Vanderbilt Kennedy Center

Andre H. Lagrange, Ph.D., M.D.

Associate Professor of Neurology
Investigator

Contact Info

Phone
(615) 322-5979

Email
andre.h.lagrange@vanderbilt.edu

Address
6144 MRB III

Website

http://www.mc.vanderbilt.edu/neurology/epilepsy.htm

Andre H. Lagrange, Ph.D., M.D.

Overview

Andre Lagrange's research focuses on GABA, the primary inhibitory neurotransmitter within the brain. Early in life, GABA acts as an excitatory signal that directs normal neuronal migration and synaptogenesis. Lagrange and his colleagues have found that a predominant GABA receptor expressed primarily during early life is subject to RNA editing in a developmentally regulated fashion. By introducing a single amino acid change in a key portion of these GABA receptors, RNA editing leads to significant changes in receptor function, thereby producing a brief window in late embyogenesis/early postnatal life in which GABA causes the prolonged/slow depolarizations that are important for the subsequent formation of both excitatory and inhibitory connections later in life.

Lagrange's clinical interest is in the treatment of women with epilepsy. It has been known for a few years that some of the medications used to treat epilepsy may increase the risk of having a child with congenital malformations. Unfortunately, these teratogenic drugs are also widely used for a number of other neurological and psychiatric disorders, such as migraines and bipolar disorder. Alarmingly, recent work has suggested that children exposed to a subset of these drugs in utero have reduced IQ later in life, and an increased incidence of neurodevelopmental disorders such as autism. Further animal work has suggested that these poor cognitive outcomes may involve subtle cortical malformation/laminar disruption, which are thought to be mediated by the GABA modulatory nature of these drugs. Lagrange's lab is working to understand the role of specific GABA receptors in brain development and how these processes are regulated during normal development, as well as how they may be disrupted by disease states and medications.

BioSketch

View Biographical Sketch (.pdf)

Grants

  • Cell Specific Evolution of GABA Signaling Directs Incorporation of Newly Generated Neurons
  • Epilepsy and Disrupted Thalamic Physiology in Mouse Model of Angelman Syndrome (Nicholas Hobbs Discovery Grant)

In the News