Biodiversity 2 min

Evolution follows climate: oaks adapted rapidly to climate change in the Anthropocene

PRESS RELEASE - The acceleration of global warming due to human activities has made the pace of tree evolution and adaptation a core concern of researchers and foresters. Researchers from INRAE, the ONF, the CEA and the universities of Uppsala (Sweden) and Zhejiang (China) studied the evolution of oak trees in three French forests over the last three centuries, from the cold period of the Little Ice Age to the warming caused by human activities. Their results, published on 6 January in Evolution Letters, show that oaks evolve rapidly and can adapt to climatic changes in just a few generations. According to these findings, forest managers should shorten generations and promote natural forest regeneration to facilitate rapid stand evolution.

Published on 06 January 2022

illustration Evolution follows climate: oaks adapted rapidly to climate change in the Anthropocene
© INRAE - Corinne Enard

The team conducted a retrospective analysis of the evolution of oak trees between 1680 and the present day, a time scale that spans from the cold period of the Little Ice Age (1450-1850) to the warm period of the Anthropocene, from 1850 to the present day. The aim of this work was to understand how these tree populations have responded to different climatic variations. More specifically, they sequenced and analysed the complete genome of six hundred oak trees from three French forests (Tronçais in the Allier region, Réno Valdieu in the Perche region and Bercé in the Sarthe region) divided into four age-based cohorts: the first with an average age of 340 years, the second of 170 years, the third of 60 years and the last of 12 years. The scientists studied the variations in allele frequencies1 observed in the genomes of the four cohorts. They compared these variations against climate change, including the frequency of extreme events such as severe winters or extreme droughts.

A rapid evolution of oaks adapted to each climatic period

Results reveal an identical evolutionary pattern in the stands in the three forests, which differs according to the climatic periods studied. Variations observed in the genome of the oldest trees from the cold Little Ice Age are the opposite of those observed in young trees from the warm period of the Anthropocene. These evolving genomic signatures mean that oaks can evolve rapidly, with observable evolutionary jumps over just a few generations, and are able to redirect their evolutionary trajectories in a relatively short space of time to adapt quickly to changes in climate.

Adapting forest management to favour the evolution of oak trees

These results provide new knowledge for adapting forest management to climate change. They raise the issue of maintaining trees that are more than a hundred years old, adapted to a cold climate, which can slow down the evolutionary process by fertilising younger trees. Shortening generations would thus accelerate evolution and limit the effects of poor adaptation due to pollination by old stands. Foresters can adapt natural regeneration practices to make more room for evolution. In natural regeneration, seeding occurs without human intervention and with very dense seedlings of over 100,000 seeds per hectare. The trees face strong selection pressure: 95% of individual trees are eliminated in the 15-20 years that follow, and trees best adapted to the current climate conditions will be selected.

 

1 Alleles are the different possible versions of the same gene that can explain differences between trees with the same trait. The frequency of alleles of the same gene can vary according to environmental selection criteria such as drought or cold.

Reference

Dounia Saleh, Jun Chen, Jean-Charles Leplé, Thibault Leroy, Laura Truffaut, Benjamin Dencausse, Céline Lalanne, Karine Labadie, Isabelle Lesur, Didier Bert, Frédéric Lagane, François Morneau, Jean-Marc Aury, Christophe Plomion, Martin Lascoux, Antoine Kremer. Genome-wide evolutionary response of European oaks during the Anthropocene, Evolution letters, 5 January 2022 DOI: https://doi.org/10.1002/evl3.269

 

INRAE press office

Scientific contact

Antoine Kremer Biodiversity Gene Community joint research unit (BIOGECO - INRAE, University of Bordeaux)

Centre

Division

Learn more

Climate change and risks

Evolutionary survival tactics: oaks adapt drought-resistance to local conditions

PRESS RELEASE - As climate change brings an increase in the frequency and severity of droughts, forest dieback is a key cause for concern: forests act as reservoirs of biodiversity and also allow vast amounts of carbon to be stored, reducing the so-called greenhouse effect. Oak trees, iconic veterans of European and American forests, have previously been thought to be highly vulnerable to drought. Now, thanks to a novel non-invasive optical technique, scientists from INRAE and the University of Bordeaux in France, with their colleagues from University of California, Berkeley and Stanford University have studied a range of oak species in North America to find out more about their resistance to drought. The results, published on 1st March in PNAS, show an evolutionary increase in the drought resistance of oak species which has enabled them to colonise more arid climatic zones and to develop what are, for now, relatively comfortable safety margins to cope with climate change.

26 February 2021

Biodiversity

Oak genomics proves its worth

PRESS RELEASE - Some 18 months after the full pedunculate oak genome sequence was published by a French consortium led by INRAE and CEA, some initial results based on this genomic resource have been written up in a series of articles in 16 April 2020 issue of the New Phytologist. These new results help clarify the oak's evolution, from the deep roots of its diversification through the more recent evolution of the European white oaks, and identify key genes involved in its adaptation to certain environments or resistance to pathogens.

17 April 2020

Biodiversity

Tree fecundity and biological aging

PRESS RELEASE - Researchers from INRAE and Duke University have concluded that tree fecundity peaks or plateaus when trees reach adult size, and then begins to decline. Published on 17 August 2021 in Proceedings of the National Academy of Sciences, the study examines 597 species from more than 500 sites in North America, South America, Asia, Europe and Africa. Their work has led to the development of a calibrated model to accurately calculate long-term tree fecundity.

05 August 2021