Species more likely to die out with rapid climate changes
Date:
November 5, 2020
Source:
Norwegian University of Science and Technology
Summary:
The great tit and other birds can adapt to changes in their food
supply as a result of climate change, but they run into trouble
if the changes happen too quickly.
FULL STORY ==========================================================================
The climate seems to be getting warmer. This could be bad news for
species that depend on stable and abundant access to food at certain
times of the year.
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"If the changes happen too fast, species can become extinct," says Emily Simmonds, an associate professor at the Norwegian University of Science
and Technology's (NTNU) Department of Biology.
She is the first author of an article in Ecology Letters that addresses
how great tits can be affected if the supply of larvae changes in
the spring.
Several bird species depend on the abundance of larvae while their young
are small. If the larvae supply peaks earlier in the spring than normal,
there may simply be too little food for the hatchlings.
The warming climate can bring about changes like this. An earlier spring
causes trees to leaf out earlier, which in turn causes the larvae that
feed on the plants to hatch out earlier.
"When the climate changes, the interactions between different species
changes too," Simmonds says.
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She and a team of researchers at the University of Oxford used population models to calculate the consequences of different climate scenarios. They wanted to see at what point the changes would happen too fast for the
great tit to modify its behaviour quickly enough to keep up with the
larvae.
Great tits have genetic variations and varying abilities to adapt to
different conditions. This means that they can evolve in tandem with
their prey up to a point.
An earlier larvae hatch can be advantageous for the great tits that
also hatch their young earlier in the spring. This advantage can be
transferred to the next generation of birds, which can in turn become
early birds. And so on.
For this advantage to last, the great tits have to evolve fast enough and
be flexible enough to keep up with the genetic variation in their prey.
"Given conditions with big greenhouse gas emissions, the great tits
won't always be able to keep up with the changes in the larvae supply,"
says Simmonds.
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In the worst case scenario, whole populations of great tits will simply disappear by the year 2100 because they aren't able to procure enough
food for their young.
"This could happen even if the great tits are also modifying their
behaviour faster in a rapidly changing environment. The larvae might be changing even faster than the great tits," Simmonds says.
The researchers found that populations of great tits would be guaranteed
to become extinct by the year 2100 if the larvae appeared about 24 days
earlier than the current norm in 2020. This also applies to populations
that appear to be completely stable now.
"It could be that the apparent stability today is hiding a future
collapse," says Simmonds.
The reason is that we might reach a kind of threshold where the great tits aren't keeping up. The rubber band gets stretched too far, you could say.
"The good news is that the populations will be able to survive scenarios
with lower or medium warming trends," Simmonds says.
Simmonds collaborated with Dr. Ella Cole, Professor Ben Sheldon and
Professor Tim Coulson at the University of Oxford on the project, which
was part of Simmonds' doctoral dissertation at the British university.
========================================================================== Story Source: Materials provided by Norwegian_University_of_Science_and_Technology. Original written by
Steinar Brandslet. Note: Content may be edited for style and length.
========================================================================== Journal Reference:
1. Emily G. Simmonds, Ella F. Cole, Ben C. Sheldon, Tim Coulson.
Phenological asynchrony: a ticking time‐bomb for seemingly
stable populations? Ecology Letters, 2020; DOI: 10.1111/ele.13603 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/11/201105112936.htm
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