Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies

Erik J.M. Koenen; Dario I. Ojeda; Royce Steeves; Jérémy Migliore; Freek T. Bakker; Jan J. Wieringa; Catherine Kidner; Olivier J. Hardy; R.T. Pennington; Anne Bruneau; Colin E. Hughes

doi:10.1111/nph.16290

Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies

Erik J.M. Koenen^*, Dario I. Ojeda, Royce Steeves, Jérémy Migliore, Freek T. Bakker, Jan J. Wieringa, Catherine Kidner, Olivier J. Hardy, R.T. Pennington, Anne Bruneau, Colin E. Hughes

^*Corresponding author for this work

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

73 Citations (Scopus)

Abstract

Phylogenomics is increasingly used to infer deep‐branching relationships while revealing the complexity of evolutionary processes such as incomplete lineage sorting, hybridization/introgression and polyploidization. We investigate the deep‐branching relationships among subfamilies of the Leguminosae (or Fabaceae), the third largest angiosperm family. Despite their ecological and economic importance, a robust phylogenetic framework for legumes based on genome‐scale sequence data is lacking.We generated alignments of 72 chloroplast genes and 7621 homologous nuclear‐encoded proteins, for 157 and 76 taxa, respectively. We analysed these with maximum likelihood, Bayesian inference, and a multispecies coalescent summary method, and evaluated support for alternative topologies across gene trees.
We resolve the deepest divergences in the legume phylogeny despite lack of phylogenetic signal across all chloroplast genes and the majority of nuclear genes. Strongly supported conflict in the remainder of nuclear genes is suggestive of incomplete lineage sorting.
All six subfamilies originated nearly simultaneously, suggesting that the prevailing view of some subfamilies as ‘basal’ or ‘early‐diverging’ with respect to others should be abandoned, which has important implications for understanding the evolution of legume diversity and traits. Our study highlights the limits of phylogenetic resolution in relation to rapid successive speciation.

Original language	English
Pages (from-to)	1355-1369
Journal	New Phytologist
Volume	225
Issue number	3
Early online date	30 Oct 2019
DOIs	https://doi.org/10.1111/nph.16290
Publication status	Published - Feb 2020

Keywords

Fabaceae
gene tree conflict
incomplete lineage sorting
lack of phylogenetic signal
Leguminosae
phylogenomics

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10.1111/nph.16290Licence: CC BY-NC

Fabales RNA polymerase beta subunit (rpoB) gene, complete cds; chloroplast
Koenen, E. J. M. (Creator), Ojeda, D. I. (Creator), Steeves, R. (Creator), Migliore, J. (Creator), Bakker, F. (Creator), Wieringa, J. J. (Creator), Kidner, C. (Creator), Hardy, O. J. (Creator), Pennington, R. T. (Creator), Bruneau, A. (Creator) & Hughes, C. E. (Creator), University of Zurich, 12 Nov 2019
https://www.ncbi.nlm.nih.gov/popset/1773390208
Dataset
Fabales envelope membrane protein (cemA) gene, complete cds; chloroplast
Koenen, E. J. M. (Creator), Ojeda, D. I. (Creator), Steeves, R. (Creator), Migliore, J. (Creator), Bakker, F. (Creator), Wieringa, J. J. (Creator), Kidner, C. (Creator), Hardy, O. J. (Creator), Pennington, R. T. (Creator), Bruneau, A. (Creator) & Hughes, C. E. (Creator), University of Zurich, 12 Nov 2019
https://www.ncbi.nlm.nih.gov/popset/1773387266
Dataset
Fabales ribosomal protein S8 (rps8) gene, partial cds; chloroplast
Koenen, E. J. M. (Creator), Ojeda, D. I. (Creator), Steeves, R. (Creator), Migliore, J. (Creator), Bakker, F. (Creator), Wieringa, J. J. (Creator), Kidner, C. (Creator), Hardy, O. J. (Creator), Pennington, R. T. (Creator), Bruneau, A. (Creator) & Hughes, C. E. (Creator), University of Zurich, 12 Nov 2019
https://www.ncbi.nlm.nih.gov/popset/1773390798
Dataset

Cite this

Koenen, E. J. M., Ojeda, D. I., Steeves, R., Migliore, J., Bakker, F. T., Wieringa, J. J., Kidner, C., Hardy, O. J., Pennington, R. T., Bruneau, A., & Hughes, C. E. (2020). Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies. New Phytologist, 225(3), 1355-1369. Advance online publication. https://doi.org/10.1111/nph.16290

@article{20457b65242341a2839eb5b67a946e34,

title = "Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies",

abstract = "Phylogenomics is increasingly used to infer deep‐branching relationships while revealing the complexity of evolutionary processes such as incomplete lineage sorting, hybridization/introgression and polyploidization. We investigate the deep‐branching relationships among subfamilies of the Leguminosae (or Fabaceae), the third largest angiosperm family. Despite their ecological and economic importance, a robust phylogenetic framework for legumes based on genome‐scale sequence data is lacking.We generated alignments of 72 chloroplast genes and 7621 homologous nuclear‐encoded proteins, for 157 and 76 taxa, respectively. We analysed these with maximum likelihood, Bayesian inference, and a multispecies coalescent summary method, and evaluated support for alternative topologies across gene trees.We resolve the deepest divergences in the legume phylogeny despite lack of phylogenetic signal across all chloroplast genes and the majority of nuclear genes. Strongly supported conflict in the remainder of nuclear genes is suggestive of incomplete lineage sorting.All six subfamilies originated nearly simultaneously, suggesting that the prevailing view of some subfamilies as {\textquoteleft}basal{\textquoteright} or {\textquoteleft}early‐diverging{\textquoteright} with respect to others should be abandoned, which has important implications for understanding the evolution of legume diversity and traits. Our study highlights the limits of phylogenetic resolution in relation to rapid successive speciation.",

keywords = "Fabaceae, gene tree conflict, incomplete lineage sorting, lack of phylogenetic signal, Leguminosae, phylogenomics",

author = "Koenen, {Erik J.M.} and Ojeda, {Dario I.} and Royce Steeves and J{\'e}r{\'e}my Migliore and Bakker, {Freek T.} and Wieringa, {Jan J.} and Catherine Kidner and Hardy, {Olivier J.} and R.T. Pennington and Anne Bruneau and Hughes, {Colin E.}",

year = "2020",

month = feb,

doi = "10.1111/nph.16290",

language = "English",

volume = "225",

pages = "1355--1369",

journal = "New Phytologist",

issn = "0028-646X",

publisher = "Wiley",

number = "3",

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Koenen, EJM, Ojeda, DI, Steeves, R, Migliore, J, Bakker, FT, Wieringa, JJ, Kidner, C, Hardy, OJ, Pennington, RT, Bruneau, A & Hughes, CE 2020, 'Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies', New Phytologist, vol. 225, no. 3, pp. 1355-1369. https://doi.org/10.1111/nph.16290

Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies. / Koenen, Erik J.M.; Ojeda, Dario I.; Steeves, Royce et al.
In: New Phytologist, Vol. 225, No. 3, 02.2020, p. 1355-1369.

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

TY - JOUR

T1 - Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies

AU - Koenen, Erik J.M.

AU - Ojeda, Dario I.

AU - Steeves, Royce

AU - Migliore, Jérémy

AU - Bakker, Freek T.

AU - Wieringa, Jan J.

AU - Kidner, Catherine

AU - Hardy, Olivier J.

AU - Pennington, R.T.

AU - Bruneau, Anne

AU - Hughes, Colin E.

PY - 2020/2

Y1 - 2020/2

N2 - Phylogenomics is increasingly used to infer deep‐branching relationships while revealing the complexity of evolutionary processes such as incomplete lineage sorting, hybridization/introgression and polyploidization. We investigate the deep‐branching relationships among subfamilies of the Leguminosae (or Fabaceae), the third largest angiosperm family. Despite their ecological and economic importance, a robust phylogenetic framework for legumes based on genome‐scale sequence data is lacking.We generated alignments of 72 chloroplast genes and 7621 homologous nuclear‐encoded proteins, for 157 and 76 taxa, respectively. We analysed these with maximum likelihood, Bayesian inference, and a multispecies coalescent summary method, and evaluated support for alternative topologies across gene trees.We resolve the deepest divergences in the legume phylogeny despite lack of phylogenetic signal across all chloroplast genes and the majority of nuclear genes. Strongly supported conflict in the remainder of nuclear genes is suggestive of incomplete lineage sorting.All six subfamilies originated nearly simultaneously, suggesting that the prevailing view of some subfamilies as ‘basal’ or ‘early‐diverging’ with respect to others should be abandoned, which has important implications for understanding the evolution of legume diversity and traits. Our study highlights the limits of phylogenetic resolution in relation to rapid successive speciation.

AB - Phylogenomics is increasingly used to infer deep‐branching relationships while revealing the complexity of evolutionary processes such as incomplete lineage sorting, hybridization/introgression and polyploidization. We investigate the deep‐branching relationships among subfamilies of the Leguminosae (or Fabaceae), the third largest angiosperm family. Despite their ecological and economic importance, a robust phylogenetic framework for legumes based on genome‐scale sequence data is lacking.We generated alignments of 72 chloroplast genes and 7621 homologous nuclear‐encoded proteins, for 157 and 76 taxa, respectively. We analysed these with maximum likelihood, Bayesian inference, and a multispecies coalescent summary method, and evaluated support for alternative topologies across gene trees.We resolve the deepest divergences in the legume phylogeny despite lack of phylogenetic signal across all chloroplast genes and the majority of nuclear genes. Strongly supported conflict in the remainder of nuclear genes is suggestive of incomplete lineage sorting.All six subfamilies originated nearly simultaneously, suggesting that the prevailing view of some subfamilies as ‘basal’ or ‘early‐diverging’ with respect to others should be abandoned, which has important implications for understanding the evolution of legume diversity and traits. Our study highlights the limits of phylogenetic resolution in relation to rapid successive speciation.

KW - Fabaceae

KW - gene tree conflict

KW - incomplete lineage sorting

KW - lack of phylogenetic signal

KW - Leguminosae

KW - phylogenomics

U2 - 10.1111/nph.16290

DO - 10.1111/nph.16290

M3 - Article

SN - 0028-646X

VL - 225

SP - 1355

EP - 1369

JO - New Phytologist

JF - New Phytologist

IS - 3

ER -

Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies

Abstract

Keywords

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Datasets

Fabales RNA polymerase beta subunit (rpoB) gene, complete cds; chloroplast

Fabales envelope membrane protein (cemA) gene, complete cds; chloroplast

Fabales ribosomal protein S8 (rps8) gene, partial cds; chloroplast

Cite this