The γ-aminobutyric acid (GABA) type A receptor (GABA A R) is the major inhibitory neurotransmitter receptor in the brain. Its multiple subunits show regional, developmental, and disease-related plasticity of expression; however, the regulatory networks controlling GABA A R subunit expression remain poorly understood. We report that the seizure-induced decrease in GABA A R α1 subunit expression associated with epilepsy is mediated by the Janus kinase (JAK)/ signal transducer and activator of transcription (STAT) pathway regulated by brain-derived neurotrophic factor (BDNF). BDNF-and seizure-dependent phosphorylation of STAT3 cause the adenosine 3′,5′-monophosphate (cAMP) response element-binding protein (CREB) family member ICER (inducible cAMP early repressor) to bind with phosphorylated CREB at the Gabra1:CRE site. JAK/STAT pathway inhibition prevents the seizure-induced decrease in GABA A R α1 abundance in vivo and, given that BDNF is known to increase the abundance of GABA A R α4 in a JAK/STATindependent manner, indicates that BDNF acts through at least two distinct pathways to influence GABA A R-dependent synaptic inhibition.
Differential expression of GABA A receptor (GABR) subunits has been demonstrated in hippocampus from patients and animals with temporal lobe epilepsy (TLE), but whether these changes are important for epileptogenesis remains unknown. Previous studies in the adult rat pilocarpine model of TLE found reduced expression of GABR ␣1 subunits and increased expression of ␣4 subunits in dentate gyrus (DG) of epileptic rats compared with controls. To investigate whether this altered subunit expression is a critical determinant of spontaneous seizure development, we used adeno-associated virus type 2 containing the ␣4 subunit gene (GABRA4) promoter to drive transgene expression in DG after status epilepticus (SE). This novel use of a condition-dependent promoter upregulated after SE successfully increased expression of GABR ␣1 subunit mRNA and protein in DG at 1-2 weeks after SE. Enhanced ␣1 expression in DG resulted in a threefold increase in mean seizure-free time after SE and a 60% decrease in the number of rats developing epilepsy (recurrent spontaneous seizures) in the first 4 weeks after SE. These findings provide the first direct evidence that altering GABR subunit expression can affect the development of epilepsy and suggest that ␣1 subunit levels are important determinants of inhibitory function in hippocampus.
Altered function of ␥-aminobutyric acid type A receptors (GABA A Rs) in dentate granule cells of the hippocampus has been associated with temporal lobe epilepsy (TLE) in humans and in animal models of TLE. Such altered receptor function (including increased inhibition by zinc and lack of modulation by benzodiazepines) is related, in part, to changes in the mRNA levels of certain GABA A R subunits, including ␣4, and may play a role in epileptogenesis. The majority of GABA A Rs that contain ␣4 subunits are extra-synaptic due to lack of the ␥2 subunit and presence of ␦. However, it has been hypothesized that seizure activity may result in expression of synaptic receptors with altered properties driven by an increased pool of ␣4 subunits. Results of our previous work suggests that signaling via protein kinase C (PKC) and early growth response factor 3 (Egr3) is the plasticity trigger for aberrant ␣4 subunit gene (GABRA4) expression after status epilepticus. We now report that brain derived neurotrophic factor (BDNF) is the endogenous signal that induces Egr3 expression via a PKC/MAPK-dependent pathway. Taken together with the fact that blockade of tyrosine kinase (Trk) neurotrophin receptors reduces basal GABRA4 promoter activity by 50%, our findings support a role for BDNF as the mediator of Egr3-induced GABRA4 regulation in developing neurons and epilepsy and, moreover, suggest that BDNF may alter inhibitory processing in the brain by regulating the balance between phasic and tonic inhibition.The type A ␥-aminobutyric acid (GABA) 5 receptor (GABA A R) is an integral ligand gated ion channel that mediates the majority of inhibition in the central nervous system. Being a hetero-oligomeric complex, it is composed of five membrane spanning subunits that are chosen from the products of 19 different genes (␣ 1-6 ,  1-3 , ␥ 1-3 , ␦, ⑀, , 1-3 , and ). These genes are differentially transcribed during development and in various regions of the adult brain and spinal cord (1-5). Alteration in the function of GABA A Rs has been associated with a variety of diseases whose etiology leads to an imbalance between inhibition and excitation in specific populations of neurons (6 -8).For instance, changes in certain GABA A R subunit levels occur in dentate granule cells (DGCs) of both humans with temporal lobe epilepsy (TLE) and in animal models of TLE (6, 9). These molecular responses have been hypothesized to underlie persistent changes in GABA A R function associated with epileptogenesis. Most notably, individual DGCs display an elevation of ␣4 subunit mRNAs and a decrease in ␣1 (6). Receptors that contain ␣4 subunits have unique pharmacological properties that include heightened blockade of receptor function by zinc (11-13) and decreased benzodiazepine modulation (14). In addition, the majority of GABA A Rs that contain ␣4 subunits (co-assembled with a  and ␦) are located extrasynaptically and mediate tonic GABA currents, while those containing ␣(1, 2, 3, or 5) without ␦ and with ␥2 are targeted to the synapse (1, 15). Although...
Fig. 1. Protein-protein interactions between gp32 and gp59 on fDNA. (A) The fluorescence from individual molecules of fDNA with the proteins bound in the order as indicated at the side of each row. The gp32 protein is labeled with A488 (gp32 D ) and the gp59 protein is labeled with A555 (gp59 A ). The filter sets are described in Experimental Methods: F1 is for A488 emission, F2 for FRET between A488 and A555, and F3 for A555 emission. (B) Ensemble FRET studies of Oregon-green-488-maleimide-labeled gp59 titrated into a solution of 400 nM CPM-labeled gp32 and 100 nM fDNA. The fluorescence spectra of 400 nM CPM-gp32 alone (black line), the endpoint of the titration at 1 M Oregon-green-488-maleimide-gp59 (dark gray line), and several intermediate spectra (light gray lines) are shown. (C) Analysis of the donor quenching and acceptor sensitization plotted against the gp59 concentration determines the stoichiometry among gp32, gp59, and fDNA to be 1:1:1 with a calculated binding constant of Ϸ40 nM.
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