Abstract
BackgroundGut homeostasis is central to whole organism health, and its disruption is associated with a broad range of pathologies. Following damage, complex physiological events are required in the gut to maintain proper homeostasis. Previously, we demonstrated that ingestion of a nonlethal pathogen, Erwinia carotovora carotovora 15, induces a massive increase in stem cell proliferation in the gut of Drosophila. However, the precise cellular events that occur following infection have not been quantitatively described, nor do we understand the interaction between multiple pathways that have been implicated in epithelium renewal.ResultsTo understand the process of infection and epithelium renewal in more detail, we performed a quantitative analysis of several cellular and morphological characteristics of the gut. We observed that the gut of adult Drosophila undergoes a dynamic remodeling in response to bacterial infection. This remodeling coordinates the synthesis of new enterocytes, their proper morphogenesis and the elimination of damaged cells through delamination and anoikis. We demonstrate that one signaling pathway, the epidermal growth factor receptor (EGFR) pathway, is key to controlling each of these steps through distinct functions in intestinal stem cells and enterocytes. The EGFR pathway is activated by the EGF ligands, Spitz, Keren and Vein, the latter being induced in the surrounding visceral muscles in part under the control of the Janus kinase/signal transducer and activator of transcription (JAK/STAT) pathway. Additionally, the EGFR pathway synergizes with the JAK/STAT pathway in stem cells to promote their proliferation. Finally, we show that the EGFR pathway contributes to gut morphogenesis through its activity in enterocytes and is required to properly coordinate the delamination and anoikis of damaged cells. This function of the EGFR pathway in enterocytes is key to maintaining homeostasis, as flies lacking EGFR are highly susceptible to infection.ConclusionsThis study demonstrates that restoration of normal gut morphology following bacterial infection is a more complex phenomenon than previously described. Maintenance of gut homeostasis requires the coordination of stem cell proliferation and differentiation, with the incorporation and morphogenesis of new cells and the expulsion of damaged enterocytes. We show that one signaling pathway, the EGFR pathway, is central to all these stages, and its activation at multiple steps could synchronize the complex cellular events leading to gut repair and homeostasis.
Highlights
Gut homeostasis is central to whole organism health, and its disruption is associated with a broad range of pathologies
We further demonstrate that one signaling pathway, the epidermal growth factor receptor (EGFR) pathway, is key to controlling these three cellular and morphogenetic events, ensuring gut homeostasis following infection
Infection with Erwinia carotovora carotovora 15 (Ecc15) induces a major remodeling of the gut To understand the precise cellular events that occur in the gut following infection, we performed a quantitative analysis of gut remodeling following the ingestion of Ecc15
Summary
Gut homeostasis is central to whole organism health, and its disruption is associated with a broad range of pathologies. An important function of epithelial surfaces is to maintain the barrier between an organism’s internal and external environments This is especially true for the gut epithelium because of the magnitude of its surface and Drosophila adult midgut is sustained by intestinal stem cells (ISCs), which self-renew and produce a population of nondividing, undifferentiated ISC daughters, termed enteroblasts [4,5]. The turnover of enterocytes is continuous, and it is thought that the entire Drosophila gut epithelium is renewed in 7 to 10 days [5] In addition to this function in basal maintenance, epithelial renewal is critical in the host response to acute damage to the gut. These studies identified natural stimuli that provoke ISC activation, providing a powerful model system to study epithelium renewal and its genetic control
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