Cell context-dependent CFI-1/ARID3 functions control neuronal terminal differentiation.

AT-rich interaction domain 3 (ARID3) transcription factors are expressed in the nervous system, but their mechanisms of action are largely unknown. Here, we provide, in vivo, a genome-wide binding map for CFI-1, the sole C. elegans ARID3 ortholog. We identify 6,396 protein-coding genes as putative direct targets of CFI-1, most of which encode neuronal terminal differentiation markers. In head sensory neurons, CFI-1 directly activates multiple terminal differentiation genes, thereby acting as a terminal selector. In motor neurons, however, CFI-1 acts as a direct repressor, continuously antagonizing three transcriptional activators. By focusing on the glr-4/GRIK4 glutamate receptor locus, we identify proximal CFI-1 binding sites and histone methyltransferase activity as necessary for glr-4 repression. Rescue assays reveal functional redundancy between core and extended DNA-binding ARID domains and a strict requirement for REKLES, the ARID3 oligomerization domain. Altogether, this study uncovers cell-context-dependent mechanisms through which a single ARID3 protein controls the terminal differentiation of distinct neuron types.

Establishment and maintenance of motor neuron identity via temporal modularity in terminal selector function.

Terminal selectors are transcription factors (TFs) that establish during development and maintain throughout life post-mitotic neuronal identity. We previously showed that UNC-3/Ebf, the terminal selector of C. elegans cholinergic motor neurons (MNs), acts indirectly to prevent alternative neuronal identities (Feng et al., 2020). Here, we globally identify the direct targets of UNC-3. Unexpectedly, we find that the suite of UNC-3 targets in MNs is modified across different life stages, revealing 'temporal modularity' in terminal selector function. In all larval and adult stages examined, UNC-3 is required for continuous expression of various protein classes (e.g. receptors, transporters) critical for MN function. However, only in late larvae and adults, UNC-3 is required to maintain expression of MN-specific TFs. Minimal disruption of UNC-3's temporal modularity via genome engineering affects locomotion. Another C. elegans terminal selector (UNC-30/Pitx) also exhibits temporal modularity, supporting the potential generality of this mechanism for the control of neuronal identity.