De novo apical domain formation inside the Drosophila adult midgut epithelium

In the adult Drosophila midgut, basal intestinal stem cells give rise to enteroblasts that integrate into the epithelium as they differentiate into enterocytes. Integrating enteroblasts must generate a new apical domain and break through the septate junctions between neighboring enterocytes, while maintaining barrier function. We observe that enteroblasts form an apical membrane initiation site when they reach the septate junction between the enterocytes. Cadherin clears from the apical surface and an apical space appears above the enteroblast. New septate junctions then form laterally with the enterocytes and the AMIS develops into pre-apical compartment before it has a free apical surface in contact with the gut lumen. Finally, the enterocyte septate junction dissolves and the pre-enterocyte reaches the gut lumen with a fully-formed brush border. The process of enteroblast integration resembles lumen formation in mammalian epithelial cysts, highlighting the similarities between the fly midgut and mammalian epithelia.

Ecdysone regulates the Drosophila imaginal disc epithelial barrier, determining the length of regeneration checkpoint delay

ABSTRACT Regeneration of Drosophila imaginal discs, larval precursors to adult tissues, activates a regeneration checkpoint that coordinates regenerative growth with developmental progression. This regeneration checkpoint results from the release of the relaxin-family peptide Dilp8 from regenerating imaginal tissues. Secreted Dilp8 protein is detected within the imaginal disc lumen, in which it is separated from its receptor target Lgr3, which is expressed in the brain and prothoracic gland, by the disc epithelial barrier. Here, we demonstrate that following damage the imaginal disc epithelial barrier limits Dilp8 signaling and the duration of regeneration checkpoint delay. We also find that the barrier becomes increasingly impermeable to the transepithelial diffusion of labeled dextran during the second half of the third instar. This change in barrier permeability is driven by the steroid hormone ecdysone and correlates with changes in localization of Coracle, a component of the septate junctions that is required for the late-larval impermeable epithelial barrier. Based on these observations, we propose that the imaginal disc epithelial barrier regulates the duration of the regenerative checkpoint, providing a mechanism by which tissue function can signal the completion of regeneration.

A novel membrane protein Hoka regulates septate junction organization and stem cell homeostasis in the Drosophila gut

Smooth septate junctions (sSJs) regulate the paracellular transport in the intestinal and renal system in arthropods. In Drosophila, the organization and physiological function of sSJs are regulated by at least three sSJ-specific membrane proteins: Ssk, Mesh, and Tsp2A. Here, we report a novel sSJ membrane protein Hoka, which has a single membrane-spanning segment with a short extracellular region having 13-amino acids, and a cytoplasmic region with three repeats of the Tyr-Thr-Pro-Ala motif. The larval midgut in hoka-mutants shows a defect in sSJ structure. Hoka forms a complex with Ssk, Mesh, and Tsp2A and is required for the correct localization of these proteins to sSJs. Knockdown of hoka in the adult midgut leads to intestinal barrier dysfunction, stem cell overproliferation, and epithelial tumors. In hoka-knockdown midguts, aPKC is up-regulated in the cytoplasm and the apical membrane of epithelial cells. The depletion of aPKC and yki in hoka-knockdown midguts results in reduced stem cell overproliferation. These findings indicate that Hoka cooperates with the sSJ-proteins Ssk, Mesh, and Tsp2A to organize sSJs, and is required for maintaining intestinal stem cell homeostasis through the regulation of aPKC and Yki activities in the Drosophila midgut.Summary statementDepletion of hoka, a gene encoding a novel septate junction protein, from the Drosophila midgut results in the disruption of septate junctions, intestinal barrier dysfunction, stem cell overproliferation, and epithelial tumors.

Tetanus neurotoxin sensitive SNARE-mediated glial signaling limits motoneuronal excitability

Peripheral nerves contain motoneuron axons coated by glial cells, which essentially contribute to function but cellular reactions remain poorly understood. We here identify non-neuronal Synaptobrevin (Syb) as the essential vesicular SNARE in glia to insulate and metabolically supply Drosophila motoneurons. Interfering with Syb-functionality by glial knockdown, or glial expression of tetanus neurotoxin light chain (TeNT-LC) caused motonerve disintegration, blocked axonal transport, induced tetanic muscle hyperactivity and caused lethal paralysis. Surprisingly, not the established TeNT-LC-target, neuronal Synaptobrevin (nSyb), is the relevant SNARE, but non-neuronal Synaptobrevin (Syb): Knockdown of Syb- (but not nSyb-) phenocopied glial TeNT-LC expression whose effects were reverted by a TeNT-LC-insensitive Syb mutant. We link Syb-necessity to two distinct glia: to establish nerve insulating septate junctions in subperineurial glia and to integrate monocarboxylate transporters along the nerve in wrapping glia for motoneuronal metabolic supply. Our study identifies crucial roles of Syb in glial subtypes for nerve function and pathology, animal motility and survival.

The septate junction protein Tetraspanin 2A is critical to the structure and function of Malpighian tubules in Drosophila melanogaster

Tetraspanin-2A (Tsp2A) is an integral membrane protein of smooth septate junctions in Drosophila melanogaster. To elucidate its structural and functional roles in Malpighian tubules, we used the c42-GAL4/UAS system to selectively knock down Tsp2A in principal cells of the tubule. Tsp2A localizes to smooth septate junctions (sSJ) in Malpighian tubules in a complex shared with partner proteins Snakeskin (Ssk), Mesh, and Discs large (Dlg). Knockdown of Tsp2A led to the intracellular retention of Tsp2A, Ssk, Mesh, and Dlg, gaps and widening spaces in remaining sSJ, and tumorous and cystic tubules. Elevated protein levels together with diminished V-type H+-ATPase activity in Tsp2A knockdown tubules are consistent with cell proliferation and reduced transport activity. Indeed, Malpighian tubules isolated from Tsp2A knockdown flies failed to secrete fluid in vitro. The absence of significant transepithelial voltages and resistances manifests an extremely leaky epithelium that allows secreted solutes and water to leak back to the peritubular side. The tubular failure to excrete fluid leads to extracellular volume expansion in the fly and to death within the first week of adult life. Expression of the c42-GAL4 driver begins in Malpighian tubules in the late embryo and progresses upstream to distal tubules in third instar larvae, which can explain why larvae survive Tsp2A knockdown and adults do not. Uncontrolled cell proliferation upon Tsp2A knockdown confirms the role of Tsp2A as tumor suppressor in addition to its role in sSJ structure and transepithelial transport.

Interplay between Anakonda, Gliotactin and M6 for tricellular junction assembly and anchoring of septate junctions in Drosophila epithelium

SummaryIn epithelia, Tricellular junctions (TCJs) serve as pivotal sites for barrier function and integration of both biochemical and mechanical signals. While essential for tissue homeostasis, TCJ assembly, composition and links to adjacent bicellular junctions (BCJs) remain poorly understood. Here we have characterized the assembly of TCJs within the plane of adherens junctions (tAJ) and the plane of septate junctions (tSJ) in Drosophila and report that their formation is spatiotemporally decoupled. The assembly and stabilization of previously described tSJ components Anakonda (Aka) and Gliotactin (Gli) as well as the newly reported tSJ proteolipid protein M6, is shown to be a complex process. Aka and M6, whose localization is interdependent, act upstream to locate Gli. In turn, Gli stabilizes Aka at tSJ. Those results unravel a previous unknown role of M6 at tSJ and a tight interplay between tSJ components to assemble and maintain tSJs. In addition, tSJ components are not only essential at vertex as we found that loss of tSJ integrity also induces micron-length bicellular SJs deformations that are free of tensile forces. This phenotype is associated with the disappearance of SJ components at tricellular contacts, indicating that bSJ are no longer connected to tSJs. Reciprocally, SJ components are in turn required to restrict the localization of Aka and Gli at vertex. We propose that tSJs function as pillars to anchor bSJs to ensure the maintenance of tissue integrity in Drosophila proliferative epithelia.