We are interested in identifying genes that are expressed in a panneuronal manner throughout the nervous system (Stefanakis et al., 2015). The Drosophila elav locus is a panneuronally expressed RNA binding protein (Campos et al., 1987; Robinow and White, 1988). Elav protein staining is routinely used in Drosophila to identify neurons and cis-regulatory control regions from the elav locus are routinely used as panneuronal Gal4 drivers (Berger et al., 2007; Luo et al., 1994; ONeill et al., 1994; Osterwalder et al., 2001; Robinow and White, 1991). Based on sequence homology, the C. elegans
exc-7 locus is the sole C. elegans orthologue of elav (Fujita et al., 2003; Fujita et al., 1999; Loria et al., 2003; Samson, 2008). Previous expression pattern analyses have shown that
exc-7 is expressed only in a subset of neurons of the nervous system (the expressing neurons were mostly unidentified) (Fujita et al., 1999; Loria et al., 2003). However, reporter gene constructs previously used to infer
exc-7 expression did not contain all intergenic region of the large
exc-7 locus. Therefore, the possibility remained that through the use of more distal cis-regulatory elements, C. elegans
exc-7 could also be panneuronally expressed, like its fly orthologue. To address this possibility, we tagged endogenous
exc-7 with gfp::3xflag at its C-terminus using CRISPR/Cas9 genome engineering (Dokshin et al., 2018) and examined its expression. We cloned gfp from the
che-1(
ot856[
che-1::gfp]) allele (Leyva-Diaz and Hobert, 2019), inserted it into the pMiniT 2.0 vector (NEB), and used that resulting plasmid for subsequent cloning of the gfp tag.Embryonic expression of
exc-7 was first observed at the bean stage. By reverse lineaging with use of SIMI-Biocell software (Schnabel et al., 1997), we confirm the identity of one of the expressing cells at this stage as the excretory canal cell (Fig. 1B, arrow). In L1 animals, broad expression in the head, ventral nerve cord (VNC), and tail was observed (Fig. 1C). In young adults, expression is notably observed in vulva cells (Fig. 1D). In the nervous system specifically, expression is observed in many neurons throughout the body (Fig. 1D-D), but unlike Drosophila Elav,
exc-7::gfp it is not panneuronally expressed. We used the NeuroPAL transgene (https://www.biorxiv.org/content/10.1101/676312v1) to individually identify each neuron in which
exc-7 is expressed in the young adult worm. Sites of expression are listed in Fig. 1F and some examples of neuronal expression are shown in Fig. 1E. Expression in all neurons is at least several fold more intense than UPN::NLS::TagRFP-T signal from NeuroPAL. We confirmed previously reported expression in cholinergic VNC MNs, but absence of GABAergic VNC MNs (Fig. 1E), consistent with previous reports (Fujita et al., 1999; Loria et al., 2003) and consistent with
exc-7 functioning in cholinergic, but not GABAergic neurons to control alternative splicing (Norris et al., 2014).
exc-7::gfp is also expressed in some non-neuronal cell types, including muscle and hypodermis, but not in the gut (Fig. 1D-D). A previous report showed that
exc-7 is only transiently and weakly expressed in the excretory cell, which, based on
exc-7s excretory mutant phenotype, has puzzled researchers (Fujita et al., 2003). We find that the gfp tagged
exc-7 locus is strongly and continuously expressed in the excretory canal cell (Fig. 1B-D, arrow). We conclude that unlike its fly orthologue elav,
exc-7 is not a panneuronally expressed gene.