How multicellular organisms maintain immune homeostasis across various organs and cell types is an outstanding question in immune biology and cell signaling. In Drosophila, blood cells (hemocytes) respond to local and systemic cues to mount an immune response. While endosomal regulation of Drosophila hematopoiesis is reported, the role of endosomal proteins in cellular and humoral immunity is not well-studied. Here we demonstrate a functional role for endosomal proteins in immune homeostasis. We show that the ubiquitous trafficking protein ADP Ribosylation Factor 1 (ARF1) and the hemocyte-specific endosomal regulator Asrij differentially regulate humoral immunity. Asrij and ARF1 play an important role in regulating the cellular immune response by controlling the crystal cell melanization and phenoloxidase activity. ARF1 and Asrij mutants show reduced survival and lifespan upon infection, indicating perturbed immune homeostasis. The ARF1-Asrij axis suppresses the Toll pathway anti-microbial peptides (AMPs) by regulating ubiquitination of the inhibitor Cactus. The Imd pathway is inversely regulated- while ARF1 suppresses AMPs, Asrij is essential for AMP production. Several immune mutants have reduced Asrij expression, suggesting that Asrij co-ordinates with these pathways to regulate the immune response. Our study highlights the role of endosomal proteins in modulating the immune response by maintaining the balance of AMP production. Similar mechanisms can now be tested in mammalian hematopoiesis and immunity.
Mitochondria are highly dynamic organelles whose activity is an important determinant of blood stem and progenitor cell state. Mitochondrial morphology is maintained by continuous fission and fusion and affects stem cell proliferation, differentiation, and aging. However, the mechanism by which mitochondrial morphology and dynamics regulate cell differentiation and lineage choice remains incompletely understood. Asrij/OCIAD1 is a conserved protein that governs mitochondrial morphology, energy metabolism and human embryonic stem cell (hESC) differentiation. To investigate the in vivo relevance of these properties, we compared hESC phenotypes with those of Drosophila hematopoiesis, where Asrij is shown to regulate blood progenitor maintenance by conserved mechanisms. In concordance with hESC studies, we found that Drosophila Asrij also localizes to mitochondria of larval blood cells and its depletion from progenitors results in elongated mitochondria. Live imaging of asrij knockdown hemocytes and of OCIAD1 knockout hESCs showed reduced mitochondrial dynamics. Since key regulators of mitochondrial dynamics actively regulate mitochondrial morphology, we hypothesized that mitochondrial fission and fusion may control progenitor maintenance or differentiation in an Asrij-dependent manner. Knockdown of the fission regulator Drp1 in Drosophila lymph gland progenitors specifically suppressed crystal cell differentiation whereas depletion of the fusion regulator Marf (Drosophila Mitofusin) increased the same with concomitant upregulation of Notch signaling. These phenotypes were stronger in anterior progenitors and were exacerbated by Asrij depletion. Asrij is known to suppress Notch signaling and crystal cell differentiation. Our analysis reveals that synergistic interactions of Asrij with Drp1 and Marf have distinct impacts on lymph gland progenitor mitochondrial dynamics and crystal cell differentiation. Taken together, using invertebrate and mammalian model systems we demonstrate a conserved role for Asrij/OCIAD1 in linking mitochondrial dynamics and progenitor differentiation. Our study sets the stage for deciphering how regulators of mitochondrial dynamics may contribute to functional heterogeneity and lineage choice in vertebrate blood progenitors.
Identification of molecules and processes that regulate hematopoiesis using Drosophila lymph gland (LG) as a model, is important for widening its scope and applicability as a tool to understand mechanisms regulating blood cell homeostasis. Using Asrij modulation, we compared the LG proteome under conditions that maintain precursors or promote differentiation in vivo and identified conserved as well as additional regulators of Drosophila hematopoiesis. The LG proteome provides an invaluable resource for studying insect as well as vertebrate blood cell development.
Tissue heterogeneity permits diverse biological outputs in response to systemic signals but requires context-dependent spatiotemporal regulation of a limited number of signaling circuits. In addition to their stereotypical roles of transport and cargo sorting, endocytic networks provide rapid, adaptable, and often reversible means of signaling. Aberrant function of the Endosomal Sorting Complex Required for Transport (ESCRT) components results in ubiquitinated cargo accumulation, uncontrolled signaling and neoplastic transformation. However, context-specific effects of ESCRT on developmental decisions are not resolved. By a comprehensive spatiotemporal profiling of ESCRT in Drosophila hematopoiesis in vivo, here we show that pleiotropic ESCRT components have distinct effects on blood progenitor maintenance, lineage choice and response to immune challenge. Of all 13 core ESCRT components tested, only Vps28 and Vp36 were required in all progenitors, whereas others maintained spatiotemporally defined progenitor subsets. ESCRT depletion also sensitized posterior progenitors that normally resist differentiation, to respond to immunogenic cues. Depletion of the critical Notch signaling regulator Vps25 did not promote progenitor differentiation at steady state but made younger progenitors highly sensitive to wasp infestation, resulting in robust lamellocyte differentiation. We identify key heterotypic roles for ESCRT in controlling Notch activation and thereby progenitor proliferation and differentiation. Further, we show that ESCRT ability to regulate Notch activation depends on progenitor age and position along the anterior-posterior axis. The phenotypic range and disparity in signaling upon depletion of components provides insight into how ESCRT may tailor developmental diversity. These mechanisms for subtle control of cell phenotype may be applicable in multiple contexts.SignificanceThe Endosomal Sorting Complex Required for Transport (ESCRT) machinery sorts ubiquitinated cargo for degradation or recycling. Aberrant ESCRT function is associated with many blood disorders. We did a comprehensive functional analysis of all 13 core ESCRT components in maintenance and differentiation of Drosophila larval blood progenitors. We show that ESCRT have diverse and non-compensatory functions in blood progenitors. ESCRT depletion from progenitors affects ubiquitination status cell autonomously and independent of progenitor maintenance. ESCRT function is more critical to maintain older progenitors and to prevent Notch-dependent crystal cell differentiation. Further, ESCRT depletion sensitizes refractile younger progenitors for lamellocyte differentiation. Our in situ developmental map of ESCRT function reveals critical checkpoints for cell fate choice and new paradigms for generating progenitor heterogeneity.
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