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.     

Purification and characterization of liver lectins from a lizard, Sceloporus spinosus

This study discusses the purification of soluble beta-galactose lectins obtained from the lizard liver of Sceloporus spinosus. The first lectin named lizard hepatic lectin-1 (LHL-1) presented a molecular weight of 31,750, with an isoelectric point of 4.25. The highest specific hemagglutinating activity was achieved using human blood type A1: N-acetylgalactosamine (GalNAc)-galactose (Gal)-fucose (Fuc). Carbohydrate inhibition assays indicated a higher lectin specificity for GalNAc. For LHL-2 the molecular weight obtained was 23,850 with an isoelectric point of 3.25. The highest carbohydrate specificity was observed for Gal. These lizard hepatic lectins are similar to the mammal hepatic lectins previously reported. However, it is different from the alligator hepatic lectin (AHL). The homology analyses of LHL-1 resulted in 100% identity with the Steroidogenic acute regulatory protein (StAR), while LHL-2 was similar to adenylate kinase (75% identity). We suggest that these liver lectins are related to the inherent functions of liver previously reported.     

Human macrophage C-type lectin specific for galactose and N-acetylgalactosamine promotes filovirus entry

Filoviruses cause lethal hemorrhagic disease in humans and nonhuman primates. An initial target of filovirus infection is the mononuclear phagocytic cell. Calcium-dependent (C-type) lectins such as dendritic cell- or liver/lymph node-specific ICAM-3 grabbing nonintegrin (DC-SIGN or L-SIGN, respectively), as well as the hepatic asialoglycoprotein receptor, bind to Ebola or Marburg virus glycoprotein (GP) and enhance the infectivity of these viruses in vitro. Here, we demonstrate that a recently identified human macrophage galactose- and N-acetylgalactosamine-specific C-type lectin (hMGL), whose ligand specificity differs from DC-SIGN and L-SIGN, also enhances the infectivity of filoviruses. This enhancement was substantially weaker for the Reston and Marburg viruses than for the highly pathogenic Zaire virus. We also show that the heavily glycosylated, mucin-like domain on the filovirus GP is required for efficient interaction with this lectin. Furthermore, hMGL, like DC-SIGN and L-SIGN, is present on cells known to be major targets of filoviruses (i.e., macrophages and dendritic cells), suggesting a role for these C-type lectins in viral replication in vivo. We propose that filoviruses use different C-type lectins to gain cellular entry, depending on the cell type, and promote efficient viral replication.     

Phagocytosis of lectin-coated beads by dystrophic and normal retinal pigment epithelium

In the dystrophic pigmented Royal College of Surgeons (RCS) rat, the retinal pigment epithelium (RPE) has a diminished capacity to phagocytose shed photoreceptor outer segments (ROS). An alteration in phagocytic recognition or ligand-receptor interactions between the RPE and ROS's could contribute to this defect. To this end, we have examined whether or not RPE lectin receptors are implicated in phagocytosis in the normal and dystrophic rat RPE by comparing differences in phagocytic uptake of lectin-coated beads. To test this, the following lectins were bound either indirectly to sugar-coated latex beads or directly to activated beads: Concanavalin A (conA), specific for mannose; Ulex europeus (ULEX), specific for fucose; Lens culinaris (LcH), specific for mannose; and wheat germ agglutinin (WGA), specific for N-acetyl glucosamine and sialic acid. The distribution of the lectin binding around beads was visualized and confirmed using lectin-Ferritin conjugates. Lectin-coated beads were fed to normal and dystrophic pigmented RPE tissue explants to determine differences in phagocytic uptake. We found that whether beads were directly or indirectly coated, similar results were obtained, but that there were differences in uptake of two types of lectin-coated beads by dystrophic as compared with normal animals. The dystrophic RPE phagocytosed greater numbers of conA-mannose beads (6.9/cell) than the normal RPE (3.6/cell). LcH-mannose beads were also phagocytosed by dystrophic (2.7/cell) but not by the normal (0/cell). A similar number of ULEX-fucose beads were taken up by dystrophic (3.8/cell) and normal (3.4/cell) RPE and neither took up WGA-N-acetyl glucosamine beads (0/cell). These results showing that the dystrophic RPE takes up greater numbers of conA and LcH-coated beads than the normal RPE suggest that a ligand-receptor interaction involving mannose may contribute to this difference in phagocytic uptake.     

Effect of lysozyme on the lectin-mediated phagocytosis of Bacillus cereus by haemocytes of the cockroach, Blaberus discoidalis

Lysozyme-like activity has been demonstrated in both cell-free haemolymph and, more abundantly, in haemocyte-lysate supernatants of Blaberus discoidalis. This activity was non-inducible, but heat-stable, with a maximum activity at pH 6.2. When B. cereus was pre-incubated in a concentration of chicken egg-white lysozyme equivalent to the concentration of lysozyme-like activity in cell-free haemolymph, the phagocytosis of B. cereus opsonized with GlcNAc-specific lectins, i.e. BDL2, WGA and HPA, was significantly reduced by up to 50%, while phagocytosis of B. cereus opsonized with mannose-specific lectins, such as BDL1 and Con A, was significantly increased. Pre-incubation of B. cereus in a higher concentration of lysozyme resulted in a smaller, shorter lived increase in the phagocytic rate of bacteria opsonized with these mannose-specific lectins. The action of lysozyme on the peptidoglycan in the cell wall of B. cereus probably resulted in a reduction in the number of binding sites for the GlcNAc-specific lectins, and, therefore, reduced the phagocytic rate of BDL2, HPA and WGA-opsonized B. cereus. Concomitantly, the breakdown of peptidoglycan probably exposed mannose-containing polysaccharides, previously embedded in the peptidoglycan layer, resulting in an increase in the phagocytic rate of the BDL1- and Con A-opsonized B. cereus. These results are discussed in relation to the immune-potential of B. discoidalis.     

Comparative cross-linking activities of lactose-specific plant and animal lectins and a natural lactose-binding immunoglobulin G fraction from human serum with asialofetuin

Plant and animal lectins bind and cross-link certain multiantennaryoligosaccharides, glycopeptides, and glycoproteins. This canlead to the formation of homogeneous cross-linked complexes,which may differ in their stoichiometry depending on the natureof the sugar receptor involved. As a precisely defined ligand,we have employed bovine asialofetuin (ASF), a glycoprotein thatpossesses three asparagine-linked triantennary complex carbohydratechains with terminal LacNAc residues. In the present study,we have compared the carbohydrate cross-linking properties oftwo Lac-specific plant lectins, an animal lectin and a naturallyoccurring Lac-binding polyclonal iminunoglobulin G subfractionfrom human serum with the ligand. Quantitative precipitationstudies of the Lac-specific plant lectins, Viscum album agglutininand Ricinus communis agglutinin, and the Lac-specific 16 kDadimenc galectin from chicken liver demonstrate that these lectinsform specific, stoichiometric cross-linked complexes with ASF.At low concentrations of ASF, 1:9 ASF/lectin (monomer) complexesformed with both plant lectins and the chicken lectin. Withincreasing concentrations of ASF, 1:3 ASF/lectin (monomer) complexesformed with the lectins irrespective of their source or size.The naturally occurring polyclonal antibodies, however, revealeda different cross-linking behavior. They show the formationof 1:3 ASF/antibody (per Fab moiety) cross-linked complexesat all concentrations of ASF. These studies demonstrate thatLac-specific plant and animal lectins as well as the Lac-bindingimmunoglobulin subfraction form specific stoichiometric cross-linkedcomplexes with ASF. These results are discussed in terms ofthe structure-function properties of multivalent lectins andantibodies. asialofetuin Lac-specific lectins immunoglobulin subfraction     

Mapping of the rat liver endothelial membrane with lectins and glycosylated ferritins

We explored the luminal surface of liver sinus endothelium for the presence of lectin receptors and lectinlike substances capable of interacting with specific sugars. We used ferritin-conjugated lectins and glycosylated ferritins as probes. Incubation of small blocks of rat liver with these probes led to the binding of concanavalin A (on A), Ricinus communis (RCA), wheat germ agglutinin (WGA), phytohemagglutinin (PHA) and mannosyl ferritins to the luminal surface of endothelium. Ulex europaeus agglutinin I (UEA), fucosyl, galactosyl, and chitobiosyl-ferritins did not bind. The binding was patchy and sparse in the case of Con A and mannosyl-ferritins but uniform for others. Binding density did not correlate with hemagglutinability of lectins, suggesting that the difference in the hemagglutinability of these lectins did not account for the difference in their binding densities. Bindings were all completely inhibited in the presence of excess specific sugar inhibitors, indicating the specificity of binding. The distribution of binding was segregated on the endothelial membrane, being heaviest on luminal pits. To define the functional significance of this segregated distribution, sinus endothelium was compared to portal-vein endothelium in which endothelial fenestrations are also seen; and these fenestrations as well as pits may be covered by a thin diaphragm. Of interest was the total absence of binding to the diaphragm. The significance of these findings is discussed.     

Separation and characterization of isoforms of DT-diaphorase from rat liver cytosol.

Rats were treated with 3-methylcholanthrene (MC) and DT-diaphorase from liver was partially purified on an azodicoumarol-Sepharose 6B column and applied to an FPLC-chromatofocusing column in order to resolve isoforms. Six peaks showing significant DT-diaphorase activity were eluted from this column with a pH gradient between 7.30 to 4.80. The amino acid compositions of the two major peaks (II and VIb) were found to be nearly identical, suggesting existence of isoforms rather than isozymes of DT-diaphorase. The isoforms of DT-diaphorase showed broad substrate specificities towards four different quinones (menadione, vitamin K-1, benzo(a)pyrene 3,6-quinone and cyclized-dopamine ortho-quinone), although quantitative differences in the specific activities were also found. All isoforms are glycoproteins but contain different carbohydrates. Thus isoform II reacts with biotinylated lectins which are specific for N-acetylgalactosamine, mannose, fucose and galactosyl(beta-1,3)N-acetylgalactosamine, while isoform VIb reacts only with biotinylated lectins specific for mannose and N-acetylgalactosamine. Separation of DT-diaphorase isoforms from control rat liver cytosol using FPLC-chromatofocusing revealed that the induction of the isoforms is not uniform, since isform II was not found and the major isoform was composed of three peaks, whereas the major isoform of DT-diaphorase from liver cytosol of rats treated with 3-methylcholanthrene was composed of only two peaks.     

The binding of fucose-containing glycoproteins by hepatic lectins. Purification of a fucose-binding lectin from rat liver

A lectin with a high affinity for binding ligands through fucose residues has been purified to homogeneity from rat liver. Affinity chromatography of the lectin on fucosyl-bovine serum albumin-agarose is the key step in the purification. Contaminating amounts of a previously described lectin that binds mannose and N-acetylglucosamine are removed from the fucose-binding lectin by either immunoadsorption on anti-mannose/N-acetylglucosamine lectin IgG-agarose or by specific elution of the fucose-binding lectin from fucosyl-bovine serum albumin-agarose. The pure fucose-binding lectin contains two polypeptide subunits with molecular weights of 88,000 and 77,000, respectively, as judged by gel electrophoresis. Peptide maps of the subunits, however, show that they are very similar structurally. In addition, peptide maps show that the fucose lectin is structurally distinct from other rat hepatic lectins. This is supported by the lack of cross-reaction among the different rat liver lectins and their specific antibodies and the inability of specific antibodies to the mannose/N-acetylglucosamine lectin to inhibit the binding of fucosyl-bovine serum albumin by the fucose lectin.     

Phagocytic specificity during sexual development in Dictyostelium discoideum

During the sexual cycle of Dictyostelium discoideum, zygote giant cells develop and serve as foci for further development by chemoattracting and cannibalizing hundreds of local amoebae. Previous work has shown that the phagocytic process bears similarities to and differences from asexual endocytosis. In the present study, sexual phagocytosis in D. discoideum was found to be species and developmental stage specific. It was inhibited selectively by glucose and concanavalin A. Although a partial, inhibitory effect of mannose on phagocytosis was not statistically significant, alpha-methylmannosamine, like alpha-methyl-glucose, significantly restored the phagocytic competence of giant cells treated with concanavalin A. Other sugars (N-acetyl-glucosamine, N-acetylgalactosamine, and galactose) and lectins (wheat germ agglutinin, Ulex europus type I, and Ricinis communis agglutinin type I) had no significant effect on sexual phagocytosis. Together these data indicate that a glucose-type receptor is involved in selective uptake of D. discoideum amoebae by giant cells.     

Binding of human liver hydrolases by immobilized lectins.

The binding of 22 human liver hydrolase activities by immobilized lectins of six different carbohydrate specificities, namely alpha-D-mannose (glucose), D-N-acetylglucosamine, D-N-acetylgalactosamine, L-fucose, alpha-D-galactose and beta-D-galactose, were examined. Differences in binding among these enzymes and within specific enzymes were observed. For example, the neutral forms of alpha-mannosidase and beta-xylosidase were bound by the Ulex europaeus lectin I (specific for L-fucose), whereas the acidic forms were not. Bandierea simplicifolia lectin (specific for alpha-galactose) bound 65% of beta-glucuronidase activity; recycling experiments demonstrated complete binding of the enzyme that had been eluted with the competitor D-galactose and no binding of the fraction that was not initially bound. These results suggested the presence of two forms of this enzyme. Similar data were obtained for acidic beta-galactosidase activity. These experiments may provide the basis for the expanded use of immobilized lectins for purification and characterization of hydrolases and other glycoproteins.     

Biomphalaria glabrata: influence of calcium, lectins, and plasma factors on in vitro phagocytic behavior of hemocytes of noninfected or Schistosoma mansoni-infected snails.

In vitro phagocytosis of erythrocytes by hemocytes of B. glabrata, intermediate host of S. mansoni, is strongly influenced by calcium, several lectins, and plasma factors. Our results indicate that two different mechanisms of non-self-recognition in B. glabrata may occur: (1) In the presence of calcium, phagocytosis occurs in noninfected and in infected snails without involvement of any other substances, and hemocytes of schistosome resistant as well as those of susceptible snails are able to recognize and phagocytose the target cells. (2) In the absence of calcium, phagocytosis occurs if bridging molecules (heterologous lectins in our assays) were present for which effector and target cells possess binding sites or if target cells were plasma coated prior to the assays. In suspensions in homologous plasma, hemocytes of both snail strains, infected or noninfected, subsequently showed phagocytic activities of about 70-80%. Preincubation of target cells in homologous plasma resulted in similar high phagocytic activities of hemocytes even in the absence of plasma during the standard assay. In these assays, a significantly higher proportion of hemocytes of resistant snails phagocytosed plasma-opsonized erythrocytes, whereas hemocytes of susceptible snails internalized less erythrocytes per cell and needed 60 min to phagocytose at percentages equivalent to that of resistant hemocytes within 10 min. Preincubation of erythrocytes in resistant plasma significantly increased the subsequent phagocytic activity of susceptible hemocytes, whereas preincubation of erythrocytes in susceptible plasma decreased the phagocytosis level of resistant hemocytes.     

Isolation and some properties of mammalian hepatic membrane lectins

Membrane lectins were isolated from sheep, goat, and buffalo liver by chromatography on an asialofetuin (ASF)-Sepharose 4B column. The lectins moved as a single protein band in SDS-PAGE with molecular masses of 42, 54 and 50 kDa, respectively, for sheep, goat and buffalo lectins. The molecular masses remained unchanged in 0.2 M 2-mercaptoethanol. As judged from the inhibition of binding of the lectin to ASF gel, the three lectins were beta-galactoside-specific. Sheep, goat and buffalo lectins were found to be sialoglycoproteins containing 18.6, 27 and 38.8 mol/mol lectin of neutral hexose, respectively; the corresponding values for the sialic acid content being 5.3, 8.7 and 11.8 mol/mol lectin. Thus goat and buffalo lectins are physico-chemically different from many mammalian hepatic lectins described so far.     

Developmentally regulated lectins from chick muscle, brain, and liver have similar chemical and immunological properties

Developmentally regulated lectins in extracts from brain, liver and muscle of 16-day-old chick embryos and liver of 7-day-old chicks have been purified by affinity chromatography. The purified preparations from the different tissues were indistinguishable in molecular weight and isoelectric point. The lectins could also not be distinguished when tested as antigens with antiserum raised against highly purified muscle lectin. This apparent identity was indicated both in double gel diffusion tests and by determination of the antibody-mediated inhibition of hemagglutination activity of the various lectins. Thiodigalactoside and lactose were potent inhibitors of the lectins from all sources. Galactose was a less potent inhibitor, especially with preparations from embryonic liver. After isoelectric focusing of these purified preparations, they all showed reduced and equivalent galactose sensitivity. Since the lectins from the different tissues appear identical, there is presently no basis to infer that they impart qualitative uniqueness to these tissues during differentiation.     

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.     

Characterization of sinusoidal endothelial cells of the liver and bone marrow using an intravital lectin injection method

The vascular endothelia express a variety of structural and biological phenotypes. We used an intravital injection method of plant derived lectins (Lycopersicon esculentum lectin (LEL), Ricinus communis Agglutinin-I (RCA-I), Ulex europaeus Agglutinin-I (UEA-I) and Concanavalin A (ConA)) to elucidate the morphology and function of the sinusoidal endothelium of the liver and bone marrow. All four lectins stained the sinusoidal endothelia of the liver and bone marrow in a patchy granular pattern which differed from the uniform and smooth staining pattern of non-sinusoidal vessels in other organs. By transmission electron microscopy, the granular pattern was identified as internalization of these lectins and subsequent accumulation within the endothelial cells, suggesting their active endocytosis. The endocytosis of these lectins emphasizes the fact that sinusoidal endothelial cells of the liver and bone marrow belong to the reticuloendothelial system (RES), a cell system characterized by internalization of foreign material. We introduce this intravital lectin injection as a useful technique to discriminate sinusoidal endothelial of the liver and bone marrow from other vascular endothelia.     

Cloning and expression of cDNA for two endogenous UV-2237 fibrosarcoma lectin genes

cDNA libraries from the murine UV-2237-IP3 fibrosarcoma cell line were prepared in the expression vector lambda gt11. Using specific antibodies, cDNA clones coding for the 14.5-kDa and the 34.0-kDa endogenous galactoside-specific lectins were isolated. In vitro translation and immunoprecipitation of mRNAs hybrid-selected by the cloned sequences from whole cell RNA provided confirmation for the clones. RNA and DNA blot analyses revealed that the two lectin proteins represent products of two different genes. We found differential levels of the specific mRNAs when low- and high-metastatic counterparts of the UV-2237 tumor system were compared, and these genes were not expressed in detectable amounts in normal mouse liver.     

Studies into secretions of Tetrahymena: enzymes secreted into inorganic medium.

The peptides secreted by Tetrahymena cells into inorganic medium were chromatographed. Six fractions showing a marked enzyme-like activity were examined for influence on certain physiological parameters of Tetrahymena. The enzymatically active fractions increased the phagocytic activity of Tetrahymena and decreased its binding capacity for lectins and hormone (insulin), but enhanced insulin imprinting at primary interaction. It remains to be clarified whether these effects were due to the enzymatic or other components of the fractions investigated, or to lack of the compensatory influence of the fractions not studied.     

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.     

Interaction of pea (Pisum sativum L.) lectins with rhizobial strains

Lectins from two varieties (PG-3 and LFP-48) of pea have been purified by affinity chromatography on Sephadex G-50. The specific activity increased by 23 and 25 folds, respectively. These lectins from both the varieties were found to be specific for mannose. The purified fluorescein isothiocyanate (FITC)-labelled lectins showed binding reaction with homologous as well as heterologous strains of Rhizobium spp. The results revealed that pea lectins are not highly specific to their respective rhizobia. Moreover, these lectins showed a greater stimulatory effect on homologous Rhizobium leguminosarum strains.