Role of caveolae in Leishmania chagasi phagocytosis and intracellular survival in macrophages

Caveolae are membrane microdomains enriched in cholesterol, ganglioside M1 (GM1) and caveolin-1. We explored whether caveolae facilitate the entry of Leishmania chagasi into murine macrophages. Transient depletion of macrophage membrane cholesterol by 1 h exposure to methyl-beta-cyclodextrin (MbetaCD) impaired the phagocytosis of non-opsonized and serum-opsonized virulent L. chagasi. In contrast, MbetaCD did not affect the phagocytosis of opsonized attenuated L. chagasi. As early as 5 min after phagocytosis, virulent L. chagasi colocalized with the caveolae markers GM1 and caveolin-1, and colocalization continued for over 48 h. We explored the kinetics of lysosome fusion. Whereas fluorescent-labelled dextran entered macrophage lysosomes by 30 min after addition, localization of L. chagasi in lysosomes was delayed for 24-48 h after phagocytosis. However, after transient depletion of cholesterol from macrophage membrane with MbetaCD, the proportion of L. chagasi-containing phagosomes that fused with lysosomes increased significantly. Furthermore, intracellular replication was impaired in parasites entering after transient cholesterol depletion, even though lipid microdomains were restored by 4 h after treatment. These observations suggest that virulent L. chagasi localize in caveolae during phagocytosis by host macrophages, and that cholesterol-containing macrophage membrane domains, such as caveolae, target parasites to a pathway that promotes delay of lysosome fusion and intracellular survival.     

Different fates of phagocytosed particles after delivery into macrophage lysosomes

Phagocytosis in macrophages is often studied using inert polymer microspheres. An implicit assumption in these studies is that such particles contain little or no specific information in their structure that affects their intracellular fate. We tested that assumption by examining macrophage phagosomes containing different kinds of particles and found that although all particles progressed directly to lysosomes, their subsequent fates varied. Within 15 min of phagocytosis, >90% of phagosomes containing opsonized sheep erythrocytes, poly-e-caprolactone microspheres, polystyrene microspheres (PS), or polyethylene glycol- conjugated PS merged with the lysosomal compartment. After that point, however, the characteristics of phagolysosomes changed in several ways that indicated differing degrees of continued interaction with the lysosomal compartment. Sheep erythrocyte phagolysosomes merged together and degraded their contents quickly, poly-e-caprolactone phagolysosomes showed intermediate levels of interaction, and PS phagolysosomes became isolated within the cytoplasm. PS were relatively inaccessible to an endocytic tracer, Texas red dextran, added after phagocytosis. Moreover, immunofluorescent staining for the lysosomal protease cathepsin L decreased in PS phagolysosomes to 23% by 4 h after phagocytosis, indicating degradation of the enzyme without replacement. Finally, PS surface labeled with fluorescein-labeled albumin showed a markedly reduced rate of protein degradation in phagolysosomes, when compared to rates measured for proteins in or on other particles. Thus, particle chemistry affected both the degree of postlysosomal interactions with other organelles and, consequently, the intracellular half-life of particle-associated proteins. Such properties may affect the ability of particles to deliver macromolecules into the major histocompatibility complex class I and II antigen presentation pathways.     

Phagosome resolution regenerates lysosomes and maintains the degradative capacity in phagocytes

Phagocytes engulf unwanted particles into phagosomes that then fuse with lysosomes to degrade the enclosed particles. Ultimately, phagosomes must be recycled to help recover membrane resources that were consumed during phagocytosis and phagosome maturation, a process referred to as “phagosome resolution.” Little is known about phagosome resolution, which may proceed through exocytosis or membrane fission. Here, we show that bacteria-containing phagolysosomes in macrophages undergo fragmentation through vesicle budding, tubulation, and constriction. Phagosome fragmentation requires cargo degradation, the actin and microtubule cytoskeletons, and clathrin. We provide evidence that lysosome reformation occurs during phagosome resolution since the majority of phagosome-derived vesicles displayed lysosomal properties. Importantly, we show that clathrin-dependent phagosome resolution is important to maintain the degradative capacity of macrophages challenged with two waves of phagocytosis. Overall, our work suggests that phagosome resolution contributes to lysosome recovery and to maintaining the degradative power of macrophages to handle multiple waves of phagocytosis.     

Phagocytized intracellular microsporidian blocks phagosome acidification and phagosome-lysosome fusion

This study examines the relationship between phagosome acidification and phagosome-lysosome fusion events using phagocytized Glugea hertwigi spores. The incidence of lysosome fusion with Glugea spores in phagosomes of mouse peritoneal macrophages and of Tetrahymena was monitored using colloidal gold and acridine orange as labels for secondary lysosomes. Over 80% of the Glugea phagosomes remained segregated from the labeled compartments in macrophages after 60 min; this inhibition of fusion was still evident after 4 h. In Tetrahymena, Glugea spores also showed a high capacity to block fusion with secondary lysosomes (67%); however, spores coated with cationized ferritin showed an 80% fusion rate with labeled acidic compartments (i.e. lysosomes) after 60 min with both Tetrahymena and macrophages. The pH of phagosome compartments was monitored by measuring the emissions of fluorescein isothiocyanate (FITC)-labeled Glugea ingested by Tetrahymena. Tetrahymena phagosomes with FITC-Glugea did not acidify within the first hour after phagocytosis; however, phagosomes with cationized ferritin-labeled Glugea underwent acidification during this time period. This acidification took place although the capability of the host cells' lysosomes to fuse was blocked by pretreatment with poly-D-glutamic acid. The cationized ferritin bound to Glugea spores was uncoupled from the spore wall prior to fusion with colloidal gold-labeled compartments. In vitro testing showed that ferritin dissociation requires an acid pH, indicating that phagosomes acidify prior to lysosome fusion.     

Mycobacterium and Leishmania: stowaways in the endosomal network

Microbial pathogens have evolved to exploit a wide range of niches inside the vertebrate host cell. Both Leishmania and Mycobacterium species remain within vacuoles following phagocytosis by their host's macrophages. Leishmania survives in acidic, lysosomal compartments, whereas Mycobacterium species limit the maturation of their phagosomes into hydrolytic lysosomes. Recent advances in our appreciation of the biology of these pathogens is providing unique insights into the normal conversion of phagosomes into lysosomes.     

Influence of phagosomal contents on the apparent inhibition of phagosome-lysosome fusion mediated by polyanionic substances in mouse peritoneal macrophages.

The study of fusion of phagosomes with secondary lysosomes in macrophages is facilitated by assessing transfer of fluorescent or electron-opaque markers (or both) from the lysosomes to the phagosomes. When certain virulent viable pathogens are phagocytosed by mouse peritoneal macrophages, phagosome-lysosome fusion (P-LF) is inhibited. Nonviable counterparts ordinarily cannot impose this block. A similar, but spurious, block to P-LF seems to be mediated from the lysosomal domain following sequestration of certain polyanionic substances. This block has been judged to be relieved by, for example, heat-killed yeasts and various viable bacteria designated as fusion-inducing microorganisms, acting from the phagosome. In this study we tested this concept and believed it to be unfounded. Macrophages labeled with Thorotrast and incubated with dextran sulfate were offered a variety of viable and heat-killed microorganisms for phagocytosis: Saccharomyces cerevisiae, Mycobacterium lepraemurium, Streptococcus faecalis, and Escherichia coli. By electron microscopy, a transfer of Thorotrast to phagosomes up to 18 h was seen to be highly suppressed as compared with controls, but was not notably different for any of the targets, whether viable or not. Instead, inert 0.45-micron carboxylated polystyrene beads (the smallest target) showed the most delivery of marker. If polyanionic agents truly inhibited fusion, then "fusiogenic" microorganisms should free the marker for delivery. If polyanions do not inhibit P-LF and only trap the marker, the behavior of the various targets would correspond to what we found.     

Changes in the composition of the lysosomes in hepatocytes cultured in vitro in modelling pathological states

The monolayer cultures of newborn rats hepatocytes were treated with substrate starvation (20 min.) anoxia accompanied with substrate starvation (1 h.), following rehabilitation (1 h.) and cooling (4 degrees C, 30 min). After the neutral red staining we have examined the alterations in lysosomes quantity and the development of phagocytosis; we also tested the hepatocytes distribution due to the amount of the second lysosomes per cell. We have shown that a short time pathological treatment caused a decrease in large lysosomes (1-3 microns) amount in significant portion of hepatocytes. There were neither increase in phagosomes amount per cell nor alterations in the quantity of cells, containing phagosomes. However a long time pathological treatment caused the increase in phagosomes and cells. We propose that initial stage of lysosomal apparatus alterations, connected with reduction of CAMP level, is accompanied by a stamping of large lysosomes.     

PIKfyve Inhibition Interferes with Phagosome and Endosome Maturation in Macrophages

Macrophages eliminate pathogens and cell debris through phagocytosis, a process by which particulate matter is engulfed and sequestered into a phagosome. Nascent phagosomes are innocuous organelles resembling the plasma membrane. However, through a maturation process, phagosomes are quickly remodeled by fusion with endosomes and lysosomes to form the phagolysosome. Phagolysosomes are highly acidic and degradative leading to particle decomposition. Phagosome maturation is intimately dependent on the endosomal pathway, during which diverse cargoes are sorted for recycling to the plasma membrane or for degradation in lysosomes. Not surprisingly, various regulators of the endosomal pathway are also required for phagosome maturation, including phosphatidylinositol‐3‐phosphate, an early endosomal regulator. However, phosphatidylinositol‐3‐phosphate can be modified by the lipid kinase PIKfyve into phosphatidylinositol‐3,5‐bisphosphate, which controls late endosome/lysosome functions. The role of phosphatidylinositol‐3,5‐bisphosphate in macrophages and phagosome maturation remains basically unexplored. Using Fcγ receptor‐mediated phagocytosis as a model, we describe our research showing that inhibition of PIKfyve hindered certain steps of phagosome maturation. In particular, PIKfyve antagonists delayed removal of phosphatidylinositol‐3‐phosphate and reduced acquisition of LAMP1 and cathepsin D, both common lysosomal proteins. Consistent with this, the degradative capacity of phagosomes was reduced but phagosomes appeared to still acidify. We also showed that trafficking to lysosomes and their degradative capacity was reduced by PIKfyve inhibition. Overall, we provide evidence that PIKfyve, likely through phosphatidylinositol‐3,5‐bisphosphate synthesis, plays a significant role in endolysosomal and phagosome maturation in macrophages.      

Phagocytized Intracellular Microsporidian Blocks Phagosome Acidification and Phagosome-Lysosome Fusion

This study examines the relationship between phagosome acidification and phagosome-lysosome fusion events using phagocytized Glugea hertwigi spores. The incidence of lysosome fusion with Glugea spores in phagosomes of mouse peritoneal macrophages and of Tetrahymena was monitored using colloidal gold and acridine orange as labels for secondary lysosomes. Over 80% of the Glugea phagosomes remained segregated from the labeled compartments in macrophages after 60 min; this inhibition of fusion was still evident after 4 h. In Tetrahymena, Glugea spores also showed a high capacity to block fusion with secondary lysosomes (67%); however, spores coated with cationized ferritin showed an 80% fusion rate with labeled acidic compartments (i.e. lysosomes) after 60 min with both Tetrahymena and macrophages. The pH of phagosome compartments was monitored by measuring the emissions of fluorescein isothiocyanate (FITQ-labeled Glugea ingested by Tetrahymena. Tetrahymena phagosomes with FITC-Glugea did not acidify within the first hour after phagocytosis; however, phagosomes with cationized ferritin-labeled Glugea underwent acidification during this time period. This acidification took place although the capability of the host cells' lysosomes to fuse was blocked by pretreatment with poly-D-glutamic acid. The cationized ferritin bound to Glugea spores was uncoupled from the spore wall prior to fusion with colloidal gold-labeled compartments. In vitro testing showed that ferritin dissociation requires an acid pH, indicating that phagosomes acidify prior to lysosome fusion.     

Magnetic Separation of Phagosomes of Defined Age from Tetrahymena thermophila

ABSTRACT. We describe a new mass isolation procedure for both pure and stage-specific phagosomes from Tetrahymena thermophila . We prepared magnetic iron dextran particles about 1 μm in diameter to label the phagosomes. The oral apparatus of the cells concentrated these particles so readily that after 1 min the majority of the cells had formed a single phagosome. A short wash removed non-ingested particles, enabling us to follow the age-dependent changes of a single labeled phagosome through the cell. Phagosomes of different ages, including very young and nascent phagosomes, were removed easily from the non-magnetic cell debris of mechanically homogenized cells by means of a permanent magnet. The isolated phagosomes are pure as tested by enzymatic assays and light and electron microscopy. Since the yield of pure phagosomes of all ages is high (∼ 90%), this method could be generally applied for phagosome isolation from ciliates.     

Ca2+ and synaptotagmin VII-dependent delivery of lysosomal membrane to nascent phagosomes

Synaptotagmin (Syt) VII is a ubiquitously expressed member of the Syt family of Ca2+ sensors. It is present on lysosomes in several cell types, where it regulates Ca2+-dependent exocytosis. Because [Ca2+]i and exocytosis have been associated with phagocytosis, we investigated the phagocytic ability of macrophages from Syt VII-/- mice. Syt VII-/- macrophages phagocytose normally at low particle/cell ratios but show a progressive inhibition in particle uptake under high load conditions. Complementation with Syt VII rescues this phenotype, but only when functional Ca2+-binding sites are retained. Reinforcing a role for Syt VII in Ca2+-dependent phagocytosis, particle uptake in Syt VII-/- macrophages is significantly less dependent on [Ca2+]i. Syt VII is concentrated on peripheral domains of lysosomal compartments, from where it is recruited to nascent phagosomes. Syt VII recruitment is rapidly followed by the delivery of Lamp1 to phagosomes, a process that is inhibited in Syt VII-/- macrophages. Thus, Syt VII regulates the Ca2+-dependent mobilization of lysosomes as a supplemental source of membrane during phagocytosis.     

X-ray microanalysis of cellular localization of ferritin in mammalian spleen and liver

X-ray microanalysis of mineral core of cellular localizations of ferritin in horse, sheep and rat spleen macrophages and in parenchymal cells of normal and pathological human liver was performed to obtain the net intensities of iron and phosphorus in the irradiated areas and to calculate the P:Fe ratios.For comparison the same analysis was performed on commercially produced horse spleen ferritin in two processings: unembedded and after treatment similar to tissue and embedded in Epon. Our analytical results of unembedded commercially produced horse spleen ferritin particles (1:15) confirmed the weight ratio suggested by Granick and Hahn (J. biol. Chem., 155: 661–669, 1944) for isolated crystallizable horse spleen ferritin in their chemical studies (1:16 or 1:14). After application of EM-tissue processing procedures to commercially produced horse spleen ferritin the ratio changed into 1:22, presumably by the loss of phosphorus. In spleen of three species the X-ray analytical results of ferritin particles in situ showed that in both localizations (clusters and lysosomes) the P:Fe ratios varied widely and the mean P:Fe ratios were generally higher than in embedded commercially produced horse spleen ferritin. Within these three species the mean P:Fe ratios of ferritin particles in two localizations of sheep and rat spleen were higher than in horse spleen. Moreover in sheep and rat spleen one third of the analysed clusters and lysosomes contained ferritin particles with zero phosphorus although sufficient iron was detected. Within all three species we found no statistically significant difference in mean P:Fe ratios between clusters and lysosomes.The X-ray analytical results in normal human liver parenchymal cells showed that as a result of very variable P:Fe ratios in ferritin-containing lysosomes, the mean P:Fe ratio was higher than in embedded commercially produced horse spleen ferritin and was nearly the same as in ferritin within clusters and lysosomes of horse spleen. In human liver with haemochromatosis, there were no significant variations in P:Fe ratios. The mean P:Fe ratio for ferritin particles in lysosomes was 1:13, much lower than in normal liver (1:39) and nearly the same as in unembedded commercially produced horse spleen ferritin (1:15). Our findings led us to conclude that in spleen macrophages and in parenchymal cells of normal liver among the populations of ferritin particles the iron-poor ferritin particles are more extensively present (especially in sheep and rat spleen) than in isolated crystallized horse spleen ferritin or ferritin-containing lysosomes of pathological human liver. In these iron-poor ferritin molecules the P:Fe ratio is variable from molecule to molecule and different from that suggested in the literature. The hypothesis of a constant ratio P:Fe for ferritin with different iron content is rejected. The formula for the composition of the mineral core of ferritin, as proposed by Granick and Hahn (1944) can only be considered correct for ferritin as iron-rich as isolated from horse spleen.     

Mycobacterium tuberculosis resides in nonacidified vacuoles in endocytically competent alveolar macrophages from patients with tuberculosis and HIV infection

Alveolar macrophages (AM) are the first professional phagocytes encountered by aerosols containing infections in the lungs, and their phagocytic capacity may be affected by these infections or environmental particles. The aim of this study was to evaluate the innate endocytic and phagocytic properties of human AM obtained from patients with pulmonary tuberculosis and to characterize the vacuoles in which Mycobacterium tuberculosis bacilli reside in vivo. AM were obtained by bronchoalveolar lavage from patients with suspected tuberculosis and from asymptomatic volunteers (controls). Clinical case definitions were based on mycobacterial culture of respiratory specimens and HIV serology. To assess phagocytosis, endocytosis, and acidification of the endosomal system, AM were cultured with IgG-coated polystyrene beads, dextran, and a pH-sensitive reporter (3-(2,4-dinitroanilino)-3-amino-N-methyldipropylamine) and were evaluated by light and immunoelectron microscopy. Cells from 89 patients and 10 controls were studied. We found no significant difference between the two groups in the ability of AM either to ingest beads and dextran or to deliver them to acidified lysosomes. In AM from patients with tuberculosis, the bacilli were located in vacuoles that failed to accumulate endocytosed material and were not acidified. We concluded that AM from patients with tuberculosis and HIV infections were competent to endocytose and phagocytose material and to deliver the material to functional, acidified lysosomes. M. tuberculosis residing in these AM arrests the progression of their phagosomes, which fail to fuse with acidified lysosomes. This confirms, for the first time in humans with tuberculosis and HIV, the conclusions from previous animal and in vitro studies.     

The metabolic activity of Mycobacterium tuberculosis, assessed by use of a novel inducible GFP expression system, correlates with its capacity to inhibit phagosomal maturation and acidification in human macrophages

Mycobacterium tuberculosis generally reside in phagosomes within human macrophages that resist maturation and acidification, but exhibit significant heterogeneity. In this study we have constructed an IPTG-inducible GFP expression system in M. tuberculosis to assess the relationship between the metabolic status of M. tuberculosis and the degree of phagosomal maturation. Using these recombinant bacteria, we have found that, in human macrophages, M. tuberculosis that respond to IPTG with expression of GFP fluorescence, and hence are metabolically active, reside in non-acidified phagosomes that have not fused with Texas red dextran pre-labelled lysosomes. In contrast, M. tuberculosis that fail to express GFP in response to IPTG, and hence are metabolically inactive, reside within acidified phagosomes that have fused with Texas red dextran labelled lysosomes. These studies demonstrate that metabolic activity of M. tuberculosis correlates strongly with phagosomal maturation and that the inducible GFP expression system is useful for assessing metabolic activity of intracellular M. tuberculosis.     

Study of Phagolysosome Biogenesis in Live Macrophages

Phagocytic cells play a major role in the innate immune system by removing and eliminating invading microorganisms in their phagosomes. Phagosome maturation is the complex and tightly regulated process during which a nascent phagosome undergoes drastic transformation through well-orchestrated interactions with various cellular organelles and compartments in the cytoplasm. This process, which is essential for the physiological function of phagocytic cells by endowing phagosomes with their lytic and bactericidal properties, culminates in fusion of phagosomes with lysosomes and biogenesis of phagolysosomes which is considered to be the last and critical stage of maturation for phagosomes. In this report, we describe a live cell imaging based method for qualitative and quantitative analysis of the dynamic process of lysosome to phagosome content delivery, which is a hallmark of phagolysosome biogenesis. This approach uses IgG-coated microbeads as a model for phagocytosis and fluorophore-conjugated dextran molecules as a luminal lysosomal cargo probe, in order to follow the dynamic delivery of lysosmal content to the phagosomes in real time in live macrophages using time-lapse imaging and confocal laser scanning microscopy. Here we describe in detail the background, the preparation steps and the step-by-step experimental setup to enable easy and precise deployment of this method in other labs. Our described method is simple, robust, and most importantly, can be easily adapted to study phagosomal interactions and maturation in different systems and under various experimental settings such as use of various phagocytic cells types, loss-of-function experiments, different probes, and phagocytic particles.     

Use of a calibrated melamine-formaldehyde latex for the luminescence microscopic study of phagocytosis in a macrophage culture

The possibility has been demonstrated of the use of calibrated melamine-formaldehyde latex for studying phagocytosis as an object not undergoing intracellular digestion. Latex was discovered to be actively phagocytized by macrophages and to exert no toxic action on them. A study was made of the time course of changes in the color and brightness of the fluorescence of the latex phagocytized particles in macrophages intravitally fluorochrominated by acridine orange. These changes were demonstrated to be analogous to those observed previously during phagocytosis of bacteria and other objects. The data obtained demonstrate once more the transition of the fluorescent complex from lysosomes to phagosomes and the lack of the relationship of these changes with intracellular death and digestion of the phagocytized objects. The possibility has been also shown to differentiate between phagocytized particles of latex and those located outside the cells.     

RNA interference in J774 macrophages reveals a role for coronin 1 in mycobacterial trafficking but not in actin-dependent processes

Macrophages are crucial for innate immunity, apoptosis, and tissue remodeling, processes that rely on the capacity of macrophages to internalize and process cargo through phagocytosis. Coronin 1, a member of the WD repeat protein family of coronins specifically expressed in leukocytes, was originally identified as a molecule that is recruited to mycobacterial phagosomes and prevents the delivery of mycobacteria to lysosomes, allowing these to survive within phagosomes. However, a role for coronin 1 in mycobacterial pathogenesis has been disputed in favor for its role in mediating phagocytosis and cell motility. In this study, a role for coronin 1 in actin-mediated cellular processes was addressed using RNA interference in the murine macrophage cell line J774. It is shown that the absence of coronin 1 in J774 macrophages expressing small interfering RNA constructs specific for coronin 1 does not affect phagocytosis, macropinocytosis, cell locomotion, or regulation of NADPH oxidase activity. However, in coronin 1-negative J774 cells, internalized mycobacteria were rapidly transferred to lysosomes and killed. Therefore, these results show that in J774 cells coronin 1 has a specific role in modulating phagosome-lysosome transport upon mycobacterial infection and that it is dispensable for most F-actin-mediated cytoskeletal rearrangements.     

The different autophagic roads by which phagosomes travel to lysosomes

Autophagy delivers cytoplasmic constituents, like damaged mitochondria, to lysosomes. Recently, it was noted that the same molecular machinery also regulates phagosome delivery for degradation. In this issue of The EMBO Journal, Brooks and colleagues demonstrate that KIM‐1/TIM‐1 receptor‐mediated phagocytosis in epithelial cells does not seem to cause modification of the phagosomal membrane itself by the autophagic machinery, but engulfment of phagosomes by autophagosomes for delivery to lysosomes and MHC restricted antigen presentation. This study suggests that the autophagic machinery can regulate phagocytosis via two pathways, modification of phagosomes during LC3‐associated phagocytosis (LAP) and macroautophagy of phagosomes.     

Live Salmonella modulate expression of Rab proteins to persist in a specialized compartment and escape transport to lysosomes

We investigated the intracellular route of Salmonella in macrophages to determine a plausible mechanism for their survival in phagocytes. Western blot analysis of isolated phagosomes using specific antibodies revealed that by 5 min after internalization dead Salmonella-containing phagosomes acquire transferrin receptors (a marker for early endosomes), whereas by 30 min the dead bacteria are found in vesicles carrying the late endosomal markers cation-dependent mannose 6-phosphate receptors, Rab7 and Rab9. In contrast, live Salmonella-containing phagosomes (LSP) retain a significant amount of Rab5 and transferrin receptor until 30 min, selectively deplete Rab7 and Rab9, and never acquire mannose 6-phosphate receptors even 90 min after internalization. Retention of Rab5 and Rab18 and selective depletion of Rab7 and Rab9 presumably enable the LSP to avoid transport to lysosomes through late endosomes. The presence of immature cathepsin D (48 kDa) and selective depletion of the vacuolar ATPase in LSP presumably contributes to the less acidic pH of LSP. In contrast, proteolytically processed cathepsin D (M(r) 17,000) was detected by 30 min on the dead Salmonella-containing phagosomes. Morphological analysis also revealed that after uptake by macrophages, the dead Salmonella are transported to lysosomes, whereas the live bacteria persist in compartments that avoid fusion with lysosomes, indicating that live Salmonella bypass the normal endocytic route targeted to lysosomes and mature in a specialized compartment.     

Acid sphingomyelinase is required for efficient phago-lysosomal fusion

The acid sphingomyelinase (ASMase) localizes to the lumen of endosomes, phagosomes and lysosomes as well as to the outer leaflet of the plasma membrane and hydrolyses sphingomyelin to ceramide and phosphorylcholine. Using the facultative intracellular bacterium Listeria monocytogenes , we show that maturation of phagosomes into phagolysosomes is severely impaired in macrophages genetically deficient for ASMase. Unlike in wild-type macrophages, phagosomes containing L. monocytogenes in ASMase^−/− macrophages remained positive for the late phagosomal markers mannose-6-phosphate receptor (M6PR) and Rab7 for at least 2 h and, correspondingly, showed delayed acquisition of lysosomal markers like lysosome associated membrane protein 1 (Lamp1). The transfer of lysosomal fluid phase markers into phagosomes containing L. monocytogenes was severely impaired in ASMase^−/− macrophages and decreased with increasing size of the cargo. Moreover, phagosomes containing L. monocytogenes from ASMase^−/− cells acquired significantly less listeriocidal proteases cathepsin D, B and L. The results of this study suggest that ASMase is required for the proper fusion of late phagosomes with lysosomes, which is crucial for efficient transfer of lysosomal antibacterial hydrolases into phagosomes.