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. 1981 Oct;78(10):6548–6552. doi: 10.1073/pnas.78.10.6548

Abnormal action potentials associated with the Shaker complex locus of Drosophila

Mark A Tanouye 1, Alberto Ferrus 1,*, Shinobu C Fujita 1
PMCID: PMC349078  PMID: 16593105

Abstract

Intracellular recordings of action potentials were made from the cervical giant axon in Shaker (Sh) mutants and normal Drosophila. The mutants showed abnormally long delays in repolarization. The defect is not due to abnormal Ca2+ channels, because it persists in the presence of Co2+, a Ca2+-channel blocker. On the other hand, the K+-channel blocker 4-aminopyridine causes a similar effect in normal animals, suggesting that the Sh mutant may have abnormal K+ conductance. Gene-dosage analysis of Sh shows that the defect is not due to underproduction of an otherwise normal molecule; it may be due to an abnormal molecule produced by the mutated gene. Gel electrophoresis failed to detect an abnormal protein, suggesting that, if Sh codes for a nervous system protein, it is rare. Genetic analysis of the Sh locus indicates three regions. Mutations or chromosome breaks in the two flanking regions cause Sh mutant physiology; the central region shows a “haplolethal effect”—i.e., heterozygous females are lethal.

Keywords: behavior, neurogenetics, potassium channel, membrane physiology, gene complex

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Selected References

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