New optical technique, used in mice, offers detailed look at how dopamine works in the brain
Columbia University scientists have developed a new optical technique to study how information is transmitted in the brains of mice. Using this method, they found that only a small portion of synapses — the connections between cells that control brain activity–may be active at any given time.
The study was published in the latest issue of Nature Neuroscience.
“Understanding how we accomplish complex tasks, such as learning and memory, requires us to look at how our brains transmit key signals — called neurotransmitters — across synapses from one neuron to another,” said David Sulzer, PhD, professor of neurobiology in Psychiatry, Neurology, and Pharmacology at Columbia University Medical Center (CUMC). “Older techniques only revealed what was going on in large groups of synapses. We needed a way to observe the neurotransmitter activity of individual synapses, to help us better understand their intricate behavior.”
To obtain a detailed view of synaptic activity, Sulzer’s team collaborated with the laboratory of Dalibor Sames, PhD, associate professor of chemistry at Columbia, to develop a novel compound called fluorescent false neurotransmitter 200 (FFN200). When added to brain tissue or nerve cells from mice, FFN200 mimics the brain’s natural neurotransmitters and allows researchers to spy on chemical messaging in action.
Using a fluorescence microscope, the researchers were able to view the release and reuptake of dopamine — a neurotransmitter involved in motor learning, habit formation, and reward-seeking behavior — in individual synapses. When all the neurons were electrically stimulated in a sample of brain tissue, the researchers expected all the synapses to release dopamine. Instead, they found that less than 20 percent of dopaminergic synapses were active following a pulse of electricity.
“Why are there these large reservoirs of synapses that are silent?” said Dr. Sames, a co-author of the paper. “Perhaps these silent terminals hint at a mechanism of information coding in the brain that’s yet to be revealed.”
The study’s authors plan to pursue this hypothesis in future experiments, as well as examine how other neurotransmitters behave.
“This particular study didn’t explain what’s causing most of the synapses to remain silent,” said Dr. Sulzer. “If we can work this out, we may learn a lot more about how alterations in dopamine levels are involved in brain disorders such as Parkinson’s disease, addiction, and schizophrenia.”