FGFR/Heartless and Smog interact synergistically to negatively regulate Fog mediated GPCR signaling

Abstract

AbstractG-protein coupled receptor (GPCR) signaling triggered by Folded gastrulation (Fog) is one of the pathways known to regulate glial organization and morphogenesis in the embryonic CNS in Drosophila. Fog is best known for its role in epithelial morphogenesis during gastrulation. Here, the signaling pathway includes GPCRs Mist and Smog and the G-Protein Concertina (Cta) which activate downstream effectors to bring about cytoskeletal changes essential for cell shape changeIn this study, we identify molecular players that mediate and serve as important regulators of Fog signaling in the embryonic CNS. We find that while Cta is essential for Fog signaling neither receptors, Mist nor Smog mediates signaling in the CNS. On the contrary, we find that Smog functions as a negative regulator of the pathway. Surprisingly, Heartless which encodes a fibroblast growth factor receptor, also functions as a negative regulator of Fog signaling. Further, we find that both heartless and smog interact in a synergistic manner to regulate Fog signaling.This study thus identifies novel regulators of Fog signaling that may play an important role in fine-tuning the pathway to control cell morphogenesis. It also suggests the likelihood of there being multiple receptors for Fog that mediate and regulate signaling in a context specific manner.Author SummaryIn Drosophila, Folded gastrulation (Fog) functions as ligand that signals via GPCRs to regulate cell shape during gastrulation -one of the earliest events in embryogenesis. Here, Fog signals via receptors Mist and Smog to activate the G-protein Concertina to elicit change in cell shape. In the embryonic central nervous system (CNS) this pathway regulates shape and organization of glia important for functions such as insulation of neurons and synapses.The mechanism of Fog signal transduction in the CNS and its regulation is not well understood. We have sought to address these questions in our study. We find that Concertina is an essential factor for Fog signaling in the CNS but interestingly Mist is not. In contrast, Smog functions as a negative regulator such that loss of Smog enhances Fog signaling. A similar role is played by the receptor tyrosine kinase-Heartless. Interestingly, we find that Smog and Heartless interact as part of a common genetic network to regulate Fog signaling. Our results thus provide novel insights into the regulation of Fog signaling and shed light on how signaling can be fine-tuned in a context dependent manner to control cell shape change which plays a critical role during development and organ formation.