Media release

From: Frontiers

Hot dragonfly summer: species with darker wings have evolved to withstand heat and attract partners

Researchers found that male dragonflies with dark coloration on their wings have evolved to tolerate higher temperatures, possibly a decisive advantage in a warming world

Males of some dragonfly species display dark ornamental coloration on their wings to attract potential mates. This, however, comes at a cost, as these dark spots absorb more heat, which can cause thermal stress. Now, researchers found that some dragonfly species with dark wing coloration have evolved to be able to tolerate higher temperatures. This could influence how populations respond to the changing climates of the future.

Temperature determines where species can live and if they are threatened by a warming climate. So, for a long time, biologists studied how heat tolerance affects survival. Yet, less is known about how thermal traits influence reproduction, which is directly linked to extinction risk.

Now, researchers in the US have examined if males of dragonfly species that produce sexual signals in the form of dark coloration on their wings are more resistant to heat. They published their results in Frontiers in Ethology.

“We show that dragonfly species that have evolved dark breeding coloration on their wings have also evolved the ability to tolerate high temperatures,” said Dr Noah Leith, a biologist at the University of Pittsburgh. “This finding paves the way for a whole new field of research exploring interactions between thermal traits and sexual signals.”

Dark spots, hot dragonflies

In dragonflies – same as in many animals – sexual signals can help them effectively locate mates, identify the correct species to mate with, and decide when to back out of mating contests.

Producing extensive dark wing coloration, though, comes at a cost. Dark ornaments absorb extra heat, increasing dragonflies’ body temperature. This can cause physiological stress or lead to males abandoning reproductive territories. “We see time and time again that animals will put their lives on the line to reproduce, even if it means encountering potentially lethal temperatures,” Leith said.

The researchers examined the wing coloration of 14 dragonfly species living in tropical climates and five species living in temperate climates. They found that species that possess dark, heat-absorbing wing coloration have evolved to be able to withstand higher heat stress before reaching critical thermal maxima. “This enhanced ability to tolerate high body temperatures is likely crucial for shaping how dragonflies may respond to the changing climates of the future,” Leith explained.

Beat the heat

Dark wing ornaments cause additional heating of 1°C to 2°C, which roughly equals the increased thermal maxima of ornamented species. Of the species studied, the arch-tipped glider (Tauriphila argo), a tropical species with very dark wing color patches near their core body, could tolerate the highest temperatures. Generally, this pattern of co-evolution was even stronger in tropical species.

Previous research showed that due to rising temperatures worldwide, some ornamented dragonfly species are evolving reduced wing coloration. The present results, however, suggest that even if those species lose their coloration, they will still have a leg up on adaptation to climate change because they’ve already evolved to tolerate hotter temperatures, the researchers said.

Preventing extinction

The study is one of the first to test whether thermal tolerance co-evolves with reproductive traits. “Our finding is particularly exciting because dark sexual coloration has evolved over and over across the tree of life and causes a wide variety of other animals to absorb extra heat too—from reptiles, to lions, and fruit flies,” Leith pointed out.

In a rapidly warming world, being able to predict which species are vulnerable to extinction is essential to preserving biodiversity, the researchers said. “Looking at vulnerability in only one aspect of animals’ lives is insufficient. We need a more nuanced understanding of how animals respond to changing environments as whole, complex organisms, in which their reproductive traits might influence their chances of surviving a heat wave, and vice versa,” Leith said.

While the researchers noted that looking at 19 species was plenty for their analysis, they said that there are thousands of dragonfly species. Future research should examine if similar patterns exist in other species, as well as in different types of animals. “It would be fantastic to someday test if heat tolerance co-evolves with sexual traits across life on Earth,” Leith concluded.