Mutual repression between JNK/AP-1 and JAK/STAT stratifies cell behaviors during tissue regeneration

Abstract

AbstractEpithelial repair relies on the activation of stress signaling pathways to coordinate cellular repair behaviors. Their deregulation is implicated in chronic wound and cancer pathologies. Despite such translational importance, an understanding of how spatial patterns of signaling pathways and repair behaviors arise in damaged tissues remains elusive. Using TNF-α/Eiger-mediated inflammatory damage to Drosophila imaginal discs, we uncover that JNK/AP-1 signaling cells act as paracrine organizers and initiate a mutual repression network that spatially segregates JNK/AP-1 and JAK/STAT signaling cells into distinct populations. While JNK/AP-1 signaling cells produce JAK/STAT-activating Upd ligands, these signal-sending cells suppress activation of JAK/STAT via Ptp61F. Conversely, responding cells with activated JAK/STAT suppress JNK activation via Zfh2. The resulting bistable segregation of signaling domains is associated with distinct cellular tasks and regenerative potential. While JNK/AP-1 signaling cells at the wound center act as paracrine organizers, their cell cycle is senescently arrested. Thus, compensatory proliferation occurs exclusively in JAK/STAT signaling cells at the wound periphery. This spatial stratification is essential for proper tissue repair, as co-activation of JNK/AP-1 and JAK/STAT in the same cells creates conflicting inputs on cell cycle progression, leading to excess apoptosis of senescently arrested organizer cells. Finally, we demonstrate that bistable spatial segregation of JNK/AP-1 and JAK/STAT drives senescent and proliferative behaviors in transient as well as chronic tissue damage models, and importantly, in RasV12, scrib tumors under the influence of JNK/AP-1 activity. Revealing this previously uncharacterized regulatory network between JNK/AP-1, JAK/STAT and associated cell behaviors have important implications for our conceptual understanding of tissue repair, chronic wound pathologies and tumor microenvironments, where both pathways are strongly implicated.