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Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation

Assisted gene flow (AGF) can restore fitness in small plant populations. Due to climate change, current fitness patterns could vary in the future ecological scenario, as highly performant lineages can undergo maladaptation under the new climatic contexts. Peripheral populations have been argued to r...

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Autores principales: Gargano, Domenico, Bernardo, Liliana, Rovito, Simone, Passalacqua, Nicodemo G, Abeli, Thomas
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Oxford University Press 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9167561/
https://www.ncbi.nlm.nih.gov/pubmed/35673362
http://dx.doi.org/10.1093/aobpla/plac022
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author Gargano, Domenico
Bernardo, Liliana
Rovito, Simone
Passalacqua, Nicodemo G
Abeli, Thomas
author_facet Gargano, Domenico
Bernardo, Liliana
Rovito, Simone
Passalacqua, Nicodemo G
Abeli, Thomas
author_sort Gargano, Domenico
collection PubMed
description Assisted gene flow (AGF) can restore fitness in small plant populations. Due to climate change, current fitness patterns could vary in the future ecological scenario, as highly performant lineages can undergo maladaptation under the new climatic contexts. Peripheral populations have been argued to represent a potential source of species adaptation against climate change, but experimental evidence is poor. This paper considers the consequences of within- and between-population mating between a large core population and the southernmost population, the rare Dianthus guliae, to evaluate optimal AGF design under current and future conditions. We performed experimental self-pollinations and within- and between-population cross-pollinations to generate seed material and test its adaptive value to aridity. Seed germination, seedling growth and survival were measured under current and expected aridity. Effects of population type, pollination treatment and stress treatment on fitness components were analysed by generalized linear models. Relative measures of inbreeding depression and heterosis were taken under different stress treatments. Self-pollination reduced fitness for all the considered traits compared to within- and between-population cross-pollination. Under current aridity regime, the core population expressed higher fitness, and a larger magnitude of inbreeding depression. This indicated the core unit is close to its fitness optimum and could allow for restoring the fitness of the small peripheral population. Contrarily, under increased aridity, the fitness of outbred core lineages decreased, suggesting the rise of maladaptation. In this scenario, AGF from the small peripheral population enhanced the fitness of the core unit, whereas AGF from the core population promoted a fitness loss in the peripheral population. Hence, the small peripheral population could improve fitness of large core units versus climate change, while the contrary could be not true. Integrating reciprocal breeding programmes and fitness analyses under current and predicted ecological conditions can support optimal AGF design in a long-term perspective.
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spelling pubmed-91675612022-06-06 Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation Gargano, Domenico Bernardo, Liliana Rovito, Simone Passalacqua, Nicodemo G Abeli, Thomas AoB Plants Studies Assisted gene flow (AGF) can restore fitness in small plant populations. Due to climate change, current fitness patterns could vary in the future ecological scenario, as highly performant lineages can undergo maladaptation under the new climatic contexts. Peripheral populations have been argued to represent a potential source of species adaptation against climate change, but experimental evidence is poor. This paper considers the consequences of within- and between-population mating between a large core population and the southernmost population, the rare Dianthus guliae, to evaluate optimal AGF design under current and future conditions. We performed experimental self-pollinations and within- and between-population cross-pollinations to generate seed material and test its adaptive value to aridity. Seed germination, seedling growth and survival were measured under current and expected aridity. Effects of population type, pollination treatment and stress treatment on fitness components were analysed by generalized linear models. Relative measures of inbreeding depression and heterosis were taken under different stress treatments. Self-pollination reduced fitness for all the considered traits compared to within- and between-population cross-pollination. Under current aridity regime, the core population expressed higher fitness, and a larger magnitude of inbreeding depression. This indicated the core unit is close to its fitness optimum and could allow for restoring the fitness of the small peripheral population. Contrarily, under increased aridity, the fitness of outbred core lineages decreased, suggesting the rise of maladaptation. In this scenario, AGF from the small peripheral population enhanced the fitness of the core unit, whereas AGF from the core population promoted a fitness loss in the peripheral population. Hence, the small peripheral population could improve fitness of large core units versus climate change, while the contrary could be not true. Integrating reciprocal breeding programmes and fitness analyses under current and predicted ecological conditions can support optimal AGF design in a long-term perspective. Oxford University Press 2022-05-12 /pmc/articles/PMC9167561/ /pubmed/35673362 http://dx.doi.org/10.1093/aobpla/plac022 Text en © The Author(s) 2022. Published by Oxford University Press on behalf of the Annals of Botany Company. https://creativecommons.org/licenses/by/4.0/This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.
spellingShingle Studies
Gargano, Domenico
Bernardo, Liliana
Rovito, Simone
Passalacqua, Nicodemo G
Abeli, Thomas
Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation
title Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation
title_full Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation
title_fullStr Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation
title_full_unstemmed Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation
title_short Do marginal plant populations enhance the fitness of larger core units under ongoing climate change? Empirical insights from a rare carnation
title_sort do marginal plant populations enhance the fitness of larger core units under ongoing climate change? empirical insights from a rare carnation
topic Studies
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9167561/
https://www.ncbi.nlm.nih.gov/pubmed/35673362
http://dx.doi.org/10.1093/aobpla/plac022
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