N-glycosylated catalytic unit meets O-glycosylated propeptide: complex protein architecture in a fungal hexosaminidase

β-N-Acetylhexosaminidase from a filamentous fungus Aspergillus oryzae is a secreted enzyme known to be an important component of the binary chitinolytic system. Cloning of the hexA gene and sequencing of the enzyme revealed its unique preproprotein structure. While the enzyme's zincin-like and catalytic domain had significant similarities with members of the glycohydrolase 20 family, the propeptide was unique for the fungal enzyme. Detailed pulse–chase and inhibition studies revealed that propeptide was processed during the biosynthesis of the enzyme. Moreover, the presence of propeptide was necessary for enzyme activation, dimerization and secretion. The catalytic unit was N-glycosylated, and the propeptide was O-glycosylated, both in their C-terminal parts. Deglycosylation experiments revealed that the N-glycosylation increased the stability and solubility of the enzyme. In contrast, O-glycosylated propeptide was necessary to attain the full enzymic activity.

Lymphocyte activation receptors: new structural paradigms in group V of C-type animal lectins

The structure–function relationship in group V of C-type animal lectins remains incompletely understood despite the new structures of NK (natural killer) cell receptors that have been solved recently. Recombinant, soluble forms of rat and human NKR-P1 and CD69 that we obtained after in vitro refolding were analysed by Fourier transform–ion cyclotron resonance MS and heteronuclear NMR (1H-15N correlation). In NKR-P1, calcium may not be removed by chelating agents because of the very high affinity of binding. In CD69, incorporation of calcium causes a structural shift in several amino acids important for the interaction with carbohydrates. Structural studies have also allowed us to understand an interesting preference of these receptors for either linear (NKR-P1) or branched (CD69) carbohydrate sequences.

Mass spectrometry is a powerful tool for identification of proteins associated with lipid rafts of Jurkat T-cell line

Many proteins involved in signal-transduction pathways are concentrated in membrane microdomains enriched in lipids with distinct physical properties. Since these microdomains are insoluble in non-ionic detergents in cold, proteins associated with them could be efficiently purified by techniques such as sucrose-density gradient centrifugation. The complexity of the resulting protein mixture requires powerful MS technique for its analysis. We have found that successful identification of biologically relevant proteins is critically dependent on the enrichment of the starting material (plasma membranes), and on the extraction procedure. Applying these conditions in combination with microHPLC-ESI (electrospray ionization)-MS/MS, we have identified proteins involved in signalling, cytoskeletal association and cellular adhesion in Jurkat cells that are not stimulated by any antibody incubation.

Synthesis of chitooligomer-based glycoconjugates and their binding to the rat natural killer cell activation receptor NKR-P1

NKR-P1 protein is an important activating receptor at the surface of the rat natural killer cells. GlcNAc and chitooligomers were identified as strong activation ligands in vitro and in vivo. Their clustering brings about increase of their affinity to the NKR-P1 by 3-6 orders. Here we describe novel methodology for preparation of neoglycoproteins based on BSA carrying the chitooligomers (n = 2-5). Further on we developed novel methodology of the coupling of glycosylamines via aromatic-SCN activated linker both to protein or synthetic cores. Inhibition studies of chitooligomer glycoconjugates with the NKR-P1 receptor show that our neoglycoproteins are very strong ligands with high binding affinity (-log IC(50) = 13-15). In analogy with our previous observations with GlcNAc clustered on protein or PAMAM backbones the synthetic chitooligomer clusters should provide considerably better ligands in the in vivo antitumor treatment.

Toward an optimal oligosaccharide ligand for rat natural killer cell activation receptor NKR-P1

Aminosugars have a good affinity for the NKR-P1A protein, the major activating receptor at the surface of rat natural killer cells. We have systematically investigated the structural requirements of the recombinant soluble dimeric form of the receptor for its optimal carbohydrate ligands. While N-acetylD-mannosamine was the best neutral monosaccharide ligand, its participation in the context of an extended oligosaccharide sequence was equally important. The IC(50) value for the GalNAcbeta1 --> ManNAc disaccharide was nearly 10(-10) M with a further possible increase depending on the type of the glycosidic linkage and the aglycon nature. From the point of view of its availability, stability, and affinity for the receptor and a potential in vivo use, these studies are pivotal for the design of an oligosaccharide or glycomimetics suitable for further clustering into the multivalent glycodendrimers.

Purification and characterization of the enantioselective nitrile hydratase from Rhodococcus equi A4

The nitrile hydratase from Rhodococcus equi A4 consisted of two kinds of subunits which slightly differed in molecular weight (both approximately 25 kDa) and showed a significant similarity in the N-terminal amino acid sequences to those of the nitrile hydratase from Rhodococcus sp. N-774. The enzyme preferentially hydrated the S-isomers of racemic 2-(2-, 4-methoxyphenyl)propionitrile, 2-(4-chlorophenyl)propionitrile and 2-(6-methoxynaphthyl)propionitrile (naproxennitrile) with E-values of 5-15. The enzyme functioned in the presence of 5-98% (v/v) of different hydrocarbons, alcohols or diisopropyl ether. The addition of 5% (v/v) of n-hexane, n-heptane, isooctane, n-hexadecane, pristane and methanol increased the E-value for the enzymatic hydration of 2-(6-methoxynaphthyl)propionitrile.

Link between a novel human gammaD-crystallin allele and a unique cataract phenotype explained by protein crystallography

We describe a 5-year-old boy with a unique congenital cataract caused by deposition of numerous birefringent, pleiochroic and macroscopically prismatic crystals. Crystal analysis with subsequent automatic Edman degradation and matrix-associated laser desorption ionization time-of-flight mass spectrometry have identified the crystal-forming protein as gammaD-crystallin (CRYGD) lacking the N-terminal methionine. Sequencing of the CRYGD gene has shown a heterozygous C-->A transversion in position 109 of the inferred cDNA (36R-->S transversion of the processed, N-terminal methionine-lacking CRYGD). The lens protein crystals were X-ray diffracting, and our crystal structure solution at 2.25 A suggests that mutant R36S CRYGD has an unaltered protein fold. In contrast, the observed crystal packing is possible only with the mutant protein molecules that lack the bulky Arg36 side chain. This is the first described case of human cataract caused by crystallization of a protein in the lens. It involves the third known mutation in the CRYGD gene but offers, for the first time, a causative explanation of the phenotype.

Cancer immunomodulation by carbohydrate ligands for the lymphocyte receptor NKR-P1

Natural killer (NK) and T cells express a superfamily of proteins with structural features of C-type lectins. Recombinantly prepared soluble form of rat NKR-P1 (CD161) recognized carbohydrate GalNac and GlcNac moieties. Ganglioside GM2 and heparin related-IS oligosaccharides representing the high affinity ligands for this receptor, increased the sensitivity of targets for killing by the rat effectors isolated from blood and spleen in vitro. Based on these results, we investigated in vivo the possible therapeutic effect of GM2 and IS carried by liposomes during induced rat colorectal carcinogenesis. The reduction of cancer incidence versus the controls (50% vs 88.88%), approached the 5-fluorouracil treatment (41.66%).

Determination of the complete covalent structure of the major glycoform of DQH sperm surface protein, a novel trypsin-resistant boar seminal plasma O-glycoprotein related to pB1 protein

The complete covalent structure of a novel boar DQH sperm surface protein resistant to many classical procedures of enzymatic fragmentation was determined. The relative molecular mass of the major form of this protein determined by ESI-MS and MALDI-MS was 13,065.2+/-1.0 and 13,065.1, respectively. However, additional peaks differing by 162 Da (i.e., minus hexose), 365 Da (i.e., minus hexose and N-acetylhexosamine), 146 Da (i.e., plus deoxyhexose), and 291 Da (i.e., plus sialic acid) indicated the heterogeneity due to differences in glycosylation. The complete covalent structure of the protein was determined using automated Edman degradation, MALDI-MS, and post-source decay (PSD) MALDI-MS, and shown to consist of N-terminal O-glycosylated peptide followed by two fibronectin type II repeats. The carbohydrates are O-glycosidically linked to threonine 10, as confirmed by PSD MALDI-MS of the isolated N-terminal glycopeptide. Eight cysteine residues of the protein form four disulfide bridges, the positions of which were assigned from MALDI-MS and Edman degradation data. We conclude that mass spectral techniques provide an indispensable tool for the detailed analysis of the covalent structure of proteins, especially those that are refractory to standard approaches of protein chemistry.

Peptide fragments induce a more rapid immune response than intact proteins in earthworms

The effect of in vivo proteolytic processing of protein antigen was studied in Eisenia foetida earthworms. Parenteral administration of the protein antigen induces elevated levels of an antigen-binding protein (ABP) which recognizes the protein used for stimulation. When the protein antigen is administered simultaneously with nontoxic serine proteinase inhibitor, ABP levels remain close to background. On the other hand, the in vivo adaptive response of earthworms to peptide fragments obtained by coelomic fluid digestion of the foreign antigen occurs even in the presence of proteinase inhibitor and, moreover, is significantly faster as compared to the response to intact antigen. These findings confirm the role of proteolytic processing in earthworms. MALDI mass spectrometric analysis of the fragments after coelomic fluid digestion has revealed the presence of the peptide fragments with molecular weights in the mass range 700-1100 Da.

Spermadhesins of the AQN and AWN families, DQH sperm surface protein and HNK protein in the heparin-binding fraction of boar seminal plasma

Heparin-binding proteins (designated BHB-2-BHB-9) were isolated from boar seminal plasma by affinity chromatography on heparin immobilized on polyacrylamide gel, followed by reverse phase HPLC. According to their N-terminal amino acid sequences, BHB-3-BHB-5 belong to the AQN family of spermadhesins and BHB-7-BHB-9 to the AWN family. BHB-6 is composed of two different proteins. The dominant protein (14 kDa) has the N-terminal amino acid sequence HNKQEGRDHD that is identical to the sequence of human semenogelin at positions 85-94. The minor proteins (16 and 17 kDa) belong to the AWN family of spermadhesins. The 14 kDa HNK protein does not crossreact with antibodies against AQN or AWN spermadhesins. BHB-2 also binds to the acrosome of boar epididymal spermatozoa but has the N-terminal sequence DQH. Therefore, basic protein BHB-2 belongs to a new family of DQH sperm surface proteins that are homologous to the acidic proteins from bull and stallion seminal plasma, to the collagen binding domain II in fibronectin and to the leucocyte cell-cell adhesion regulator, but are not homologous to AQN or AWN spermadhesins. Nevertheless, anti-AQN-1 spermadhesin antibodies crossreact strongly with DQH protein. All boar heparin-binding proteins bind concanavalin A indicating their glycoprotein nature, which was proved by the detection of glucosamine and galactosamine residues in their molecules. Furthermore, spermadhesins interact with zona pellucida, protease inhibitors and a polyacrylamide derivative of heparin. Affinity chromatography experiments showed that the DQH protein bound to gelatin-agarose together with the AWN proteins and that the DQH protein and AQN-1 spermadhesin belong to the phosphoryl choline binding proteins.

Structure analysis of trivalent glycoclusters by post-source decay matrix-assisted laser desorption/ionization mass spectrometry

Post-source decay (PSD) matrix-assisted laser desorption/ionization time-of-flight mass spectra were found to be useful for the structural elucidation of a series of tris [2-(glycosylthiourylene)ethyl]amines. The reported fragmentation behaviours of [M + H]+, [M + Na]+ and [M - H]- ions differ from each other significantly; however, they can be compared to tree pruning in every case. Whereas detailed structural information on unprotected glycoclusters is obtained from all PSD experiments, only the positive-ion mode can be used to gain relevant information about the acetylated glycoclusters.

GlcNAc-terminated glycodendrimers form defined precipitates with the soluble dimeric receptor of rat natural killer cells, sNKR-P1A

Synthetic GlcNAc-terminated thiourea-bridged glycoclusters were found to be potent inhibitors of binding of the soluble dimeric receptor of rat natural killer cells, sNKR-P1A protein, to its high affinity ligand. Moreover, we have shown here that characteristic precipitation curves can be recorded upon mixing of the GlcNAc glycoclusters with sNKR-P1A. For the GlcNAc8 glycocluster the precipitation curve is biphasic, with high affinity and low affinity precipitates differing in their sensitivity towards GlcNAc-mediated inhibition of precipitation. Quantitative analyses of the precipitates indicate the occurrence of a single sugar binding site per sNKR-P1A subunit, and lead to a model of the most possible spatial arrangements of the glycocluster-receptor lattices. These results provide new tools for further studies on carbohydrate recognition by NKR-P1A.

beta-Glucosylation of chitooligomers by galactosyltransferase

Galactosyltransferase from bovine milk was found to be able to utilise UDP-Glc to transfer Glc onto GlcNAc and chitooligomers[-beta-GlcNAc-(1-->4)-]n, n = 2-4. beta-Glucosylated products were used in binding studies with NKR-P1A protein cloned from rat natural killer cells.

NKR-P1A protein, an activating receptor of rat natural killer cells, binds to the chitobiose core of uncompletely glycosylated N-linked glycans, and to linear chitooligomers

NKR-P1 represent a family of activating receptors in rodent natural killer cells related to C-type animal lectins. We identify here the elements involved in the reactivity of the major receptor of rat, NKR-P1A, with N-linked oligosaccharides of glycoproteins. Plate inhibition assays with isolated, structurally defined N-glycans as inhibitors of binding of NKR-P1A to GlcNAc16-BSA revealed that the removal of both the external sialic acids and the penultimate galactose residues resulted in attaining of significant inhibitory activities. Surprisingly, additional plate inhibition and glycoprotein overlay experiments brought evidence that the core chitobiose, depending on its substitution, can per se support the interaction with NKR-P1A. In a series of linear chitooligomers (n = 2-7), the inhibitory activities reached a maximum for the chitotetraose. The ability of NKR-P1 to recognize both the periphery and the core region of complex type oligosaccharides may define its dual specificity towards carbohydrate components of eukaryotic (e.g., tumor) cell surfaces, but also reflect an evolutionarily conserved reactivity with microbial saccharides important in immune recognition and signaling functions.

Association of human NK cell surface receptors NKR-P1 and CD94 with Src-family protein kinases

Human natural killer (NK) cells express on their surface several members of the C-type lectin family such as NKR-P1, CD94, and NKG2 that are probably involved in recognition of target cells and delivery of signals modulating NK cell cytotoxicity. To elucidate the mechanisms involved in signaling via these receptors, we solubilized in vitro cultured human NK cells by a mild detergent, Brij-58, immunoprecipitated molecular complexes containing the NKR-P1 or CD94 molecules, respectively, by specific monoclonal antibodies, and performed in vitro kinase assays on the immunoprecipitates. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis, autoradiography, and phospho-amino acid analysis revealed the presence of in vitro tyrosine phosphorylated proteins that were subsequently identified by re-precipitation (and/or by western blotting) as the respective C-type lectin molecules and Src family kinases Lck, Lyn, and Fyn. The NKR-P1 and the CD94-containing complexes were independent of each other and both very large, as judged by Sepharose 4B gel chromatography. Crosslinking of NKR-P1 on the cell surface induced transient in vivo tyrosine phosphorylation of cellular protein substrates. These results indicate involvement of the associated Src-family kinases in signaling via the NKR-P1 and CD94 receptors.

CD 69 antigen of human lymphocytes is a calcium-dependent carbohydrate-binding protein

CD69 is a signal transducing molecule of hematopoietic cells. Previous molecular cloning of CD69 has revealed a type II transmembrane orientation and the presence of an extracellular domain related to the Ca(2+)-dependent (C-type) animal lectins. As the predicted amino acid sequence for the lectin-like domain is highly divergent from those of other C-type lectin-like proteins - a feature shared with NKR-P1 of natural killer cells - CD69 and NKR-P1 are among proteins assigned to a separate group, group V. To initiate ligand identification studies, we have prepared soluble forms of CD69 protein by bacterial expression of its extracellular portion. We show that cysteine 68 located in the short membrane-proximal neck region of CD69 which adjoins the C-terminal lectin-like domain is a critical element for dimerization. We have evidence that the soluble dimeric CD69 has a tight association with calcium, a feature shared with NKR-P1, and that it is a carbohydrate-binding protein with N-acetyl-D-glucosamine and N-acetyl-D-galactosamine as the best inhibitors: 4-8 x 10(-5) M giving 50% inhibition of binding to N-acetyl-D-glucosamine neoglycoprotein. Thus, the tight association with calcium and high affinities for carbohydrate binding appear to be features of at least two members of the C-type lectin group V.

Oligosaccharide ligands for NKR-P1 protein activate NK cells and cytotoxicity

A diversity of high-affinity oligosaccharide ligands are identified for NKR-P1, a membrane protein on natural killer (NK) cells which contains an extracellular Ca(2+)-dependent lectin domain. Interactions of such oligosaccharides on the target cell surface with NKR-P1 on the killer cell surface are crucial both for target cell recognition and for delivery of stimulatory or inhibitory signals linked to the NK cytolytic machinery. NK-resistant tumour cells are rendered susceptible by preincubation with liposomes expressing NKR-P1 ligands, suggesting that purging of tumour or virally infected cells in vivo may be a therapeutic possibility.

Rat natural killer cell antigen, NKR-P1, related to C-type animal lectins is a carbohydrate-binding protein

Natural killer receptor protein 1 (NKR-P1, a family of proteins), which is a dimeric transmembrane protein predominantly on rat and murine natural killer cells, contains an extracellular motif related to calcium-dependent animal lectins. The domain architecture of this protein and the finding that its cross-linking with antibody results in activation of natural killer cells make it a promising candidate for a receptor function. We have expressed a full-length NKR-P1 protein of the rat in COS cells and prepared soluble extracellular fragments by controlled proteolysis or by expression of truncated cDNA in bacteria. Dimerization of soluble NKR-P1 is predominantly dependent on the presence of an intact juxta-membrane stalk region and independent of N-glycosylation. Binding and inhibition studies using monosaccharides and neoglycoconjugates indicate that NKR-P1 is a lectin with a preference order of GalNAc > GlcNAc >> Fuc >> Gal > Man. At neutral pH, Ca2+ is tightly associated with the protein such that only a proportion can be removed by 10 mM EGTA. However, NKR-P1 can be decalcified completely at pH 10 with a total loss of carbohydrate binding. After recalcification at pH 8, carbohydrate binding is completely restored. Thus, NKR-P1 differs from other calcium-dependent animal lectins investigated so far in its pattern of monosaccharide recognition and in the tightness of Ca2+ binding.

Sulfated blood group Lewis(a). A superior oligosaccharide ligand for human E-selectin

In earlier studies of oligosaccharide probes (neoglycolipids) generated from an ovarian cystadenoma glycoprotein, one of the components that strongly supported binding of the endothelial adhesion molecule, E-selectin, was identified as an equimolar mixture of tetrasaccharides of blood group Le(a) and Le(x) type sulfated at position 3 of the outer galactose (C.-T. Yuen, A. M. Lawson, W. Chai, M. Larkin, M. S. Stoll, A. C. Stuart, F. X. Sullivan, T. J. Ahern, and T. Feizi (1992) Biochemistry 31, 9126-9131). In the present studies, the individual sulfated Le(a) and sulfated Le(x) oligosaccharides synthesized chemically have been investigated, first, for their ability to support E-selectin binding when converted into neoglycolipids, and second, for their ability to inhibit E-selectin binding to immobilized lipid-linked sialyl-Le(a), sialyl-Le(x), or sulfated Le(a) pentasaccharides; their activities have been compared with those of the sialyl-Le(a) and sialyl-Le(x) analogues. From these studies, the sulfated Le(a) tetra- and pentasaccharides emerge as the most potent E-selectin ligands so far. In particular, the inhibitory activity of the sulfated Le(a) pentasaccharide is substantially greater than that of the sialyl-Le(x) trisaccharide, which is currently the most widely used inhibitor of E-selectin binding: 45-, 35-, or 15-fold greater depending on whether adhesion is to sialyl-Le(a), sulfated Le(a), or sialyl-Le(x) pentasaccharides, respectively. These findings have an important bearing on design of new generations of inhibitors of E-selectin binding as antiinflammatory compounds.

Peripheral membrane molecules of leukocytes and NK cytotoxicity

Some leukocyte effector cell-surface molecules movement toward the adjoining target cells takes place during the reaction of NK cytotoxicity (NK R). The majority of the moving molecules are usually anchored via a divalent-ion-dependent interaction (PMM-M2+). The released PMM-M2+ can interact also with the secreted tumor necrosis factor alfa (TNF-alpha). In agreement with PMM-M2+ movement, the number of TNF-alpha binding sites on the target cell surface increases during NK R. In addition, antibodies against PMM-M2+, as well as D-mannose- or N-acetyl-D-glucosamine-terminated oligosaccharides of PMM-M2+ inhibit NK R. A more detailed analysis of PMM-M2+ with monoclonal antibodies used flow cytometry and cell-surface biotinylation. Only 3 of 31 tested CD antigens (CD2, LAK-1 and CD45) were passed through this first strongly restricted experimental screening. The EDTA-released LAK-1 antigen, but not CD2 and CD45, interact with TNF-alpha and cell surface via a mannose-inhibitable interaction dependent on the presence of Ca2+ ions. The mechanism of possible participation of PMM-M2+ in cytotoxic events is discussed in relation to Ca2+ influx and subsequent cytolysin secretion.

Characterization of the high-affinity oligosaccharide-binding site of the 205-kDa porcine large granular lymphocyte lectin, a member of the leukocyte common antigen family

Membrane lectins of mammalian large granular lymphocytes are thought to be important receptors in their non-major-histocompatibility complex-restricted activation. A triantennary desialylated oligosaccharide has been reported as the most effective triggering structure [Pospísil M., Kubrycht J., Bezouska K., Táborský O., Novák M. & Kocourek J. (1986) Immunol. Lett. 12, 83-90] while its cell surface receptor has recently been identified in pig natural killer cells as a 205-kDa membrane lectin resembling the proteins of the leukocyte common antigen family (LCA). In this study we have prepared 4-azidophenyl (photoactivatable) and 4-hydroxyphenyl (radio-iodinatable) derivatives of triantennary oligosaccharides by a new procedure which allows the natural conformation of the N-glycosidic linkage between the oligosaccharide and the respective labeling group to be retained. We used these high-affinity ligands to investigate the oligosaccharide-combining site of the 205-kDa lectin. Photoaffinity labeling of the whole cells and solubilized proteins confirmed that a 205-kDa polypeptide constitutes the major cell-surface calcium-independent receptor for triantennary oligosaccharides in pig lymphocytes. Isolation and manual sequencing of two ligand-labeled and eleven other peptides proved that the 205-kDa lectin represents a member of the LCA family expressing exons 4 and 6 during alternative splicing and that the high-affinity binding site is localized in the N-terminal 70-kDa extracellular domain. Binding studies with radiolabeled oligosaccharides and the above carbohydrate-recognition domain subjected to various chemical and enzymatic treatments indicated that the binding of oligosaccharides might be significantly modulated by sialylated O-glycosidically linked lineage-specific carbohydrate epitopes localized within this domain. Affinity chromatography of LCA isolated by conventional methods on immobilized oligosaccharides revealed that only a fraction of these cell-surface glycoproteins expressed high-affinity binding sites for the oligosaccharide ligands. Thus, N-linked oligosaccharide moieties of cell-surface glycoproteins seem to represent possible ligands of LCA that may be important in intercellular adhesion and oligosaccharide-mediated activation of lymphocytes.

Localization and characterization of the carbohydrate-binding site of the porcine lymphocyte mannan-binding protein

Mannan-binding proteins found in the liver and serum of several vertebrate species are supposed to play an important role in the intracellular transport of glycoproteins, as well as in several protective reactions including complement activation and elimination of various pathogens. To study these protective functions at molecular level it is necessary to understand the fine oligosaccharide specificity and mutual relation among various forms of these soluble lectins. We have isolated mannan-binding protein as peripheral membrane proteins of porcine lymphocytes. This lectin was purified to homogeneity and shown to possess many properties in common with the well studied rat liver proteins (mol. mass, subunit composition and general organization of the molecule). Binding studies performed with three series of defined oligosaccharides (high mannose, hybrid type, and complex) on native lectin molecules as well as isolated carbohydrate-binding domains revealed distinctive features of this mannan-binding protein, including its impaired ability to bind the oligosaccharide ligand after reduction and decyclization at core N-acetyl-D-glucosamine 1.

Organization of the gene encoding the human macrophage mannose receptor (MRC1)

The gene for the human macrophage mannose receptor (MRC1) has been characterized by isolation of clones covering the entire coding region. Sequence analysis reveals that the gene is divided into 30 exons. The first three exons encode the signal sequence, the NH2-terminal cysteine-rich domain, and the fibronectin type II repeat, while the final exon encodes the transmembrane anchor and the cytoplasmic tail. The intervening 26 exons encode the eight carbohydrate-recognition domains and intervening spacer elements. However, no simple correlation between intron boundaries and functional carbohydrate-recognition domains is apparent. The pattern of intron positions as well as comparison of the sequences of the carbohydrate-recognition domains suggests that the duplication of these domains was an evolutionarily ancient event.

Contribution to ligand binding by multiple carbohydrate-recognition domains in the macrophage mannose receptor

The extracellular portion of the macrophage mannose receptor is composed of several cysteine-rich domains, including a fibronectin type II repeat and eight segments related in sequence to Ca(2+)-dependent carbohydrate-recognition domains (CRDs) of animal lectins. Expression of portions of the receptor in vitro, in fibroblasts and in bacteria, has been used to determine which of the extracellular domains are involved in binding and endocytosis of ligand. The NH2-terminal cysteine-rich domain and the fibronectin type II repeat are not necessary for endocytosis of mannose-terminated glycoproteins. CRDs 1-3 have at most very weak affinity for carbohydrate, so the carbohydrate binding activity of the receptor resides in CRDs 4-8. CRD 4 shows the highest affinity binding and has multispecificity for a variety of monosaccharides. However, CRD 4 alone cannot account for the binding of the receptor to glycoproteins. At least 3 CRDs (4, 5, and 7) are required for high affinity binding and endocytosis of multivalent glycoconjugates. In this respect, the mannose receptor is like other carbohydrate-binding proteins, in which several CRDs, each with weak affinity for single sugars, are clustered to achieve high affinity binding to oligosaccharides. In the mannose receptor, these multiple weak interactions are achieved through several active CRDs in a single polypeptide chain rather than by oligomerization of polypeptides each containing a single CRD.

Evolutionary conservation of intron position in a subfamily of genes encoding carbohydrate-recognition domains

The structure of the gene encoding a chicken liver receptor, the chicken hepatic lectin, which mediates endocytosis of glycoproteins has been established. The coding sequence is divided into six exons separated by five introns. The first three exons correspond to separate functional domains of the receptor polypeptide (cytoplasmic tail, transmembrane sequence, and extracellular neck region), while the final three exons encode the Ca(2+)-dependent carbohydrate-recognition domain. These results, as well as computer-assisted multiple sequence comparisons, establish this receptor as the evolutionary homolog of the mammalian asialoglycoprotein receptors. It is interesting that the chicken receptor falls into a subfamily of proteins along with the mammalian asialoglycoprotein receptors, since the saccharide-binding specificity of the chicken receptor resembles more closely that of a different set of calcium-dependent animal lectins, which includes the mannose-binding proteins. The portions of the genes encoding the carbohydrate-recognition domains of these proteins lack introns. The results suggest that divergence of intron-containing and intron-lacking carbohydrate-recognition domains preceded shuffling events in which other functional domains were associated with the carbohydrate-recognition domains. This was followed by further divergence, generating a variety of saccharide-binding specificities.

Interaction of egg-white glycoproteins and their oligosaccharides with the monomer and the hexamer of chicken liver lectin. A multivalent oligosaccharide-combining site exists within the carbohydrate-recognition domain

Binding of egg-white glycoproteins and their oligosaccharides to hexameric solubilized form of the chicken hepatic lectin and the monomeric soluble fragment containing the carbohydrate-recognition domain has been investigated by several techniques. Ligand blotting revealed significant differences in binding to two forms of the lectin only for glycoproteins bearing multiple N-linked oligosaccharide moieties in their molecule (riboflavin-binding glycoprotein, avidin or ovomucoid). Inhibition studies indicated that inhibitory potency in a series of linear and branched N-acetyl-D-glucosamine-terminated oligosaccharides is critically dependent on the number and spatial arrangement of the terminal monosaccharide residues for both forms of the lectin. Direct binding of 4-hydroxyphenyl-derivatized radioiodinated oligosaccharides measured by equilibrium dialysis and frontal affinity chromatography points to the existence of two N-acetyl-D-glucosamine-combining sites per one subunit of the lectin, as has been recently reported for the rabbit and rat liver lectin [Lee & Lee (1988) Biochem. Biophys. Res. Commun. 155, 1444-1452]. Highly branch (penta-antennary) oligosaccharides interact with more than one subunit of the hexameric form of the lectin and thus resemble the more complex interaction of the whole glycoprotein.

[Transport and intracellular distribution of components of the cortisol-asialotranscortin complex in the liver]

The effect of desialation of human transcortin on the transcortin-cortisol complex transport into hepatocytes and on subsequent intracellular distribution of the complex components was studied in model experiments with perfused rat liver. It was demonstrated that in the presence of desialated transcortin the time of [3H]cortisol incubation in the perfusion medium decreased more than 200 times as compared with the native protein. [3H]cortisol and [131I]asialotranscortin trapping by hepatocytes occurs simultaneously. The content of the [3H]cortisol--[131I]asialotranscortin complex in rat liver plasma membranes reaches a maximum 3 min after beginning of perfusion. Then the intact complex is transported into lysosomes, where it dissociates with a subsequent release of asialotranscortin and cortisol metabolites into the cytoplasm.

Lactosamine type asialooligosaccharide recognition in NK cytotoxicity

Inhibition of pig NK cell activity by asialooligosaccharides (aOS) isolated from human serum glycoproteins was investigated. Train-tennary aOS (aOSIII) of ceruloplasmin was found to be the most potent inhibitor up to the concentration 0.1 micrograms/ml, which is in agreement with its highly specific binding to NK-activity-enriched pig lymphocytes (with a morphology similar to human large granular lymphocytes (LGL]. Only lectins with the specificity to Gal(beta 1----4)GlcNAc or Gal(beta 1----3)GalNAc structures exhibited inhibition of NK cytotoxicity. F(ab)2 fragments of rabbit antibodies against pig spleen membrane lectin cross-reacting with the pig liver membrane lectin completely inhibited NK activity when preincubated with the effectors or present in the incubation mixture during the assay. These data suggest that lectin receptors on cells of pig NK-activity-enriched fraction specific for aOSIII and antigenically related to membrane lectins isolated from pig spleen and liver, are involved in the NK recognition of several xenogeneic targets.

Transport and intracellular localization of cortisol-asialotranscortin complexes in rat liver

The influence of desialylation of human transcortin on transport of the transcortin-cortisol complex into the liver cells and its intracellular distribution was investigated in perfused rat liver. Under experimental conditions used the half-time of cortisol in perfusion medium was decreased more than 200 times in presence of asialotranscortin compared to that of native transcortin. Experiments with [3H]cortisol and [131I]asialotranscortin demonstrated a simultaneous uptake of cortisol and asialotranscortin by the hepatocytes. Distribution of [3H]cortisol and [131I]asialotranscortin in subcellular fractions showed the following pathway of cortisol-asialotranscortin complex: cell membrane, lysosomes, cytoplasm. The complex dissociates in lysosomes.

Carbohydrate-structure-dependent recognition of desialylated serum glycoproteins in the liver and leucocytes. Two complementary systems

Oligosaccharides with four different types of branching were prepared from purified human transferrin, alpha 2-macroglobulin, caeruloplasmin and alpha 1-acid glycoprotein and labelled with NaBH3 3H. Binding of these oligosaccharides to rat liver plasma membrane, rat leucocytes, pig liver plasma membranes and pig leucocyte plasma membranes was investigated. A striking dependence of binding on oligosaccharide branching was observed. The values of apparent association constants Ka at 4 degrees C vary from 10(6) M-1 (biantennary structure) to 10(9) M-1 (tetra-antennary structure) in the liver, whereas in the leucocytes the Ka values were found to be of reversed order, from 1.8 X 10(9) M-1 for biantennary to 2.2 X 10(6) M-1 for tetra-antennary structures. The binding is completely inhibited by 150 mM-D-galactose, but 150 mM-D-mannose has almost no effect on binding. Leucocyte plasma membranes bind preferentially 125I-asialoglycoproteins with biantennary oligosaccharides, thus completing the specificity pattern of the hepatic recognition system for desialylated glycoproteins. Possible physiological roles of these two complementary recognition systems under normal and pathological conditions are discussed.