic resources, thus stimulating efficient resource use for the many pressing research questions in molecular ecology.
Keywords: Biodiversity, Genome scan, Genotyping by sequencing, In silico digestion, RADseq, Southern Ocean

Originele taal-2	English
Artikelnummer	625
Pagina's (van-tot)	625
Aantal pagina's	20
Tijdschrift	BMC Genomics
Volume	22
Nummer van het tijdschrift	1
DOI's	https://doi.org/10.1186/s12864-021-07917-3
Status	Published - 21 aug. 2021

Bibliografische nota

Funding Information:
This is contribution no. 35 of the vERSO project, funded by the Belgian Science Policy Office (BELSPO, Contract no. BR/132/A1/vERSO) and contribution no. 8 of the RECTO project (BELSPO, Contract no. BR/154/A1/RECTO). TP thanks BELSPO for funding JPIO Mining Impact. Research was also supported by the Scientific Research Network “Eco-evolutionary dynamics in natural and anthropogenic communities” (grant W0.037.10 N), and the European Marine Biological Resource Center (EMBRC) Belgium, both funded by the Research Foundation – Flanders (FWO). The first author was supported by an individual grant from the former Flemish Agency for Innovation by Science and Technology, now managed through Flanders Innovation & Entrepreneurship (VLAIO, grant no. 141328). The funding bodies had no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript.

Funding Information:
We are very grateful to everyone that contributed to field work and provided samples. In particular, we thank S. Brandão for ostracod DNA and H. Griffiths and K. Linse (BAS), C. Held (AWI), S. Mills and D. Macpherson (NIWA), H. Baird and G. Johnstone (AAD), and the MNHN in Paris for amphipod samples. We thank M. Clark (BAS) and the scientific staff involved for the generous collection of bivalve samples from Rothera station. We thank the captains, crew and science leaders who contributed to the collection of sea stars from RRS James Clark Ross (JR15005) and RV Polarstern (PS77, PS81). We thank the scientific team of IPEV (Institut Polaire Français Paul-Emile Victor) program 1124 REVOLTA (Radiation EVOLutives en Terre Adélie; chief scientists M. Eléaume, N. Améziane and G. Lecointre). For fishes, we thank K. Roche and P. Jurajda who provided fin clips from James Ross Island. The toothfish fishery observers and S. Parker (NIWA) are acknowledged for fish samples from the Ross Sea. We thank G.E. Maes and K. Herten from the KU Leuven Genomics Core for technical support and advice. We thank the two anonymous reviewers for their constructive comments.

Publisher Copyright:
© 2021, The Author(s).

Copyright:
Copyright 2022 Elsevier B.V., All rights reserved.

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Code and data associated with Christiansen et al. 2021 "Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing"
Christesen, H. T. (Creator), Heindler, F. M. (Creator), Hellemans, B. (Creator), Jossart, Q. (Creator), Pasotti, F. (Creator), Robert, H. (Creator), Verheye, M. (Creator), Danis, B. (Creator), Kochzius, M. (Creator), Leliaert, F. (Creator), Moreau, C. V. E. (Creator), Patel, T. (Creator), Van de Putte, A. P. (Creator), Vanreusel, A. (Creator), Volckaert, F. A. M. (Creator) & Schön, I. (Creator), Zenodo, 30 jun. 2021
DOI: 10.5281/zenodo.5045573., http://10.1186/s12864-021-07917-3
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Christiansen, H., Heindler, F. M., Hellemans, B., Jossart, Q., Pasotti, F., Robert, H., Verheye, M., Danis, B., Kochzius, M., Leliaert, F., Moreau, C., Patel, T., Van de Putte, A. P., Vanreusel, A., Volckaert, F. A. M., & Schon, I. (2021). Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing. BMC Genomics, 22(1), 625. Artikel 625. https://doi.org/10.1186/s12864-021-07917-3

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abstract = "Background: Genome-wide data are invaluable to characterize differentiation and adaptation of natural populations. Reduced representation sequencing (RRS) subsamples a genome repeatedly across many individuals. However, RRS requires careful optimization and fine-tuning to deliver high marker density while being cost-efficient. The number of genomic fragments created through restriction enzyme digestion and the sequencing library setup must match to achieve sufficient sequencing coverage per locus. Here, we present a workflow based on published information and computational and experimental procedures to investigate and streamline the applicability of RRS.Results: In an iterative process genome size estimates, restriction enzymes and size selection windows were tested and scaled in six classes of Antarctic animals (Ostracoda, Malacostraca, Bivalvia, Asteroidea, Actinopterygii, Aves). Achieving high marker density would be expensive in amphipods, the malacostracan target taxon, due to the large genome size. We propose alternative approaches such as mitogenome or target capture sequencing for this group. Pilot libraries were sequenced for all other target taxa. Ostracods, bivalves, sea stars, and fish showed overall good coverage and marker numbers for downstream population genomic analyses. In contrast, the bird test library produced low coverage and few polymorphic loci, likely due to degraded DNA.Conclusions: Prior testing and optimization are important to identify which groups are amenable for RRS and where alternative methods may currently offer better cost-benefit ratios. The steps outlined here are easy to follow for other non-model taxa with little genomic resources, thus stimulating efficient resource use for the many pressing research questions in molecular ecology.Keywords: Biodiversity, Genome scan, Genotyping by sequencing, In silico digestion, RADseq, Southern Ocean",

keywords = "Biodiversity, Genome scan, Genotyping by sequencing, In silico digestion, RADseq, Southern Ocean",

author = "Henrik Christiansen and Heindler, {Franz M.} and Bart Hellemans and Quentin Jossart and Francesca Pasotti and Henri Robert and Marie Verheye and Bruno Danis and Marc Kochzius and Frederik Leliaert and Camille Moreau and Tasnim Patel and {Van de Putte}, {Anton P.} and Ann Vanreusel and Volckaert, {Filip A. M.} and Isa Schon",

note = "Funding Information: This is contribution no. 35 of the vERSO project, funded by the Belgian Science Policy Office (BELSPO, Contract no. BR/132/A1/vERSO) and contribution no. 8 of the RECTO project (BELSPO, Contract no. BR/154/A1/RECTO). TP thanks BELSPO for funding JPIO Mining Impact. Research was also supported by the Scientific Research Network “Eco-evolutionary dynamics in natural and anthropogenic communities” (grant W0.037.10 N), and the European Marine Biological Resource Center (EMBRC) Belgium, both funded by the Research Foundation – Flanders (FWO). The first author was supported by an individual grant from the former Flemish Agency for Innovation by Science and Technology, now managed through Flanders Innovation & Entrepreneurship (VLAIO, grant no. 141328). The funding bodies had no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript. Funding Information: We are very grateful to everyone that contributed to field work and provided samples. In particular, we thank S. Brand{\~a}o for ostracod DNA and H. Griffiths and K. Linse (BAS), C. Held (AWI), S. Mills and D. Macpherson (NIWA), H. Baird and G. Johnstone (AAD), and the MNHN in Paris for amphipod samples. We thank M. Clark (BAS) and the scientific staff involved for the generous collection of bivalve samples from Rothera station. We thank the captains, crew and science leaders who contributed to the collection of sea stars from RRS James Clark Ross (JR15005) and RV Polarstern (PS77, PS81). We thank the scientific team of IPEV (Institut Polaire Fran{\c c}ais Paul-Emile Victor) program 1124 REVOLTA (Radiation EVOLutives en Terre Ad{\'e}lie; chief scientists M. El{\'e}aume, N. Am{\'e}ziane and G. Lecointre). For fishes, we thank K. Roche and P. Jurajda who provided fin clips from James Ross Island. The toothfish fishery observers and S. Parker (NIWA) are acknowledged for fish samples from the Ross Sea. We thank G.E. Maes and K. Herten from the KU Leuven Genomics Core for technical support and advice. We thank the two anonymous reviewers for their constructive comments. Publisher Copyright: {\textcopyright} 2021, The Author(s). Copyright: Copyright 2022 Elsevier B.V., All rights reserved.",

year = "2021",

month = aug,

day = "21",

doi = "10.1186/s12864-021-07917-3",

language = "English",

volume = "22",

pages = "625",

journal = "BMC Genomics",

issn = "1471-2164",

publisher = "BioMed Central",

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Christiansen, H, Heindler, FM, Hellemans, B, Jossart, Q, Pasotti, F, Robert, H, Verheye, M, Danis, B, Kochzius, M, Leliaert, F, Moreau, C, Patel, T, Van de Putte, AP, Vanreusel, A, Volckaert, FAM & Schon, I 2021, 'Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing', BMC Genomics, vol. 22, nr. 1, 625, blz. 625. https://doi.org/10.1186/s12864-021-07917-3

TY - JOUR

T1 - Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing

AU - Christiansen, Henrik

AU - Heindler, Franz M.

AU - Hellemans, Bart

AU - Jossart, Quentin

AU - Pasotti, Francesca

AU - Robert, Henri

AU - Verheye, Marie

AU - Danis, Bruno

AU - Kochzius, Marc

AU - Leliaert, Frederik

AU - Moreau, Camille

AU - Patel, Tasnim

AU - Van de Putte, Anton P.

AU - Vanreusel, Ann

AU - Volckaert, Filip A. M.

AU - Schon, Isa

N1 - Funding Information: This is contribution no. 35 of the vERSO project, funded by the Belgian Science Policy Office (BELSPO, Contract no. BR/132/A1/vERSO) and contribution no. 8 of the RECTO project (BELSPO, Contract no. BR/154/A1/RECTO). TP thanks BELSPO for funding JPIO Mining Impact. Research was also supported by the Scientific Research Network “Eco-evolutionary dynamics in natural and anthropogenic communities” (grant W0.037.10 N), and the European Marine Biological Resource Center (EMBRC) Belgium, both funded by the Research Foundation – Flanders (FWO). The first author was supported by an individual grant from the former Flemish Agency for Innovation by Science and Technology, now managed through Flanders Innovation & Entrepreneurship (VLAIO, grant no. 141328). The funding bodies had no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript. Funding Information: We are very grateful to everyone that contributed to field work and provided samples. In particular, we thank S. Brandão for ostracod DNA and H. Griffiths and K. Linse (BAS), C. Held (AWI), S. Mills and D. Macpherson (NIWA), H. Baird and G. Johnstone (AAD), and the MNHN in Paris for amphipod samples. We thank M. Clark (BAS) and the scientific staff involved for the generous collection of bivalve samples from Rothera station. We thank the captains, crew and science leaders who contributed to the collection of sea stars from RRS James Clark Ross (JR15005) and RV Polarstern (PS77, PS81). We thank the scientific team of IPEV (Institut Polaire Français Paul-Emile Victor) program 1124 REVOLTA (Radiation EVOLutives en Terre Adélie; chief scientists M. Eléaume, N. Améziane and G. Lecointre). For fishes, we thank K. Roche and P. Jurajda who provided fin clips from James Ross Island. The toothfish fishery observers and S. Parker (NIWA) are acknowledged for fish samples from the Ross Sea. We thank G.E. Maes and K. Herten from the KU Leuven Genomics Core for technical support and advice. We thank the two anonymous reviewers for their constructive comments. Publisher Copyright: © 2021, The Author(s). Copyright: Copyright 2022 Elsevier B.V., All rights reserved.

PY - 2021/8/21

Y1 - 2021/8/21

N2 - Background: Genome-wide data are invaluable to characterize differentiation and adaptation of natural populations. Reduced representation sequencing (RRS) subsamples a genome repeatedly across many individuals. However, RRS requires careful optimization and fine-tuning to deliver high marker density while being cost-efficient. The number of genomic fragments created through restriction enzyme digestion and the sequencing library setup must match to achieve sufficient sequencing coverage per locus. Here, we present a workflow based on published information and computational and experimental procedures to investigate and streamline the applicability of RRS.Results: In an iterative process genome size estimates, restriction enzymes and size selection windows were tested and scaled in six classes of Antarctic animals (Ostracoda, Malacostraca, Bivalvia, Asteroidea, Actinopterygii, Aves). Achieving high marker density would be expensive in amphipods, the malacostracan target taxon, due to the large genome size. We propose alternative approaches such as mitogenome or target capture sequencing for this group. Pilot libraries were sequenced for all other target taxa. Ostracods, bivalves, sea stars, and fish showed overall good coverage and marker numbers for downstream population genomic analyses. In contrast, the bird test library produced low coverage and few polymorphic loci, likely due to degraded DNA.Conclusions: Prior testing and optimization are important to identify which groups are amenable for RRS and where alternative methods may currently offer better cost-benefit ratios. The steps outlined here are easy to follow for other non-model taxa with little genomic resources, thus stimulating efficient resource use for the many pressing research questions in molecular ecology.Keywords: Biodiversity, Genome scan, Genotyping by sequencing, In silico digestion, RADseq, Southern Ocean

AB - Background: Genome-wide data are invaluable to characterize differentiation and adaptation of natural populations. Reduced representation sequencing (RRS) subsamples a genome repeatedly across many individuals. However, RRS requires careful optimization and fine-tuning to deliver high marker density while being cost-efficient. The number of genomic fragments created through restriction enzyme digestion and the sequencing library setup must match to achieve sufficient sequencing coverage per locus. Here, we present a workflow based on published information and computational and experimental procedures to investigate and streamline the applicability of RRS.Results: In an iterative process genome size estimates, restriction enzymes and size selection windows were tested and scaled in six classes of Antarctic animals (Ostracoda, Malacostraca, Bivalvia, Asteroidea, Actinopterygii, Aves). Achieving high marker density would be expensive in amphipods, the malacostracan target taxon, due to the large genome size. We propose alternative approaches such as mitogenome or target capture sequencing for this group. Pilot libraries were sequenced for all other target taxa. Ostracods, bivalves, sea stars, and fish showed overall good coverage and marker numbers for downstream population genomic analyses. In contrast, the bird test library produced low coverage and few polymorphic loci, likely due to degraded DNA.Conclusions: Prior testing and optimization are important to identify which groups are amenable for RRS and where alternative methods may currently offer better cost-benefit ratios. The steps outlined here are easy to follow for other non-model taxa with little genomic resources, thus stimulating efficient resource use for the many pressing research questions in molecular ecology.Keywords: Biodiversity, Genome scan, Genotyping by sequencing, In silico digestion, RADseq, Southern Ocean

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KW - Genome scan

KW - Genotyping by sequencing

KW - In silico digestion

KW - RADseq

KW - Southern Ocean

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JF - BMC Genomics

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ER -

Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing

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Code and data associated with Christiansen et al. 2021 "Facilitating population genomics of non-model organisms through optimized experimental design for reduced representation sequencing"

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