Both Sides now: Brain Reward Molecule helps Learning to Avoid Unpleasant Experience, too

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Dopamine innervation into the hippocampus. Green denotes general catecholamine -- a general name for dopamine -- innervation of the CA1 region of the hippocampus. Yellows denotes dopamine nerve endings in the same region. Scale bar is 50 microns. Credit: John Dani, Ph.D., Perelman School of Medicine, University of Pennsylvania

Dopamine innervation into the hippocampus. Green denotes general catecholamine — a general name for dopamine — innervation of the CA1 region of the hippocampus. Yellows denotes dopamine nerve endings in the same region. Scale bar is 50 microns. Credit: John Dani, Ph.D., Perelman School of Medicine, University of Pennsylvania

Dopamine regulates how mice learn to avoid a disagreeable encounter, according to new research from the Perelman School of Medicine at the University of Pennsylvania. “We know that dopamine reinforces ‘rewarding’ behaviors, but to our surprise, we have now shown that situations that animals learn to avoid are also regulated by dopamine,” said John Dani, PhD, chair of the department of Neuroscience.

Special neurons in the brain send out a burst of dopamine in both negative and positive situations. However, the exact way in which dopamine neurons are wired and connected to the hippocampus remains controversial among neuroscientists. Knowing exactly how the neurotransmitter dopamine shapes memory and behavior in association with an event or the surrounding environment is important to better understand such conditions as PTSD.

“We showed in mice that a special circuit in the hippocampus has flexibility in combining with environmental input to shape behavior during an experiment in which the mice learn to avoid an unpleasant experience,” Dani said. “This is the first time that we have been able to show, as proof of principle, that the dopamine circuitry is also involved in learning to avoid aversive situations. ”

In previous animal experiments, when mice experience an unexpected reward, for example discovering a tube in which they can obtain a sugar-water treat, a burst of dopamine is emitted in the brain. The team found that if the mice encounter an negative stimuli, a subgroup of neurons fires and releases dopamine in conjunction with the aversive environmental input. They also showed that when the dopamine signal to the hippocampus is chemically blocked in the mice, it prevents them from learning to avoid the negative stimulus. However, if the dopamine signal is chemically boosted in the mice, they remember to avoid the aversive event longer. “The bottom line of our study is that dopamine plays a role in both conditions, and that dopamine enables mice to learn and remember to avoid the negative situation, in this case avoid a light foot shock in one room of a two-room enclosure.” http://www.uphs.upenn.edu/news/News_Releases/2016/02/dani/