Abstract
Proneural genes are among the most early-acting genes in nervous system development, instructing blast cells to commit to a neuronal fate. Drosophila Atonal and Achaete-Scute complex (AS-C) genes, as well as their vertebrate orthologs, are basic helix-loop-helix (bHLH) transcription factors with such proneural activity. We show here that a C. elegans AS-C homolog, hlh-4, functions in a fundamentally different manner. In the embryonic, larval, and adult nervous systems, hlh-4 is expressed exclusively in a single nociceptive neuron class, ADL, and its expression in ADL is maintained via transcriptional autoregulation throughout the life of the animal. However, in hlh-4 null mutants, the ADL neuron is generated and still appears neuronal in overall morphology and expression of panneuronal and pansensory features. Rather than acting as a proneural gene, we find that hlh-4 is required for the ADL neuron to function properly, to adopt its correct morphology, to express its unusually large repertoire of olfactory receptor–encoding genes, and to express other known features of terminal ADL identity, including neurotransmitter phenotype, neuropeptides, ion channels, and electrical synapse proteins. hlh-4 is sufficient to induce ADL identity features upon ectopic expression in other neuron types. The expression of ADL terminal identity features is directly controlled by HLH-4 via a phylogenetically conserved E-box motif, which, through bioinformatic analysis, we find to constitute a predictive feature of ADL-expressed terminal identity markers. The lineage that produces the ADL neuron was previously shown to require the conventional, transient proneural activity of another AS-C homolog, hlh-14, demonstrating sequential activities of distinct AS-C-type bHLH genes in neuronal specification. Taken together, we have defined here an unconventional function of an AS-C-type bHLH gene as a terminal selector of neuronal identity and we speculate that such function could be reflective of an ancestral function of an “ur-” bHLH gene.
Highlights
Nervous system development proceeds through sequential steps, starting with the early commitment to a neuronal fate, followed by the progressive restriction of fates, to reaching a terminal, differentiated end state
We describe here a distinct function for a specific member of this family, hlh-4, in the nematode Caenorhabditis elegans. hlh-4 is exclusively expressed in a nociceptive neuron class and is not required for this neuron class to be generated but is rather required for the execution of its terminal differentiation program. hlh-4 directly controls the expression of scores of terminal identity features of this neuron class, including its large battery of chemoreceptor-encoding genes
We propose that a role of basic helix-loop-helix (bHLH) genes in controlling terminal differentiation may be the ancestral function of members of this gene family
Summary
Nervous system development proceeds through sequential steps, starting with the early commitment to a neuronal fate, followed by the progressive restriction of fates, to reaching a terminal, differentiated end state. The C. elegans AS-C ortholog hlh-14 and the C. elegans Atonal ortholog, lin-32, provide proneural activity in several distinct sensory neuron lineages of the peripheral and central nervous system (CNS) of the worm [10,11,12]. In both cases, the proneural activity of hlh-14 and lin-32 is exemplified by a transformation of neuroblasts into cells with a hypodermal identity in the respective mutant backgrounds
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