Drosophila Calmodulin Mutants With Specific Defects in the Musculature or in the Nervous System

Drosophila Calmodulin Mutants With Specific Defects in the Musculature or in the Nervous System

Bo Wang^a, Kathleen M. C. Sullivan^b, and Kathy Beckingham^a
^a Department of Biochemistry and Cell Biology, Rice University, Houston, Texas 77005
^b Howard Hughes Medical Institute and Department of Molecular and Cell Biology, University of California, Berkeley, California 94702

Corresponding author: Kathy Beckingham, MS-140 Rice University, P.O. Box 1892, Houston, TX 77251., kate{at}bioc.rice.edu (E-mail)

Communicating editor: T. KAUFMAN

We have studied lethal mutations in the single calmodulin gene(Cam) of Drosophila to gain insight into the in vivo functionsof this important calcium sensor. As a result of maternal calmodulin(CaM) in the mature egg, lethality is delayed until the postembryonicstages. Prior to death in the first larval instar, Cam nullsshow a striking behavioral abnormality (spontaneous backwardmovement) whereas a mutation, Cam⁷, that results in a singleamino acid change (V91G) produces a very different phenotype:short indented pupal cases and pupal death with head eversiondefects. We show here that the null behavioral phenotype originatesin the nervous system and involves a CaM function that requirescalcium binding to all four sites of the protein. Further, backwardmovement can be induced in hypomorphic mutants by exposure tohigh light levels. In contrast, the V91G mutation specificallyaffects the musculature and causes abnormal calcium releasein response to depolarization of the muscles. Genetic interactionstudies suggest that failed regulation of the muscle calciumrelease channel, the ryanodine receptor, is the major defectunderlying the Cam⁷ phenotype.

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