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Abstract The copackaging of mRNAs into biomolecular condensates called germ granules is a conserved strategy to posttranscriptionally regulate germline mRNAs. In Drosophila melanogaster, mRNAs accumulate in germ granules by forming homotypic clusters, aggregates containing multiple transcripts from the same gene. Nucleated by Oskar (Osk), homotypic clusters are generated through a stochastic seeding and self-recruitment process that requires the 3′ untranslated region (UTR) of germ granule mRNAs. Interestingly, the 3′ UTR belonging to germ granule mRNAs, such as nanos (nos), have considerable sequence variations among Drosophila species and we hypothesized that this diversity influences homotypic clustering. To test our hypothesis, we investigated the homotypic clustering of nos and polar granule component (pgc) in four Drosophila species and concluded that clustering is a conserved process used to enrich germ granule mRNAs. However, we discovered germ granule phenotypes that included significant changes in the abundance of transcripts present in species’ homotypic clusters, which also reflected diversity in the number of coalesced primordial germ cells within their embryonic gonads. By integrating biological data with computational modeling, we found that multiple mechanisms underlie naturally occurring germ granule diversity, including changes in nos, pgc, osk levels and/or homotypic clustering efficacy. Furthermore, we demonstrated how the nos 3′ UTR from different species influences nos clustering, causing granules to have ∼70% less nos and increasing the presence of defective primordial germ cells. Our results highlight the impact that evolution has on germ granules, which should provide broader insight into processes that modify compositions and activities of other classes of biomolecular condensate. 

Abstract The diversity among Drosophila species presents an opportunity to study the molecular mechanisms underlying the evolution of biological phenomena. A challenge to investigating these species is that, unlike the plethora of molecular and genetics tools available for D. melanogaster research, many other species do not have sequenced genomes; a requirement for employing these tools. Selecting transgenic flies through white (w) complementation has been commonly practiced in numerous Drosophila species. While tolerated, the disruption of w is associated with impaired vision, among other effects in D. melanogaster. The D. nebulosa fly has a unique mating behavior which requires vision, and is thus unable to successfully mate in dark conditions. Here, we hypothesized that the disruption of w will impede mating success. As a first step, using PacBio long-read sequencing, we assembled a high-quality annotated genome of D. nebulosa. Using these data, we employed CRISPR/Cas9 to successfully disrupt the w gene. As expected, D. nebulosa males null for w did not court females, unlike several other mutant strains of Drosophila species whose w gene has been disrupted. In the absence of mating, no females became homozygous null for w. We conclude that gene disruption via CRISPR/Cas9 genome engineering is a successful tool in D. nebulosa, and that the w gene is necessary for mating. Thus, an alternative selectable marker unrelated to vision is desirable.