Breakthrough discovery on brain cortex functionality

UTSA College of Sciences researchers Alice Bertero, Hector Zurita and Marc Normandin and biology associate professor Alfonso Junior Apicella collaborated on the research project.

In the past, labeling individual neurons allowed researchers to study the neurons that project from the brain's cortex to the striatum. The results suggested that the pathways are exclusively excitatory. For this reason most people assumed that inhibition must occur when excitatory cortical neurons activate intrastriatal inhibitory.

The UTSA team contested this view by providing anatomical and physiological evidence for the existence of long-range parvalbumin-expression neurons from the cortex to the striatum in the brains of mice.

This finding is an essential step toward better understanding the neuronal mechanism of cortical long-range GABAerginc neurons in healthy and diseased brains. In particular this could lead to new treatments for patients with epilepsy, post-traumatic stress disorder, schizophrenia and other mental conditions in which GABAergic neurons play a significant role.

"Daily we are bombarded by multiple auditory stimuli, including various speeches," said Apicella. "Particularly, listeners must determine which speech acoustic features are relevant and generalize across irrelevant ones during speech perception. We think that the interaction between the cortex and the striatum is fundamental to optimize nonnative speech learning in adulthood. Therefore, it is crucial to determine which of the cortical-striatum pathway's cellular elements are involved in this process."

The discovery that the striatum receives both excitatory and inhibitory inputs from the cortex suggests that these inputs' timing and relative strength can modulate the striatum's activity. This is important because it invites the scientific community to speculate that the long-range parvalbumin-expressing projects could play a role through gamma oscillation synchronization between the auditory cortex and striatum.

The team proposes that future experiments will provide further insight into the role of the timing and ratio of excitation and inhibition, two opposing forces in the mammalian cerebral cortex, affecting the cortico-striatal dynamic.