Maritime
pine forest in the Castilian Plateau, central Spain. Maritime pine forests
support a great diversity of associated fauna and flora, in particular in the
Mediterranean region where they grow within an intensively humanized
agricultural landscape.
Data from only a small number of gene variants can predict which
maritime pine trees are most vulnerable to climate change, scientists
report in the March issue of
Genetics. The results will improve
computer models designed to forecast where forests will grow as the
climate changes, and promises to help forestry managers decide where to
focus reforestation efforts. The results will also guide the choice of
tree stocks.
The maritime pine (
Pinus pinaster) grows widely in
southwestern Europe and parts of northern Africa. But the tree's
important economic value and ecological roles in the region may be at
risk as the
changing climate threatens the more vulnerable forests and the productivity of commercial plantations.
To predict which regions will sustain pine forests in the future,
researchers and managers rely on computer models. But these forecasts
don't take into account two major factors that influence a forest's
fate: genetics and evolution. Genetic differences between tree
populations mean that forests vary in how well they cope with warmer,
drier conditions. Ongoing evolution of trees also influences the
prevalence of these
genetic differences;
for example, trees with gene variants allowing them to withstand higher
temperatures will become increasingly common as the climate changes.
"These genetic effects are not included in forest range shift models,
but we know they can completely change the resulting predictions. Our
goal was to identify such effects in a way that can be readily
incorporated into the forecasts," said study leader Santiago
González-Martínez, from the Forest Research Centre of Spain's Institute
for Agricultural Research (CIFOR-INIA).
To find genetic variants that affect the species' fitness in
different climate conditions, maritime pine researchers from around the
world pooled their expertise and the results of previous research,
yielding a list of more than 300 variants in 200 candidate genes.
Creating a shortlist of targets is considerably faster and more
economical than searching the entire genome of the maritime pine, which
is about nine times larger than the human genome.
Maritime
pine forest in Serra Calderona, eastern Spain. Typical Mediterranean forests as
the one pictured here are under severe risk due to summer droughts and
wildfire. It is expected that extinction risk of this valuable ecosystem will
increase due to climate change.
From this list, the
team tested whether any of the candidates were more common in regions
that shared similar climates. Such geographic patterns can be the result
of natural selection and point to gene variants that influence tree
survival and reproduction according to climate. By testing the frequency
of each variant at 36 locations in Portugal, Spain, France, Morocco,
and Tunisia, the researchers found 18 variants that showed correlations
with the local climate. These variants affected genes involved in many
different biological processes, including growth and response to heat
stress.
The researchers then looked for evidence that these variants
are important for the trees' fitness by planting seedlings from 19 of
the locations together in a dry part of Spain, at the extreme end of the
species' climatic range. This allowed the team to compare how well
genetically different trees would survive under similar conditions.
After five years, the seedlings carrying gene variants predicted to be
beneficial in the
local climate indeed tended to have higher survival rates.
These results demonstrate the feasibility of this relatively fast
approach of finding and confirming genetic variants associated with
climate. "Now that we have shown that the method works well, we are
planning similar experiments on a bigger scale, with more test sites,
looking at more genes, and different traits. For example, the single
biggest
climate change
threat to pine forests is the increased frequency of wildfires, so
we're searching for variants that affect fire tolerance," said
González-Martínez.
"Good decisions require good data, and this collaborative work shows
how crucial genetic data can be for managing biodiversity and commercial
forestry amid a changing
climate," said
Genetics Editor-in-Chief Mark Johnston.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
Maritime pine forest in
the Castilian Plateau, central Spain. Maritime pine forests support a
great diversity of associated fauna and flora, in particular in the
Mediterranean region where they grow within an intensively humanized
agricultural landscape.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
From this list, the team tested
whether any of the candidates were more common in regions that shared similar
climates. Such geographic patterns can be the result of natural selection and
point to gene variants that influence tree survival and reproduction according
to climate. By testing the frequency of each variant at 36 locations in
Portugal, Spain, France, Morocco, and Tunisia, the researchers found 18
variants that showed correlations with the local climate. These variants
affected genes involved in many different biological processes, including
growth and response to heat stress.
The researchers then looked for
evidence that these variants are important for the trees' fitness by planting
seedlings from 19 of the locations together in a dry part of Spain, at the
extreme end of the species' climatic range. This allowed the team to compare
how well genetically different trees would survive under similar conditions.
After five years, the seedlings carrying gene variants predicted to be
beneficial in the local climate indeed tended to have higher
survival rates.
These results demonstrate the
feasibility of this relatively fast approach of finding and confirming genetic
variants associated with climate. "Now that we have shown that the method
works well, we are planning similar experiments on a bigger scale, with more
test sites, looking at more genes, and different traits. For example, the
single biggest climate change threat to pine forests is the
increased frequency of wildfires, so we're searching for variants that affect
fire tolerance," said González-Martínez.
"Good decisions require good
data, and this collaborative work shows how crucial genetic data can be for
managing biodiversity and commercial forestry amid a changing climate,"
said Genetics Editor-in-Chief Mark Johnston.
From this list, the
team tested whether any of the candidates were more common in regions
that shared similar climates. Such geographic patterns can be the result
of natural selection and point to gene variants that influence tree
survival and reproduction according to climate. By testing the frequency
of each variant at 36 locations in Portugal, Spain, France, Morocco,
and Tunisia, the researchers found 18 variants that showed correlations
with the local climate. These variants affected genes involved in many
different biological processes, including growth and response to heat
stress.
The researchers then looked for evidence that these variants
are important for the trees' fitness by planting seedlings from 19 of
the locations together in a dry part of Spain, at the extreme end of the
species' climatic range. This allowed the team to compare how well
genetically different trees would survive under similar conditions.
After five years, the seedlings carrying gene variants predicted to be
beneficial in the
local climate indeed tended to have higher survival rates.
These results demonstrate the feasibility of this relatively fast
approach of finding and confirming genetic variants associated with
climate. "Now that we have shown that the method works well, we are
planning similar experiments on a bigger scale, with more test sites,
looking at more genes, and different traits. For example, the single
biggest
climate change
threat to pine forests is the increased frequency of wildfires, so
we're searching for variants that affect fire tolerance," said
González-Martínez.
"Good decisions require good data, and this collaborative work shows
how crucial genetic data can be for managing biodiversity and commercial
forestry amid a changing
climate," said
Genetics Editor-in-Chief Mark Johnston.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
From this list, the
team tested whether any of the candidates were more common in regions
that shared similar climates. Such geographic patterns can be the result
of natural selection and point to gene variants that influence tree
survival and reproduction according to climate. By testing the frequency
of each variant at 36 locations in Portugal, Spain, France, Morocco,
and Tunisia, the researchers found 18 variants that showed correlations
with the local climate. These variants affected genes involved in many
different biological processes, including growth and response to heat
stress.
The researchers then looked for evidence that these variants
are important for the trees' fitness by planting seedlings from 19 of
the locations together in a dry part of Spain, at the extreme end of the
species' climatic range. This allowed the team to compare how well
genetically different trees would survive under similar conditions.
After five years, the seedlings carrying gene variants predicted to be
beneficial in the
local climate indeed tended to have higher survival rates.
These results demonstrate the feasibility of this relatively fast
approach of finding and confirming genetic variants associated with
climate. "Now that we have shown that the method works well, we are
planning similar experiments on a bigger scale, with more test sites,
looking at more genes, and different traits. For example, the single
biggest
climate change
threat to pine forests is the increased frequency of wildfires, so
we're searching for variants that affect fire tolerance," said
González-Martínez.
"Good decisions require good data, and this collaborative work shows
how crucial genetic data can be for managing biodiversity and commercial
forestry amid a changing
climate," said
Genetics Editor-in-Chief Mark Johnston.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
Maritime pine forest in
the Castilian Plateau, central Spain. Maritime pine forests support a
great diversity of associated fauna and flora, in particular in the
Mediterranean region where they grow within an intensively humanized
agricultural landscape.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
Maritime pine forest in
the Castilian Plateau, central Spain. Maritime pine forests support a
great diversity of associated fauna and flora, in particular in the
Mediterranean region where they grow within an intensively humanized
agricultural landscape.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
Maritime pine forest in
the Castilian Plateau, central Spain. Maritime pine forests support a
great diversity of associated fauna and flora, in particular in the
Mediterranean region where they grow within an intensively humanized
agricultural landscape.
Read more at:
http://phys.org/news/2015-03-genetic-forests-cope-climate.html#jCp
