The Stellate meiotic drive system of Drosophila melanogaster is active in contemporary populations

Meiotic drivers are selfish elements that bias their own transmission so that they are overrepresented among the functional gametes produced. The selective costs imposed by drivers on their hosts may trigger intragenomic conflict, promoting the evolution of suppressors and fueling an ongoing arms race between drivers and suppressors. Stellate (Ste) is an X-linked tandemly arrayed multicopy gene. Its copy number ranges from 3 to more than 300 among Drosophila melanogaster strains from the Global Diversity Lines. In wild-type animals, Ste expression is usually suppressed by homologous piRNAs produced from the Suppressor of Stellate (Su(Ste)) array on the Y chromosome. Derepression of Ste in the absence Su(Ste) results in the formation of proteinaceous crystals in spermatocytes, chromatin compaction defects, reductions in fertility, and female-biased sex ratios arising from under-recovery of Y-bearing sperm. Despite extensive study, the function of the Stellate array and evolutionary significance of its persistence in the genome have remained elusive. It has been suggested to be a now-inactive relic of an ancient meiotic drive system, as perturbations in lab stocks can produce Ste-mediated meiotic distortions. Meiotic drive occurring among natural variants, however, has not been reported. We established crosses between females with high Ste copy number X chromosomes and males carrying low Su(Ste) copy number Y chromosomes and found that the male progeny displayed non-Mendelian sex chromosome transmission. Importantly, deletion of the euSte array in an otherwise matched genetic background rescues this phenotype, demonstrating that Stellate is an active driver in contemporary populations.