BRAIN CIRCUIT THAT THAT CONTROLS COMPULSIVE OVEREATING AND SUGAR ADDICTION DISCOVERED
Compulsive overeating
and sugar addiction are major threats to human health, but potential treatments
face the risk of impairing normal feeding behaviors that are crucial for
survival. A study published January 29th in the journal Cell reveals a reward-related neural
circuit that specifically controls compulsive sugar consumption in mice without
preventing feeding necessary for survival, providing a novel target for the
safe and effective treatment of compulsive overeating in humans
Although obesity and Type 2 diabetes
are major problems in our society, many treatments do not tackle the primary
cause: unhealthy eating habits," says senior study author Kay Tye of the
Massachusetts Institute of Technology. "Our findings are exciting because
they raise the possibility that we could develop a treatment that selectively
curbs compulsive overeating without altering healthy eating behavior."
Compulsive overeating is a type of
reward-seeking behavior, similar to drug addiction. But the major difference
between the two behaviors is that eating is required for survival, underscoring
the need to tease apart brain circuits involved in compulsive overeating versus
normal feeding to develop safe and effective therapies. Tye and her team
suspected that a neural pathway from the lateral hypothalamus to the ventral
tegmental area might play an important role in compulsive overeating because
these brain regions have been implicated in reward-related behaviors such as
eating, sexual activity, and drug addiction.
To test this idea, Tye and her team
used a technique called optogenetics, which involves genetically modifying
specific populations of neurons to express light-sensitive proteins that
control neural excitability, and then delivering either blue or yellow light
through an optic fiber to activate or inhibit those cells, respectively.
Activation of the pathway from the lateral hypothalamus to the ventral
tegmental area caused well-fed mice to spend more time feeding and increased
the number of times mice poked their nose into a port to receive a sugar
reward, even when they had to cross a platform that delivered foot shocks to
get to the reward. By contrast, inhibition of the same pathway reduced this
compulsive sugar-seeking behavior without decreasing food consumption in hungry
mice, suggesting that different neural circuits control feeding in hungry
animals.
In an independent study also
published January 29th in Cell, Garret Stuber of the University of
North Carolina School of Medicine and his team similarly used an optogenetic
approach in mice to identify neurons in the lateral hypothalamus that control
both feeding and reward-seeking behavior. By imaging the activity of hundreds
of individual lateral hypothalamus neurons as the mice freely explored an area
with food or worked to obtain a sweet reward, they further uncovered distinct
subsets of neurons that either mediate food-seeking behavior or respond to
reward consumption.
According to Tye, it makes sense
that brain circuits evolved to support binging on scarce, sugary foods whenever
these valuable sources of energy become transiently available during certain
seasons. But in the winter, it might be adaptive for separate neural circuits
to drive hungry animals to eat whatever type of food is available but to
consume less overall to ration out limited resources.
"However, in our modern day
society, there is no scarcity of palatable foods, and high-sugar or high-fat
foods are often even more available than fresh produce or proteins," Tye
says. "We have not yet adapted to a world where there is an overabundance
of sugar, so these circuits that drive us to stuff ourselves with sweets are
now serving to create a new health problem. The discovery of a specific neural
circuit underlying compulsive sugar consumption could pave the way for the
development of targeted drug therapies to effectively treat this widespread
problem."
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