Possible Novel Migraine Therapy?
Published:09 Oct.2022    Source:University of Sydney
Amynah Pradhan, associate professor of psychiatry at the University of Illinois ChicagoPradhan, whose research focus is on the neurobiology of pain and headache, explained that the dynamic process of routing and rerouting connections among nerve cells, called neural plasticity, is critical to both the causes and cures for disorders of the central nervous system such as depression, chronic pain, and addiction.
 
The structure of the cell is maintained by its cytoskeleton which is made up of the protein, tubulin. Tubulin is in a constant state of flux, waxing and waning to change the size and shape of the cell. This dynamic property of the cell allows the nervous system to change in response to its environment.
 
Tubulin is modified in the body through a chemical process called acetylation. When tubulin is acetylated it encourages flexible, stable cytoskeleton; while tubulin deacetylation-induced by histone deacetylase 6, or HDAC6, promotes cytoskeletal instability. Studies in mice models show that decreased neuronal complexity may be a feature, or mechanism, of chronic migraine, Pradhan said. When HDAC6 is inhibited, tubulin acetylation and cytoskeletal flexibility is restored. Additionally, HDAC6 reversed the cellular correlates of migraine and relieved migraine-associated pain, according to the study.
 
"Blocking HDAC6 would allow neurons to restore its flexibility so the brain would be more receptive to other types of treatment. In this model we are saying, maybe chronic migraine sufferers have decreased neuronal flexibility. If we can restore that complexity maybe we could get them out of that cycle," she said.
 
Once out of the cycle of decreased neuronal complexity, the brain may become more responsive to pain management therapies, Pradhan said. HDAC6 inhibitors are currently in development for cancer, and HDCA6 as a target has been identified for other types of pain.