Immune cells are key to teen brain wiring

Researchers have discovered that microglia, the brain’s immune cells, play a key role in wiring the adolescent brain during adolescence.
The frontal cortex, responsible for executive functions such as empathy and decision-making, undergoes profound changes during adolescence, which can set the stage for neurodevelopmental disorders like schizophrenia and ADHD.
Microglia have been found to recruit to the frontal dopamine circuit in adolescent mice, strengthening the brain’s communication network and promoting structural changes at the axon.
A better understanding of microglial function during adolescence may lead to new targets for disease treatment, particularly for psychiatric disorders impacted by deficits in this area of the brain.
Future research aims to explore the molecular mechanisms underlying microglia’s role in adolescent brain development and how combining pharmacological therapies with dopamine stimulation could help treat neurodevelopmental disorders.

A teen with blue hair holds a hand up to her face while looking at the camera.

The brain’s immune cells are key to wiring the adolescent brain, according to new research in mice.

Making a smoothie, going for an evening walk, or having empathy for a loved one are all examples of executive functions that are controlled by the brain’s frontal cortex.

This area of the brain goes through profound change throughout adolescence, and it is during this time that abnormalities in maturing circuits can set the stage for neurodevelopmental disorders, such as schizophrenia and ADHD.

Now, researchers have discovered that microglia, the brain’s immune cells, play a key role in how the brain adapts to the changes in this area during adolescence, which may transform how neurodevelopmental disorders are treated during this window and, possibly, into adulthood.

“A better understanding of the ways we can drive changes in these circuits offers new targets for disease treatment,” says Rianne Stowell, research assistant professor of neuroscience at the University of Rochester Medical Center, and first author of the study in Nature Communications.

“This area is also susceptible to change, both good and bad, during adolescence. Previous work in our lab has found that both direct activation of frontal dopamine circuits and rewarding behavior drive plasticity of dopaminergic connections to the frontal cortex during adolescence, but not adulthood.”

The dopaminergic circuits in the brain are made up of networks of neurons that use dopamine to send information. These circuits are critical for regulating brain functions, including movement, motivation, and cognition.

Exercise, or wheel running for mice, is a natural, rewarding experience that activates the frontal dopamine circuit. Using this model and optogenetics, a technique that uses light to control genetically targeted neurons, researchers observed that microglia in the living brain are recruited to the frontal dopaminergic circuit in adolescent mice.

The microglia responded to dopaminergic activation by making contact with the axons, the long part of the neuron that acts like a cable relaying signals, and then new boutons formed along those axons. Boutons are the parts of the neuron that transmit signals to other cells.

According to Stowell, this shows that microglia have a direct impact on increased dopaminergic circuit connectivity. Basically, the brain’s immune cells appear to play a key role in strengthening the brain’s communication network.

“We were surprised to see that the microglial contact with the axon happens before the formation of new boutons,” Stowell says.

“This research suggests that microglia are very sensitive to changes in dopamine activity, and there is a compelling connection between microglial contact and structural changes at the axon.”

Research in the Wang lab showed that administering a dopamine D2 receptor agonist, quinpirole, blocked plasticity in adolescence. Conversely, administering a D2 antagonist, eticlopride—an antipsychotic drug—to adult mice reinstated microglia recruitment to axons and promoted the formation of new boutons.

Stowell says that future research will explore if combining pharmacological therapies with dopamine stimulation, such as through exercise, could help treat psychiatric disorders impacted by deficits in this area of the brain.

“We now want to determine, at the molecular level, what exactly microglia are doing within the circuit. For example, how they are influencing the growth of boutons,” Stowell says.

“We will be using pharmacological manipulations of specific microglial signaling systems as well as single-cell sequencing to dig into what makes this circuit malleable during adolescence but not adulthood.”

Support for this research came from the National Institutes of Health and a pilot grant from the Del Monte Institute for Neuroscience.

Source: University of Rochester

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Q. What is the role of immune cells in the brain during adolescence?

A. Immune cells, specifically microglia, play a key role in wiring the adolescent brain and adapting to changes in the frontal cortex.

Q. How do abnormalities in maturing circuits during adolescence affect neurodevelopmental disorders?

A. Abnormalities in maturing circuits can set the stage for neurodevelopmental disorders such as schizophrenia and ADHD.

Q. What is the significance of microglia in the brain’s communication network?

A. Microglia appear to play a key role in strengthening the brain’s communication network by making contact with axons and forming new boutons.

Q. How do exercise and rewarding behavior affect the frontal dopamine circuit during adolescence?

A. Exercise, or wheel running for mice, activates the frontal dopamine circuit, leading to plasticity of dopaminergic connections to the frontal cortex during adolescence.

Q. What is the connection between microglial contact with axons and structural changes in the brain?

A. Microglial contact with axons happens before the formation of new boutons, suggesting a direct impact on increased dopaminergic circuit connectivity.

Q. How do dopamine D2 receptor agonists affect plasticity in adolescence?

A. Administering a dopamine D2 receptor agonist, quinpirole, blocks plasticity in adolescence.

Q. What is the potential for combining pharmacological therapies with dopamine stimulation to treat psychiatric disorders?

A. Combining pharmacological therapies with dopamine stimulation, such as through exercise, may help treat psychiatric disorders impacted by deficits in this area of the brain.

Q. How will future research explore the role of microglia in the brain’s communication network?

A. Future research will use pharmacological manipulations of specific microglial signaling systems and single-cell sequencing to dig into what makes this circuit malleable during adolescence but not adulthood.

Q. What is the source of support for this research?

A. Support for this research came from the National Institutes of Health and a pilot grant from the Del Monte Institute for Neuroscience.