The Y chromosome gene draupnir reveals constraints on engineering Y-linked sex-ratio distorters in malaria mosquitoes

Y chromosome sex distorters offer a powerful strategy for mosquito population suppression, but their implementation is constrained by the transcriptional silencing of Y-linked transgenes during spermatogenesis. To investigate how endogenous Y genes evade this repression, we characterized draupnir (formerly YG5 ), a multicopy Y-linked gene of Anopheles gambiae encoding a Zip3-like meiotic protein. Comparative genomic and phylogenetic analyses revealed that draupnir originated through duplication of the autosomal paralog skirnir , itself derived from the ancestral recombination factor vilya , followed by amplification into a tandem array on the Y chromosome. We show that draupnir is actively transcribed during meiosis, making it the only known Y-linked gene expressed during mosquito spermatogenesis.

To test whether its regulatory region is sufficient to confer sperm-specific expression from the Y chromosome, we cloned the draupnir promoter to drive expression of an X-chromosome shredder. When inserted on an autosome, the construct drove meiotic expression and strong sex-ratio distortion in the progeny of transgenic males. In contrast, the same construct inserted on the Y chromosome was transcriptionally silent and produced balanced sex ratios. These results demonstrate that draupnir expression depends on its native genomic context within a multicopy Y-linked array and that its promoter alone cannot overcome transcription silencing. Our findings reveal a fundamental constraint on Y-chromosome-based genetic control strategies and point to future approaches for enabling transcription from otherwise repressed sex chromosomes.