3D electron microscopy reveals Insights into brain circuitry
3D electron microscopy reveals insights into brain circuitry
New research from a team led by Marshall University scientist W. Christopher Risher, Ph.D., reveals novel molecular insights into how multiple cell types drive the formation and maturation of brain circuits.
W. Christopher Risher, Ph.D., assistant professor of biomedical sciences at the Marshall University Joan C. Edwards School of Medicine, is lead author of new research on how multiple cell types drive the formation and maturation of brain circuits.
The brain is a highly complex organ that enables us to think, remember, move and perform simple to complicated tasks. These processes require the function of circuits in the brain made up of connections between cells called neurons. Neurons contact each other at sites known as synapses.
Risher, an assistant professor in the department of biomedical sciences at the Marshall University Joan C. Edwards School of Medicine, and the team studied synapses in the cerebral cortex, a brain region that controls sensory information processing and motor control. The study involved the use of mice that were missing the α2δ-1 receptor, which is necessary for how neurons respond to signals coming from non-neuronal cells called astrocytes. α2δ-1 is significant because it is also the receptor for the commonly prescribed pain medication, gabapentin. With α2δ-1 missing, cortical neurons made very few synapses with each other, showing that brain circuitry was highly impaired.
Using a technique called 3D electron microscopy, the authors determined that α2δ-1 was also required for proper synapse structure. Risher et al. further observed that α2δ-1 is able to promote synapse formation and growth through a well-known signaling molecule called Rac1, while promotion of α2δ-1 and/or Rac1 signaling is sufficient to restore brain connectivity.
The work by Risher et al. provides new insights into the development of impaired synaptic circuitry that exists in most psychiatric disorders, implicating astrocyte-to-neuron signaling as a major therapeutic target.
"Though this work is primarily basic cellular and molecular biology, there are a number of implications raised for neurological/neuropsychiatric disease, particularly autism and addiction," Risher said. "These results indicate that astrocytes are critical for the formation of functional neuronal networks in a region of the brain that controls many higher order functions. This signaling pathway can be inhibited by gabapentin, suggesting that synaptic dysfunction in conditions commonly treated by gabapentin, including seizure, neuropathic pain and addiction, is due to impairments in these cellular processes."
The team's findings were published July 27, 2018, in the Journal of Cell Biology.
MEDICA.com; Source: Marshall University Joan C. Edwards School of Medicine