Abstract
Neuronal diversity is at the core of the complex processing operated by the nervous system supporting fundamental functions such as sensory perception, motor control or memory formation. A small number of progenitors guarantee the production of this neuronal diversity, with each progenitor giving origin to different neuronal types over time. How a progenitor sequentially produces neurons of different fates and the impact of extrinsic signals conveying information about developmental progress or environmental conditions on this process represent key, but elusive questions. Each of the four progenitors of the Drosophila mushroom body (MB) sequentially gives rise to the MB neuron subtypes. The temporal fate determination pattern of MB neurons can be influenced by extrinsic cues, conveyed by the steroid hormone ecdysone. Here, we show that the activation of Transforming Growth Factor-β (TGF-β) signalling via glial-derived Myoglianin regulates the fate transition between the early-born α’β’ and the pioneer αβ MB neurons by promoting the expression of the ecdysone receptor B1 isoform (EcR-B1). While TGF-β signalling is required in MB neuronal progenitors to promote the expression of EcR-B1, ecdysone signalling acts postmitotically to consolidate theα’β’ MB fate. Indeed, we propose that if these signalling cascades are impaired α’β’ neurons lose their fate and convert to pioneer αβ. Conversely, an intrinsic signal conducted by the zinc finger transcription factor Krüppel-homolog 1 (Kr-h1) antagonises TGF-β signalling and acts as negative regulator of the response mediated by ecdysone in promoting α’β’ MB neuron fate consolidation. Taken together, the consolidation of α’β’ MB neuron fate requires the response of progenitors to local signalling to enable postmitotic neurons to sense a systemic signal.
Highlights
The central nervous system displays great diversity of neuronal cell types, which are assembled into neural circuits to serve brain functions [1]
Throughout the development of the central nervous system (CNS), a vast number of neuronal types are produced with striking precision
The unique identity of each neuronal cell type and the great cellular complexity in the CNS are established by intricate gene regulatory networks
Summary
The central nervous system displays great diversity of neuronal cell types, which are assembled into neural circuits to serve brain functions [1]. Complementary studies in vertebrate models indicated that, together with intrinsic factors, external cues are required to define the fate competence of neuronal progenitors [3, 4] This discrepancy was recently challenged as recent studies in Drosophila postembryonic lineages revealed the importance of external cues in ensuring the proper temporal generation of neuronal diversity [5, 6]. In those systems extrinsic factors seem to display complex interdependent functional relationships with intrinsic transcriptional programs that are just starting to be elucidated [5, 6]. A fate program involving both external and intrinsic factors appears to be conserved and essential during brain development to generate neuronal variety
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