Developmental (phenotypic) plasticity describes the property of a genotype to respond to environmental variation by producing distinct phenotypes. In Pristionchus pacificus, the mouth form is developmentally plastic, resulting in two alternative mouth forms: the eurystomatous (Eu) predatory form has two strong teeth, whereas the alternative stenostomatous (St) form has a single tooth and is bacteriovorus. The switch between the two forms is environmentally sensitive, and a previous forward genetic approach showed a key switch function for the sulfatase-coding gene
eud-1, mutations in which result in all-St worms. In this study we used P. pacificus natural isolates with different Eu/St ratios to generate Recombinant Inbred Lines (RILs), and performed Quantitative Trait Locus (QTL) analysis to dissect the genetic architecture underlying mouth dimorphism in P. pacificus. Our result showed the involvement of one major locus on the X chromosome, spanning a recently described multigene locus containing
eud-1, its paralog, and two more genes encoding alpha-N-acetylglucosaminidases (nag), all of which were shown to be involved in mouth form regulation. RNA-seq analysis of parental strains revealed 40% higher expression of
eud-1 in the high Eu parental strain, and CRISPR-Cas9 mutants of the two sulftases paralogous in the high Eu parental strain showed a complete switch to the St form. With the absence of non-synonymous substitutions in
eud-1 between the parental lines, we used CRISPR-Cas9 technology to perform variant swapping in the
eud-1 regulatory region to define potential causative SNPs behind the mouth-form dimorphism. Our experimental analysis identified variations in different cis-regulatory components of
eud-1. Copy number differences in a potential Forkhead transcription factor binding site within the promoter/enhancer region, besides a SNP in the
eud-1 first intron between the parental lines caused differences in mouth-form ratios phenotype. Mutant lines showed an additive effect of these cis-regulatory elements, with a systematic change in the mouth-form phenotype and downregulation of
eud-1 expression. Currently, we are using CRISPR-Cas9 technology to examine the potential involvement of various Forkhead genes in controlling
eud-1 expression, while also expanding our analysis to test variations in the causative region within 30 more P. pacificus natural isolates.