The Synaptic Protein Syntaxin1 Is Required for Cellularization of Drosophila Embryos

doi:10.1083/jcb.138.4.861

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© The Rockefeller University Press, 0021-9525/1997//861 $5.00
The Journal of Cell Biology, Volume 138, Number 4, , 1997 861-875

Article

The Synaptic Protein Syntaxin1 Is Required for Cellularization of Drosophila Embryos

Robert W. Burgess, David L. Deitcher, and Thomas L. Schwarz

Department of Molecular and Cellular Physiology, Stanford University, Stanford, California 94305-5426

Syntaxins are membrane proteins involved in vesicle traffickingand are required for the release of neurotransmitter at nerveterminals. The presence of syntaxins on target membranes hasbeen hypothesized to confer specificity to targeting and fusionvia interactions with complementary vesicle-associated proteins, the synaptobrevins or VAMPS. We have mutagenized syntaxin1in Drosophila and have found that it links the mechanism ofsynaptic transmission to a distinct cell biological process:the cellularization of early embryos. This specialized formof cell division separates the 6,000 nuclei of the syncytialblastoderm into separate cells through the invagination ofthe surface membrane of the embryo. During this process, syntaxin1protein is present on the newly forming lateral cell surfacesand invaginating cleavage furrows. This protein is derived both from maternal deposition of mRNA and protein and fromearly zygotic transcription. To analyze syntaxin1's role inearly development, female germ line mosaics mutant for syntaxin1expression were generated by mitotic recombination to reducethe maternal contribution. Visualizing the actin cytoskeletonand glycosylated surface proteins reveals that embryos with insufficient syntaxin1 have large acellular patches. The patchesdo not appear until cellularization begins, and the processfails entirely within these regions. These results provide geneticevidence that membrane trafficking is required for the cellularizationof the syncytial blastoderm. We propose that the invaginationof the surface membrane proceeds by the fusion of intracellularmembrane vesicles with the surface. This reaction uses thesame syntaxin1 protein as is required for neurotransmitter secretionat synapses. Thus, a single syntaxin can participate in traffickingsteps that are functionally as distinct as synaptic transmissionand cell division.

Abbreviations used in this paper: AED, after egg deposition; conA, concanavalinA; syx, syntaxin1.

Address all correspondence to Thomas L. Schwarz, Departmentof Molecular and Cellular Physiology, Stanford University, Stanford,CA 94305-5426. Tel.: (415) 725-7770. Fax: (415) 725-8021. E-mail:tschwarz{at}leland.stanford.edu

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