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Autores principales: Zoe Broad, James Lefevre, Melanie J. Wilkinson, Samuel Barton, Francois Barbier, Hyungtaek Jung, Diane Donovan, Daniel Ortiz‐Barrientos
Formato: Artículo Open Access
Publicado: Wiley 2024
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Acceso en línea:https://onlinelibrary.wiley.com/doi/10.1111/mec.17543
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author Zoe Broad
James Lefevre
Melanie J. Wilkinson
Samuel Barton
Francois Barbier
Hyungtaek Jung
Diane Donovan
Daniel Ortiz‐Barrientos
author_facet Zoe Broad
James Lefevre
Melanie J. Wilkinson
Samuel Barton
Francois Barbier
Hyungtaek Jung
Diane Donovan
Daniel Ortiz‐Barrientos
Zoe Broad
James Lefevre
Melanie J. Wilkinson
Samuel Barton
Francois Barbier
Hyungtaek Jung
Diane Donovan
Daniel Ortiz‐Barrientos
collection Wiley Open Access
contents Gravitropic Gene Expression Divergence Associated With Adaptation to Contrasting Environments in an Australian Wildflower Zoe Broad James Lefevre Melanie J. Wilkinson Samuel Barton Francois Barbier Hyungtaek Jung Diane Donovan Daniel Ortiz‐Barrientos Molecular Ecology ABSTRACTPlants adapt to their local environment through complex interactions between genes, gene networks and hormones. Although the impact of gene expression on trait regulation and evolution has been recognised for many decades, its role in the evolution of adaptation is still a subject of intense exploration. We used a Multi‐parent Advanced Generation Inter‐Cross (MAGIC) population, which we derived from crossing multiple parents from two distinct coastal ecotypes of an Australia wildflower, Senecio lautus. We focused on studying the contrasting gravitropic behaviours of these ecotypes, which have evolved independently multiple times and show strong responses to natural selection in field experiments, emphasising the role of natural selection in their evolution. Here, we investigated how gene expression differences have contributed to the adaptive evolution of gravitropism. We studied gene expression in 60 pools at five time points (30, 60, 120, 240 and 480 min) after rotating half of the pools 90°. We found 428 genes with differential expression in response to the 90° rotation treatment. Of these, 81 genes (~19%) have predicted functions related to the plant hormones auxin and ethylene, which are crucial for the gravitropic response. By combining insights from Arabidopsis mutant studies and analysing our gene networks, we propose a preliminary model to explain the differences in gravitropism between ecotypes. This model suggests that the differences arise from changes in the transport and availability of the two hormones auxin and ethylene. Our findings indicate that the genetic basis of adaptation involves interconnected signalling pathways that work together to give rise to new ecotypes. 10.1111/mec.17543 http://creativecommons.org/licenses/by-nc-nd/4.0/
doi_str_mv 10.1111/mec.17543
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spellingShingle Gravitropic Gene Expression Divergence Associated With Adaptation to Contrasting Environments in an Australian Wildflower
Zoe Broad
James Lefevre
Melanie J. Wilkinson
Samuel Barton
Francois Barbier
Hyungtaek Jung
Diane Donovan
Daniel Ortiz‐Barrientos
Molecular Ecology
Gravitropic Gene Expression Divergence Associated With Adaptation to Contrasting Environments in an Australian Wildflower Zoe Broad James Lefevre Melanie J. Wilkinson Samuel Barton Francois Barbier Hyungtaek Jung Diane Donovan Daniel Ortiz‐Barrientos Molecular Ecology ABSTRACTPlants adapt to their local environment through complex interactions between genes, gene networks and hormones. Although the impact of gene expression on trait regulation and evolution has been recognised for many decades, its role in the evolution of adaptation is still a subject of intense exploration. We used a Multi‐parent Advanced Generation Inter‐Cross (MAGIC) population, which we derived from crossing multiple parents from two distinct coastal ecotypes of an Australia wildflower, Senecio lautus. We focused on studying the contrasting gravitropic behaviours of these ecotypes, which have evolved independently multiple times and show strong responses to natural selection in field experiments, emphasising the role of natural selection in their evolution. Here, we investigated how gene expression differences have contributed to the adaptive evolution of gravitropism. We studied gene expression in 60 pools at five time points (30, 60, 120, 240 and 480 min) after rotating half of the pools 90°. We found 428 genes with differential expression in response to the 90° rotation treatment. Of these, 81 genes (~19%) have predicted functions related to the plant hormones auxin and ethylene, which are crucial for the gravitropic response. By combining insights from Arabidopsis mutant studies and analysing our gene networks, we propose a preliminary model to explain the differences in gravitropism between ecotypes. This model suggests that the differences arise from changes in the transport and availability of the two hormones auxin and ethylene. Our findings indicate that the genetic basis of adaptation involves interconnected signalling pathways that work together to give rise to new ecotypes. 10.1111/mec.17543 http://creativecommons.org/licenses/by-nc-nd/4.0/
title Gravitropic Gene Expression Divergence Associated With Adaptation to Contrasting Environments in an Australian Wildflower
topic Molecular Ecology
url https://onlinelibrary.wiley.com/doi/10.1111/mec.17543