Midline lineages in grasshopper produce neuronal siblings with asymmetric expression of Engrailed

The median neuroblast lineage of grasshopper has provided a model for the development of differing neuronal types within the insect central nervous system. According to the prevailing model, neurons of different types are produced in sequence. Contrary to this, we show that each ganglion mother cell from the median neuroblast produces two neurons of asymmetric type: one is Engrailed positive (of interneuronal fate); and one is Engrailed negative (of efferent fate). The mature neuronal population, however, results from differential neuronal death. This yields many interneurons and relatively few efferent neurons. Also contrary to previous reports, we find no evidence for glial production by the median neuroblast. We discuss evidence that neuronal lineages typically produce asymmetric progeny, an outcome that has important developmental and evolutionary implications.

Jumeaux, a novel Drosophila winged-helix family protein, is required for generating asymmetric sibling neuronal cell fates

The great majority of neurons in the Drosophila embryonic CNS are generated through two successive asymmetric cell divisions; neuroblasts (NBs) divide to produce another NB and a smaller ganglion mother cell (GMC); GMCs divide to generate two sibling neurons which can adopt distinct identities. During the division of the first born GMC from the NB4-2 lineage, GMC4-2a, Inscuteable (Insc) is localised to the apical cortex, Pon/Numb is localised to the basal cortex and two daughters with distinct identities, the RP2 motoneuron and its sibling RP2sib, are born. Resolution of distinct sibling neuronal fates requires correct apical localisation of Insc to facilitate the asymmetric localisation and preferential segregation of Pon/Numb to the basal daughter destined to become RP2. Here we report that jumeaux (jumu), which encodes a new member of the winged-helix family of transcription factors, is required to mediate the asymmetric localisation and segregation of Pon/Numb but is dispensable for Insc apical localisation during the GMC4-2a cell division. In jumu mutants GMC4-2a Pon/Numb asymmetric localisation is defective and both daughter neurons can adopt the RP2 identity. Jumu protein shows nuclear localisation and within the NB4-2 lineage is first detected only after the first neuroblast cell division, in GMC4-2a. Our results suggest that in addition to the correct formation of an apical complex, transcription mediated by Jumu is also necessary to facilitate the correct asymmetric localisation and segregation of Pon/Numb.

A functional analysis of inscuteable and its roles during Drosophila asymmetric cell divisions

Cellular diversity in the Drosophila central nervous system is generated through a series of asymmetric cell divisions in which one progenitor produces two daughter cells with distinct fates. Asymmetric basal cortical localisation and segregation of the determinant Prospero during neuroblast cell divisions play a crucial role in effecting distinct cell fates for the progeny sibling neuroblast and ganglion mother cell. Similarly asymmetric localisation and segregation of the determinant Numb during ganglion mother cell divisions ensure that the progeny sibling neurons attain distinct fates. The most upstream component identified so far which acts to organise both neuroblast and ganglion mother cell asymmetric divisions is encoded by inscuteable. The Inscuteable protein is itself asymmetrically localised to the apical cell cortex and is required both for the basal localisation of the cell fate determinants during mitosis and for the orientation of the mitotic spindle along the apical/basal axis. Here we define the functional domains of Inscuteable. We show that aa252-578 appear sufficient to effect all aspects of its function, however, the precise requirements for its various functions differ. The region, aa288-497, is necessary and sufficient for apical cortical localisation and for mitotic spindle (re)orientation along the apical/basal axis. A larger region aa288-540 is necessary and sufficient for asymmetric Numb localisation and segregation; however, correct localisation of Miranda and Prospero requires additional sequences from aa540-578. The requirement for the resolution of distinct sibling neuronal fates appears to coincide with the region necessary and sufficient for Numb localisation (aa288-540). Our data suggest that apical localisation of the Inscuteable protein is a necessary prerequisite for all other aspects of its function. Finally, we show that although inscuteable RNA is normally apically localised, RNA localisation is not required for protein localisation or any aspects of inscuteable function.

miranda localizes staufen and prospero asymmetrically in mitotic neuroblasts and epithelial cells in early Drosophila embryogenesis

When neuroblasts divide, prospero protein and mRNA segregate asymmetrically into the daughter neuroblast and sibling ganglion mother cell. miranda is known to localize prospero protein to the basal cell cortex of neuroblasts while the staufen RNA-binding protein mediates prospero mRNA localization. Here we show that miranda is required for asymmetric staufen localization in neuroblasts. Analyses using miranda mutants reveal that prospero and staufen interact with miranda under the same cell-cycle-dependent control. miranda thus acts to partition both prospero protein and mRNA. Furthermore, miranda localizes prospero and staufen to the basolateral cortex in dividing epithelial cells, which express the three proteins prior to neurogenesis. Our observations suggest that the epithelial cell and neuroblast (both of epithelial origin) share the same molecular machinery for creating cellular asymmetry.

Cell fate specification by even-skipped expression in the Drosophila nervous system is coupled to cell cycle progression

The correct specification of defined neurons in the Drosophila central nervous system is dependent on even-skipped. During CNS development, even-skipped expression starts in the ganglion mother cell resulting from the first asymmetric division of neuroblast NB 1–1. This first division of NB 1–1 (and of the other early neuroblasts as well) is temporally controlled by the transcriptional regulation of string expression, which we have manipulated experimentally, even-skipped expression still occurs if the first neuroblast division is delayed, but not if the division is prohibited. Moreover, even-skipped expression is also dependent on progression through S phase which follows immediately after the first division. However, cytokinesis during the first NB division is not required for even-skipped expression as revealed by observations in pebble mutant embryos. Our results demonstrate therefore that even-skipped expression is coupled to cell cycle progression, presumably in order to prevent a premature activation of expression by a positive regulator which is produced already in the neuroblast during G2 and segregated asymmetrically into the ganglion mother cell during mitosis.

The prospero transcription factor is asymmetrically localized to the cell cortex during neuroblast mitosis in Drosophila

Both intrinsic and extrinsic factors are known to regulate sibling cell fate. Here we describe a novel mechanism for the asymmetric localization of a transcription factor to one daughter cell at mitosis. The Drosophila CNS develops from asymmetrically dividing neuroblasts, which give rise to a large neuroblast and a smaller ganglion mother cell (GMC). The prospero gene encodes a transcription factor necessary for proper GMC gene expression. We show that the prospero protein is synthesized in the neuroblast where it is localized to the F-actin cell cortex. At mitosis, prospero is asymmetrically localized to the budding GMC and excluded from the neuroblast. After cytokinesis, prospero is translocated from the GMC cortex into the nucleus. Asymmetric cortical localization of prospero in neuroblasts requires entry into mitosis; it does not depend on numb function. prospero is also observed in cortical crescents in dividing precursors of the peripheral nervous system and adult midgut. The asymmetric cortical localization of prospero at mitosis is a mechanism for rapidly establishing distinct sibling cell fates in the CNS and possibly other tissues.

The Drosophila miti-mere gene, a member of the POU family, is required for the specification of the RP2/sibling lineage during neurogenesis

The Drosophila POU gene miti-mere (previously known as pdm2) has a complex spatial and temporal pattern of expression during early development; initially it is expressed in gap-gene-like pattern, then in 14 stripes and finally in a subset of the cells in the developing CNS and PNS. To study the function of this gene during development, we generated a ‘synthetic anti-morphic mutation’ by expressing a truncated version of the miti protein from a constitutive hsp83 and an inducible hsp70 promoter. We show that these delta miti transgenes behave like classical antimorphic mutations. Using these dominant negative transgenes, together with deletions and a duplication for the gene, we show that miti is required during segmentation and neurogenesis. We have also used temperature-shift experiments with the hsp70 delta miti transgene to demonstrate that miti function in segmentation is distinct and separable from its function during neurogenesis. In segmentation, miti appears to be required in the specification of the segments A2 and A6. In the CNS, miti is required for the elaboration of the NB4-2-->GMC-1-->RP2/sib lineage. miti is initially required in this lineage to establish the identity of the parental ganglion mother cell, GMC-1. miti must then be down-regulated to allow the asymmetric division of GMC-1 into the RP2 and its sibling cell.