Whiskers’ key role in reptile-mammal split

U. SHEFFIELD (US) — New research comparing rats and mice with marsupials suggests moveable whiskers were an important milestone in the evolution of mammals from reptiles.

Using high-speed digital video recording and automatic tracking, Tony Prescott, a psychology professor at the University of Sheffield, and colleagues have shed light on how rodents such as mice and rats move their whiskers back-and-forth at high speed—and in varying ways to actively sense the environment around them in a behavior known as whisking.

Whisking allows mice or rats to accurately determine the position, shape and texture of objects, make rapid and accurate decisions about objects, and then use the information to build environmental maps.


When running in a straight line, rats and mice move their whiskers back-and-forth the same amount on both sides. However when turning, they bias their whisker movements in the direction of the turn, and when the whiskers on one side of the head contact an object, those on the opposite side sweep round to gather more information.

These active sensing strategies boost the information gained by the whiskers helping the animals to better understand their world through touch.

Researchers showed whisking like that of rodents, using these active sensing strategies, is also seen in a small South American marsupial—the grey short-tailed opossum. This animal has many similarities to an early mammal that would have lived more than 125 million years ago; that is, around the same time that the evolutionary lines leading to modern rodents and marsupials diverged.

This evidence suggests that some of the first mammals may also have whisked like a modern mouse or rat, and that the appearance of moveable whiskers was pivotal in the evolution of mammals from reptiles.

The research is published in Philosophical Transactions of the Royal Society B and will also be presented November 12 at the Society for Neuroscience conference.

The earliest mammals were nocturnal and tree dwelling. In order to successfully move around and thrive in this challenging environment, these animals needed to effectively integrate information from multiple senses—sight, sound, smell, and touch. Facial whiskers provided mammals with a new tactile sense not available to reptiles that could help them to get around in the dark.

In addition to continuing to investigate the similarities and differences between rodents and marsupials, the team is also using these insights from biological whisker sensing to develop animal-like robots that can use artificial whiskers to navigate without vision. These robots could have applications in search-and-rescue, particularly in environments, such as disaster sites, where vision is compromised by smoke or dust.

“This latest research suggests that alongside becoming warm-blooded, giving birth to live young, and having an enlarged brain, the emergence of a new tactile sense based on moveable facial whiskers was an important step along the evolutionary path to modern mammals,” says Prescott. “Although humans no longer have moveable whiskers, they were a critical feature of our early mammalian ancestors.”

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