Dissecting Drosophila embryonic brain development using photoactivated gene expression.

The Drosophila brain is generated by a complex series of morphogenetic movements. To better understand brain development and to provide a guide for experimental manipulation of brain progenitors, we created a fate map using photoactivated gene expression to mark cells originating within specific mitotic domains and time-lapse microscopy to dynamically monitor their progeny. We show that mitotic domains 1, 5, and 9 give rise to discrete cell populations within specific regions of the brain. Two novel observations were that the antennal sensory system, composed of four disparate cell clusters, arose from mitotic domain 5 and that mitotic domain B produced glial cells, while neurons were produced from mitotic domains 1, 5, and 9. Time-lapse analysis of marked cells showed complex mitotic and migratory patterns for cells derived from these mitotic domains. Photoactivated gene expression was also used either to kill, to induce ectopic divisions, or to alter cell fate. This revealed that deficits were not repopulated, while ectopic cells were removed and extra glia were tolerated.

Photoactivated gene expression for cell fate mapping and cell manipulation.

A long-standing goal of developmental biologists is to create developmental fate maps by tracking individual cells through development. Another objective is to perturb the behavior of selected cells and follow the ensuing effects. To this end, we have developed a technique that allows for spatial and temporal control of gene expression in single cells or patches of cells using light to induce gene expression. This technique relies on "caging" the activity of the potent transcriptional activator GAL4VP16 with a photolabile compound, which can be removed with a brief exposure to long-wavelength ultraviolet (UV) light. The caged GAL4VP16 is injected into early-stage embryos, which are aged to the desired point in development, and the cell(s) of interest are irradiated with a brief pulse of long-wavelength UV light. This method has been used extensively in Drosophila, Xenopus, and Zebrafish embryos. The methods for purifying, caging, injection, and photoactivation of the GAL4VP16 protein, and methods for the visualization of marked cells are described in detail.