Health: Link between obesity and sleep loss
Energy
conservation may be a major function of sleep, according to new study in worms
Can
staying up late make you fat? Researchers found the opposite to be true when
they studied sleep in worms: It's not the sleep loss that leads to obesity, but
rather that excess weight can cause poor sleep.
Can
staying up late make you fat? A growing body of research has suggested that
poor sleep quality is linked to an increased risk of obesity by deregulating
appetite, which in turn leads to more calorie consumption.
But a new
study published this week in PLOS Biology found that the
direction of this reaction might actually be flipped: It's not the sleep loss
that leads to obesity, but rather that excess weight can cause poor sleep,
according to researchers from the University of Pennsylvania's Perelman School
of Medicine and the University of Nevada, Reno, who discovered their findings
in the microscopic worm Caenorhabditis elegans (C. elegans).
"We
think that sleep is a function of the body trying to conserve energy in a
setting where energetic levels are going down. Our findings suggest that if you
were to fast for a day, we would predict you might get sleepy because your
energetic stores would be depleted," said study co-author David Raizen,
MD, PhD, an associate professor of Neurology and member of the Chronobiology
and Sleep Institute at Penn.
Raizen
emphasized that while these findings in worms may not translate directly to
humans, C. elegans offer a surprisingly good model for
studying mammalian slumber. Like all other animals that have nervous systems,
they need sleep. But unlike humans, who have complex neural circuitry and are
difficult to study, a C. elegans has only 302 neurons -- one
of which scientists know for certain is a sleep regulator.
In
humans, acute sleep disruption can result in increased appetite and insulin
resistance, and people who chronically get fewer than six hours of sleep per
night are more likely be obese and diabetic. Moreover, starvation in humans,
rats, fruit flies, and worms has been shown to affect sleep, indicating that it
is regulated, at least in part, by nutrient availability. However, the ways in
which sleeping and eating work in tandem has remained unclear.
"We
wanted to know, what is sleep actually doing? Short sleep and other chronic
conditions, like diabetes, are linked, but it's just an association. It's not
clear if short sleep is causing the propensity for obesity, or that the
obesity, perhaps, causes the propensity for short sleep," said study
co-author Alexander van der Linden, PhD, an associate professor of Biology at
the University of Nevada, Reno.
To study
the association between metabolism and sleep, the researchers genetically
modified C. elegans to "turn off" a neuron that
controls sleep. These worms could still eat, breathe, and reproduce, but they
lost their ability to sleep. With this neuron turned off, the researchers saw a
severe drop in adenosine triphosphate (ATP) levels, which is the body's energy
currency.
"That
suggests that sleep is an attempt to conserve energy; it's not actually causing
the loss of energy," Raizen explained.
In
previous research, the van der Linden lab studied a gene in C. elegans called
KIN-29. This gene is homologous to the Salt-Inducible Kinase (SIK-3) gene in
humans, which was already known to signal sleep pressure. Surprisingly, when
the researchers knocked out the KIN-29 gene to create sleepless worms, the
mutant C. elegans accumulated excess fat -- resembling the
human obesity condition -- even though their ATP levels lowered.
The researchers
hypothesized that the release of fat stores is a mechanism for which sleep is
promoted, and that the reason KIN-29 mutants did not sleep is because they were
unable to liberate their fat. To test this hypothesis, the researchers again
manipulated the KIN-29 mutant worms, this time expressing an enzyme that
"freed" their fat. With that manipulation, the worms were again able
to sleep.
Raizen
said this could explain one reason why people with obesity may experience sleep
problems. "There could be a signaling problem between the fat stores and
the brain cells that control sleep," he said.
While
there is still much to unravel about sleep, Raizen said that this paper takes
the research community one step closer to understanding one of its core
functions -- and how to treat common sleep disorders.
"There
is a common, over-arching sentiment in the sleep field that sleep is all about
the brain, or the nerve cells, and our work suggests that this isn't
necessarily true," he said. "There is some complex interaction
between the brain and the rest of the body that connects to sleep
regulation."
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