Abstract
Neural circuitry for mating and reproduction resides within the terminal segments of central nervous system (CNS) which express Hox paralogous group 9–13 (in vertebrates) or Abdominal-B (Abd-B) in Drosophila. Terminal neuroblasts (NBs) in A8-A10 segments of Drosophila larval CNS are subdivided into two groups based on expression of transcription factor Doublesex (Dsx). While the sex specific fate of Dsx-positive NBs is well investigated, the fate of Dsx-negative NBs is not known so far. Our studies with Dsx-negative NBs suggests that these cells, like their abdominal counterparts (in A3-A7 segments) use Hox, Grainyhead (Grh) and Notch to undergo cell death during larval development. This cell death also happens by transcriptionally activating RHG family of apoptotic genes through a common apoptotic enhancer in early to mid L3 stages. However, unlike abdominal NBs (in A3-A7 segments) which use increasing levels of resident Hox factor Abdominal-A (Abd-A) as an apoptosis trigger, Dsx-negative NBs (in A8-A10 segments) keep the levels of resident Hox factor Abd-B constant. These cells instead utilize increasing levels of the temporal transcription factor Grh and a rise in Notch activity to gain apoptotic competence. Biochemical and in vivo analysis suggest that Abdominal-A and Grh binding motifs in the common apoptotic enhancer also function as Abdominal-B and Grh binding motifs and maintains the enhancer activity in A8-A10 NBs. Finally, the deletion of this enhancer by the CRISPR-Cas9 method blocks the apoptosis of Dsx-negative NBs. These results highlight the fact that Hox dependent NB apoptosis in abdominal and terminal regions utilizes common molecular players (Hox, Grh and Notch), but seems to have evolved different molecular strategies to pattern CNS.
Highlights
Establishment of precise neural circuitry is a prerequisite for a functional central nervous system (CNS)
One of the ways by which Hox factors do this is by mediating differential programmed cell death of the neural stem cells along the head to tail axis of the developing central nervous system, thereby regulating the numerical diversity of the neurons generated along this axis
While apoptosis of neuronal and glial cells plays an important role in establishing a functional neural circuitry, the death of the neural stem cells (NSCs) is expected to bring about gross changes to the developing CNS [9, 14]
Summary
Establishment of precise neural circuitry is a prerequisite for a functional central nervous system (CNS) This precision critically relies on generation of right cellular diversity (and numbers) in a region specific manner across the anterior-posterior (AP) axis of developing CNS [1, 2]. While apoptosis of neuronal and glial cells plays an important role in establishing a functional neural circuitry, the death of the NSCs is expected to bring about gross changes to the developing CNS [9, 14]. Hox genes specify the AP axis of the developing CNS, and play an important role in apoptosis of both NSCs as well their progeny [4, 5, 8,9,10,11,12,13, 15,16,17,18,19,20,21,22,23,24]. The molecular mechanism of Hox mediated NSC apoptosis in different regions of the developing CNS is yet to be elucidated
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