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a mouse model, researchers discovered that insulin controls a molecular pathway
in the brain that activates during stress and leads to more weight gain.
New research explains why eating high-calorie foods when stressed may lead to more significant weight gain.
Researchers
have long been aware that stresscan lead to addiction and increase the risk of
disease. Studies have also shown that chronic stress can change
eating patterns and affect food choices. Although some people eat less while
under stress, most tend to overeat and increase their intake of high-calorie
foods.
When
stress occurs, the adrenal glands release a hormone called cortisol, which
increases appetite and motivates a person to eat, especially foods high in fat,
sugar, or both. In combination with high insulin — one of the hormones that control
food intake, high cortisol levels are a key factor in so-called stress eating.
Eating
patterns vary from person to person, but some research suggests that a person's
biological sex may affect their stress-coping behavior. A Finnish study,
which included almost 7,000 adolescents, showed that females were more likely
than males to overeat when under stress and had a higher risk of obesity.
Understanding
what controls stress eating
Professor
Herbert Herzog, head of the Eating Disorders laboratory at the Garvan Institute
of Medical Research in Darlinghurst, Australia, recently led a team of
researchers conducting a study in mice to understand what controls stress
eating. The researchers published their findings in the journal Cell Metabolism.
"This
study indicates that we have to be much more conscious about what we're eating
when we're stressed to avoid a faster development of obesity."
Prof.
Herbert Herzog
A
part of the brain called the hypothalamus plays the most significant role in
controlling food intake, while scientists have implicated the amygdala in
emotional processing. In this study, the researchers made a discovery: an
insulin-controlled molecular pathway in the brain that may lead to excessive
weight gain.
"Our
study showed that when stressed over an extended period and high-calorie food
was available, mice became obese more quickly than those that consumed the same
high-fat food in a stress-free environment," says Dr. Kenny Chi Kin Ip,
lead author of the study.
The
molecule at the center of this pathway in the brain is called NPY. The brain
produces this molecule naturally during stressful times, and the study showed
that NPY stimulates the intake of high-calorie foods in mice.
"We
discovered that when we switched off the production of NPY in the amygdala,
weight gain was reduced. Without NPY, the weight gain on a high-fat diet with
stress was the same as weight gain in the stress-free environment,"
explains Dr. Ip.
Stress
and calorific foods create vicious cycle
The
researchers analyzed the nerve cells that produced NPY in the amygdala and
found that they had receptors for insulin, a hormone that the pancreas
produces, which helps the body store and use glucose.
In
a stress-free environment, after a meal, the body produces insulin, which is
responsible for delivering the glucose from the bloodstream to the cells so
that they can use it for fuel. It also signals to the hypothalamus that it is
time to stop eating.
By
comparing mice under stress with those that were stress-free, the researchers
showed that the production of insulin increased only slightly during stressful
times. However, when they compared stressed mice on a high-calorie diet with
stress-free mice on a normal diet, they found that the levels of this hormone
became 10 times higher in the former group.
These
high levels of insulin caused the nerve cells in the amygdala to become
desensitized to insulin and to boost NPY levels.
"Our
findings revealed a vicious cycle, where chronic, high insulin levels driven by
stress and a high-calorie diet promoted more and more eating," concludes
Prof. Herzog.
The
research team was surprised to discover that insulin had such a significant
effect on the amygdala. The results show that insulin does not only regulate
functions in the peripheral regions of the body, but it may also affect
important pathways in the brain. The team hopes to investigate these effects
further in the future.
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