Bacterial antigen immunolabeling in macrophages after phagocytosis and degradation of Bacillus subtilis

Uptake of oxidized LDL by macrophages differs from that of acetyl LDL and leads to expansion of an acidic endolysosomal compartment

Accumulation of cholesterol by macrophage foam cells in atherosclerotic lesions is thought to involve the uptake of modified low density lipoproteins (LDLs). Previous studies have shown that there is impaired degradation of oxidized LDL in macrophages. The present study was done to determine whether the differences in intracellular metabolism of oxidized LDL and acetyl LDL were associated with delivery to different intracellular compartments. Mouse peritoneal macrophages were incubated with 1,1'-dioctadecyl-3, 3,3',3'-tetramethylindocarbocyanine perchlo- rate-labeled oxidized LDL or 3,3'-dioctadecyloxacarbocyanine perchlorate-labeled acetyl LDL and examined by fluorescence microscopy. Deconvolution image analysis showed <10% colocalization of the 2 lipoproteins at incubation times ranging from 30 minutes to 6 hours. Subcellular fractionation of macrophages after incubation with (99m)Tc-labeled oxidized LDL revealed accumulation of the tracer in a compartment with a d=1.042 g/mL, consistent with endosomes. Surprisingly, there was a concurrent dramatic shift of the density of lysosomal marker enzymes from d=1.1 g/mL to the same fractions that contained (99m)Tc, indicating that this compartment was formed after fusion with primary lysosomes. Parallel experiments in J774 cells, a murine macrophage-like cell line, did not show a similar density shift, perhaps because of the slower rate of accumulation of oxidized LDL by these cells. Fluorescence microscopy of macrophages labeled with a lysosomotropic dye revealed a marked expansion of the acidic compartment after exposure of cells to oxidized LDL. We conclude that oxidized LDL and acetyl LDL are internalized by morphologically distinct pathways. Furthermore, because of its impaired lysosomal degradation, oxidized LDL causes expansion of and a decrease in the density of the lysosomal compartment in macrophages.

Lysosomal Accumulation and Recycling of Lipopolysaccharide to the Cell Surface of Murine Macrophages, an In Vitro and In Vivo Study

In this study, we detailed in a time-dependent manner the trafficking, the recycling, and the structural fate of Brucella abortus LPS in murine peritoneal macrophages by immunofluorescence, ELISA, and biochemical analyses. The intracellular pathway of B. abortus LPS, a nonclassical endotoxin, was investigated both in vivo after LPS injection in the peritoneal cavity of mice and in vitro after LPS incubation with macrophages. We also followed LPS trafficking after infection of macrophages with B. abortus strain 19. After binding to the cell surface and internalization, Brucella LPS is routed from early endosomes to lysosomes with unusual slow kinetics. It accumulates there for at least 24 h. Later, LPS leaves lysosomes and reaches the macrophage cell surface. This recycling pathway is also observed for LPS released by Brucella S19 following in vitro infection. Indeed, by 72 h postinfection, bacteria are degraded by macrophages and LPS is located inside lysosomes dispersed at the cell periphery. From 72 h onward, LPS is gradually detected at the plasma membrane. In each case, the LPS present at the cell surface is found in large clusters with the O-chain facing the extracellular medium. Both the antigenicity and heterogenicity of the O-chain moiety are preserved during the intracellular trafficking. We demonstrate that LPS is not cleared by macrophages either in vitro or in vivo after 3 mo, exposing its immunogenic moiety toward the extracellular medium.

Entry of Borrelia burgdorferi into macrophages is end-on and leads to degradation in lysosomes

The Lyme disease spirochete, Borrelia burgdorferi, is ingested rapidly by mouse macrophages in vitro. Spirochetes attach by their ends and become progressively coiled as they move deeper into cells. From the earliest measurements, spirochetes colocalize with a marker of endosomes and lysosomes, and degradation of spirochetes occurs within lysosomes.

Susceptibility of lipopolysaccharide-responsive and -hyporesponsive ItyS Mice to infection with rough mutants of Salmonella typhimurium

The R5 (chemotype Rb) but not the R10 (chemotype Rd) mutant of murine pathogen Salmonella typhimurium 395MS was extremely virulent in intraperitoneal infections of C57BL/10ScCr mice carrying the ityS and lpsD alleles. C57BL/6J (ityS lpsN) and C3H/HeJ (ityR lpsD) mice showed a much higher resistance to the R5 mutant. Further studies were performed with peritoneal macrophages in vitro in order to elucidate susceptibility in lipopolysaccharide (LPS)-hyporesponsive mice carrying ItyS. The intracellular killing capacity of the ItyS LpsD macrophages was lower than that of the ItyS LpsN macrophages for the R5 mutant and may partly explain the increased susceptibility of the ItyS LpsD mice. The deep rough mutant, R10, was rapidly killed intracellularly by the ItyS LpsD macrophages. Processing of the bacteria in macrophages that had phagocytosed R5 or R10 bacteria was followed for up to 18 days by endotoxin measurements (limulus assay) and immunostaining, with monoclonal antibodies to various parts of the LPS molecule being used. Only 0.1% or less of the macrophage-associated bacteria remained alive after 48 h of incubation, and none were alive on day 7. Although immunostaining showed that LPS was present in both the LpsD and LpsN macrophages during the whole incubation period of 18 days, endotoxin activity in the LpsD macrophages on day 7 was lower than that in the LpsN macrophages, indicating that qualitative modifications of the chemical composition or physical state of the LPS molecule occurred. The interleukin-6 response in the ItyS LpsD macrophages was delayed and of shorter duration compared with that in the ItyS LpsN macrophages. The results suggest that the difference between the LPS-hyporesponsive and -responsive ItyS mice in susceptibility to infection with the R5 mutant was due to the lower activation state of the LpsD macrophages during infection, leading to a lower intracellular bactericidal systems of the macrophages. A rapid killing of the bacterium should restrict the infection and may partly compensate for a diminished inflammatory response. The persistence of LPS within the cells is discussed.

Fate of Listeria monocytogenes in murine macrophages: evidence for simultaneous killing and survival of intracellular bacteria

The intracellular survival of the ubiquitous pathogen Listeria monocytogenes was studied in primary cultures of bone marrow-derived mouse macrophages. Bacteria were able to grow rapidly in these cells, with an apparent multiplication rate of about 40 min. Electron microscopy demonstrated that intracellular bacterial replication was the consequence of simultaneous intracellular killing and replication of bacteria in the same cells. Within the first hour following phagocytosis, most bacteria were destroyed in the phagosomal compartment to which they were confined. This was due to early transfer of hydrolytic enzymes to phagosomes, undoubtedly via phagosome-lysosome (P-L) fusion, as demonstrated by a quantitative analysis after staining for a lysosomal marker, acid phosphatase. One hour after infection, about 14% of the bacteria were free in the cytoplasm, in which they multiplied and induced actin polymerization and spreading to adjacent macrophages, as in epithelial cells. By using the 3-(2,4-dinitroanilino)-3'-amino-N-methyldipropylamine staining procedure, direct evidence is presented that all phagosomes were acidified immediately after phagocytosis, thus indicating that intraphagosomal bacteria were exposed to an acidic environment that might favor vacuolar lysis by listeriolysin O. Intracellular growth in macrophages, therefore, appears to be the result of a competition between the expression of the hydrolytic activity of these cells following P-L fusion and the capacity of L. monocytogenes to escape from the acidified phagosomal compartment before P-L fusion has occurred. The finding that concomitant intracellular killing and survival of L. monocytogenes occurs in the same macrophages might explain the high immunogenicity observed in vivo with live bacteria, as opposed to killed bacteria.

Yersinia lipopolysaccharide is modified by human monocytes

Reactive arthritis is usually self-limiting polyarthritis, which develops after certain gastrointestinal or urogenital tract infections, mostly in susceptible HLA B27-positive individuals. In the pathogenesis of this arthritis, it is probably important that structures of the causative bacteria are found in the affected joints. The structure found in the synovial fluid phagocytes of the patients with reactive arthritis after Yersinia, Salmonella, and Shigella infections has always been lipopolysaccharide (LPS) of the causative bacteria. It has been in a highly processed form but still immunoreactive. To follow the degradation process of LPS, we fed peripheral blood monocytes of healthy blood donors with heat-killed Yersinia enterocolitica O:3 bacteria in vitro and monitored the fate of LPS by immunofluorescence and immunoblotting methods. Heat-killed bacteria were used since Y. enterocolitica O:3 bacteria are able to live inside monocytes in vitro and dividing intracellular bacteria would have made it impossible to monitor the degradation process of LPS with these methods. Both the core region and the O-polysaccharide chain of LPS persisted in cytoplasmic vacuoles and on plasma membrane of monocytes through the 7-day follow-up time. Migration properties of processed LPS in sodium dodecyl sulfate-polyacrylamide gel electrophoresis suggested structural modifications of LPS. We also demonstrated that core epitopes appearing on the surface of Yersinia-fed monocytes on day 4 of incubation were processed intracellularly, suggesting that LPS-containing phagocytes are a constant source of membrane-active LPS in their microenvironment as well as in the joints of arthritic patients.

Tracing iron and transferrin in the macrophage by visual means

The purpose of the study was to investigate the movement of iron and transferrin in the macrophage using light and electron microscopy. First, depicted here are the phagocytosis of antibody sensitized murine red cells by the murine bone marrow derived macrophage and the formation of red cell phagosomes. Second, we show the fusion of the lysosomes with the red cell phagosome to form a lysophagosome and the lysis of the red cell using acid phosphatase as a lysosome marker. Third by autoradiography, the presence of 55Fe silver grains in the phagocytosed red cells and its delivery to the organelles of the macrophage are demonstrated. Fourth a transferrin species is shown in red cells of all ages, in the phagocytosed as well as the non-phagocytosed, and in the phagocytosed as well as the non-phagocytosed, and in the macrophage itself. Transferrin was detected using immunogold and fluorescence labelling. These studies suggest that iron, using vesicles as means of transport, moves from the effete red cells inside the macrophage to the outside possibly bound to transferrin.

Class II MHC molecules are present in macrophage lysosomes and phagolysosomes that function in the phagocytic processing of Listeria monocytogenes for presentation to T cells

Phagocytic processing of heat-killed Listeria monocytogenes by peritoneal macrophages resulted in degradation of these bacteria in phagolysosomal compartments and processing of bacterial antigens for presentation to T cells by class II MHC molecules. Within 20 min of uptake by macrophages, Listeria peptide antigens were expressed on surface class II MHC molecules, capable of stimulating Listeria-specific T cells. Within this period, degradation of labeled bacteria to acid-soluble low molecular weight catabolites also commenced. Immunoelectron microscopy was used to evaluate the compartments involved in this processing. Upon uptake of the bacteria, phagosomes containing Listeria fused rapidly with both lysosomes and endosomes. Class II MHC molecules were present in a tubulo-vesicular lysosome compartment, which appeared to fuse with phagosomes, as well as in the resulting phagolysosomes containing internalized Listeria; these compartments were all positive for Lamp 1 and cathepsin D and lacked 46-kD mannose-6-phosphate receptors. In addition, class II MHC and Lamp 1 were co-localized in vesicles of the trans Golgi reticulum, where they were segregated from 46-kD mannose-6-phosphate receptors. Vesicles containing both Listeria-derived components and class II MHC molecules were also observed; some of these may represent vesicles recycling from phagolysosomes, potentially bearing processed immunogenic peptides complexed with class II MHC. These results support a central role for lysosomes and phagolysosomes in the processing of bacterial antigens for presentation to T cells. Tubulo-vesicular lysosomes appear to represent an important convergence of endocytic, phagocytic and biosynthetic pathways, where antigens may be processed to allow binding to class II MHC molecules and recycling to the cell surface.

Presentation of Leishmania donovani promastigotes occurs via a brefeldin A-sensitive pathway

For the presentation of Leishmania promastigotes to polyclonal CD4+ T cells, a processing period within activated macrophages of 3-4 h is required. Presentation can be inhibited by both chloroquine and brefeldin A (BFA), the latter implicating a requirement for newly synthesized MHC class II molecules. This inhibition is both reversible and specific, in that BFA did not inhibit mixed lymphocyte reaction stimulation by these infected macrophages. Immunogold labeling demonstrated that class II was associated with the parasite-containing phagolysosome. The level of class II was not significantly altered in BFA-treated cells in the time period studied, suggesting that antigen may exist the phagolysosome and interact with class II in another cellular compartment.

Localization of MHC class II molecules in murine bone marrow-derived macrophages

The localization of MHC class II molecules (Ia) was studied by ultrastructural immunocytochemistry in murine bone marrow-derived macrophages stimulated by recombinant interferon-gamma (rIFN-gamma). Ia molecules were detected on the plasma membrane and on the limiting membrane and internal structures of vesicular acidic compartments. Some of these vesicules also contained cathepsin B and/or cathepsin D. The use of BSA-gold, a marker of fluid phase endocytosis, allowed the identification of Ia-positive organelles as endocytic compartments. The first to be labelled with BSA-gold also contained the cation-independent mannose 6-phosphate receptor (MPR) but not the 120,000 molecular weights lysosomal glycoprotein (lgp 120). Later on, BSA-gold appeared in Ia+, MPR+, lgp 120+ compartments. Collectively these data suggest that intracellular Ia molecules are mainly present in early and late endosomes.

Immunolabelling of Shiga toxin in macrophages infected with Shigella dysenteriae 1

Immunolabelling of Shiga toxin in macrophages infected with a non-invasive Shigella dysenteriae 1 isolate showed that bacteria remained alive for 3 h after ingestion within the phagocytic vacuole and synthesized Shiga toxin. The normal process of toxin secretion was, however, impaired by the phagosomal environment and toxin molecules accumulated within the bacterial cytoplasm.

Improved sectioning and ultrastructure of bacteria and animal cells embedded in Lowicryl

Lowicryl K4M-embedded Gram-positive and Gram-negative bacteria have a tendency to separate between the cell surface and the resin. This often leads to distortion of bacteria and more especially of mycobacteria. We describe attempts made to overcome this technical problem. Different assays were made on Bacillus subtilis, Escherichia coli, and Mycobacterium avium: 1) Modification of the bacterial surface by coating of bacteria with proteinic compounds; 2) treatment of bacteria with metallic salts known to modify cell wall polysaccharides; and 3) comparison between Lowicryl K4M and HM20. Conditions have been found in which the separation of all bacterial species from the resin is abolished. The most important factor appeared to be the treatment of bacteria before dehydration, with 0.5% uranyl acetate for 30 min. The second most important factor, especially for M. avium and to a lower extent for Gram-negative bacteria, was the use of Lowicryl HM20. No differences were observed with Gram-positive bacteria between K4M and HM20. Pre-embedding in gelatin instead of agar improved sectioning of M. avium, but had no effects on the other bacterial species. These conditions applied to macrophages infected with Shigella dysenteriae or M. avium also gave excellent results. In addition to sectioning improvement of bacteria, uranyl acetate improved the ultrastructure of bacteria and macrophages. All organelles were more clearly delineated and, hence, more easily identified. Finally, it was shown that UA treatment did not affect immunogold labeling of a variety of antigens.

Intracellular survival of wild-type Salmonella typhimurium and macrophage-sensitive mutants in diverse populations of macrophages

Salmonella typhimurium survives within macrophages and causes a fatal infection in susceptible strains of mice. A number of S. typhimurium mutants that contain Tn10 insertions in genes which are necessary for survival within the macrophage have been isolated. To demonstrate the importance of each gene in intracellular survival, the mutations were transduced into a smooth-strain background and the ability to survive intracellularly was assayed in five different populations of macrophages. The majority of the original macrophage-sensitive mutants retained the macrophage-sensitive phenotype in the smooth-strain background. The ability to survive or grow within macrophages varied with both the source of macrophages and the individual mutants. S. typhimurium grew best in the macrophage-like cell line J774, survived at moderate levels in splenic and bone marrow-derived macrophages, and was killed most efficiently in peritoneal macrophages. Macrophage-sensitive mutants transduced into a smooth background were also less virulent than the parent, with a 50% lethal dose of 2 to 5 logs greater than that of the parental strain. These experiments demonstrate that survival of S. typhimurium within macrophages varies with the source of cells, with a distinct ability to survive in macrophages from mouse spleens, where S. typhimurium grows rapidly. These experiments also demonstrate the heterogeneity in intracellular survival among the various macrophage-sensitive mutants, which may reflect the relative importance of the individual mutated genes in survival within macrophages.