Genomic editing of the roundworm Caenorhabditis elegans using the CRISPR/Cas9 system has allowed for widespread creation of null mutants vital for scientific understanding of this model organism. A closely-related nematode species, Caenorhabditis briggsae, is emerging as an alternative model organism to better understand how findings in C. elegans can broaden and develop the larger field of nematology (Gupta et al. 2007). To that end, we have developed an effective and efficient co-conversion CRISPR/Cas9 system for use in C. briggsae using the gene
dpy-10.
We modified the universal STOP-IN cassette method, as described by Wang et al. (2018), for use in C. briggsae (Wang et al. 2018). Using the wildtype AF16 strain, we tested the method by choosing the gene
Cbr-dpy-10 because of its readily observed predicted phenotype.
Cbr-dpy-10 is a predicted one-to-one ortholog of C. elegans
dpy-10, which encodes a protein important for cuticle development and has a phenotype characterized by short, fat animals relative to wild type (Brenner 1974).
A universal STOP-IN allele of
Cbr-dpy-10,
sy1387, was generated and confirmed by genotype sequencing. The expected phenotype was subsequently observed, consistent with the creation of a null allele (Figure 1). Surprisingly,
sy1387 is dominant. Injections of 20 animals produced 15 successful injections; 247 animals from these 15 injections (F1) were singled out and allowed to self-fertilize to produce F2. 81% of the F1 Dumpy progeny were homozygous as evidenced by their segregation of only Dumpy progeny one of these candidates became
sy1387. 2% of the F1s did not produce progeny. 17% of the 247 F1 Dumpy progeny were heterozygotes and had a mixture of Dumpy and non-Dumpy progeny; these non-Dumpy F2s only produced non-Dumpy progeny. This discovery of a dominant mutation will allow for more effective use of this as a co-conversion marker when screening for other mutations. We used
Cbr-dpy-10 as a potential co-CRISPR marker for a second target that will be described elsewhere. We used PCR to detect insertion of a STOP-IN cassette at this other locus; we screened 39 Dumpy strains to obtain 11 candidates for our target gene, from which we have three STOP-IN alleles.