Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation
Abstract Understanding how tree species will respond to a future climate requires reliable and quantitative estimates of intra‐specific variation under current climate conditions. We studied three 10‐year‐old common garden experiments established across a rainfall and drought gradient planted with n...
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Wiley
2020-10-01
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| Series: | Evolutionary Applications |
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| Online Access: | https://doi.org/10.1111/eva.13034 |
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doaj-d19621b094dd4883bb7127e2e803a9802020-11-25T03:12:06ZengWileyEvolutionary Applications1752-45712020-10-011392422243810.1111/eva.13034Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptationJan‐Peter George0Guillaume Theroux‐Rancourt1Kanin Rungwattana2Susanne Scheffknecht3Nevena Momirovic4Lea Neuhauser5Lambert Weißenbacher6Andrea Watzinger7Peter Hietz8Department of Forest Genetics Federal Research and Training Centre for ForestsNatural Hazards and Landscape (BFW) Vienna AustriaInstitute of Botany University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaInstitute of Botany University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaInstitute of Botany University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaInstitute of Botany University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaInstitute of Botany University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaDepartment of Forest Genetics Federal Research and Training Centre for ForestsNatural Hazards and Landscape (BFW) Vienna AustriaInstitute of Soil Research University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaInstitute of Botany University of Applied Life Sciences and Natural Resources Vienna (BOKU) Vienna AustriaAbstract Understanding how tree species will respond to a future climate requires reliable and quantitative estimates of intra‐specific variation under current climate conditions. We studied three 10‐year‐old common garden experiments established across a rainfall and drought gradient planted with nearly 10,000 pedunculate oak (Quercus robur L.) trees from ten provenances with known family structure. We aimed at disentangling adaptive and plastic responses for growth (height and diameter at breast height) as well as for leaf and wood functional traits related to adaptation to dry environments. We used restricted maximum likelihood approaches to assess additive genetic variation expressed as narrow‐sense heritability (h2), quantitative trait differentiation among provenances (QST), and genotype‐by‐environment interactions (GxE). We found strong and significant patterns of local adaptation in growth in all three common gardens, suggesting that transfer of seed material should not exceed a climatic distance of approximately 1°C under current climatic conditions, while transfer along precipitation gradients seems to be less stringent. Moreover, heritability reached 0.64 for tree height and 0.67 for dbh at the dry margin of the testing spectrum, suggesting significant additive genetic variation of potential use for future selection and tree breeding. GxE interactions in growth were significant and explained less phenotypic variation than origin of seed source (4% versus 10%). Functional trait variation among provenances was partly related to drought regimes at provenances origins but had moderate explanatory power for growth. We conclude that directional selection, either naturally or through breeding, is the most likely and feasible outcome for pedunculate oak to adapt to warmer and drier climate conditions in the future.https://doi.org/10.1111/eva.13034adaptive plasticityfunctional traitsgenotype‐by‐environment interactionsheritabilitylocal adaptationtree growth |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Jan‐Peter George Guillaume Theroux‐Rancourt Kanin Rungwattana Susanne Scheffknecht Nevena Momirovic Lea Neuhauser Lambert Weißenbacher Andrea Watzinger Peter Hietz |
| spellingShingle |
Jan‐Peter George Guillaume Theroux‐Rancourt Kanin Rungwattana Susanne Scheffknecht Nevena Momirovic Lea Neuhauser Lambert Weißenbacher Andrea Watzinger Peter Hietz Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation Evolutionary Applications adaptive plasticity functional traits genotype‐by‐environment interactions heritability local adaptation tree growth |
| author_facet |
Jan‐Peter George Guillaume Theroux‐Rancourt Kanin Rungwattana Susanne Scheffknecht Nevena Momirovic Lea Neuhauser Lambert Weißenbacher Andrea Watzinger Peter Hietz |
| author_sort |
Jan‐Peter George |
| title |
Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation |
| title_short |
Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation |
| title_full |
Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation |
| title_fullStr |
Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation |
| title_full_unstemmed |
Assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (Quercus robur L.) suggests that directional selection can drive climatic adaptation |
| title_sort |
assessing adaptive and plastic responses in growth and functional traits in a 10‐year‐old common garden experiment with pedunculate oak (quercus robur l.) suggests that directional selection can drive climatic adaptation |
| publisher |
Wiley |
| series |
Evolutionary Applications |
| issn |
1752-4571 |
| publishDate |
2020-10-01 |
| description |
Abstract Understanding how tree species will respond to a future climate requires reliable and quantitative estimates of intra‐specific variation under current climate conditions. We studied three 10‐year‐old common garden experiments established across a rainfall and drought gradient planted with nearly 10,000 pedunculate oak (Quercus robur L.) trees from ten provenances with known family structure. We aimed at disentangling adaptive and plastic responses for growth (height and diameter at breast height) as well as for leaf and wood functional traits related to adaptation to dry environments. We used restricted maximum likelihood approaches to assess additive genetic variation expressed as narrow‐sense heritability (h2), quantitative trait differentiation among provenances (QST), and genotype‐by‐environment interactions (GxE). We found strong and significant patterns of local adaptation in growth in all three common gardens, suggesting that transfer of seed material should not exceed a climatic distance of approximately 1°C under current climatic conditions, while transfer along precipitation gradients seems to be less stringent. Moreover, heritability reached 0.64 for tree height and 0.67 for dbh at the dry margin of the testing spectrum, suggesting significant additive genetic variation of potential use for future selection and tree breeding. GxE interactions in growth were significant and explained less phenotypic variation than origin of seed source (4% versus 10%). Functional trait variation among provenances was partly related to drought regimes at provenances origins but had moderate explanatory power for growth. We conclude that directional selection, either naturally or through breeding, is the most likely and feasible outcome for pedunculate oak to adapt to warmer and drier climate conditions in the future. |
| topic |
adaptive plasticity functional traits genotype‐by‐environment interactions heritability local adaptation tree growth |
| url |
https://doi.org/10.1111/eva.13034 |
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