Abstract
During neurogenesis, transcription factors combinatorially specify neuronal fates and then differentiate subtype identities by inducing subtype-specific gene expression profiles. But how is neuronal subtype identity maintained in mature neurons? Modeling this question in two Drosophila neuronal subtypes (Tv1 and Tv4), we test whether the subtype transcription factor networks that direct differentiation during development are required persistently for long-term maintenance of subtype identity. By conditional transcription factor knockdown in adult Tv neurons after normal development, we find that most transcription factors within the Tv1/Tv4 subtype transcription networks are indeed required to maintain Tv1/Tv4 subtype-specific gene expression in adults. Thus, gene expression profiles are not simply “locked-in,” but must be actively maintained by persistent developmental transcription factor networks. We also examined the cross-regulatory relationships between all transcription factors that persisted in adult Tv1/Tv4 neurons. We show that certain critical cross-regulatory relationships that had existed between these transcription factors during development were no longer present in the mature adult neuron. This points to key differences between developmental and maintenance transcriptional regulatory networks in individual neurons. Together, our results provide novel insight showing that the maintenance of subtype identity is an active process underpinned by persistently active, combinatorially-acting, developmental transcription factors. These findings have implications for understanding the maintenance of all long-lived cell types and the functional degeneration of neurons in the aging brain.
Highlights
Tremendous progress has been made in delineating the transcriptional mechanisms that diversify neuronal subtype identities during development
For neurons to function properly, they must establish and maintain their unique, subtype-specific gene expression profiles. These unique gene expression profiles are established during development by networks of DNA– binding proteins, termed transcription factors (TFs)
We examined the effect of knocking down TF expression in two adult neuronal subtypes
Summary
Tremendous progress has been made in delineating the transcriptional mechanisms that diversify neuronal subtype identities during development. Spatiotemporally-patterned transcription factor cascades act within increasingly diversified progenitor populations to specify postmitotic neuron subtype fate. Within those postmitotic neurons, subtype-specific sets of transcription factors act combinatorially to differentiate subtype identity by initiating expression of the genes that define subtype form and function [1,2,3]. Subtype-specific sets of transcription factors act combinatorially to differentiate subtype identity by initiating expression of the genes that define subtype form and function [1,2,3] These so-called terminal differentiation genes include subtype-specific neuropeptides, neurotransmitter enzymes and ion channels [4]. We apply the term ‘subtype transcription network’ to refer to the transcription factors that direct subtype specification and differentiation, their cross-regulatory relationships (or configuration), and the manner in which they direct the expression of subtype-specific sets of terminal differentiation genes
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