A number of reagents have been generated for CRISPR/Cas9 genome editing in Drosophila (Gratz et al. 2014; Ren et al. 2013; Kondo and Ueda 2013; Port et al. 2014; Port and Bullock 2016). The ability to efficiently express multiple gRNAs from a single vector provides the advantage of creating multiple CRISPR/Cas9 alleles at a time. An elegant design has previously shown that gRNAs separated by tRNAs allow for genomic editing at multiple loci in Drosophila (Port and Bullock 2016). We generated a similar polycistronic gRNA cassette under the control of the Drosophila snRNA:U6:96Ac (U6:3) regulatory sequences. Individual gRNAs were separated by the Drosophila tRNA:His-GTG-1-4 tRNA (tRNAHis) and targeted the genes yellow (y), crossveinless (cv), vermilion (v), forked (f), and carnation (car) along the X chromosome (A). In theory, after expression of the gRNA cassette, the tRNAs should lead to the formation of secondary RNA structures and be recognized for cleavage by RNase enzymes P and Z (Frendewey et al. 1985; Dubrovsky et al. 2004), releasing the gRNAs for incorporation into Cas9. The gRNA cassette (U6:3-tRNAHis-gRNAy,cv,v,f,car) was stably integrated into the Drosophila genome and crossed to a Cas9 line under the control of the Act5C promoter (Zhang, Koolhaas, and Schnorrer 2014). Females with the genotype Act5c-Cas9/FM7c; U6:3-tRNAHis-gRNAy,cv,v,f,car/+ showed y-, cv-, and f- phenotypes while females with the genotype
y1 w1/FM7c; U6:3-tRNAHis-gRNAy,cv,v,f,car/+ were wild type. We also conducted experiments with a wild type X chromosome in the place of the FM7c balancer chromosome. Results from these experiments were the same, with only evidence for y-, cv-, and f- phenotypes and all females were v+ and car+. We then decided to outcross Act5c-Cas9/FM7c; U6:3-tRNAHis-gRNAy,cv,v,f,car/+ females to a
y1 cv1 v1 f1 stock and score germline transmission of editing at y, cv, and f, on the FM7c balancer chromosome (FM7c = In(1)FM7,
y31d
sc8 wa snX2 vOf
g4 B1). We could not score v since FM7c is vOf and also did not score car since we lacked evidence for car phenotypes based on the wild type X experiments. Germline transmission of mutants resulted in 14% of progeny not mutant at any locus, 40% were mutant at one locus, 40% were mutant at two loci, and 6% were mutant at three loci (B). We sequenced the gRNA targeted genomic sites of y, cv, v, f, and car of two phenotypically y+ cv- f- and two y- cv- f- balancers to compare with the original FM7c chromosome. All flies contained out-of-frame indels at the loci consistent with their phenotypes. None of the flies had mutations at v, and one fly had an in-frame indel at car (C). We are unsure why these flies did not show a car- phenotype, however, our sequencing results indicate that germline transmission of editing events did occur at the car locus. Our data suggests that gRNAs targeting y, cv, f, and car were cleaved from the cassette and loaded into Cas9 allowing for subsequent genomic editing. The ability to express multiple gRNAs from a single vector offers advantages over traditional gRNA vectors for Drosophila and will allow researchers to expand their experimental repertoire for CRISPR/Cas9 genome editing. Practically, polycistronic gRNA vectors can be used to quickly generate and expand new balancer genotypes, that would otherwise be difficult and time-consuming through traditional methods.