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.     

Preclustered receptor arrangement is a prerequisite for galactose-specific clearance of large particulate ligands in rat liver

We had hypothesized that preclustered arrangement of galactose-specific receptor activity on rat liver macrophages enables these cells to internalize multivalent, particulate ligands in contrast to the clearance of molecules mediated by statistically distributed receptors on hepatocytes. We now took advantage of the nonclustered receptor distribution in newborn rat liver macrophages to study the in vivo clearance of particulate ligands. Gold particles 5, 17, and 50 nm in diameter (Au5, Au17, Au50), coated with lactosylated bovine serum albumin (LacBSA), were injected into the vena cava and livers were perfusion fixed after allowing for binding and uptake for 3 min. In sinusoidal cells from rats 15 days old LacBSA-Au5 and LacBSA-Au17 were taken up by endothelial cells and all sizes by liver macrophages. In newborn rat liver no LacBSA-Au50 or LacBSA-Au17 was retained in liver macrophages. Uptake of LacBSA-Au5 by sinusoidal cells was significant. LacBSA-Au17 was taken up in significant amounts by endothelial cells of newborn rats which correlates to the findings that galactose-specific binding sites on endothelial cells were found to localize as clusters over coated pits irrespective of age. These results demonstrate the crucial role of clustered receptors in binding and uptake of larger particulate ligands via this lectin-like binding activity.     

A membrane-associated form of C-reactive protein is the galactose-specific particle receptor on rat liver macrophages

Rat liver macrophages express a galactose-specific receptor which mediates endocytosis of particles or neuraminidase-treated blood cells. From rat serum we now have isolated and purified a galactose-specific lectin by affinity chromatography. Comparative analysis of this serum galactose-binding protein with the galactose-particle receptor protein purified from rat liver macrophages and with C-reactive protein (CRP) reveals close relation or identity of these proteins. An apparent m.w. of 30,000 was determined for all three proteins by SDS-PAGE under reducing conditions and m.w. of about 130,000 by native PAGE. All three proteins exhibit the same pentameric, ring-shaped structure in electron microscopy after negative staining. Antibodies raised against the serum galactose-binding protein or against the macrophage receptor cross-react. A mAb specific for rat neo-CRP labels liver macrophages but not hepatocytes and reacts with the isolated protein in a Western blot assay. Furthermore, the galactose-particle receptor can be functionally replaced by purified CRP: the binding capacity for neuraminidase-treated E of receptor-depleted liver macrophages can be restored by preincubation with purified rat CRP. We therefore conclude that CRP occurs as a membrane-associated protein constitutively expressed on liver macrophages functioning as a receptor mediating galactose-specific binding of particulate ligands.     

The galactose-specific receptor system in rat liver during development

The number and distribution of galactose-specific binding sites were investigated in rat liver cells during perinatal development. Ligand binding to hepatocytes, macrophages and endothelial cells was followed with in vitro and in situ experiments by electron microscopy, using lactosylated bovine serum albumin adsorbed onto 5 nm colloidal gold particles as ligand. Binding capacity, starting at a late stage of fetal development, is very low both on the hepatocyte and on the macrophage surface, which show single particles statistically distributed. By contrast, bound particles are absent from fetal endothelial cells, which also lack the typical coated regions. In vivo, experiments at 37 degrees C show that endocytosis occurs to some extent in prenatal life. These results indicate that the expression of galactose-specific receptors' activity on the different liver cell types follows different developmental patterns, which are independently modulated.     

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)     

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.     

Quantification and localization of galactose-specific binding sites in rat liver during postnatal development

We investigated the number and distribution of galactose-specific binding sites in developing livers from suckling rats of various ages using Lac-BSA-Au5 (lactosylated bovine serum albumin adsorbed onto colloidal gold particles 5 nm in diameter) as electron-dense ligand, and performing transmission electron microscopy of the specimen. It has been reported that the number of galactose-specific binding sites increases rapidly during organ development post partum (p.p.) and this was ascribed to hepatocyte receptor increase only. We now have investigated in in situ and in vitro experiments whether the binding sites of identical sugar specificity but located on sinusoidal cells show the same increase in expression or are independently regulated. We therefore quantified the number of particles bound by isolated hepatocytes and liver macrophages and found a gradual increase of both binding activities with age, the binding levels of adult liver cells being reached at day 15 p.p. This was confirmed with experiments using in situ prefixed organs thus proving the validity of this finding also for the intact organ. In both sets of experiments--in vitro as well as in vivo--ligand was found binding statistically distributed as single particles on hepatocytes of all ages, whereas on liver macrophages the binding pattern changed during development. On liver macrophages from rats 15 days of age ligand binding occurs in the preclustered pattern described for macrophages from adult rat livers whereas liver macrophages of newborn rats express a different binding pattern: they bind the ligands mostly as single particles with only few and small microaggregates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human T-lymphocytes--clinical and methodological studies on the detection of Fc-IgM- and Fc-IgG-receptor bearing T-lymphocytes (Tm and Tg)

Several methodical aspects for determination of T lymphocytes with Fc receptors for IgM (TM) and IgG (TG) were studied including separation technique of T cells with E-rosetting, culture conditions of T cells for determination of TM and the rosetting of TM and TG with EA complexes. The bests results were obtained by stabilization of E-rosettes with human serum albumin, after separation of E-rosette forming cells lysis of sheep erythrocytes with save hypotonic shock, culturing of T cells in medium containing 20% AB Serum. Furthermore it was shown the possibility using EA complexes produced with not purifieded IgG or IgM anti-ox-red-blood cells antisera without lost of specifity for TM and TG. The percentage of TM and TG in peripheral blood of thirty healthy persons as well as monitoring TM and TG in three cases was investigated.     

Galactose-specific receptors on liver cells. I. Hepatocyte and liver macrophage receptors differ in their membrane anchorage

Colloidal gold particles coated with asialoglycoproteins are bound by hepatocytes as well as by liver macrophages. Binding by both cell types is inhibited by N-acetylgalactosamine and related saccharides and is dependent on the presence of Ca2+. We have now performed an electron microscopic study on receptor anchorage in the plasma membranes. Cells with prebound ligand were treated with 20 mM EDTA at 4 degrees C, washed free of chelator and tested for residual galactose-specific receptor activity. Whereas hepatocytes preserve binding activity (73% of untreated control), liver macrophages lose galactose-specific receptor activity (12% of untreated control). Liver macrophages regain binding activity after a 2 min incubation at 37 degrees C allowing for receptor recycling. If the macrophages were fixed with low glutaraldehyde concentration prior to EDTA treatment they fully retained their receptor activity (74% of control). Ligands were also removed from both cell types by incubation with 80 mM N-acetylgalactosamine. After washing the cells free of the competing monosaccharide, both the hepatocytes as well as the macrophages show full binding activity (120% and 85% of untreated controls). Therefore, membrane anchorage sites of the macrophage receptors are not identical to ligand-binding sites. These results suggest a Ca2+-Mg2+-dependent receptor anchorage on the macrophage plasma membrane. As shown in the accompanying paper (Roos, P.H., Hartmann, H.J., Schlepper-Sch?fer, J., Kolb, H. and Kolb-Bachofen, V. (1985) Biochim. Biophys. Acta 847, 115-121), EDTA-induced dissociation from the membrane can be used for isolation of the galactose-specific receptors of liver macrophages.     

A lectin-like receptor on mammalian macrophages

Rat Kupffer cells in vitro strongly bind neuraminidase-treated rat erythrocytes but not untreated erythrocytes. Binding between cells is inhibited by preincubation of macrophages with D-galactose and related sugars, but not with unrelated saccharides. We therefore suggest that cell adherence is mediated by a galactose-specific receptor on the Kupffer cell membrane.     

Comparative studies on biological activities of subcomponents C1q of the first component of human, bovine, mouse and guinea-pig complement

Both the haemolytic activity and the binding ability to immunoglobulin G(IgG) (Fc-binding ability) were comparatively assayed among human, bovine, mouse and guinea-pig C1q. The haemolytic activity was measured by using the sensitized sheep erythrocytes with rabbit immunoglobulin M(IgM)- or IgG-haemolysin. The Fc-binding ability was assayed by using immune complexes made of rabbit IgG-antibody against human serum albumin as well as agglutination of latex particles coated with human, bovine or rabbit IgG (IgG-latex). The specific haemolytic activity was comparable with between bovine and mouse C1q, while those of guinea pig and human C1q were significantly lower than those of the others. Only the human and mouse C1q showed significantly positive agglutinating activity of human or bovine IgG-latex. In the case of the use of rabbit IgG-latex, each of these C1q gave much weaker agglutination. On the other hand, the ability of all these C1q to bind to Fc of immune complexes specifically was almost comparable. The discrepancy in specific activities between the haemolysis and the Fc-binding ability may suggest that these two biological activities are not always correlative and that these are independent biological phenomena.     

Expression of membrane-associated C-reactive protein by human monocytes: indications for a selectin-like activity participating in adhesion

We have shown previously that rat liver macrophages (Kupffer cells) express a membrane-bound form of C-reactive protein (mCRP) on their surface which is identical to a galactose-specific particle receptor activity. We now establish the presence of mCRP on human monocyte-macrophages using immunocytochemistry with an anti-neoCRP specific monocloncal antibody and RNA-RNAin situ hybridization to demonstrate the presence of CRP-specific mRNA. Concomitant with mCRP expression, cells exhibit galactose-dependent uptake of particles coated with lactosylated bovine serum albumin. Adhesion experiments on fibronectin-coated surfaces that mCRP on human blood monocytes may act as a selectin-like adhesion molecule, mediating initial carbohydrate-specific contacts which are followed by peptide-specific recognition via integrin receptors.     

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.     

Carbohydrates as recognition determinants in phagocytosis and in lectin-mediated killing of target cells

Carbohydrate-lectin interactions serve as the basis of recognition by phagocytic cells of particles and of various target cells. Such interactions occur in the following systems: between sugars on the surface of the phagocytic cells and lectins on the surface of other cells—the best studied example is the binding of mannose-specific Escherichia coli and related organisms via their surface lectins to oligo-mannose residues on macrophages; between lectins on the surface of phagocytic cells and sugars on particles or other cells—phagocytosis of zymosan and of sialidase-treated erythrocytes, mediated respectively by mannose-specific and galactose-specific lectins on macrophages, belongs to this category; by extracellular lectins that form bridges between sugars on both types of cell—as shown by enhancement of phagocytosis of staphylococci by wheat germ agglutinin, and by lectin-dependent killing of target cells by macrophages. These interactions may play an important role in the activities of phagocytic cells in vivo. They may provide an initial host defense mechanism immediately after microbial infection, operate in tissues where phagocytic activity is poor, and participate in tumor rejection.     

Diaminobenzidine cytochemistry in cryo-ultramicrotomy for the detection of peroxidases.

Rat erythrocytes and lymphoid cells were fixed by glutaraldehyde and encapsulated in bovine serum albumin plus rabbit IgG globulins for cryo-ultramicrotomy. A technical procedure is described by which endogenous peroxidases of erythrocytes in ultrathin frozen sections were detected by hydrogen peroxide and diaminobenzidine as hydrogen donor. Modifications of this classical cytochemical procedure proved also useful in cryoultramicrotomy for immunoperoxidase labeling of antigenic determinants in rabbit IgG globulins which have been crosslinked within the supporting matrix of cells.     

Effects of inflammation products on immune systems

Summary Microbial infection causes inflammation which stimulates macrophage functions. One of the inflammatory products, lysophosphatidylcholine (lyso-Pc), can stimulate macrophage activities. Treatment of mice with lyso-Pc enhanced spreading and ingestion activities of peritoneal macrophages. In vitro treatment of macrophages with lyso-Pc greatly enhanced spreading but not ingestion activities. However, incubation of a mixture of adherent and nonadherent cells with lyso-Pc produced a markedly enhanced ingestion activity of macrophages, implying the contribution of nonadherent cells to the stimulation of macrophages. Time course studies of the stimulation of these macrophages showed that spreading activity is stimulated immediately, even 30 min, after their contact with lyso-Pc while induction of ingestion activity requires a latent period of about 5 h. When the specificity of the macrophage receptors for ingestion was analyzed using defined immunoglobulins (i.e., IgG and IgM) with or without complement, lyso-Pc-activated macrophages efficiently ingested IgG-coated sheep erythrocytes independent of complement. However, macrophages of the same lyso-Pc-treated mice did not ingest erythrocytes coated with IgM and complement. These observations suggest that lyso-Pc-stimulated macrophages ingest the targets via Fc-receptors but not C3b receptors.     

Uptake and degradation of formaldehyde-treated 125I-labelled human serum albumin in rat liver cells in vivo and in vitro

The uptake of formaldehyde-treated 125I-labelled human serum albumin in rat hepatocytes and nonparenchymal liver cells was measured in vivo and in vitro. Isolated liver cells were prepared by treating the perfused liver with collagenase. Purified hepatocytes and nonparenchymal cells were obtained by differential centrifugation. Human serum albumin was found to be taken up exclusively or almost exclusively by nonparenchymal cells in vitro and in vivo (after intravenous injection). The maximal rate of human serum albumin-uptake in vitro was comparable to that in vivo. Nonparenchymal cells degraded human serum albumin in vitro as indicated by release of trichloroacetic acid-soluble radioactivity. Degradation started about 20-30 min after addition of human serum albumin to cells and rate of degradation was proportional to rate of uptake. Human serum albumin-degradation could be studied without interference of concurrent uptake by separating cells that had been preincubated with human serum albumin from the medium and then reincubating them with human serum albumin-free medium. The lag phase before human serum albumin-degradation starts and the inhibitory effect of chloroquine on degradation indicate that human serum albumin is degraded in lysosomes. The data obtained show that enzymatically prepared nonparenchymal liver cells retain their endocytic activity in vitro. Denatured human serum albumin should be useful both as a marker for rat liver macrophages and for the study of intracellular proteolysis in these cells.     

Uptake and degdradation of formaldehyde-treated 125I-labeled human serum albumin in rat liver cells in vivo and in vitro

The uptake of formaldehyde-treated ¹²⁵I-labelled human serum albumin in rat hepatocytes and nonparenchymal liver cells was measured in vivo and in vitro. Isolated liver cells were prepared by treating the perfused liver with collagenase. Purified hepatocytes and nonparenchymal cells were obtained by differential centrifugation. Human serum albumin was found to be taken up exclusively or almost exclusively by nonparenchymal cells in vitro and in vivo (after intravenous injection). The maximal rate of human serum albumin-uptake in vitro was comparable to that in vivo. Nonparenchymal cells degraded human serum albumin in vitro as indicated by release of trichloroacetic acid-soluble radioactivity. Degradation started about 20–30 min after addition of human serum albumin to cells and rate of degradation was proportional to rate of uptake. Human serum albumin-degradation could be studied without interference of concurrent uptake by separating cells that had been preincubated with human serum albumin from the medium and then reincubating them with human serum albumin-free medium. The lag phase before human serum albumin-degradation starts and the inhibitory effect of chloroquine on degradation indicate that human serum albumin is degraded in lysosomes. The data obtained show that enzymatically prepared nonparenchymal liver cells retain their endocytic activity in vitro. Denatured human serum albumin should be useful both as a marker for rat liver macrophages and for the study of intracellular proteolysis in these cells.     

Experimental pulmonary candidiasis in modified rabbits

Pulmonary lesions induced by an intratracheal inoculation of Candida albicans into rabbits in untreated control, bovine serum albumin (BSA)-sensitized and C. albicans-sensitized groups were examined immunohistochemically to clarify the localization of IgG, IgM and C3. In the control group no inflammatory cells were immunoreactive for IgG and only a few macrophages for IgM and C3, whereas in the BSA- and C. albicans-sensitized groups there were a small number of IgG-positive polymorphonuclear leukocytes and IgM- and C3-positive macrophages in the lesions, the latter group being more prominent. Furthermore, epithelioid granulomatous lesions at the late stage in the C. albicans-sensitized animals showed scattered epithelioid cells containing IgG as well as abundant IgG- and IgM-positive plasma cells. These immunohistochemical results were considered to support the estimation that immune complexes contributed to the modification of fungal lesions in the C. albicans-sensitized hosts, although non-immunological defense mechanisms seemed to be more important in the elimination of the fungus.     

The immune response in the hamster. VII. Studies on cytophilic immunoglobulin.

Hamster 7S IgG1 and IgG2 antibodies to hen-egg albumin (HEA) were tested for their capacity to bind to macrophage cytophilic Ig receptors. Both IgG1 and IgG2 were cytophilic for hamster macrophages though the membrane receptor had a predominant specificity for IgG1. Hamster IgG1 bound primarily to homologous macrophages whereas IgG2 bound to macrophages from other rodent species as well. The binding of hamster Ig to hamster macrophages was inhibited by a wide range of heterologous rodent sera. The only exception was guinea pig serum since guinea pig IgG2 was found to bind only to homologous macrophages. Sheep red blood cells (SRBC) coated with hamster IgG2 were ingested by macrophages more readily than those coated with hamster IgG1. Thus, there appeared to be a paradoxical relationship between the apparently strong affinity of IgG1 for the hamster macrophage Ig receptor and its reactivity weak ingestion promoting activity. Implications of this phenomenon are discussed.