Sexually dimorphic traits and male-specific differentiation are actively regulated by Doublesex during specific developmental windows in Nasonia vitripennis

Abstract Sexually dimorphic traits in insects are rapidly evolving due to sexual selection which can ultimately lead to speciation. However, our knowledge of the underlying sex-specific molecular mechanisms is still scarce. Here we show that the highly conserved gene, Doublesex (Dsx), regulates rapidly diverging sexually dimorphic traits in the model parasitoid wasp Nasonia vitripennis (Hymenoptera: Pteromalidae). We present here the revised full Dsx gene structure with an alternative first exon, and two additional male NvDsx isoforms, which gives important insights into the evolution of the sex-specific oligomerization domains and C-termini. We show the sex-specific NvDsx expression throughout development, and demonstrate that transient NvDsx silencing in different male developmental stages dramatically shifts the morphology of two sexually dimorphic traits from male to female, with the effect being dependent on the timing of silencing. In addition, transient silencing of NvDsx in early male larvae affects male genitalia tissue growth but not morphology. This indicates that male NvDsx is actively required to suppress female-specific traits and to promote male-specific traits during specific developmental windows. These results also strongly suggest that in N. vitripennis most sex-specific tissues fully differentiate in the embryonic stage and only need the input of NvDsx for growth afterwards. This provides a first insight into the regulatory activity of Dsx in the Hymenoptera and will help to better understand the evolutionary and molecular mechanisms involved in sex-specific development in this parasitoid wasp, which can eventually lead to the development of new synthetic genetics-based tools for biological pest control by parasitoid wasps. Significance StatementIn insects, male and female differentiation is regulated by the highly conserved transcription factor Doublesex (Dsx). The role of Dsx in regulating rapidly evolving sexually dimorphic traits has received less attention, especially in wasps and bees. Here, we mainly focused on Dsx regulation of two sexually dimorphic traits and male genitalia morphology in the parasitoid wasp, Nasonia vitripennis. We demonstrate that Dsx actively regulates male-specific tissue growth and morphology during specific developmental windows. These findings will help to better understand the molecular mechanisms underlying the rapid evolution of sexual differentiation and sexually dimorphic traits in insects, but may also be the starting point for the development of new tools for biological control of pest insects by parasitoid wasps.