Phagocyte-bacteria interactions.

Recognition and phagocytosis of micro-organisms in a serum-poor environment represent innate immunity against many extracellular pathogens. As a paradigm for such processes, we discuss the recognition of Klebsiella pneumoniae by alveolar macrophages and monocyte-derived macrophages in the absence of serum. Macrophages recognize and subsequently kill Klebsiella expressing Man-alpha 2/3-Man or Rha-alpha 2/3-Rha sequences in their capsular polysaccharides by two mechanisms: (a) recognition of the capsular structures by macrophage mannose receptors, and (b) opsonization by the lung surfactant protein A (SP-A), which binds to the capsular polysaccharides of Klebsiella and to SP-A receptors on the macrophages. Sp-A may also enhance phagocytosis by increasing the activity of macrophage mannose receptors. We conclude that a specific microbial surface structure may be a target for recognition by macrophages via several mechanisms, as exemplified in the case of Klebsiella capsular polysaccharides. Multiple recognition mechanisms of pathogens by macrophages may be essential to provide innate immunity to reduce the frequency of infections caused by a relatively less virulent bacterium in the immuno-compromised host.

Lung surfactant protein A (SP-A) activates a phosphoinositide/calcium signaling pathway in alveolar macrophages.

Lung surfactant protein A (SP-A), the main protein component of lung surfactant which lines the alveoli, strongly enhances serum-independent phagocytosis of bacteria by rat alveolar macrophages. We tested if the effect of SP-A is due to interaction with the macrophages or to opsonization of the bacteria. In phagocytosis assays with fluorescein isothiocyanate labeled bacteria, SP-A had no opsonic effect on Escherichia coli, Pseudomonas aeruginosa and Staphylococcus aureus, but enhanced phagocytosis by acting only on the macrophages. We characterized this activation mechanism. With single cell measurements of fura-2 loaded cells we demonstrate that SP-A raises the intracellular free calcium ion concentration 6 to 8 seconds after addition. This calcium mobilization is dose-dependent in that increased SP-A concentrations lead to a higher percentage of responding cells. Additionally, SP-A leads to a dose-dependent and transient generation of inositol 1,4.5-trisphosphate. Release of intracellular stored calcium by SP-A is a prerequisite for its stimulatory effect on phagocytosis, since SP-A-induced enhancement of phagocytosis can be impaired by prior addition of thapsigargin, a Ca(2+)-ATPase inhibitor that leads to depletion of intracellular calcium stores. We conclude that SP-A activates a phosphoinositide/calcium signaling pathway in alveolar macrophages leading to enhanced serum-independent phagocytosis of bacteria.

Relationships among capsular structure, phagocytosis, and mouse virulence in Klebsiella pneumoniae.

Klebsiella pneumoniae strains of the K2 capsular serotype are usually highly virulent in mice, which is in contrast to the low virulence of most other serotypes. Here we used a genetic approach to examine the relative contribution of capsule type to the virulence of K. pneumoniae in mice. We used wild-type strains expressing capsular polysaccharide (CPS) serotypes K2 (strain KPA1) and K21a (strains KPB1 and KPC1), which were then used to construct capsule-switched derivatives. The close proximity of the cps gene cluster to selectable his markers made it possible to mobilize the cps genes by conjugation from one serotype (donor) to another (recipient) and to obtain recombinants in which interserotype switching had occurred by reciprocal recombination. Each capsule-switched derivative examined of the KPA and KPC strain backgrounds produced a CPS that was immunologically and structurally identical to that of the donor. Strain background was confirmed by demonstrating restriction fragment length polymorphism patterns identical to those of the respective recipients. The parent strains were then compared with capsule-switched recombinants for phenotypic properties associated with virulence. Clearance from the bloodstreams of mice was rapid in serotype K21a strains of either wild-type or recombinant origin, whereas K2 strains remained viable in the blood during the period examined. These differences appeared to be dependent upon the CPS type but independent of strain background. Binding to macrophages was higher in K21a strains than in those with the K2 capsule and was also independent of the strain background. Both blood clearance and macrophage-binding activities were completely inhibited by yeast mannan, suggesting that they were mediated via the macrophage mannose receptor. The K2 parent strain was highly virulent to mice (50% lethal dose [LD50], 3 x 10(3)), while the K21a parent strains demonstrated low virulence (LD50, > 2 x 10(8)). Interestingly, the virulence of recombinant KPC10(cpsK2), originally of the KPC1(cpsK21a) background, was intermediate (LD50, 4 x 10(5)). In contrast, both cpsK21a recombinants of the originally virulent KPA1 (cpsK2) background became nearly avirulent (LD50, > 2 x 10(8)). Six additional serotypes (K12, K24, K32, K55, K62, and K67) were examined, and all showed a positive correlation between the ability of the Klebsiella serotype to interact with a human mannose receptor, as expressed by Cos I cell recombinants, and the LD50 of the serotype. These results suggest that expression of a capsule which is recognized by the mannose receptor markedly affects the interaction with macrophages and blood clearance.(ABSTRACT TRUNCATED AT 400 WORDS)

Interaction of lung surfactant protein A with alveolar macrophages.

We analyzed the binding mechanism of human recombinant lung surfactant protein A (SP-A) to rat alveolar macrophages using anti-SP-A antiserum and protein A coated onto gold particles. Results were compared with our recent data on binding and uptake of SP-A-coated colloidal gold particles. The rationale for the current approach was to avoid any possible steric effects on SP-A binding to the cell surface. Binding of unlabeled SP-A depends on the presence of calcium ions in the medium and involves a mannose-specific mechanism. Binding is partly inhibited by the collagenase-resistant fragment of SP-A, representing mainly the globular part of SP-A. Taken together, these facts indicate binding of SP-A via the carbohydrate binding site on the globular region of SP-A. On the other hand, a partial inhibition of SP-A binding by fragments of C1q (representing the collagenous region of C1q) indicates a second binding site for SP-A by the collagen-like portion to the C1q receptor of macrophages. We conclude that two different mechanisms are probably involved in SP-A binding to alveolar macrophages. Specificity of the binding was shown with fluorescein-labeled SP-A. Binding was inhibited by an excess of unlabeled SP-A. Binding and uptake of SP-A are seen only with alveolar macrophages and not with other macrophage populations isolated from rat, such as liver macrophages (Kupffer cells), resident peritoneal macrophages, and peritoneal macrophages activated by Corynebacterium parvum. Therefore, binding sites for SP-A occur exclusively on alveolar macrophages.(ABSTRACT TRUNCATED AT 250 WORDS)

Lung surfactant protein A (SP-A) enhances serum-independent phagocytosis of bacteria by alveolar macrophages.

Surfactant protein A (SP-A) is the main protein component of lung surfactant. We studied the involvement of SP-A in body defense, i.e., effect of SP-A on the phagocytosis of bacteria by alveolar macrophages. We show here that SP-A enhances the phagocytosis of some non-opsonized bacteria: Escherichia coli growing logarithmically (E. coli/log), Pseudomonas aeruginosa/log as well as from stationary phase (P. aeruginosa/stat) and Staphylococcus aureus/log. Furthermore, not only serum-independent phagocytosis was effected by SP-A but also phagocytosis of serum-opsonized S. aureus/stat. No effect of SP-A on phagocytosis was observed with E. coli/stat neither on serum-independent nor on serum-dependent phagocytosis and on phagocytosis of non-opsonized S. aureus/stat. Thus, effect of SP-A on phagocytosis is dependent on bacterial species and on the growth phase of the microorganisms, and this effect is concentration dependent. We studied two different human recombinant SP-As and SP-A isolated from lung lavage material from proteinosis patients. These SP-A molecules contain different isomeric chains, and they differ in complexity of their structure. Qualitatively, we found the same effect with all three substances. Quantitatively, the proteinosis SP-A that forms the most complex structure was the most effective. Taken together, we demonstrated a stimulating effect of SP-A on serum-independent as well as on serum-dependent phagocytosis of bacteria by alveolar macrophages, both depending on species and growth phase of the bacteria.

Electron microscopic demonstration of glucocorticoid recognition sites on isolated rat hepatocytes.

Ultrastructural evidence is presented for the presence of membrane-bound glucocorticoid recognition and binding sites. Corticosterone was derivatized at 3 different positions and coupled covalently to bovine serum albumin (BSA). All three derivatives competed for binding of [3H]corticosterone by isolated rat hepatocytes. The most effective competitor, corticosterone-succinate-BSA (CSB), was adsorbed onto colloidal gold particles (CSB-gold, 17 +/- 3 nm dia). When isolated rat hepatocytes or mouse pituitary tumor cells (AtT 20) are incubated with CSB-gold, specific binding in the microvilli-rich region of these cells is seen. This binding of CSB-gold is reduced by about 50% in the presence of unlabelled CSB or corticosterone.

Specific interaction of lung surfactant protein A (SP-A) with rat alveolar macrophages.

We have analyzed interaction of recombinant human surfactant protein A (SP-A) with isolated rat alveolar macrophages in the electron microscope. SP-A coated onto gold particles of different diameter is bound and internalized by macrophages. Binding and uptake occurs via coated membrane structures. SP-A gold particles are transported to secondary lysosomes. Binding and uptake is specific; i.e., excess of SP-A inhibits SP-A gold particle binding and uptake by 67% and depends on the presence of divalent cations. In experiments with ManBSA (5 x 10(-6) M) inhibition is 60%, but no inhibition occurs with GalBSA. The mannose-dependent interaction of SP-A particles with macrophages is not due to the mannose-specific receptor on the cell surface of macrophages as shown in experiments with macrophages exhibiting reduced mannose receptor activity. These cells show reduced binding and uptake of mannan gold particles (42% inhibition) but no reduction of SP-A gold particle binding and uptake. Furthermore, mannan gold particles do not compete with binding of SP-A gold particles.

The interaction of a lung surfactant protein (SP-A) with macrophages is mannose dependent.

Lung surfactant protein A (SP-A) is the main protein component of pulmonary surfactant, which lines the alveolar space. We examined the interaction between recombinant human SP-A and human macrophages or monocytes. Binding and uptake of SP-A adsorbed onto colloidal gold particles was followed by electron microscopy and quantitated on micrographs. SP-A particles were internalized via coated pits/vesicles and transported to secondary lysosomes. Uptake was inhibited in the presence of alpha-D-mannosyl-bovine serum albumin (BSA) but not by beta-D-galactosyl-BSA. Two mannose-dependent recognition mechanisms might mediate SP-A uptake by macrophages. First, as SP-A is a glycoprotein with N-glycosylated glycans it could act as a ligand for the mannose-specific receptor on macrophages. Second, as SP-A is a mannose-specific lectin itself it could bind to mannose residues on the macrophage's cell surface. Activity of the Man-receptor on macrophages was demonstrated with alpha-D-mannosyl-BSA coated onto gold particles. Exposed alpha-D-mannosyl residues on macrophages were identified by Concanavalin A adsorbed onto gold particles. Hence, both mechanisms may be involved in principle. As monocytes have no mannose-specific receptor activity on their cell surface but internalize SP-A gold particles in a mannose-dependent manner, we conclude that at least the second mechanism participates in the recognition of SP-A by macrophages.

Carcinoma autoantigens T and Tn and their cleavage products interact with Gal/GalNAc-specific receptors on rat Kupffer cells and hepatocytes.

We studied interactions of isolated Thomsen-Friedenreich (T)- and Tn-specific glycoproteins with the Gal/GalNAc-specific receptors on rat Kupffer cells and compared them to those with rat hepatocytes. Immunoreactive T and Tn are specific pancarcinoma epitopes. Electron microscopy of gold-labelled T and Tn antigens revealed their specific binding to Kupffer cells, followed by their uptake via the coated pit/vesicle pathway of receptor-mediated endocytosis. Preincubation of Kupffer cells with GalNAc and GalNAc-BSA, but not GlcNAc or GlcNAc-BSA specifically inhibited binding of the T and Tn glycoproteins. Desialylated, isologous erythrocytes (T RBC) are known to bind to the Gal/GalNAc receptors of rat Kupffer cells and hepatocytes. This attachment was specifically inhibited by T and Tn in a concentration-dependent manner: 50% T RBC-Kupffer cell contacts were inhibited at 8.5.10(-6) mM T and 8.5.10(-5) mM Tn antigen concentrations, respectively. The corresponding figures for hepatocytes were 6.10(-6) mM T and 1.2.10(-6) mM Tn antigen. Amino-terminal cleavage products of the T glycoprotein, possessing clusters terminating in non-reducing Gal/GalNAc, inhibited T RBC binding to Kupffer cells and hepatocytes usually at 10(-2) to 10(-5) mM concentrations, whereas GalNAc, galactose and galactose glycosides inhibited at millimolar concentrations. Galactose-unrelated carbohydrates were inactive at concentrations greater than or equal to 50 mM.

Red cell aging results in a change of cell surface carbohydrate epitopes allowing for recognition by galactose-specific receptors of rat liver macrophages.

Binding and uptake studies of in vitro aged or senescent rat erythrocytes by isolated rat liver macrophages suggest recognition by galactose-specific receptors on the cell surface of the macrophages. We analyzed carbohydrates exposed on old erythrocytes by plant lectins in an agglutination assay in comparison with freshly isolated untreated erythrocytes. Rat erythrocytes aged in vitro by storage are agglutinated by a panel of lectins that do not react with freshly isolated erythrocytes. Specificity of agglutination was shown by inhibition with monosaccharides. Antibodies eluted from senescent rat erythrocytes agglutinate in vitro aged as well as senescent rat erythrocytes, but not freshly isolated cells nor human erythrocytes. Galactose-specific lectins isolated from rat liver give similar results; they also agglutinate normal human erythrocytes. Agglutination by the liver lectin is inhibitable by galactose and N-acetylgalactosamine but not by N-acetylglucosamine or mannose. Furthermore, rat liver macrophages devoid of galactose-specific receptors show markedly reduced binding of senescent rat erythrocytes. We conclude that recognition of old rat erythrocytes is mediated by two systems: old erythrocytes expose different terminal sugar residues or a different arrangement of glycans when compared to young erythrocytes, rendering them recognizable by liver lectins and by autoantibodies.

Recognition of xenogeneic erythrocytes: the GalNAc/Gal-particle receptor of rat liver macrophages mediates or participates in recognition.

We studied mechanisms that mediate recognition of human erythrocytes (HRBC) and sheep erythrocytes (SRBC) by rat liver macrophages. We used an in vitro cell binding assay that allows spontaneous formation of cell contacts. Binding of HRBC to rat macrophages shows the following characteristics: inhibition studies with several monosaccharides and oligosaccharides yield complete inhibition of cell contacts with saccharides, which block the GalNAc/Gal-particle receptor on rat liver macrophages. We found the inhibition pattern: N-acetyl-D-galactosamine, lactose greater than D-galactose, D-fucose greater than L-fucose much greater than N-acetyl-D-glucosamine. Cell binding is dependent on the presence of calcium ions, but not influenced by heat-aggregated IgG or gangliosides. The inhibition pattern was the same after treatment of HRBC with neuraminidase. Therefore, binding of HRBC, as well as binding of neuraminidase-treated HRBC, is mediated by the GalNAc/Gal-particle receptor. Binding of SRBC is partly inhibited by galactose-related saccharides. Binding is also partly inhibited by heat-aggregated IgG, gangliosides, and L-fucose. Complete inhibition of cell contacts with SRBC is achieved by combination of all inhibitors. We therefore conclude that binding of SRBC is mediated by several different mechanisms, including the GalNAc/Gal-particle receptor. Binding of neuraminidase-treated SRBC, however, was found to be completely inhibited by saccharides, which block the GalNAc/Gal-particle receptor. We conclude that the GalNAc/Gal-particle receptor mediates or participates in recognition of non-self structures.

Endocytosis via galactose receptors in vivo. Ligand size directs uptake by hepatocytes and/or liver macrophages.

We followed the intrahepatic binding and uptake of variously sized ligands with terminal galactosyl residues in rat livers. The ligands were administered to prefixed livers in binding studies and in vivo and in situ (serum-free perfused livers) in uptake studies. Gold sols with different particle diameters were prepared: 5 nm (Au5), 17 nm (Au17), 50 nm (Au50) and coated with galactose exposing glycoproteins (asialofetuin (ASF) or lactosylated BSA (LacBSA)). Electron microscopy of mildly prefixed livers perfused with LacBSA-Au5 in serum-free medium showed ligand binding to liver macrophages, hepatocytes and endothelial cells. Ligands bound to prefixed cell surfaces reflect the initial distribution of receptor activity: pre-aggregated clusters of ligands are found on liver macrophages, single particles statistically distributed on hepatocytes and pre-aggregated clusters of particles restricted to coated pits on endothelial cells. Ligand binding is prevented in the presence of 80 mM N-acetylgalactosamine (GalNAc), while N-acetylglucosamine (GlcNAc) is without effect. Electron microscopy of livers after ligand injection into the tail vein shows that in vivo uptake of electron-dense galactose particles by liver cells is size-dependent. Using a LacBSA-Au preparation with heterogeneous particle diameter (2.2-11.7 nm) we found that hepatocytes take up only ligands up to the size of 7.8 nm, whereas particles of all sizes available in this experiment are found in liver macrophages and endothelial cells. ASF-Au17 and LacBSA-Au17 are endocytosed by liver macrophages and endothelial cells, but not by hepatocytes. ASF-Au50 is taken up by liver macrophages only. In vivo uptake by liver macrophages is mediated by galactose-specific recognition as shown by inhibition with GalNAc. Some 52-65% inhibition was measured in in vivo experiments and 78% inhibition in in situ experiments. GlNAc showed no inhibitory effect. Furthermore, we measured uptake of [125J]ASF and of [125J]ASF adsorbed to Au17 by the different cell populations of rat livers in vivo. While the bulk of the molecular ligand is found in the hepatocyte fraction, the particulate ligand is located in the sinusoidal fraction.

Galactose-specific receptors on liver cells. II. Characterization of the purified receptor from macrophages reveals no structural relationship to the hepatocyte receptor.

We have isolated a galactose-specific receptor protein from rat liver macrophages by three techniques, all using EDTA extraction and subsequent affinity chromatography. The purified receptor has an apparent molecular mass of 30 kDa and exhibits hemagglutinating activity. Monospecific receptor-antisera produce one precipitation line with the macrophage receptor in Ouchterlony double diffusion but show no cross-reaction with the hepatocyte receptor. Sinusoidal cells, but not hepatocytes, are stained with monoclonal antibodies to the macrophage receptor, whereas anti-hepatocyte receptor antibodies stain hepatocyte surfaces but not sinusoidal cells. We conclude that the galactose-specific receptor from liver macrophages is structurally different from the hepatocyte receptor, although the two lectins share a similar binding specificity.

Lack of evidence for liver lectins functioning as IgM or IgG-Fc-receptors.

We have tested whether mannose- and galactose-specific lectins on liver cells are able to bind antibody-antigen complexes and thus function as Fc-receptors. Rat hepatocytes and liver sinusoidal cells were isolated by collagenase perfusion and differential centrifugation. Rat erythrocytes were coated with purified IgM or IgG from rabbits immunized with rat erythrocytes. Both IgM and IgG coated erythrocytes bound to liver macrophages but not to hepatocytes. The binding of IgM and IgG coated red blood cells to liver macrophages could not be blocked by potent inhibitors for mannose- and galactose-specific macrophage lectins such as mannan, D-mannose-bovine serum albumin, N-acetyl-D-galactosamine, D-galactose-bovine serum albumin, or asialofetuin. Although lectin activity is calcium dependent and trypsin sensitive neither condition blocked rosette formation between liver macrophages and opsonized erythrocytes. Thus mannose- and galactose-specific lectins are not involved in the sequestration of IgM- or IgG-antibody-erythrocyte complexes in the liver.

GalNAc/Gal-specific rat liver lectins: their role in cellular recognition.

By investigating the presence and distribution of GalNAc/Gal-specific receptors on liver cells in vitro and in vivo, we provided evidence that the hepatocyte is not the only liver cell expressing receptor activity but that receptors of similar specificity are found on liver macrophages and also on endothelial cells. The receptor distribution in the plasma membrane is strinkingly different between the three cell types, as judged from the binding pattern of colloidal gold particles coated with asialofetuin or lactosylated serum albumin. Binding to hepatocytes occurs as single particles statistically distributed, binding to liver macrophages in a clustered arrangement all over the cell membrane and binding to endothelial cells also in a clustered arrangement but restricted to coated pits only. The different receptor distribution results in different binding and uptake abilities. Whereas hepatocytes bind and take up molecules and small particles (5 nm) only, the clustered receptor arrangement of endothelial cells and macrophages enables them to effectively bind and ingest larger particles. Ligands larger than 35 nm can be taken up by the macrophages only. The different receptor arrangement results also in different capacities of cell contact formation. Although in vitro liver macrophages and hepatocytes can both bind desialylated cells the macrophage needs much less galactosyl groups exposed on erythrocytes to establish stable contacts than the hepatocyte. The contacts formed by hepatocytes stay reversible for 30 min at 37 degrees C, whereas the contacts formed by the liver macrophages become irreversible after 10 min at 37 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of carbohydrates in rat leukemia cell-liver macrophage cell contacts.

The mechanism by which macrophages recognize tumor cells is still unknown. We have studied interactions between rat liver macrophages and rat L 5222 leukemia cells. These tumor cells, but not normal leukocytes or erythrocytes, adhere to freshly isolated macrophages in vitro. Binding of tumor cells by macrophages can be inhibited by N-acetyl-D-galactosamine, D-galactose and more potently by glycoproteins with terminal N-acetyl-D-galactosamine or D-galactose residues. Tumor cell adhesion is calcium-dependent. The relevant leukemia cell membrane structures which bear terminal beta-D-galactosyl or related residues have been determined as trypsin- and pronase-sensitive, and hence may presumably be glycoproteins. The tumor cell receptor on liver macrophages appears to be a lectin with the carbohydrate specificity N-acetyl-D-galactosamine greater than D-galactose greater than L-fucose.

Receptor-mediated particle uptake by liver macrophages. The galactose-particle receptor mediates uptake via coated and also non-coated structures.

The endocytosis pathways of particles with terminal beta-D-galactosyl groups were studied in isolated rat Kupffer cells by electron microscopy. Colloidal gold particles of sizes 5, 17 and 50 nm were coated with asialofetuin (ASF) and isolated liver macrophages were allowed to bind (at 4 degrees C) or take up (at 37 degrees C) these ligands. Particles of all three sizes were bound via the galactose-particle receptor as shown by carbohydrate inhibition experiments and were ingested effectively. But, whereas ASF-gold particles of sizes 5 and 17 nm are taken up via the coated pit/coated vesicle pathway, the 50 nm particles are not. These enter the cell via non-coated endocytic vacuoles. All three particle sizes are transported to the same lysosomal compartment. These observations demonstrate that at least in macrophages one receptor is capable to mediate endocytosis via two different pathways depending on ligand size and/or valency.

Identification of a receptor for senescent erythrocytes on liver macrophages.

Isolated rat liver macrophages adherent to culture dishes phagocytize selectively senescent rat erythrocytes as well as in vitro aged rat erythrocytes but not young or freshly isolated erythrocytes. Since in vitro aged erythrocytes lack cell bound antibodies and phagocytosis occurs in serum free medium, antibodies do not appear to play a role. Phagocytosis as well as binding of old erythrocytes to liver macrophages is inhibited by N-acetyl-D-galactosamine and related monosaccharides (1-25 mM range) and by corresponding synthetic glycoproteins (10(-6)-10(-10) M range) but not by D-mannose or N-acetyl-D-glucosamine. We conclude that recognition and phagocytosis of senescent and in vitro aged erythrocytes is mediated by the galactose particle receptor on rat liver macrophages.