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Originally published as Genetics Published Articles Ahead of Print on April 28, 2006.
Genetics, Vol. 173, 1357-1364, July 2006, Copyright © 2006
doi:10.1534/genetics.106.057463
Metabolic Disruption in Drosophila Bang-Sensitive Seizure Mutants
Tim Fergestad, Bret Bostwick and Barry Ganetzky1
Laboratory of Genetics, University of Wisconsin, Madison, Wisconsin 53706
1 Corresponding author: Laboratory of Genetics, Genetics/Biotechnology Bldg., 425-G Henry Mall, University of Wisconsin, Madison, WI 53706-1580.
E-mail: ganetzky{at}wisc.edu
We examined a number of Drosophila mutants with increased susceptibility to seizures following mechanical or electrical stimulation to better understand the underlying factors that predispose neurons to aberrant activity. Several mutations in this class have been molecularly identified and suggest metabolic disruption as a possible source for increased seizure susceptibility. We mapped the bang-sensitive seizure mutation knockdown (kdn) to cytological position 5F3 and identified citrate synthase as the affected gene. These results further support a role for mitochondrial metabolism in controlling neuronal activity and seizure susceptibility. Biochemical analysis in bang-sensitive mutants revealed reductions in ATP levels consistent with disruption of mitochondrial energy production in these mutants. Electrophysiological analysis of mutants affecting mitochondrial proteins revealed an increased likelihood for a specific pattern of seizure activity. Our data implicate cellular metabolism in regulating seizure susceptibility and suggest that differential sensitivity of neuronal subtypes to metabolic changes underlies distinct types of seizure activity.
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