The seed germination spectrum of alpine plants: a global meta-analysis

Eduardo Fernández-Pascual; Angelino Carta; Andrea Mondoni; Lohengrin A. Cavieres; Sergey Rosbakh; Susanna Venn; Annisa Satyanti; Lydia Guja; Verónica F. Briceño; Filip Vandelook; Efisio Mattana; Arne Saatkamp; Haiyan Bu; Karen Sommerville; Peter Poschlod; Kun Liu; Adrienne Nicotra; Borja Jiménez-Alfaro

doi:10.1111/nph.17086

The seed germination spectrum of alpine plants: a global meta-analysis

Eduardo Fernández-Pascual^*, Angelino Carta, Andrea Mondoni, Lohengrin A. Cavieres, Sergey Rosbakh, Susanna Venn, Annisa Satyanti, Lydia Guja, Verónica F. Briceño, Filip Vandelook, Efisio Mattana, Arne Saatkamp, Haiyan Bu, Karen Sommerville, Peter Poschlod, Kun Liu, Adrienne Nicotra, Borja Jiménez-Alfaro

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

116 Citations (Scopus)

Abstract

Assumptions about the germination ecology of alpine plants are presently based on individual species and local studies. A current challenge is to synthesise, at the global level, the alpine seed ecological spectrum. We performed a meta-analysis of primary data from laboratory experiments conducted across four continents (excluding the tropics) and 661 species, to estimate the influence of six environmental cues on germination proportion, mean germination time and germination synchrony; accounting for seed morphology (mass, embryo : seed ratio) and phylogeny. Most alpine plants show physiological seed dormancy, a strong need for cold stratification, warm-cued germination and positive germination responses to light and alternating temperatures. Species restricted to the alpine belt have a higher preference for warm temperatures and a stronger response to cold stratification than species whose distribution extends also below the treeline. Seed mass, embryo size and phylogeny have strong constraining effects on germination responses to the environment. Globally, overwintering and warm temperatures are key drivers of germination in alpine habitats. The interplay between germination physiology and seed morphological traits further reflects pressures to avoid frost or drought stress. Our results indicate the convergence, at the global level, of the seed germination patterns of alpine species.

Original language	English
Journal	New Phytologist
Volume	229
Issue number	6
Pages (from-to)	3573-3586
Number of pages	14
ISSN	0028-646X
DOIs	https://doi.org/10.1111/nph.17086
Publication status	Published - 2021
Externally published	Yes

Bibliographical note

Funding Information:
EFP received financial support from the Government of Asturias and the FP7 – Marie Curie – COFUND programme of the European Commission (Grant ‘Clarín’ ACB17‐19). BJ‐A and EFP were funded by the Spanish Research Agency (PID2019‐108636GA/AEI/10.13039/501100011033). EM was supported by the Future Leaders Fellowship – Diversity and Livelihoods, of the Royal Botanic Gardens, Kew. Authors thank Amelia Martyn Yenson and Catherine A. Offord for germination and dormancy data for 19 Australian alpine species. This research was supported by NGSeeds, the Next Generation Seed Ecology, Evolution and Data Science virtual working group.

Funding Information:
EFP received financial support from the Government of Asturias and the FP7 ? Marie Curie ? COFUND programme of the European Commission (Grant ?Clar?n? ACB17-19). BJ-A and EFP were funded by the Spanish Research Agency (PID2019-108636GA/AEI/10.13039/501100011033). EM was supported by the Future Leaders Fellowship ? Diversity and Livelihoods, of the Royal Botanic Gardens, Kew. Authors thank Amelia Martyn Yenson and Catherine A. Offord for germination and dormancy data for 19 Australian alpine species. This research was supported by NGSeeds, the Next Generation Seed Ecology, Evolution and Data Science virtual working group.

Publisher Copyright:
© 2020 The Authors New Phytologist © 2020 New Phytologist Foundation

Keywords

alpine
alternating temperature
cold stratification
embryo endosperm ratio
light germination
seed dormancy
seed germination
seed mass

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10.1111/nph.17086

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Cite this

Fernández-Pascual, E., Carta, A., Mondoni, A., Cavieres, L. A., Rosbakh, S., Venn, S., Satyanti, A., Guja, L., Briceño, V. F., Vandelook, F., Mattana, E., Saatkamp, A., Bu, H., Sommerville, K., Poschlod, P., Liu, K., Nicotra, A., & Jiménez-Alfaro, B. (2021). The seed germination spectrum of alpine plants: a global meta-analysis. New Phytologist, 229(6), 3573-3586. https://doi.org/10.1111/nph.17086

Fernández-Pascual, E, Carta, A, Mondoni, A, Cavieres, LA, Rosbakh, S, Venn, S, Satyanti, A, Guja, L, Briceño, VF, Vandelook, F, Mattana, E, Saatkamp, A, Bu, H, Sommerville, K, Poschlod, P, Liu, K, Nicotra, A & Jiménez-Alfaro, B 2021, 'The seed germination spectrum of alpine plants: a global meta-analysis', New Phytologist, vol. 229, no. 6, pp. 3573-3586. https://doi.org/10.1111/nph.17086

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title = "The seed germination spectrum of alpine plants: a global meta-analysis",

abstract = "Assumptions about the germination ecology of alpine plants are presently based on individual species and local studies. A current challenge is to synthesise, at the global level, the alpine seed ecological spectrum. We performed a meta-analysis of primary data from laboratory experiments conducted across four continents (excluding the tropics) and 661 species, to estimate the influence of six environmental cues on germination proportion, mean germination time and germination synchrony; accounting for seed morphology (mass, embryo : seed ratio) and phylogeny. Most alpine plants show physiological seed dormancy, a strong need for cold stratification, warm-cued germination and positive germination responses to light and alternating temperatures. Species restricted to the alpine belt have a higher preference for warm temperatures and a stronger response to cold stratification than species whose distribution extends also below the treeline. Seed mass, embryo size and phylogeny have strong constraining effects on germination responses to the environment. Globally, overwintering and warm temperatures are key drivers of germination in alpine habitats. The interplay between germination physiology and seed morphological traits further reflects pressures to avoid frost or drought stress. Our results indicate the convergence, at the global level, of the seed germination patterns of alpine species.",

keywords = "alpine, alternating temperature, cold stratification, embryo endosperm ratio, light germination, seed dormancy, seed germination, seed mass",

author = "Eduardo Fern{\'a}ndez-Pascual and Angelino Carta and Andrea Mondoni and Cavieres, {Lohengrin A.} and Sergey Rosbakh and Susanna Venn and Annisa Satyanti and Lydia Guja and Brice{\~n}o, {Ver{\'o}nica F.} and Filip Vandelook and Efisio Mattana and Arne Saatkamp and Haiyan Bu and Karen Sommerville and Peter Poschlod and Kun Liu and Adrienne Nicotra and Borja Jim{\'e}nez-Alfaro",

note = "Funding Information: EFP received financial support from the Government of Asturias and the FP7 – Marie Curie – COFUND programme of the European Commission (Grant {\textquoteleft}Clar{\'i}n{\textquoteright} ACB17‐19). BJ‐A and EFP were funded by the Spanish Research Agency (PID2019‐108636GA/AEI/10.13039/501100011033). EM was supported by the Future Leaders Fellowship – Diversity and Livelihoods, of the Royal Botanic Gardens, Kew. Authors thank Amelia Martyn Yenson and Catherine A. Offord for germination and dormancy data for 19 Australian alpine species. This research was supported by NGSeeds, the Next Generation Seed Ecology, Evolution and Data Science virtual working group. Funding Information: EFP received financial support from the Government of Asturias and the FP7 ? Marie Curie ? COFUND programme of the European Commission (Grant ?Clar?n? ACB17-19). BJ-A and EFP were funded by the Spanish Research Agency (PID2019-108636GA/AEI/10.13039/501100011033). EM was supported by the Future Leaders Fellowship ? Diversity and Livelihoods, of the Royal Botanic Gardens, Kew. Authors thank Amelia Martyn Yenson and Catherine A. Offord for germination and dormancy data for 19 Australian alpine species. This research was supported by NGSeeds, the Next Generation Seed Ecology, Evolution and Data Science virtual working group. Publisher Copyright: {\textcopyright} 2020 The Authors New Phytologist {\textcopyright} 2020 New Phytologist Foundation",

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AU - Cavieres, Lohengrin A.

AU - Rosbakh, Sergey

AU - Venn, Susanna

AU - Satyanti, Annisa

AU - Guja, Lydia

AU - Briceño, Verónica F.

AU - Vandelook, Filip

AU - Mattana, Efisio

AU - Saatkamp, Arne

AU - Bu, Haiyan

AU - Sommerville, Karen

AU - Poschlod, Peter

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N2 - Assumptions about the germination ecology of alpine plants are presently based on individual species and local studies. A current challenge is to synthesise, at the global level, the alpine seed ecological spectrum. We performed a meta-analysis of primary data from laboratory experiments conducted across four continents (excluding the tropics) and 661 species, to estimate the influence of six environmental cues on germination proportion, mean germination time and germination synchrony; accounting for seed morphology (mass, embryo : seed ratio) and phylogeny. Most alpine plants show physiological seed dormancy, a strong need for cold stratification, warm-cued germination and positive germination responses to light and alternating temperatures. Species restricted to the alpine belt have a higher preference for warm temperatures and a stronger response to cold stratification than species whose distribution extends also below the treeline. Seed mass, embryo size and phylogeny have strong constraining effects on germination responses to the environment. Globally, overwintering and warm temperatures are key drivers of germination in alpine habitats. The interplay between germination physiology and seed morphological traits further reflects pressures to avoid frost or drought stress. Our results indicate the convergence, at the global level, of the seed germination patterns of alpine species.

AB - Assumptions about the germination ecology of alpine plants are presently based on individual species and local studies. A current challenge is to synthesise, at the global level, the alpine seed ecological spectrum. We performed a meta-analysis of primary data from laboratory experiments conducted across four continents (excluding the tropics) and 661 species, to estimate the influence of six environmental cues on germination proportion, mean germination time and germination synchrony; accounting for seed morphology (mass, embryo : seed ratio) and phylogeny. Most alpine plants show physiological seed dormancy, a strong need for cold stratification, warm-cued germination and positive germination responses to light and alternating temperatures. Species restricted to the alpine belt have a higher preference for warm temperatures and a stronger response to cold stratification than species whose distribution extends also below the treeline. Seed mass, embryo size and phylogeny have strong constraining effects on germination responses to the environment. Globally, overwintering and warm temperatures are key drivers of germination in alpine habitats. The interplay between germination physiology and seed morphological traits further reflects pressures to avoid frost or drought stress. Our results indicate the convergence, at the global level, of the seed germination patterns of alpine species.

KW - alpine

KW - alternating temperature

KW - cold stratification

KW - embryo endosperm ratio

KW - light germination

KW - seed dormancy

KW - seed germination

KW - seed mass

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DO - 10.1111/nph.17086

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