New discovery about bird brains sheds light on intriguing question
Brown University
While a woodpecker’s bill-hammering is a
familiar sound — and sometimes too familiar, for those who’ve
had a woodpecker take up residence in their yard — the mechanisms and
motivations driving the birds to engage in this behavior haven’t been well
understood.
From Fake Science, not Brown.
Until
now.
A
team of researchers led by a Brown University biologist has discovered new
insights into how the woodpecker’s brain works. The discovery suggests their
drums may have evolved through vocal learning, which is the same way that
songbirds learn to make their own more melodious sounds.
In a study published in PLOS Biology, the researchers describe how they found evidence of specialized gene expression in the forebrains of woodpeckers that was anatomically similar to that of birds who communicate by singing.
The
researchers hypothesize that the same brain mechanisms that helped birds
develop the motor control involved in creating and voicing songs is also what
helped woodpeckers develop their drumming system of communication.
This
discovery expands what is known not just about woodpeckers, but about the
evolution of birds in general, said study author Matthew Fuxjager, an associate
professor of ecology, evolution and organismal biology with the Division of
Biology and Medicine at Brown University.
“Very little is actually known about woodpecker drumming to begin with, and certainly nobody has ever found a neurological explanation for the drumming behavior,” Fuxjager said. “More broadly, what's really exciting about this study is that this is the first time a neural basis has been found for gestural communication of any animal — outside of humans, chimps and gorillas, that is.”
Much
of the research on animal communication focuses on vocalizations, said Fuxjager
— for example, frogs calling or birds singing. In his research, Fuxjager
studies how animals use body movement and gesture to communicate, such as
jumping up and down, waving or performing a type of ritualized dance.
“A
lot of my research has looked at how these movement behaviors have evolved —
specifically, how the brain and muscles have evolved together to support these
types of displays,” he said.
Woodpeckers,
Fuxjager said, are an excellent candidate for area of inquiry because their
hammering is a form of signaling. “With the hammering, the woodpeckers are
basically telling each other, ‘Get out of my territory!’” he said.
Fuxjager
was primarily interested in how the woodpecker’s brain controls that behavior.
He teamed up with Erich Jarvis from the Rockefeller University in New York, who
had screened different bird species looking for brain regions that anatomically
resembled those that controlled song — including birds not known to sing, like
the emu, penguin, flamingo and woodpecker.
“I
was interested in the brain regions that would control drumming, and Jarvis was
interested in the song control regions,” Fuxjager said. Co-author Eric Schuppe,
at the time a Ph.D. student in Fuxjager’s lab, participated in field work to
see if the special areas in the woodpecker brain were, in fact, related to
drumming.
In
the lab, the team searched for signatures of the same gene expression
specializations in seven species of birds. They found evidence of
specialization only in the woodpeckers — these were the only non-songbirds that
possessed forebrain regions that were anatomically similar to the song systems
in birds known to use vocal learning.
The
researchers therefore hypothesized that the ancient forebrain nuclei for
refined motor control may have given rise not only to the song control systems
of the vocal learning birds, but also the drumming system of the woodpeckers.
In
explaining the importance of the drumming, Fuxjager noted that there are over
200 species of woodpeckers around the world, and each species drums at a
specific speed and rhythm that changes depending on what they want to
communicate and to whom. “So they’re hammering in coordinated bursts,” he said.
And
if a woodpecker does it wrong, then the other woodpeckers of that species won’t
be able to recognize or understand it — they won’t get the message.
“But
if they get the parameters right, the other woodpeckers will listen to the
drum, measure certain aspects of it and use that to assess the drumming
woodpecker as a competitor,” he said. “They’ll be able to understand what
they’re trying to communicate. The specialized brain regions coordinate the
physiology that controls the movements that allow the birds to peck in certain
ways.”
These
findings broaden the understanding of brain regions specialized for vocal
communications in birds, Fuxjager said.
“This
prompts us to rethink how these characteristics evolved: Was it just something
that happened in these particular species of birds, or does it hint at
something farther back in the evolutionary history of birds, in general?”
Future
research will dive deeper into these questions, he said.
Funding
for this work was provided in part by the National Science Foundation
(IOS-1947472, OISE-1952542).
