The restrictive element-1 silencing transcription factor (REST)/neuron-restrictive silencing factor (NRSF) is a transcriptional repressor which actively suppresses genes involved in a wide array of neuronal processes such as global ischemia, neurodegenerative conditions and seizure disorders (Calderone et al., 2003; Lu et al., 2014; McClelland et al., 2011). In C. elegans,
spr-4 is the homolog of REST; a mutation in
spr-4(
by105) enhanced amyloid-beta-induced neurotoxicity of glutamatergic neurons in a worm Alzheimer’s disease model (Lu et al., 2014). Previously published research in mammals has reported that REST contributes to the onset of epilepsy via repression of specific genes (McClelland et al., 2011). Additionally, there is a 2- to 6-fold increase in the prevalence and incidence of seizures in Alzheimers disease patients (Nicastro et al., 2016). Taken together, we hypothesized there might be a REST-dependent convulsion phenotype in
spr-4(
by105) mutants. We previously developed a protocol for studying epileptic-like convulsions in C. elegans that involved treating worms with the GABA antagonist, pentylenetetrazole (PTZ) on agar plates (Locke et al., 2008). Here, we tested
spr-4(
by105) worms for convulsions using our previously developed agar plate assay and a newly developed liquid-based assay from another lab (Wong et al., 2018), both of which used PTZ to induce convulsions. As a negative control, we examined N2 wild-type animals. It should be noted that these wild-type animals did not exhibit a single convulsion at any concentration (2-10 mg/mL PTZ) with either the liquid or plate-based assay. For both assays, we used the
unc-43(
n498 n1186) worms as a positive convulsion control (Fig. 1A) as these animals are responsive to PTZ on agar plates (Williams et al., 2004) and in liquid containing PTZ (Wong et al., 2018). Notably, the behavioral response of the
unc-43 animals was similar in both assay types. The
unc-43 animals had more active phenotypes at higher concentrations (6, 8, and 10 mg/mL PTZ) where they displayed a rubberband, or clonic convulsion, phenotype. At lower concentrations (4 mg/mL) the animals exhibited either a rubberband or paralysis phenotype. Paralyzed animals still displayed pharyngeal activity and completely recovered normal movement within 20-30 minutes following removal from PTZ. These control animals informed our experimental conditions. We wanted to determine if the convulsion response in
spr-4 mutant worms would be similar between the assays or preferentially modulated. Notably, populations of
spr-4 mutant animals displayed significantly different convulsion levels at every concentration of PTZ in response to these alternate assay conditions (Fig. 1B). In all cases, the population of animals responsive to PTZ was significantly lower using the liquid-based assay in comparison to the plate-based assay. With both assays, however, the
spr-4 worms did display similar types of phenotypic convulsions at comparable concentrations. Specifically, at higher concentrations of PTZ (8 and 10 mg/mL)
spr-4 worms exhibited tonic-clonic, or head-bobbing, convulsions where the anterior region of the animal had a repetitive movement while the posterior was paralyzed. Conversely, at lower concentrations of PTZ (2 and 4 mg/mL),
spr-4 animals displayed primarily full body paralysis. We do not know why
spr-4 animals displayed such stark differences in convulsion levels following exposure to PTZ from these two assay types when such distinct and contrasting variability was not displayed by the
unc-43 worms. However, it is known that environmental circumstances can induce convulsions in humans. In this regard, we suggest that in our worm assays, mechanosensory or osmotic stress differences might modulate the PTZ-induced epileptic-like convulsive behavior of certain C. elegans mutants in an assay and concentration-dependent manner.