Mac-2-binding glycoproteins. Putative ligands for a cytosolic beta-galactoside lectin

Mac-2, a galactose-binding lectin secretion by activated macrophages, is the major non-integrin laminin-binding protein in these cells. Mac-2 is also expressed by epithelial cells in the intestine and kidney. We wished to identify intestinal glycoproteins other than laminin that have a high affinity for Mac-2 and that could be considered as candidate ligands or partners for this lectin in intestinal epithelium. Certain lines of human colon adenocarcinoma cells produce two Mac-2-binding glycoproteins (M2BP-1 and M2BP-2) that were identified by their avid association with Mac-2 following detergent lysis and immunoprecipitation. These glycoproteins do not share a common epitope with Mac-2, and the interaction between Mac-2 and these proteins is mediated through the carbohydrate-binding domain of Mac-2 and sugar moieties on M2BP-1 and M2BP-2. M2BP-1 (98 kDa) and M2BP-2 (70 kDa) were purified by immunoaffinity chromatography and were specifically eluted with either galactose or lactose. Peptide maps revealed that M2BP-1 and M2BP-2 are structurally related. M2BP-1 is secreted and could conceivably associate with Mac-2 extracellularly. N-terminal sequence analysis of M2BP-2 suggests that these glycoproteins represent a unique subset of candidate ligands for this mammalian beta-galactoside lectin.     

Characteristics of lichen lectins and their role in symbiosis

Lectins are proteins or glycoproteins of non-immune origin which bind reversibly to carbohydrates that are exposed on cellular surfaces and mediate cellular recognition processes in a variety of biological interactions. Though initially discovered in plants, lectins from various sources including lichens, have been extensively studied by researchers all over the world. The symbiotic interaction between a fungus (mycobiont) and its photosynthetic partner (photobiont), usually an alga, constitutes a lichen. Some lichen lectins displays activity to human or animal erythrocytes. Although only a few lichen lectins have been examined to date, their characteristics suggest that they play an important role in the symbiotic interactions of this association. Lectin binding and the related enzymatic activity with respect to algal cell recognition illustrates a finely tuned mechanistic system which involved in the lichen symbiosis. This review provides an overview of the characteristics of lichen lectins and an insight into lectin-mediated symbiotic interactions and the galectin encoding genes. Future prospects for lichen lectin research in different areas are also highlighted.     

Interaction of Diocleinae lectins with glycoproteins based in surface plasmon resonance

Interaction of glucose/mannose-binding lectins in solution with immobilized glycoproteins was followed in real time using surface plasmon resonance technology. The lectins which share many biochemical and structural features could be clearly differentiated in terms of their specificity for complex glycoconjugates. The most prominent interaction of the lectins with PHA-E comparing with soybean agglutinin, both glycoproteins exhibiting high mannose oligosaccharides, suggests that the whole structure of the glycoproteins themselves, may interfere in affinity. These findings also support the hypothesis that minor amino acid replacements in the primary sequence of the lectins might be responsible for their divergence in fine specificity and biological activities. This is the first report using surface plasmon resonance technology that evidences differences of Diocleinae lectins in respect their fine glycan-specificity.     

Effects of clustered epitopes in multivalent ligand-receptor interactions

Many biological ligands are composed of clustered binding epitopes. However, the effects of clustered epitopes on the affinity of ligand-receptor interactions in many cases are not well understood. Clustered carbohydrate epitopes are present in naturally occurring multivalent carbohydrates and glycoproteins, which are receptors on the surface of cells. Recent studies have provided evidence that the enhanced affinities of lectins, which are carbohydrate binding proteins, for multivalent carbohydrates and glycoproteins are due to internal diffusion of lectin molecules from epitope to epitope in these multivalent ligands before dissociation. Indeed, binding of lectins to mucins, which are large linear glycoproteins, appears to be similar to the internal diffusion mechanism(s) of protein ligands binding to DNA, which have been termed the "bind and slide" or "bind and hop" mechanisms. The observed increasing negative cooperativity and gradient of decreasing microaffinity constants of a lectin binding to multivalent carbohydrates and glycoproteins result in an initial fraction of lectin molecules that bind with very high affinity and dynamic motion. These findings have important implications for the mechanisms of binding of lectins to mucins, and for other ligand-biopolymer interactions and clustered ligand-receptor systems in general.     

Influence of quaternary structure on glycosylation. Differential subunit association affects the site-specific glycosylation of the common beta-chain from Mac-1 and LFA-1

The influence of quaternary structure on glycosylation was evaluated in a macrophage-like cell line, P388D1. This cell line simultaneously synthesizes two structurally related glycoproteins, Mac-1 and LFA-1. Mac-1 and LFA-1 each contain two subunits in noncovalent association in an alpha 1 beta 1 structure. The beta-chain polypeptides of these two glycoproteins have identical primary structures while their alpha-chain polypeptides are distinct. For both Mac-1 and LFA-1, the association of the alpha- and beta-chains occurs prior to any Golgi-mediated processing of the oligosaccharide moieties on either one of the subunits. To evaluate the effects of differential subunit association on the site-specific glycosylation of the beta-chain, [3H]glucosamine-labeled oligosaccharides were isolated from the beta-chain of Mac-1 and LFA-1 and were compared by a variety of enzymatic and chromatographic techniques. Reverse-phase high performance liquid chromatography analyses of tryptic-chymotryptic glycopeptides suggest that each beta-chain has at least five glycosylation sites. Structural analysis of oligosaccharides from each corresponding glycopeptide fraction of the beta-chains of Mac-1 or LFA-1 (comparing their glycosidase sensitivities, behavior on serial lectin affinity chromatography, size heterogeneity, extent of sialylation, and branching) indicates that the LFA-1 beta-chain is glycosylated substantially differently on at least four of its sites, compared to the corresponding sites of the Mac-1 beta-chain, even though they are simultaneously synthesized in the same cells. Thus, these data demonstrate that quaternary structure can influence the site-specific glycosylation of a protein, even when the polypeptide structure and the cellular glycosylation machinery remain constant.     

从生物大分子结构特征解析植物凝集素的多样性

利用计算机模拟分析了植物凝集素结构与功能的特征。结果显示：(1)植物凝集素在结合糖之前其结构变化是一致的;(2)植物凝集素存在结构上的多样性,且可能与其生物功能的多样性有关;(3)在结合糖的过程中,植物凝集素表面局部结构的构象会有所变化,这种变化有利于其识别不同的糖而结合不同的外来糖缀合物,发挥其防御功能。对于同一家族的植物凝集素,虽然序列同源性较高,但在功能上却表现出强烈的多样性。分析表明：对于生物大分子而言,欲完成同一功能,不一定结构相同;结构相同,不一定功能一样。     

Macrophage surface glycoproteins binding to galectin-3 (Mac-2-antigen)

Galectin-3 (formerly called Mac-2 antigen) is a ∼30 kDa carbohydrate-binding protein expressed on the surface of inflammatory macrophages and several macrophage cell lines. We have purified from lysates of the murine macrophage cell line WEHI-3 glycoproteins that bind to a galectin-3 affinity column. Several of these receptors are labelled after biotinylation of intact cells showing their location at the cell surface. N-terminal aminoacid sequencing of intact galectin-3-binding glycoproteins isolated from preparative SDS-gels or of chemically derived fragments showed several homologies with known proteins and identification was confirmed by immunoprecipitation with specific antibodies. The glycoproteins were shown to be: the α-subunit(CD11b) of the CD11b/CD18 integrin(Mac-1 antigen); the lysosomal membrane glycoproteins LAMPs 1 and 2 which are known in part to be expressed at cell surfaces; the Mac-3 antigen, a mouse macrophage differentiation antigen defined by the M3/84 monoclonal antibody and related immunochemically to LAMP-2; the heavy chain of CD98, a 125 kDa heterodimeric glycoprotein identified by the 4F2/RL388 monoclonal antibodies respectively on human and mouse monocytes/macrophages and on activated T cells. Further studies showed that CD11b/CD18, CD98 and Mac-3 are major surface receptors for galectin-3 on murine peritoneal macrophages elicited by thioglycollate. Abbreviations: PBS, phosphate buffered saline; CNBR, cyanogen bromide; PMSF, phenyl methyl sulphonyl fluoride This revised version was published online in November 2006 with corrections to the Cover Date.     

Some common properties of lectins from marine algae

Twelve kinds of lectins isolated from four species of marine algae, Boodlea coacta (Chlorophyta) and Hypnea japonica, Carpopeltis flabellata and Solieria robusta (Rhodophyta), were compared for their chemical and biological properties. These lectins were proteins or glycoproteins, similar to terrestrial plant lectins. However, unlike most terrestrial plant lectins, they had a small molecular size (4,200 to 25,000 daltons), were mostly monomeric, and had no affinity for monosaccharides. They strongly agglutinated trypsin-treated rabbit erythrocytes, and their activities commonly were inhibited by glycoproteins bearing N-glycans. From hemagglutination-inhibition tests with various glycoproteins and related compounds, it was found that B. coacta lectins recognize high-mannose N-glycans; H. japonica lectins complex N-glycans, and C. flabellata and S. robusta lectins recognize both types of N-glycans.     

Characterising adhesiveness ofPhytophthora cinnamomi zoospores during encystment

During encystment,Phytophthora cinnamomi zoospores bind firmly to the host surface. We have developed a microassay to study adhesion of the zoospores to solid surfaces, both biological and non-biological. The results show that timing of the acquisition of adhesiveness during encystment correlates closely with the secretion of high molecular weight glycoproteins. The adhesive phase is short lived, occurring between 1 and 4 min after induction of encystment. During this period, cells that come into contact with a variety of surfaces (glass, plastic, and onion epidermis) become firmly attached, while cells that come into contact with one of these substrata after this period are unable to bind. Our results also show that EGTA inhibits cyst adhesion, while addition of calcium promotes cyst adhesion, especially of cysts more than 4 min old. To help identify the cyst surface component involved in adhesion we tested a number of lectins for their ability to block cyst adhesion. Soybean agglutinin andHelix pomatia agglutinin, lectins which bind to the secreted high molecular weight glycoproteins, both inhibit adhesion in the presence and absence of the hapten sugar, indicating that inhibition was non-specific. Wheatgerm agglutinin, a lectin which does not bind to the cyst surface, also blocked adhesion non-specifically.     

Intracellular lectins associated with N-linked glycoprotein traffic

The vectorial intracellular transport of N-glycan-linked glycoproteins is indispensable for biological functions. In order to sort these glycoproteins to the correct destination, animal intracellular lectins play important roles as sorting receptors. The roles of such lectins in the biosynthetic pathway from the endoplasmic reticulum (ER) to the cell surface are addressed in this review. Calnexin and calreticulin function via specific carbohydrates in quality control of newly synthesized glycoproteins in the ER, and ERGIC-53 seems to function in the transport of glycoproteins from ER to the Golgi complex. In addition to the well-understood role of mannose 6-phosphate receptor in lysosomal protein sorting, the vesicular integral protein of 36 kDa (VIP36) functions as a sorting receptor by recognizing high-mannose type glycans containing alpha1-->2Man residues for transport from Golgi to the cell surface in polarized epithelial cells.     

Characterization and biological implications of membrane lectins in tumor, lymphoid and myeloid cells

Complex carbohydrates and sugar receptors at the surface of eukaryotic cells are involved in recognition phenomena. Membrane lectins have been characterized, using biochemical, biological and cytological methods. Their biological activities have been assessed using labeled glycoproteins or neoglycoproteins. Specific glycoproteins or neoglycoproteins have been used to inhibit their binding capacity in both in vitro and in vivo experiments. In adults, lymphoid and myeloid cells as well as tumor cells grow in a given organ and eventually migrate and home in another organ; these phenomena are known as the homing process or metastasis, respectively. In specific cases, membrane lectins of endothelial cells recognize cell surface glycoconjugates of lymphocytes or tumor cells, while membrane lectins of lymphocytes and of tumor cells recognize glycoconjugates of extracellular matrices or of non-migrating cells. Therefore, membrane lectins are involved in cell-cell recognition phenomena. Membrane lectins are also involved in endocytosis and intracellular traffic of glycoconjugates. This property has been demonstrated not only in hepatocytes, fibroblasts, macrophages and histiocytes but also in tumor cells, monocytes, thyrocytes, etc. Upon endocytosis, membrane lectins are present in endosomes, whose luminal pH rapidly decreases. In cells such as tumor cells or macrophages, endosomes fuse with lysosomes; it is therefore possible to target cytotoxic drugs or activators, by binding them to specific glycoconjugates or neoglycoproteins through a linkage specifically hydrolyzed by lysosomal enzymes. In cells such as monocytes, the delivery of glycoconjugates to lysosomes is not active; in this case, it would be preferable to use an acid-labile linkage. Cell surface membrane lectins are developmentally regulated; they are present at given stages of differentiation and of malignant transformation. Cell surface membrane lectins usually bind glycoconjugates at neutral pH but not in acidic medium: their ligand is released in acidic specialized organelles; the internalized ligand may be then delivered into lysosomes, while the membrane lectin is recycled. Some membrane lectins, however, do bind their ligand in relatively acidic medium as in the case of thyrocytes. The presence of cell surface membrane lectins which recognize specific sugar moieties opens the way to interesting applications: for instance, isolation of cell subpopulations such as human suppressor T cells, targeting of anti-tumor or anti-viral drugs, targeting of immunomodulators or biological response modifiers.     

LAMP-1 in CHO cells is a primary carrier of poly-N-acetyllactosamine chains and is bound preferentially by a mammalian S-type lectin

Recent studies indicate that some mammalian S-type lectins bind preferentially to oligosaccharides containing the repeating disaccharide [3Gal beta 1,4GlcNAc beta 1]n or poly-N-acetyllactosamine (PL) sequence. We report here our investigation on the distribution of these sequences in glycoproteins in Chinese hamster ovary (CHO) cells and the interaction of glycoproteins containing PL chains with an immobilized S-type lectin (L14) from calf heart tissue. Our results demonstrate that PL chains are carried by a few high molecular weight glycoproteins which are bound by tomato-lectin Sepharose and one of these was precipitated by antibody to LAMP-1 (a lysosomal-associated membrane glycoprotein). More importantly, these high molecular weight glycoproteins, including LAMP-1, were bound with high affinity by L14. These results indicate that mammalian S-type lectins are highly specific in their interactions with glycoproteins and that LAMPs carry important recognition sequences for these lectins.     

Toshiaki Osawa: biochemistry of lectins and their applications in immunochemistry and cellular biology

Lectins are proteins that agglutinate cells and exhibit an antibody like, sugar-binding specificity. Professor Toshiaki Osawa has discovered, purified and characterized many plant lectins that display diverse biological activities. Using lectins as biochemical tools, he developed methods to determine the biochemical structures of glycoprotein glycans that react with lectins; separated and characterized glycoproteins and cell populations; analysed the mechanisms by which lectins activate cells; and characterized several cytokines produced by immune cells stimulated by lectins. The studies on lectins, the field he took strong leadership, developed into an essential hub of the biology of multicellular organisms.     

Carbohydrate and glycoprotein specificity of two endogenous cerebellar lectins

Two endogenous cerebellar mannose binding lectins have been isolated in an active form by immunoaffinity chromatography employing their respective immobilized antibodies. One of them, termed cerebellar soluble lectin (CSL), was extracted in the absence of detergents, whereas the other, called Receptor 1 (R1), was soluble only in the presence of detergents. Tests of inhibition of agglutination of erythrocytes were performed with mono-, oligo and polysaccharides, as well as glycoconjugates of known structures. On the basis of agglutinating activities these 2 lectins are different from the previously reported lectins in brain, since they were not inhibited by galactosides and lactosides and were only marginally inhibited by glycosaminoglycans. CSL and R1 were better inhibited by mannose-rich glycopeptides as compared to the corresponding oligosaccharides. The different inhibition patterns obtained with glycans of known structures indicated that these lectins are very discriminative. Although CSL and R1 have similar specificities, they differed in their binding properties towards glycopeptides of ovalbumin. Both lectins showed considerable affinity for endogenous cerebellar glycopeptides, also rich in mannose. These glycopeptides belong to a few endogenous Con A-binding cerebellar glycoprotein subunits and are not present on other endogenous Con A-binding glycoproteins. In the forebrain, where CSL and R1 were also present, at least some of the glycoproteins interacting with the lectins were different from that observed in the cerebellum. Our data overall suggest that specific cell recognition in the nervous system could be invoked via the interactions between widely distributed lectins and cell-specific glycoproteins.     

History of lectins: from hemagglutinins to biological recognition molecules

The occurrence in nature of erythrocyte-agglutinating proteins has been known since the turn of the 19th century. By the 1960s it became apparent that such proteins also agglutinate other types of cells, and that many of them are sugar-specific. These cell-agglutinating and sugar-specific proteins have been named lectins. Although shown to occur widely in plants and to some extent also in invertebrates, very few lectins had been isolated until the early 1970s, and they had attracted little attention. This attitude changed with the demonstration that lectins are extremely useful tools for the investigation of carbohydrates on cell surfaces, in particular of the changes that the latter undergo in malignancy, as well as for the isolation and characterization of glycoproteins. In subsequent years numerous lectins have been isolated from plants as well as from microorganisms and animals, and during the past two decades the structures of hundreds of them have been established. Concurrently, it was shown that lectins function as recognition molecules in cell-molecule and cell-cell interactions in a variety of biological systems. Here we present a brief account of 100-plus years of lectin research and show how these proteins have become the focus of intense interest for biologists and in particular for the glycobiologists among them.     

Structural views of glycoprotein-fate determination in cells

Processing of the N-glycans is coupled with the fates of glycoproteins in cells. A series of processing intermediates of high-mannose-type glycans are generated by specific glycosidases and thereby express biological signals recognized by intracellular lectins operating as molecular chaperones, cargo receptors, and ubiquitin ligases. Consequently, these lectins govern the intracellular processes of folding, transport, and degradation of the carrier polypeptides. To understand the underlying mechanisms of glycoprotein-fate determination, structural information on modes of molecular recognition by these lectins and enzymes is undoubtedly important. This article overviews our current knowledge of the structural basis for quality control of glycoproteins in cells.     

Estimating glycoprotein carbohydrate chain structures by lectin reactivities in polyacrylamide gels

Complex mixtures of cellular glycoproteins contain a myriad of different carbohydrate chains that cannot be easily analyzed without rigorous purification of each individual glycoprotein. We have analyzed the carbohydrate chains in complex mixtures of cellular glycoproteins by separation using sodium dodecyl-sulfate polyacrylamide gel electrophoresis and interacting the gels with several 125I-labeled lectins. By use of in situ chemical modifications of the glycoproteins after their electrophoretic separation together with the known carbohydrate-binding specifities of several lectins, it has been possible to estimate glycoprotein carbohydrate chain structures. As an example we have examined the cellular glycoproteins of a ovary-colonizing metastatic variant of B16 melanoma and report the types of carbohydrate chains that are found on various melanoma glycoproteins.     

Production of hybrid glycoproteins and accumulation of oligosaccharides in the brain of sheep and pigs administered swainsonine or locoweed

Swainsonine and swainsonine-containing plants produce biochemical and neurological changes in several mammalian species. The toxin is a potent inhibitor of liver lysosomal alpha-D-mannosidase and Golgi mannosidase II. The inhibition of the latter enzyme causes the production of abnormal glycoproteins containing hybrid oligosaccharides instead of complex types in a variety of cultured cells. In view of the widespread occurrence and biological importance of N-linked glycoproteins in the central nervous system, we initiated studies to determine the structure of oligosaccharides in glycoproteins prepared from the brain of control, swainsonine-fed, and locoweed-fed animals. The results presented here indicate that the feeding led to alteration in the structure of brain glycoproteins. Over 25% of the glycoproteins which presumably contained complex-type oligosaccharides were modified and now contained hybrid oligosaccharides. The structure of the N-linked oligosaccharide (glycopeptide) was established by (a) studying the binding properties of the glycopeptide to immobilized lectins of known sugar specificity, and (b) comparing the size of the glycopeptide before and after treatment with exo- and endoglycosidases. The production of hybrid oligosaccharides occurred despite the apparent absence of mannosidase II in brain. The relationships of the altered structure of brain glycoproteins, accumulation of mannose-rich oligosaccharides in the brain, and abnormal behavior of the animals administered swainsonine or locoweed are discussed.     

新的豆类凝集素FRIL及其体外维持造血干/祖细胞特性的作用机制

凝集素是一类蛋白质或糖蛋白。自然界中,很多植物可产生凝集素。植物凝集素在分子间的识别过程中起着重要作用。本文主要就新近发现的豆类凝集素FRIL的生物学特性及体外维持造血干／祖细胞的作用机制进行综述。     

FRACTIONATION OF GLYCOPROTEINS ASSOCIATED TO ADULT RAT BRAIN MYELIN FRACTIONS

Abstract— The chloroform-methanol insoluble residue of adult rat brain myelin fractions (My-CMI) contains only 20% of protein but all myelin-associated glycoproteins (Z anetta et al ., 1977a). After solubilization in sodium dodecyl sulphate, these glycoproteins were separated by sequential affinity chromatography on 4 immobilized lectins. Ten fractions (9 of which contained only glycoproteins) were obtained. Glycoproteins added up to at least 25% of My-CMI proteins. Many minor glycoproteins were detected in the different fractions. However most of them appeared not to be intrinsic to myelin. On the contrary a major glycoprotein electrophoretic band, component A, appeared to be intrinsic to myelin although its presence also on oligodendrocyte plasma membrane cannot be excluded. Component A was tentatively identified with the'major myelin associated glycoprotein'described by QUARLES (1972, 1973 a, b ). It accounted for less than 0.4% of proteins and 8% of glycoproteins of myelin fractions and consisted of at least two'glycopolypeptides'which, both, bind to concanavalin A and to the Ulex europeus lectin. The other major glycoprotein, component B, did not bind to any of the lectins used and, thus, must have N -acetyl neuraminic acid as only terminal sugar. The separation of myelin-associated glycoproteins according to their affinity for lectins allowed a tentative identification of the lectin binding sites of myelin sheath.