Klumpfuss, a putative Drosophila zinc finger transcription factor, acts to differentiate between the identities of two secondary precursor cells within one neuroblast lineage.

doi:10.1101/gad.11.11.1396

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GENES & DEVELOPMENT 11:1396-1408, 1997
ISSN 0890-9369

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Research Papers

Klumpfuss, a putative Drosophila zinc finger transcription factor, acts to differentiate between the identities of two secondary precursor cells within one neuroblast lineage.

X Yang, S Bahri, T Klein, and W Chia

Institute of Molecular and Cell Biology, National University of Singapore, Singapore.

Abstract

The approximately 300 distinct neurons comprising each hemineuromereof the Drosophila embryonic central nervous system are derivedfrom a segmentally reiterated array of approximately 30 progenitorcells, neuroblasts (NBs). Each NB has a unique identity andundergoes repeated cell divisions to produce several smallersecondary precursor cells, ganglion mother cells (GMCs); eachGMC divides once to produce two neurons and/or glia, therebygenerating a specific lineage of neurons/glia. Understandingthe generation of neuronal diversity requires not only elucidationof the molecules and mechanisms that specify NB identity butalso those that act to differentiate between the cell typesproduced within one NB lineage. Here we show that the DrosophilaZn finger protein Klumpfuss (Klu), which shows sequence similaritiesto the mammalian Wilm's tumor suppressor (WT-1), acts to differentiatebetween the identities of the first two secondary precursorcells produced from one NB lineage. Klu is expressed in theNB4-2 lineage only after two rounds of NB cell division, inthe second born GMC (GMC4-2b). In loss-of-function mutant embryos,the first born GMC (GMC4-2a) as well as its progeny neuronsare duplicated; we show that this duplication of the GMC4-2asublineage arises because GMC4-2b adopts the identity of GMC4-2aand divides to produce the GMC4-2a progeny. Moreover, when Kluis ectopically expressed in GMC4-2a, it fails to acquire itsnormal identity and fails to produce correctly specified progeny.klu therefore acts to specify the identity of GMC4-2b and tomake it distinct from GMC4-2a. Our findings further suggestthat the determination of GMC cell fate occurs in two steps;the initial GMC identity is the consequence of inheritance fromthe maternal NB, however, the subsequent stabilization of thisidentity requires functions like klu in the GMC.

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