Lysosomes receive and degrade cargo from endocytosis, phagocytosis and autophagy. They also play an important role in sensing and instructing cells on their metabolic state. The lipid kinase PIKfyve generates phosphatidylinositol-3,5-bisphosphate to modulate lysosome function. PIKfyve inhibition leads to impaired degradative capacity, ion dysregulation, abated autophagic flux and a massive enlargement of lysosomes. Collectively, this leads to various physiological defects, including embryonic lethality, neurodegeneration and overt inflammation. The reasons for such drastic lysosome enlargement remain unclear. Here, we examined whether biosynthesis and/or fusion-fission dynamics contribute to swelling. First, we show that PIKfyve inhibition activates TFEB, TFE3 and MITF, enhancing lysosome gene expression. However, this did not augment lysosomal protein levels during acute PIKfyve inhibition, and deletion of TFEB and/or related proteins did not impair lysosome swelling. Instead, PIKfyve inhibition led to fewer but enlarged lysosomes, suggesting that an imbalance favouring lysosome fusion over fission causes lysosome enlargement. Indeed, conditions that abated fusion curtailed lysosome swelling in PIKfyve-inhibited cells.
Summary Macrophages internalize pathogens through phagocytosis, entrapping them into organelles called phagosomes. Phagosomes then fuse with lysosomes to mature into phagolysosomes, acquiring an acidic and hydrolytic lumen that kills the pathogens. During an ongoing infection, macrophages can internalize dozens of bacteria. Thus, we hypothesized that an initial round of phagocytosis might boost lysosome function and bactericidal ability to cope with subsequent rounds of phagocytosis. To test this hypothesis, we employed Fcγ receptor-mediated phagocytosis and endocytosis, which respectively internalize immunoglobulin G (IgG)-opsonized particles and polyvalent IgG immune complexes. We report that Fcγ receptor activation in macrophages enhanced lysosome-based proteolysis and killing of subsequently phagocytosed E. coli compared to naïve macrophages. Importantly, we show that Fcγ receptor activation caused nuclear translocation of TFEB, a transcription factor that boosts expression of lysosome genes. Indeed, Fc receptor activation was accompanied by increased expression of specific lysosomal proteins. Remarkably, TFEB silencing repressed the Fcγ receptor-mediated enhancements in degradation and bacterial killing. In addition, nuclear translocation of TFEB required phagosome completion and failed to occur in cells silenced for MCOLN1, a lysosomal Ca2+ channel, suggesting that lysosomal Ca2+ released during phagosome maturation activates TFEB. Finally, we demonstrated that non-opsonic phagocytosis of E. coli also enhanced lysosomal degradation in a TFEB-dependent manner suggesting that this phenomenon is not limited to Fcγ receptors. Overall, we show that macrophages become better killers after one round of phagocytosis and suggest that phagosomes and lysosomes are capable of bi-directional signaling.
Background: Based on qualitative pH probes, loss of Fab1/PIKfyve was thought to impair vacuolar/lysosomal acidification. Results: Using several quantitative assays, vacuoles/lysosomes remained acidic in Fab1/PIKfyve-inhibited cells in a V-ATPasedependent manner. Conclusion: Fab1/PIKfyve is not necessary to maintain the steady-state vacuolar/lysosomal pH. Significance: Contrary to current thought, we propose a model in which Fab1/PIKfyve is dispensable to maintain vacuolar/ lysosomal acidification.
Phosphoinositides (PtdInsPs) modulate a plethora of functions including signal transduction and membrane trafficking. PtdInsPs are thought to consist of seven interconvertible species that localize to a specific organelle, to which they recruit a set of cognate effector proteins. Here, in reviewing the literature, we argue that this model needs revision. First, PtdInsPs can carry a variety of acyl chains, greatly boosting their molecular diversity. Second, PtdInsPs are more promiscuous in their localization than is usually acknowledged. Third, PtdInsP interconversion is likely achieved through kinase-phosphatase enzyme complexes that coordinate their activities and channel substrates without affecting bulk substrate population. Additionally, we contend that despite hundreds of PtdInsP effectors, our attention is biased toward few proteins. Lastly, we recognize that PtdInsPs can act to nucleate coincidence detection at the effector level, as in PDK1 and Akt. Overall, better integrated models of PtdInsP regulation and function are not only possible but needed.
Neutrophils rapidly arrive at an infection site because of their unparalleled chemotactic ability, after which they unleash numerous attacks on pathogens through degranulation and reactive oxygen species (ROS) production, as well as by phagocytosis, which sequesters pathogens within phagosomes. Phagosomes then fuse with lysosomes and granules to kill the enclosed pathogens. A complex signaling network composed of kinases, GTPases, and lipids, such as phosphoinositides, helps to coordinate all of these processes. There are seven species of phosphoinositides that are interconverted by lipid kinases and phosphatases. PIKfyve is a lipid kinase that generates phosphatidylinositol-3,5-bisphosphate and, directly or indirectly, phosphatidylinositol-5-phosphate [PtdIns(5)P]. PIKfyve inactivation causes massive lysosome swelling, disrupts membrane recycling, and, in macrophages, blocks phagosome maturation. In this study, we explored for the first time, to our knowledge, the role of PIKfyve in human and mouse neutrophils. We show that PIKfyve inhibition in neutrophils does not affect granule morphology or degranulation, but it causes LAMP1 lysosomes to engorge. Additionally, PIKfyve inactivation blocks phagosome-lysosome fusion in a manner that can be rescued, in part, with Ca ionophores or agonists of TRPML1, a lysosomal Ca channel. Strikingly, PIKfyve is necessary for chemotaxis, ROS production, and stimulation of the Rac GTPases, which control chemotaxis and ROS. This is consistent with observations in nonleukocytes that showed that PIKfyve and PtdIns(5)P control Rac and cell migration. Overall, we demonstrate that PIKfyve has a robust role in neutrophils and propose a model in which PIKfyve modulates phagosome maturation through phosphatidylinositol-3,5-bisphosphate-dependent activation of TRPML1, whereas chemotaxis and ROS are regulated by PtdIns(5)P-dependent activation of Rac.
Summary statementPIKfyve inhibition causes lysosomes to coalesce, resulting in fewer, enlarged lysosomes. We also show that TFEB-mediated lysosome biosynthesis does not contribute to swelling.. CC-BY-NC-ND 4.0 International license It is made available under a was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.The copyright holder for this preprint (which . http://dx.doi.org/10.1101/295246 doi: bioRxiv preprint first posted online Apr. 5, 2018; 2 AbstractLysosomes receive and degrade cargo from endocytosis, phagocytosis and autophagy. They also play an important role in sensing and instructing cells on their metabolic state. The lipid kinase PIKfyve generates phosphatidylinositol-3,5-bisphosphate to modulate lysosome function.
Phosphoinositides (PtdInsPs) are essential signaling lipids responsible for recruiting specific effectors and conferring organelles with molecular identity and function. Each of the seven PtdInsPs varies in their distribution and abundance, which are tightly regulated by specific kinases and phosphatases. The abundance of PtdInsPs can change abruptly in response to various signaling events or disturbance of the regulatory machinery. To understand how these events lead to changes in the amount of PtdInsPs and their resulting impact, it is important to quantify PtdInsP levels before and after a signaling event or between control and abnormal conditions. However, due to their low abundance and similarity, quantifying the relative amounts of each PtdInsP can be challenging. This article describes a method for quantifying PtdInsP levels by metabolically labeling cells with 3 H-myo-inositol, which is incorporated into PtdInsPs. Phospholipids are then precipitated and deacylated. The resulting soluble 3 H-glycero-inositides are further extracted, separated by high-performance liquid chromatography (HPLC), and detected by flow scintillation. The labeling and processing of yeast samples is described in detail, as well as the instrumental setup for the HPLC and flow scintillator. Despite losing structural information regarding acyl chain content, this method is sensitive and can be optimized to concurrently quantify all seven PtdInsPs in cells. Video LinkThe video component of this article can be found at
The pertussis vaccination is highly recommended for infants, children, and pregnant women. Despite a high coverage of vaccination, pertussis continues to be of public health concern as a re-emerging infectious disease. The mechanism by which vaccine-elicited anti-pertussis antibodies mediate direct bactericidal effects is poorly understood. In this study, we showed that the interaction of B. pertussis with A549 epithelial cells induce release of biological factors which enhance bacteria growth. Complement-depleted antisera from vaccine-immunized guinea pigs or monoclonal antibodies targeting FHA and FIM mediate bacteria aggregation and elicit bactericidal effects. Our in vitro results indicated that aggregation of bacteria through anti-FIM and anti-FHA specific antibodies is one of the major biological mechanisms to clear bacterial infections and restore epithelial cell survival in vitro. Our data also indicates that the anti-pertussis antibodies reduce secretion of proinflammatory chemokines and cytokines by preventing interaction of B. pertussis with host cells. The results of this study not only demonstrate mechanism of action of anti-FIM and anti-FHA antibodies, but also opens translational applications for potential therapeutic approaches or development of analytical assays such as in vitro potency assays.
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