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Genetic Analysis of a Synaptic Calcium Channel in Drosophila: Intragenic Modifiers of a Temperature-Sensitive Paralytic Mutant of cacophony
I. M. Brooksa, R. Fellinga, F. Kawasakia, and R. W. Ordwayaa Department of Biology, The Pennsylvania State University, University Park, Pennsylvania 16802
Corresponding author: R. W. Ordway, 208 Mueller Laboratory, Pennsylvania State University, University Park, PA 16802., rwo4{at}psu.edu (E-mail)
Communicating editor: T. C. KAUFMAN
1 subunit gene, cacophony (cac). Electrophysiological studies in this mutant, designated cacTS2, indicated cac encodes a primary calcium channel 1 subunit functioning in neurotransmitter release. To further examine the functions and interactions of cac-encoded calcium channels, a genetic screen was performed to isolate new mutations that modify the cacTS2 paralytic phenotype. The screen recovered 10 mutations that enhance or suppress cacTS2, including second-site mutations in cac (intragenic modifiers) as well as mutations mapping to other genes (extragenic modifiers). Here we report molecular characterization of three intragenic modifiers and examine the consequences of these mutations for temperature-sensitive behavior, synaptic function, and processing of cac pre-mRNAs. These mutations may further define the structural basis of calcium channel 1 subunit function in neurotransmitter release.
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