Neurogenetic evidence that Dilp8 promotes developmental-stability via Lgr3-neuron oscillation

The ability to achieve a species-specific size and proportion despite developmental or environmental perturbations is termed developmental stability. The molecular and cellular processes behind this are best understood in insects. In Drosophila, a peripheral-tissue stress signal, the relaxin/insulin-like peptide Dilp8, promotes developmental stability during larval development via its neuronal receptor, Lgr3, an ortholog of vertebrate relaxin receptors. Lgr3 signaling is widely accepted to occur in–and to activate (depolarize)–the central brain growth-coordinating interneurons (PIL/GCL neurons). Here, using neurogenetic approaches, we confirm the requirement of Lgr3 in PIL/GCL neurons, but unexpectedly find that they require both silenced (hyperpolarized) and active (depolarized) states for an appropriate response to Dilp8. These results are most simply explained if Lgr3 activation by Dilp8 triggers PIL/GCL-neuron oscillatory activity, and such oscillations promote developmental stability. PIL/GCL neurons express and require Cyclin A–which can form cell-cycle oscillator complexes with cyclin-dependent kinases–for their response to Dilp8, independently of Rca1 (regulator of CycA)/Emi1 (early mitotic inhibitor). This opens the possibility that cell-cycle machinery can be co-opted for postmitotic neuron oscillations, adding to an increasing list of postmitotic roles for cyclins. Neuroanatomically, we show that PIL/GCL neurons form reciprocally-innervating loops, which are common architectures in oscillating circuits and central pattern generators. The role of PIL/GCL neurons in developmental stability mirrors other homeostasis-regulating, peptide-driven oscillatory circuits found in the vertebrate hypothalamus, a developmentally-homologous region to the one occupied by PIL/GCL neurons in the fly brain.