Polyanionic agents as inhibitors of phagosome-lysosome fusion in cultured macrophages: evolution of an alternative interpretation

Various natural and synthetic substances classified as polyanionics have been implicated in antagonizing phagosome-lysosome fusion in cultured macrophages. The phenomenon has been judged by comparing the transfer of selected markers from secondary lysosomes to phagosomes in control and in "polyanion" cells. Our earlier studies showed that use of one of the markers, the membrane-permeating acridine orange, was plagued with artifacts that were especially misleading in the presence of polyanionic agents. We now question the validity of data obtained by the alternative technique, electron microscopy. Our present evidence shows that nonionic hydrocolloids of sufficiently high molecular weight prevent the transfer of various colloidal electron-opaque markers from lysosomes to phagosomes in the same manner as does the powerful polyanionic "fusion inhibitor" dextran sulfate. Both kinds of hydrocolloids, however, allow delivery of lysosomal, low-molecular-weight highly charged non-permeant fluorescent markers to phagosomes, probably by a fusion process. We propose that neither type of hydrocolloid inhibits fusion; instead, when sufficiently concentrated, they trap particulate electron-opaque markers in a gelatinous matrix, which may move only slowly out of lysosomes. The polyanionics trap the electron-opaque markers physically and acridine orange ionically. Hence, the semblance of "fusion inhibition."     

Rapid and complete fusion of macrophage lysosomes with phagosomes containing Salmonella typhimurium.

The virulence of Salmonella typhimurium for mice results, in part, from its ability to survive after phagocytosis by macrophages. Although it is generally agreed that intracellular bacteria persist in membrane-bound phagosomes, there remains some question as to whether these phagosomes fuse with macrophage lysosomes. This report describes the maturation of phagosomes containing S. typhimurium inside mouse bone marrow-derived macrophages. Macrophages were infected briefly and incubated for various intervals; then they were examined by fluorescence microscopy for colocalization of bacteria with lysosomal markers. These markers included LAMP-1, cathepsin L, and fluorescent proteins or dextrans preloaded into lysosomes by endocytosis. By all measures, phagosomes containing S. typhimurium merged completely with the lysosomal compartment within 20 min of phagocytosis. The rate of phagosome-lysosome fusion was similar to the rate for phagocytosed latex beads. Phagolysosomes remained accessible to fluid-phase probes and contained lysosomal markers for many hours. Moreover, a large percentage of the wild-type bacteria that were viable 20 min after infection survived longer incubations inside macrophages, indicating that the survivors were not a minor subpopulation that avoided phagosome-lysosome fusion. Therefore, we conclude that S. typhimurium survives within the lysosomal compartments of macrophages.     

Polyanionic agents inhibit phagosome-lysosome fusion in cultured macrophages: a reply to the suggestion of Goren, Vatter, and Fiscus to the contrary

The paper and review by Goren et al. (J. Leukocyte Biol. 41, 111, 1987) contain serious objections to the reports from several laboratories on the pattern of fusion of secondary lysosomes with phagosomes (yeasts being predominantly the target) in polyanion-treated macrophages; these reports had concluded that the polyanions were inhibitors of this fusion. The main objection by Goren et al. is to the alleged misuse of electron microscopic (EM) lysosome markers; many instances of phagosome-lysosome (P-L) fusion in the treated cells have therefore been missed. The central argument is that 1) the "hydrocolloid" properties of certain of these polyanions hinder the passage of the enmeshed marker from lysosome to phagosome after their fusion and 2) this hindrance is mistakenly interpreted as indicating that fusion has not taken place, thus giving rise to the belief that the polyanions can inhibit fusion. In reply, we explain that we score as P-L fusion any instance of marker (ferritin) being seen anywhere in a fused phagosome (phagolysosome). For this crucial reason, immobilisation of marker by a hydrocolloid polyanion, e.g., in lysosomal residue of phagolysosomes or just within phagosome membranes (as in Goren's Figs. 5 and 6 [8]), would not seriously threaten the marker distinction between fusion and nonfusion (with consequent underestimation of the former) and therefore would not invalidate the reports of a high incidence of nonfusion in polyanion-treated macrophages. Such inhibition of P-L fusion is supported by using as lysosomal label the nonpermeant fluorescent probe lucifer yellow (accepted by Goren et al. as a reliable indicator of fusion). Further support comes from the correlated inhibition of the saltatory movements of secondary lysosomes previously described; static lysosomes will have their contact with the phagosomes severely restricted. Another criticism is based on the failure of certain salient properties and functions of phagosomes to change significantly after polyanion treatment of the macrophages; these include intraphagosomal digestion, presence of lysosomal enzymes, and acidification. However, this indirect evidence can be accounted for alternatively by the operation of factors (primary lysosomes, endogenous acidification, etc.) not affected by the polyanionic block. We conclude that fusion inhibition by the polyanions is a real phenomenon, as previously reported, notwithstanding the hydrocolloid properties of some of them. Furthermore, an explanation based on hydrocolloid properties is questionable, since one or possibly two of the five main polyanionic agents appear not to be hydrocolloids.     

Role of the Brucella suis lipopolysaccharide O antigen in phagosomal genesis and in inhibition of phagosome-lysosome fusion in murine macrophages

Brucella species are gram-negative, facultative intracellular bacteria that infect humans and animals. These organisms can survive and replicate within a membrane-bound compartment inside professional and nonprofessional phagocytic cells. Inhibition of phagosome-lysosome fusion has been proposed as a mechanism for intracellular survival in both cell types. However, the molecular mechanisms and the microbial factors involved are poorly understood. Smooth lipopolysaccharide (LPS) of Brucella has been reported to be an important virulence factor, although its precise role in pathogenesis is not yet clear. In this study, we show that the LPS O side chain is involved in inhibition of the early fusion between Brucella suis-containing phagosomes and lysosomes in murine macrophages. In contrast, the phagosomes containing rough mutants, which fail to express the O antigen, rapidly fuse with lysosomes. In addition, we show that rough mutants do not enter host cells by using lipid rafts, contrary to smooth strains. Thus, we propose that the LPS O chain might be a major factor that governs the early behavior of bacteria inside macrophages.     

Inhibition of macrophage phagosome-lysosome fusion by Salmonella typhimurium.

Salmonella typhimurium-infected macrophages were examined by electron microscopy to determine whether intracellular survival of S. typhimurium is associated with failure of bacteria containing phagosomes to fuse with secondary lysosomes. S. typhimurium 14028 actively inhibited phagosome-lysosome fusion and appeared to preferentially divide within unfused phagocytic vesicles. In comparison with Escherichia coli, S. typhimurium inhibited phagosome-lysosome fusion in peritoneal macrophages, J774 macrophages, and bone marrow-derived macrophages from both BALB/c (itys) and SWR/J (ityr) mice. The mechanism responsible for Salmonella inhibition of phagosome-lysosome fusion is unknown but requires viable salmonellae, is not blocked by opsonization with fresh normal mouse serum, and is not due to lipopolysaccharide. Inhibition of phagosome-lysosome fusion may play a critical role in survival of salmonellae within macrophages and in virulence.     

Intracellular fate of Mycobacterium leprae in normal and activated mouse macrophages.

Mycobacterium leprae replicates within mononuclear phagocytes, reaching enormous numbers in the macrophage-rich granulomas of lepromatous leprosy. To examine the capability of macrophages to digest M. leprae, we studied the intracellular fate of M. leprae organisms in normal and activated mouse macrophages by using the electron-dense secondary lysosome tracer Thoria Sol. Intracellular M. leprae organisms, surrounded by a characteristic electron-transparent zone, were contained within phagosomal vacuoles of macrophages cultured in vitro for 1 to 6 days. In normal macrophages, a majority of phagosomes containing freshly isolated live M. leprae cells resisted fusion with Thoria Sol-labeled lysosomes. The extent of fusion was not significantly affected by pretreatment of M. leprae with human patient serum high in specific immunoglobulin G and M antibodies. In contrast, a majority of phagosomes containing gamma-irradiated M. leprae cells underwent lysosome fusion in normal macrophages. In addition, increased phagolysosome fusion was observed with live M. leprae-containing phagosomes in macrophages activated with gamma interferon. Increased fusion was associated with an increase in the number of fragmented and damaged bacilli, suggesting that increased digestion followed fusion. This study indicates that activated macrophages may have an increased capacity for clearance of normally resistant M. leprae.     

Role of lymphocytes in macrophage-induced killing of Coccidioides immitis in vitro.

Peritoneal macrophages from normal mice phagocytized arthroconidia and endospores of Coccidioides immitis without affecting the viability of the spores within 4 h after infection. In contrast, macrophages, when infected in the presence of lymphocytes from immune mice, significantly reduced the viability of phagocytized endospores and arthroconidia. The inability of macrophages from normal mice to kill C. immitis may in part be explained by the observation that C. immitis appeared to inhibit fusion of the phagosomes containing fungal spores with the lysosomes within the macrophages. However, fusion of phagosomes containing spores and lysosomes was observed in macrophages infected in the presence of lymphocytes from immune mice.     

Role of cholesterol and the ganglioside GM(1) in entry and short-term survival of Brucella suis in murine macrophages

Brucella species are gram-negative, facultative intracellular bacteria that infect humans and animals. These organisms can survive and replicate within a membrane-bound compartment inside professional and nonprofessional phagocytic cells. Inhibition of phagosome-lysosome fusion has been proposed as a mechanism for intracellular survival in both types of cells. We have previously shown that the maturation inhibition of the Brucella-containing phagosome appears to be restricted at the phagosomal membrane, but the precise molecular mechanisms and factors involved in this inhibition have yet to be identified. Interestingly, recent studies have revealed that caveolae or lipid rafts are implicated in the entry of some microorganisms into host cells and mediate an endocytic pathway avoiding fusion with lysosomes. In this study, we investigated the role of cholesterol and the ganglioside GM(1), two components of lipid rafts, in entry and short-term survival of Brucella suis in murine macrophages, by using cholesterol-sequestering (filipin and beta-methyl cyclodextrin) and GM(1)-binding (cholera toxin B) molecules. Our results suggest that lipid rafts may provide a portal for entry of Brucella into murine macrophages under nonopsonic conditions, thus allowing phagosome-lysosome fusion inhibition, and provide further evidence to support the idea that the phagosome maturation inhibition is restricted at the phagosomal membrane.     

Intracellular fate of Mycobacterium avium: use of dual-label spectrofluorometry to investigate the influence of bacterial viability and opsonization on phagosomal pH and phagosome-lysosome interaction.

Mycobacterium avium is a facultative intracellular pathogen that can survive and replicate within macrophages. We tested the hypotheses that survival mechanisms may include alteration of phagosomal pH or inhibition of phagosome-lysosome fusion. M. avium was surface labeled with N-hydroxysuccinimidyl esters of carboxyfluorescein (CF) and rhodamine (Rho) to enable measurement of the pH of individual M. avium-containing phagosomes and the interactions of bacterium-containing phagosomes with labeled secondary lysosomes. CF fluorescence is pH sensitive, whereas Rho is pH insensitive; pH can be calculated from their fluorescence ratios. Surface labeling of M. avium did not affect viability in broth cultures or within J774, a murine macrophage-like cell line. By fluorescence spectroscopy, live M. avium was exposed to an environmental pH of approximately 5.7 at 6 h after phagocytosis, whereas similarly labeled Salmonella typhimurium, zymosan A, or heat-killed M. avium encountered an environmental pH of < 5.0. Video fluorescence and laser scanning confocal microscopy gave consistent pH results and demonstrated the heterogeneity of intracellular fate early in infection. pH became more homogeneous 6 h after infection. M. avium cells were coated with immunoglobulin G (IgG) or opsonized to investigate whether phagocytosis by the corresponding receptors would alter intracellular fate. Opsonized, unopsonized, and IgG-coated M. avium cells entered compartments of similar pH. Finally, the spatial distribution of intracellular bacteria and secondary lysosomes was compared. Only 18% of live fluorescent M. avium cells colocalized with fluorescent lysosomes, while 98% of heat-killed bacteria colocalized. Thus, both inhibition of phagosome-lysosome fusion and alteration of phagosomal pH may contribute to the intracellular survival of M. avium.     

Localization of major histocompatibility complex class II molecules in phagolysosomes of murine macrophages infected with Leishmania amazonensis

Leishmania-infected macrophages are potential antigen-presenting cells for CD4+ T lymphocytes, which recognize parasite antigens bound to major histocompatibility complex class II molecules (Ia). However, the intracellular sites where Ia and antigens may interact are far from clear, since parasites grow within the modified lysosomal compartment of the host cell, whereas Ia molecules seem to be targeted to endosomes. To address this question, the expression and fate of Ia molecules were studied by immunocytochemistry in Leishmania amazonensis-infected murine macrophages stimulated with gamma interferon. In uninfected macrophages, Ia molecules were localized on the plasma membrane and in perinuclear vesicles, but they underwent a dramatic redistribution after infection, since most of the intracellular staining was then associated with the periphery of the parasitophorous vacuoles (p.v.) and quite often polarized towards amastigote-binding sites. The Ii invariant chain, which is transiently associated with Ia during their intracellular transport, although well expressed in infected macrophages, apparently did not reach the p.v. Similar findings were observed with macrophages from mice either resistant or highly susceptible to Leishmania infection. In order to determine the origin of p.v.-associated Ia, the fate of plasma membrane, endosomal, and lysosomal markers, detected with specific antibodies, was determined after infection. At 48 h after infection, p.v. was found to exhibit a membrane composition typical of mature lysosomes. Overall, these data suggest that (i) Ia located in p.v. originate from secondary lysosomes involved in the biogenesis of this compartment or circulate in several endocytic organelles, including lysosomes and (ii) p.v. could play a role in antigen processing and presentation. Alternatively, the presence of high amounts of Ia in p.v. could be due to a Leishmania-induced mechanism by means of which this organism may evade the immune response.     

Depletion of secondary lysosomes in mouse macrophages infected withLeishmania mexicana amazonensis: A cytochemical study

Leishmania amastigotes lodge and multiply within parasitophorous vacuoles, which can fuse with secondary lysosomes of the host macrophages. This study examines the effect of infection with amastigotes ofL. mexicana amazonensis on the secondary lysosomes of mouse macrophage cultures. The cultures were stained for the activities of two lysosomal enzyme markers, acid phosphatase and arylsulfatase, and the light microscopic observations were supplemented by electron microscopy. Nearly all noninfected macrophages contained numerous stained secondary lysosomes. The number of such lysosomes was markedly reduced 24 h postinfection, and the reduction persisted for at least 10 days. Stained secondary lysosomes reppeared after the amastigotes were destroyed by exposure of the cultures to phenazine methosulfate or by placing them at 37.5° C. The depletion of lysosomes shown by cytochemical methods may reflect a high rate of fusion of the lysosomes with the parasitophorous vacuoles, exceeding the rate of formation of new secondary lysosomes. Alternatively, the parasites may inhibit the synthesis of lysosomal hydrolases, or the assembly or formation of primary or secondary lysosomes.     

Effect of glucocorticosteroids on phagosome-lysosome interaction.

The effects of hydrocortisone on fusion of thorotrast-labeled lysosomes with phagosomes containing killed toxoplasmas was studied. Mouse peritoneal macrophages from glucocorticosteroid-treated animals fromed phagolysosomes just as effectively as macrophages from untreated animals (72% thorotrast-positive vacuoles in hydrocortisone-treated animals; 78% in controls). The electron microscopic appearence of macrophages from treated or untreated animals was similar. This observation complements studies which show no change in intracellular microbicidal activity in macrophages treated with glucocorticosteriods.     

Burkholderia cenocepacia requires the RpoN sigma factor for biofilm formation and intracellular trafficking within macrophages

Chronic respiratory infections by Burkholderia cenocepacia in cystic fibrosis patients are associated with increased morbidity and mortality, but virulence factors determining the persistence of the infection in the airways are not well characterized. Using a chronic pulmonary infection model, we previously identified an attenuated mutant with an insertion in a gene encoding an RpoN activator protein, suggesting that RpoN and/or components of the RpoN regulon play a role in B. cenocepacia virulence. In this study, we demonstrate that a functional rpoN gene is required for bacterial motility and biofilm formation in B. cenocepacia K56-2. Unlike other bacteria, RpoN does not control flagellar biosynthesis, as evidenced by the presence of flagella in the rpoN mutant. We also demonstrate that, in macrophages, the rpoN mutant is rapidly trafficked to lysosomes while intracellular wild-type B. cenocepacia localizes in bacterium-containing vacuoles that exhibit a pronounced delay in phagolysosomal fusion. Rapid trafficking to the lysosomes is also associated with the release of red fluorescent protein into the vacuolar lumen, indicating loss of bacterial cell envelope integrity. Although a role for RpoN in motility and biofilm formation has been previously established, this study is the first demonstration that the RpoN regulon in B. cenocepacia is involved in delaying phagolysosomal fusion, thereby prolonging bacterial intracellular survival within macrophages.     

Inhibition of chlamydial infectious activity due to P2X7R-dependent phospholipase D activation

Chlamydia trachomatis survives within host cells by inhibiting fusion between Chlamydia vacuoles and lysosomes. We show here that treatment of infected macrophages with ATP leads to killing of chlamydiae through ligation of the purinergic receptor, P2X(7)R. Chlamydial killing required phospholipase D (PLD) activation, as PLD inhibition led to rescue of chlamydiae in ATP-treated macrophages. However, there was no PLD activation nor chlamydial killing in ATP-treated P2X(7)R-deficient macrophages. P2X(7)R ligation exerts its effects by promoting fusion between Chlamydia vacuoles and lysosomes. P2X(7)R stimulation also resulted in macrophage death, but fusion with lysosomes preceded macrophage death and PLD inhibition did not prevent macrophage death. These results suggest that P2X(7)R ligation leads to PLD activation, which is directly responsible for inhibition of infection.     

Infection of murine peritoneal macrophages withToxoplasma gondii exposed to ultraviolet light

Exposure ofToxoplasma trophozoites to ultraviolet light (UV; 2,539 Å) remarkably inhibited intracellular multiplication of the toxoplasmas within cultured mouse peritoneal macrophages. These toxoplasmas possessed the ability to induce normal parasitophorous vacuoles (PV) and underwent gradual degeneration in the PV without participation of host-cell lysosomes. Apparently, the basic conformation of the PV, i.e., the association of mitochondria, rough endoplasmic reticulum, and microtubules of the host cell and the presence of microvillous infoldings, was maintained as seen under the electron microscope even after the toxoplasmas had died within the PV. Even PV, in which debris of the toxoplasmas could be observed, did not show the sign of fusion with ferritin-labeled secondary lysosomes.     

Localization and activity of various lysosomal proteases in Leishmania amazonensis-infected macrophages.

In mammalian hosts, Leishmania amastigotes are obligatory intracellular parasites of macrophages and multiply within parasitophorous vacuoles of phagolysosomal origin. To understand how they escape the harmful strategies developed by macrophages to kill ingested microorganisms, it is important to obtain information on the functional state of parasitophorous vacuole. For this purpose, we studied the intracellular distribution and activity of host lysosomal proteases in rat bone marrow-derived macrophages infected with Leishmania amazonensis amastigotes. Localization of cathepsins B, H, L, and D was investigated by using specific immunoglobulins. In uninfected macrophages, these enzymes were located in perinuclear granules (most of them were probably secondary lysosomes) which, after infection, disappeared progressively. In infected macrophages, cathepsins were detected mainly in the parasitophorous vacuoles, suggesting that the missing secondary lysosomes had fused with these organelles. Biochemical assays of various proteases (cathepsins B, H, and D and dipeptidyl peptidases I and II) showed that infection was accompanied by a progressive increase of all activities tested, except that of dipeptidyl peptidase II, which remained constant. No more than 1 to 10% of these activities could be attributed to amastigotes. These data indicate that (i) Leishmania infection is followed by an increased synthesis and/or a reduced catabolism of host lysosomal proteases, and (ii) amastigotes grow in a compartment rich in apparently fully active proteases. Unexpectedly, it was found that infected and uninfected macrophages degraded endocytosed proteins similarly. The lack of correlation in infected macrophages between increase of protease activities and catabolism of exogenous proteins could be linked to the huge increase in volume of the lysosomal compartment.     

Dynamic Nature of Host-Pathogen Interactions in Mycobacterium marinum Granulomas

Mycobacterium marinum causes long-term subclinical granulomatous infection in immunocompetent leopard frogs (Rana pipiens). These granulomas, organized collections of activated macrophages, share many morphological features with persistent human tuberculous infection. We examined organs of frogs with chronic M. marinum infection using transmission electron microscopy in conjunction with immunohistochemistry and acid phosphatase cytochemistry to better define the bacterium-host interplay during persistent infection. Bacteria were always found within macrophage phagosomes. These phagosomes were often fused to lysosomes, in sharp contrast to those formed during in vitro infection of J774 macrophage-like cells by M. marinum. The infected macrophages in frog granulomas showed various levels of activation, as evidenced by morphological changes, including epithelioid transformation, recent phagocytic events, phagolysosomal fusion, and disintegration of bacteria. Our results demonstrate that even long-term granulomas are dynamic environments with regard to the level of host cell activation and bacterial turnover and suggest a continuum between constantly replicating bacteria and phagocytic killing that maintains relatively constant bacterial numbers despite an established immune response. Infection with a mutant bacterial strain with a reduced capacity for intracellular replication shifted the balance, leading to a greatly reduced bacterial burden and inflammatory foci that differed from typical granulomas.     

Brucella suis-impaired specific recognition of phagosomes by lysosomes due to phagosomal membrane modifications

Brucella species are gram-negative, facultatively intracellular bacteria that infect humans and animals. These organisms can survive and replicate within a membrane-bound compartment in phagocytic and nonprofessional phagocytic cells. Inhibition of phagosome-lysosome fusion has been proposed as a mechanism for intracellular survival in both types of cells. However, the biochemical mechanisms and microbial factors implicated in Brucella maturation are still completely unknown. We developed two different approaches in an attempt to gain further insight into these mechanisms: (i) a fluorescence microscopy analysis of general intracellular trafficking on whole cells in the presence of Brucella and (ii) a flow cytometry analysis of in vitro reconstitution assays showing the interaction between Brucella suis-containing phagosomes and lysosomes. The fluorescence microscopy results revealed that fusion properties of latex bead-containing phagosomes with lysosomes were not modified in the presence of live Brucella suis in the cells. We concluded that fusion inhibition was restricted to the pathogen phagosome and that the host cell fusion machinery was not altered by the presence of live Brucella in the cell. By in vitro reconstitution experiments, we observed a specific association between killed B. suis-containing phagosomes and lysosomes, which was dependent on exogenously supplied cytosol, energy, and temperature. This association was observed with killed bacteria but not with live bacteria. Hence, this specific recognition inhibition seemed to be restricted to the pathogen phagosomal membrane, as noted in the in vivo experiments.     

Inhibition of phagosome-lysosome fusion in ovine polymorphonuclear leucocytes by Ehrlichia (Cytoecetes) phagocytophila

Ehrlichia (Cytoecetes) phagocytophila, the causative agent of tick-borne fever, is an intracellular bacterium that survives and multiplies within granulocytes and monocytes. In the present study, the possible fusion of lysosomes with phagosomes containing E. phagocytophila was investigated in poly-morphonuclear (PMN) cells of sheep infected with the agent, acid phosphatase cytochemistry and cationized ferritin being used as markers of primary and secondary lysosomal enzymes. Latex beads or Candida albicans were incubated with infected and uninfected PMN cells and labelled with the same lysosomal markers. Lysosomal enzymes labelled with the markers were commonly found in phagosomes containing latex beads or C. albicans, but there was no evidence of phagosome-lysosome (P-L) fusion in phagosomes containing E. phagocytophila. It was significant that in cells that contained E. phagocytophila, latex beads and C. albicans, P-L fusion occurred only in phagosomes containing latex beads or C. albicans. However, evidence of P-L fusion with phagosomes containing E. phagocytophila was obtained when PMN cells were incubated with oxytetracycline, which is known to inhibit synthesis of bacterial proteins. These findings indicate that E. phagocytophila is capable of inhibiting P-L fusion and that oxytetracycline depresses this capability.     

In vitro response of alveolar macrophages to infection with Coccidioides immitis.

Alveolar macrophages obtained from rhesus macaques (Macaca mulatta) by bronchial lavage were observed to phagocytize endospores and arthrospores of Coccidioides immitis. When the macrophages were subsequently maintained in vitro, the phagocytized spores developed into spherules. There was no significant reduction in the viability of C. immitis after phagocytosis by macrophages from normal macaques, nor was killing induced by the addition of immune serum, complement, or lung lining material obtained from the bronchial lavage fluid. The inability of the macrophages to kill C. immitis may in part be explained by the observation that C. immitis appeared to inhibit fusion of the phagosomes containing the fungal spores with the lysosomes within the macrophages.