Abstract Development of a multicellular organism from a fertilized egg depends on a precise
balance between symmetric cell divisions to expand the pool of similar cells, and …

We demonstrate the feasibility of generating thousands of transgenic Drosophila melanogaster
lines in which the expression of an exogenous gene is reproducibly directed to distinct …

Neural precursors often generate distinct cell types in a specific order, but the intrinsic or
extrinsic cues regulating the timing of cell fate specification are poorly understood. Here we …

Central nervous system development inDrosophilastarts with the delamination from the
neuroectoderm of about 30 neuroblasts (NBs) per hemisegment. Understanding the …

The molecular mechanisms used to generate neuronal diversity are largely unknown. To
identify genes controlling cell fate in the Drosophila central nervous system, we screened for …

Asymmetric cell divisions play a key role in establishing neuronal diversity in the mammalian
and Drosophila CNS, but the mechanisms involved are mostly unknown. The Drosophila …

Mammalian neural stem cells generate transit amplifying progenitors that expand the
neuronal population, but these type of progenitors have not been studied in Drosophila. The …

An experimental analysis of neurogenesis requires a detailed understanding of wild-type
neural development. Recent DiI cell lineage studies have begun to elucidate the family of …

The first step in generating cellular diversity in the Drosophila central nervous system is the
formation of a segmentally reiterated array of neural precursor cells, called neuroblasts. …

Stem cells are captivating because they have the potential to make multiple cell types yet
maintain their undifferentiated state. Recent studies of Drosophila and mammalian neural stem …