The objectives were to identify the receptor for Dilp8, to identify the target tissue mediating Dilp8 action on developmental timing, and finally to characterize the role of Dilp8 in the coordination of tissue growth.
We conducted a functional genetic screen that led us to the identification of the relaxin family receptor Lgr3 as the receptor for Dilp8. This objective was achieved by combining the LexA/LexO system, used to overexpress Dilp8 in imaginal discs, with the Gal4/UAS system, used to knock-down a collection of membrane receptors in candidate target tissues. Only the downregulation of Lgr3 in neuronal cells was able to rescue the developmental delay induced by Dilp8 overexpression.
In order to precisely identify the Dilp8-responsive neurons, we investigated lgr3 expression pattern with lgr3-Gal4 tools. By conducting intersection experiments, we functionally identified a single pair of bilateral Lgr3-positive neurons mediating Dilp8 function, referred to as growth coordinating Lgr3 (GCL) neurons. Interestingly, GCL neurons physically interact with PTTH neurons, which are known to project their axons directly onto the prothoracic gland (PG) and control ecdysone production. These results unravel the mechanism by which growing tissues indirectly regulate the production of steroid hormone.
Apart from its effect on developmental timing, the overexpression of Dilp8 in imaginal discs reduces their growth rate. We found that silencing lgr3 in GCL neurons, but not in the wing discs, rescued disc growth inhibition caused by Dilp8 overexpression. This suggests that Dilp8/Lgr3 signaling in GCL neurons could modulate the growth of peripheral tissues in a systemic manner through the control of ecdysone production. Moreover, analysis of fluctuating asymmetry revealed that Dilp8/Lgr3 signaling in the two GCL neurons is required for the maintenance of bilateral symmetry and the control of developmental variability.
This work was published in Current Biology, and an article written in French for a non-specialized audience was published in Médecine/Sciences. This work was also presented at the 24th European Drosophila Research Conference, at the 30th Annual French Drosophila Conference and at the 5th Drosophila growth and regeneration meeting.
In addition, we are currently addressing the role of Dilp8 in the inter-organ coordination (IOC) of growth. When growth of one imaginal disc domain is perturbed, other domains and other discs slow down their growth, maintaining proper inter-disc and intra-disc proportions. We show that Dilp8 is required for IOC. Our work also reveals that the stress-response transcription factor Xrp1 is a key player in IOC upstream of dilp8. These observations indicate that Xrp1 and Dilp8 constitute a new independent regulatory module that ensures growth coordination during development.