Researchers have a new insight into the function of REM sleep, based on studies of a seemingly unlikely animal: the fur seal. The findings are published in Current Biology.

The team, including Oleg Lyamin, PhD, and Jerome Siegel, PhD, University of California, Los Angeles, find that fur seals sleep on land in the same way other mammals do. But fur seals spend most of their lives in the water. When sleeping in water, fur seals show non-REM sleep in only one brain hemisphere at a time, just as dolphins do. The new study finds that, like dolphins, fur seals go without REM sleep when in the water.

“We show that when the fur seal stays in seawater, where it spends most of its life, it goes without REM sleep for days or weeks,” Siegel says in a release. “After this nearly complete elimination of REM sleep, it displays minimal or no REM sleep ‘rebound’ upon returning to baseline conditions. It just resumes its ‘on-land’ bilateral non-REM and REM sleep pattern.”

The findings are consistent with the hypothesis that REM sleep, which has been shown to warm the brain, functions to reverse the reduced metabolism and brain cooling that occurs in bilateral non-REM sleep. Siegel says this warming of the brain can be seen as preparation for waking, noting that humans and other animals are much more alert when they awaken from REM sleep.

The absence of REM sleep in dolphins and related whales, and in fur seals during aquatic sleep, can be explained by the fact that half their brain is always awake, which keeps the brain and especially the brainstem warm and makes REM sleep unnecessary, Siegel explains.

Dolphins have intricate social and hunting behavior, and the dolphin brain is larger than the human brain. Fur seals are also very social animals capable of complex motor and sensory learning. The majority of their lives are spent in the water, keeping track of where prey and potential predators are and navigating over long distances. It appears that REM sleep is not necessary for these behaviors.

Siegel notes that earlier studies of REM sleep deprivation are difficult to interpret because sleep deprivation itself is stressful and these prior studies did not selectively eliminate REM sleep. But the suppression of REM sleep in fur seals in water is the normal pattern, not a consequence of deprivation. The researchers now suspect that REM sleep does for brain temperature what shivering does for body temperature, bringing the brain back to a normal waking temperature so animals wake up alert and responsive.

The researchers will continue to explore the connection between REM sleep and brain temperature. They also hope to apply this data to understanding narcolepsy, which is characterized by a disruption of the REM sleep mechanism.