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Ancient Japanese birds looked a lot like New Zealand’s monster penguins

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June 29 (UPI) — New analysis suggests New Zealand’s giant penguins and a much younger group of Northern Hemisphere birds, the plotopterids, were physically quite similar.

The research, published Monday in the Journal of Zoological Systematics and Evolutionary Research, could help scientists figure out how birds evolved wings better suited for swimming than flying.

Fossil remains suggest as many as nine different species once swam the tropical seas that washed over most of what’s now New Zealand, some 62 million years ago. While some species were the size of modern penguins, others grew to heights of more than five feet.

Plotopterids don’t appear in the Northern Hemisphere fossil record until 30 million years later. Their remains have been recovered from several sites in Japan and North America. Like penguins, plotopterids used flipper-like wings to navigate coastal seas. But while the relatives of New Zealand’s ancient penguins can still be found today, plotopterids went extinct around 25 million years ago.

For the new study, scientists compared the fossilized remains of plotopterids recovered from Japan with the fossils of three giant penguin species. In addition to boasting similar wings, the analysis showed both groups of birds possessed long beaks with slit-like nostrils, as well as chest and shoulder bones conducive to swimming. Like the giant penguins, some plotopterid species were oversized, growing to heights of more than six feet.

Despite their physical similarities, plotopterids and penguins aren’t particularly close relatives. Plotopterids are more closely related to other seaworthy birds like boobies, gannets and cormorants.

“What’s remarkable about all this is that plotopterids and ancient penguins evolved these shared features independently,” study co-author Vanesa De Pietri, curator at the Canterbury Museum in New Zealand, said in a news release. “This is an example of what we call convergent evolution, when distantly related organisms develop similar morphological traits under similar environmental conditions.”

Though plotopterids and giant penguins were separated by several thousand miles and nearly 30 million years, had they lived side-by-side, they would have been hard to distinguish.

“Plotopterids looked like penguins, they swam like penguins, they probably ate like penguins — but they weren’t penguins,” said Paul Scofield, study co-author and Canterbury curator.

The newly published comparison of the two ancient bird groups has helped scientists begin to develop an explanation for why some birds developed wings for swimming.

“Wing-propelled diving is quite rare among birds; most swimming birds use their feet,” said study co-author Gerald Mayr, scientist at the Senckenberg Research Institute and Natural History Museum in Germany.

“We think both penguins and plotodopterids had flying ancestors that would plunge from the air into the water in search of food,” Mayr said. “Over time these ancestor species got better at swimming and worse at flying.”



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Sounds made by fluttering feathers help fork-tailed flycatchers communicate

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Sept. 22 (UPI) — Scientists have added another species to the list of birds that use sounds made with their feathers to communicate.

The male fork-tailed flycatcher, a passerine bird species native to the American tropics, creates unique sounds by fluttering its feathers at high frequencies, according to research published Wednesday in the journal Integrative and Comparative Biology.

“Back in the 1960’s, scientists noticed that they produce a distinctive sound only during a particular flight display,” researcher Christopher Clark, told UPI in an email.

“And those species of flycatcher in the genus Tyrannus, those that make the most distinctive sounds have the most distinctly shaped outer primary feathers,” said Clark, an associate professor of evolutionary biology at the University of California Riverside.

For the latest research, scientists conducted field studies to better understand both the mechanics of the feather fluttering and its communicative utility.

“We found that the birds don’t produce sounds every time they fly, but only under specific behavioral contexts,” lead study author Valentina Gomez told UPI in an email.

“One is during the pre-dawn display, after waking up. They begin displaying by singing and then they include feather songs. They also produce these sounds during territorial displays,” said Gomez, a doctoral student at the University of Illinois at Chicago.

To study the fluttering’s acoustic qualities, scientists captured males with mist netting, and used cameras and microphones to record the sounds the birds made as they escaped and retreated.

Fork-tailed flycatchers are quite territorial and aggressively defend their nests. Males are especially aggressive, regularly engaging in aerial battles with other males over mating opportunities and territory. They’re also more than willing to attack larger birds that stray too close to their nests.

Researchers used a taxidermy hawk outfitted with microphones and a camera to measure the movement of the fork-tailed flycatcher’s feathers during displays of aggression. The recordings revealed a difference in the sounds made by two subspecies, one that migrates long distances and another that is more stationary.

“Differences in migration likely influenced the shape of feathers and this affects the frequency at which they flutter,” Gomez said.

In effect, the two subspecies have developed dialects. Researchers suspect this phenomenon might help drive speciation, or species divergence.

“The evolution of different movement behaviors promotes the initial trigger of the speciation process,” Gomez said. “Through time, correlated evolution of morphological traits affects how they communicate.”

In other words, the difference in sound-making didn’t jumpstart the speciation process, but Gomez and her research partners hypothesize that the development of feather-flapping dialects works to reinforce the divergence.

Similarly, while the sound-making feathers of fork-tailed flycatchers may have initially evolved in response to pressures unrelated to communication, researchers claim the birds now utilize their sound-making abilities with intentionality. They’ve harnessed the power of their fluttering features for the purposes of communication.

“The birds alter how they are flapping their wings when they produce sound; their wingbeat frequency goes up by quite a bit,” Clark said. “The altered kinematics is another clue that this is ‘intentional.'”

While non-vocal communication has been observed in a variety of bird genus and species, scientists suspect the prevalence of the practice is underestimated.

Researchers hope that future investigations of feather-based communication among flycatchers will offer new insights into why so many birds have evolved non-vocal communication over and over again.

While the latest findings suggest the fork-tailed flycatcher relies on feather-based communication for pair bonding and displays of aggression, many questions about the fluttering’s utility remain.

“We still need to learn a lot about bird acoustic perception,” Gomez said.



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Once exposed to humans, animals start to lose their fear of predators

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Sept. 22 (UPI) — New research suggests animals begin to lose their fear of predators once they start encountering humans on a regular basis.

For the study, scientists surveyed the findings of 173 peer-reviewed papers on predator avoidance behaviors and traits deployed by 102 species of domesticated, captive and urbanized mammals, birds, reptiles, fish and mollusks.

The analysis, published Tuesday in the journal PLOS Biology, showed predator avoidance traits and behaviors, including vigilance, freezing and fleeing, decreased as a result of exposure to humans.

Researchers found individual variation in anti-predator characteristics increased upon a species’ initial exposure to humans, but then gradually decreased after generations of human exposure.

“While it is well known that the fact of being protected by humans decreases anti-predator capacities in animals, we did not know how fast this occurs and to what extent this is comparable between contexts,” lead researcher Benjamin Geffroy, biologist at the University of Montpellier in France, said in a news release.

The findings suggest behavioral flexibility allows for the initial increase in the variability of anti-predator traits, but researchers suspect genetic changes solidify declines in predator avoidance as subsequent generations adjust to the presence of humans.

In the studies analyzed by Geffroy and his colleagues, domesticated animals lose their anti-predator traits much more quickly than urbanized animals, which can cause problems when domesticated or urbanized species are released back into the wild.

“We also integrated physiological traits in the study but they were much less numerous that behavioral traits,” Geffroy said. “We believe they should be systematically investigated to draw a global pattern of what is happening at the individual level.

“We need more data to understand whether this occurs also with the mere presence of tourists,” Geffroy said.



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Search and rescue dogs fared well after work at 9/11 sites, study says

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Search and rescue dogs used during the 9/11 attacks lived as long as dogs not at the World Trade Center in New York City and the Pentagon, a new study finds.

“I was at Ground Zero and I would hear people make comments like, ‘Did you hear that half of the dogs that responded to the bombing in Oklahoma City died of X, Y, or Z?’ Or they’d say dogs responding to 9/11 had died,” said Dr. Cynthia Otto, director of the University of Pennsylvania’s Working Dog Center, in Philadelphia. “It was really disconcerting.”

Otto and her School of Veterinary Medicine colleagues’ findings are reassuring.

Dogs that participated in search-and-rescue efforts after 9/11 lived as long as search-and-rescue dogs not at the scene — a median of about 12.8 years, meaning half died sooner, half did not. They also outlived the life spans of their breed. There was no difference in the dogs’ cause of death.

“Honestly, this was not what we expected it’s surprising and wonderful,” said Otto, a veterinarian.

The researchers expected to see respiratory problems in the exposed dogs, but they did not. The most common cause of death was age-related conditions, such as arthritis and cancer.

For the study, Otto collected data on 95 dogs that had worked at the World Trade Center, the nearby Fresh Kills Landfill in Staten Island, N.Y., or Pentagon disaster sites in Washington, D.C. They compared these dogs with 55 search-and-rescue dogs that were not deployed on 9/11.

“We anticipated that the dogs would be the ‘canary in the coal mine’ for the human first responders since dogs age faster than humans and didn’t have any of the protective equipment during the response,” Otto said in a university news release. “But we didn’t see a lot that was concerning.”

Generally, these dogs are stronger and healthier than pets, which might partly explain why the dogs fared well, she said.

The findings were published Sept. 21 in the Journal of the American Veterinary Medical Association.

More information

For more on responder health after 9/11, visit the New York State Department of Health.

Copyright 2020 HealthDay. All rights reserved.



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