Ming-Sung Tsai

Carbohydrate specificity of a galectin from chicken liver (CG-16)

Owing to the expression of more than one type of galectin in animal tissues, the delineation of the functions of individual members of this lectin family requires the precise definition of their carbohydrate specificities. Thus, the binding properties of chicken liver galectin (CG-16) to glycoproteins (gps) and Streptococcus pneumoniae type 14 polysaccharide were studied by the biotin/avidin-mediated microtitre-plate lectin-binding assay and by the inhibition of lectin-glycan interactions with sugar ligands. Among 33 glycans tested for lectin binding, CG-16 reacted best with human blood group ABO (H) precursor gps and their equivalent gps, which contain a high density of D-galactopyranose(beta1-4)2-acetamido-2-deoxy-D-glucopyranose [Gal(beta1-4)GlcNAc] and Gal(beta1-3)GlcNAc residues at the non-reducing end, but this lectin reacted weakly or not at all with A-,H-type and sialylated gps. Among the oligosaccharides tested by the inhibition assay, the tri-antennary Gal(beta1-4)GlcNAc (Tri-II) was the best. It was 2.1x10(3) nM and 3.0 times more potent than Gal and Gal(beta1-4)GlcNAc (II)/Gal(beta1-3)GlcNAc(beta1-3)Gal(beta1-4)Glc (lacto-N-tetraose) respectively. CG-16 has a preference for the beta-anomer of Gal at the non-reducing end of oligosaccharides with a Gal(beta1-4) linkage >Gal(beta1-3)> or =Gal(beta1-6). From the results, it can be concluded that the combining site of this agglutinin should be a cavity type, and that a hydrophobic interaction in the vicinity of the binding site for sugar accommodation increases the affinity. The binding site of CG-16 is as large as a tetrasaccharide of the beta-anomer of Gal, and is most complementary to lacto-N-tetraose and Gal(beta1-4)GlcNAc related sequences.

Fine specificity of domain-I of recombinant tandem-repeat-type galectin-4 from rat gastrointestinal tract (G4-N).

Galectins, a family of beta-galactoside-specific endogenous lectins, are involved in regulating diverse activities such as proliferation/apoptosis, cell-cell (matrix) interaction and cell migration. It is presently unclear to what extent the carbohydrate fine specificities of the combining sites of mammalian galectins overlap. To address this issue, we performed an analysis of the carbohydrate-recognition domain (CRD-I) near the N-terminus of recombinant rat galectin-4 (G4-N) by the biotin/avidin-mediated microtitre plate lectin-binding assay with natural glycoproteins (gps)/polysaccharide and by the inhibition of galectin-glycan interactions with a panel of glycosubstances. Among the 35 glycans tested for lectin binding, G4-N reacted best with human blood group ABH precursor gps, and asialo porcine salivary gps, which contain high densities of the blood group Ii determinants Galbeta1-3GalNAc (the mucin-type sugar sequence on the human erythrocyte membrane) and/or GalNAcalpha1-Ser/Thr ( Tn ), whereas this lectin domain reacted weakly or not at all with most sialylated gps. Among the oligosaccharides tested by the inhibition assay, Galbeta1-3GlcNAcbeta1-3Galbeta1-4Glc was the best. It was 666.7 and 33.3 times more potent than Gal and Galbeta1-3GlcNAc, respectively. G4-N has a preference for the beta-anomer of Gal at the non-reducing ends of oligosaccharides with a Galbeta1-3 linkage, over Galbeta1-4 and Galbeta1-6. The fraction of Tn glycopeptide from asialo ovine submandibular glycoprotein was 8.3 times more active than Galbeta1-3GlcNAc. The overall carbohydrate specificity of G4-N can be defined as Galbeta1-3GlcNAcbeta1-3Galbeta1-4Glc (lacto- N -tetraose)>Galbeta1-4GlcNAcbeta1-3Galbeta1-4Glc (lacto- N -neo-tetraose) and Tn clusters>Galbeta1-4Glc and GalNAcbeta1-3Gal>Galbeta1-3GalNAc>Galbeta1-3GlcNAc>Galbeta1-4GlcNAc>GalNAc>Gal. The definition of this binding profile provides the basis to detect differential binding properties relative to the other galectins with ensuing implications for functional analysis.

Differential affinities of Erythrina cristagalli lectin (ECL) toward monosaccharides and polyvalent mammalian structural units

Previous studies on the carbohydrate specificities of Erythrina cristagalli lectin (ECL) were mainly limited to analyzing the binding of oligo-antennary Galβ1→4GlcNAc (II). In this report, a wider range of recognition factors of ECL toward known mammalian ligands and glycans were examined by enzyme-linked lectinosorbent and inhibition assays, using natural polyvalent glycotopes, and a glycan array assay. From the results, it is shown that GalNAc was an active ligand, but its polyvalent structural units, in contrast to those of Gal, were poor inhibitors. Among soluble natural glycans tested for 50% molecular mass inhibition, Streptococcus pneumoniae type 14 capsular polysaccharide of polyvalent II was the most potent inhibitor; it was 2.1 × 104, 3.9 × 103 and 2.4 × 103 more active than Gal, tri-antennary II and monomeric II, respectively. Most type II-containing glycoproteins were also potent inhibitors, indicating that special polyvalent II and Galβ1-related structures play critically important roles in lectin binding. Mapping all information available, it can be concluded that: [a] Galβ1→4GlcNAc (II) and some Galβ1-related oligosaccharides, rather than GalNAc-related oligosaccharides, are the core structures for lectin binding; [b] their polyvalent II forms within macromolecules are a potent recognition force for ECL, while II monomer and oligo-antennary II forms play only a limited role in binding; [c] the shape of the lectin binding domains may correspond to a cavity type with Galβ1→4GlcNAc as the core binding site with additional one to four sugars subsites, and is most complementary to a linear trisaccharide, Galβ1→4GlcNAcβ1→6Gal. These analyses should facilitate the understanding of the binding function of ECL.

Carbohydrate specificity of a lectin isolated from the fungus Sclerotium rolfsii.

In order to investigate the functional roles of a phytopathogenic fungal lectin (SRL) isolated from the bodies of Sclerotium rolfsii, the binding properties of SRL were studied by enzyme linked lectinosorbent assay and by inhibition of SRL-glycan interaction. Among glycoproteins (gp) tested for binding, SRL reacted strongly with GalNAc alpha1-->4Ser/Thr (Tn) and/or Gal beta1-->3GalNAc alpha1-->(T(alpha)) containing gps: human T(alpha) and Tn glycophorin, asialo salivary gps, and asialofetuin, but its reactivity toward sialylated glycoproteins was reduced significantly. Of the sugar ligands tested for inhibition of SRL-asialofetuin binding, Thomsen-Friedenreich residue (T(alpha)) was the best, being 22.4 and 2.24 x 10(3) more active than GalNAc and Gal beta1--> residues, respectively. Other ligands tested were inactive. When the glycans used as inhibitors, T(alpha), and/or Tn containing gps, especially asialo PSM, asialo BSM, asialo OSM, active antifreeze gp, asialo glycophorin and Tn-glycophorin were very active, and 1.0 x 10(4) times more potent than GalNAc. From these results, it is clear that the combining site of SRL should be of a cavity type and recognizes only Tn and T(alpha) residues of glycans; it is suggested that T(alpha) and Tn glycotopes, which are present only in abnormal carbohydrate sequences of higher orders of mammal, are the most likely sites for phytopathogenic fungal attachment as an initial step of infection. The affinity of SRL for ligands can be ranked in decreasing order as follows: multivalent T(alpha) and Tn >> monomeric T(alpha) and Tn > GalNAc >>> II (Gal beta1-->4GlcNAc), L (Gal beta1-->4Glc), and Gal.

A Guide to the Carbohydrate Specificities of Applied Lectins-2

The lectins, that can be used as tools to study glycobiological systems are defined as applied lectins (1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14).They are easily obtained, stable and have their own binding specificity extending beyond the monosaccharide(1, 2, 3, 4,15, 16, 17, 18, 19).Their biochemical application has been reviewed extensively by Goldstein and Poretz (19), Sharon and Lis (8) and Goldsteinet al. (11) Hundreds of lectins are used as applied lectins. Thus, organizing and grouping binding properties of these lectins should facilitate the selection of lectins as structural probes for studying glycans as well as the interpretation, distribution and properties of the carbohydrate chains on the cell surface. From the information provided by inhibition assays and binding properties, the carbohydrate specificities of applied lectins are classified into six groups according to their specificities to monosaccharides. The subgroups are based on lectin affinities to GalNAca1-0 to Ser(Thr) of the peptide chain, disaccharides, trisaccharides and, the number and the location of LFucal-’linked to oligosaccharides; all of these structures are found mainly in soluble glycoproteins and as cell surface glycoconjugates in mammals (1, 2, 3, 4,18). Reviews concerning coding and classification of DGa1, GaINAc and Galf31-3/4G1cNAc specificities of applied lectins are given in Secion 1–4 of this proceeding (18) together with references 1, 2, 3, 4. A scheme of the classification is shown as follows.

STUDIES ON THE BINDING OF WHEAT GERM AGGLUTININ (TRITICUM VULGARIS) TO O-GLYCANS

The binding profile of Triticum vulgaris (WGA, wheat germ) agglutinin to 23 O‐glycans (GalNAcα1→Ser/Thr containing glycoproteins, GPs) was quantitated by the precipitin assay and its specific interactions with O‐glycans were confirmed by the precipitin inhibition assay. Of the 28 glycoforms tested, six complex O‐glycans (hog gastric mucins, one human blood group A active and two precursor cyst GPs) reacted strongly with WGA and completely precipitated the lectin added. All of the other human blood group A active O‐glycans and human blood group precursor GPs also reacted well with the lectin and precipitated over two‐thirds of the agglutinin used. They reacted 4–50 times stronger than N‐glycans (asialo‐fetuin and asialo‐human α1 acid GP). The binding of WGA to O‐glycans was inhibited by either p‐NO2‐phenyl α,βGlcNAc or GalNAc. From these results, it is highly possible that cluster (multivalent) effects through the high density of weak inhibitory determinants on glycans, such as GalNAcα1→Ser/Thr (Tn), GalNAc at the non‐reducing terminal, GlcNAcβ1→ at the non‐reducing end and/or as an internal residue, play important roles in precipitation, while the GlcNAcβ1→4GlcNAc disaccharide may play a minor role in the precipitation of mammalian glycan‐WGA complexes.

Forssman pentasaccharide and polyvalent Galβ1→4GlcNAc as major ligands with affinity for Caragana arborescens agglutinin

The binding properties of Caragana arborescens agglutinin (CAA, pea tree agglutinin) were studied by enzyme linked lectinosorbent assay (ELLSA) and by inhibition of CAA‐glycan interaction. Among glycoproteins (gps) tested, CAA reacted strongly with asialo bird nest gp, asialo rat sublingual gp, human Tamm‐Horsfall Sd(a+) urinary gp (THGP) and asialo THGP that are rich in GalNAcα1→, GalNAcβ1→ and/or Galβ1→4GlcNAc residues. CAA also bound tightly with multi‐valent Galβ1→4GlcNAc (mII) containing glycoproteins (human blood group precursor gps, asialo fetuin) and asialo ovine salivary glycoprotein (Tn, GalNAcα1→Ser/Thr), but CAA reacted poorly or not at all with sialylated glycoproteins tested. Of the sugars tested for inhibition of binding, Forssman pentasaccharide (Fp, GalNAcα1→3GalNAcβ1→3Galα1→4Galβ1→4Glc) was the best. It was about 2.3, 9.5 and 52.6 times more active than Galβ1→4GlcNAc, GalNAc and Gal, respectively, and about 1.9 times more active than tri‐antennary Galβ1→4GlcNAc (Tri‐II). These results suggest that this agglutinin is mainly specific for Fp, mII and Tn clusters. This property can be used to detect human abnormal glycotopes related to Fp and unmasked mII/Tn clusters and to study cell growth and differentiation given the lack of toxicity of this lectin toward mouse fibroblast cells.

Carbohydrate specificity of an agglutinin isolated from the root of Richosanthes kirilowii

The root of Trichosanthes kirilowii, which has been used as Chinese folk medicine for more than two thousand years, contains a Gal specific lectin (TKA). In order to elucidate its binding roles, the carbohydrate specificities of TKA were studied by enzyme linked lectinosorbent assay (ELLSA) and by inhibition of lectin-glycoform binding. Among glycoproteins (gp) tested, TKA reacted strongly with complex carbohydrates with Galbeta1-->4GlcNAc clusters as internal or core structures (human blood group ABH active glycoproteins from human ovarian cyst fluids, hog gastric mucin, and fetuin), porcine salivary glycoprotein and its asialo product, but it was inactive with heparin and mannan (negative control). Of the sugar inhibitors tested for inhibition of binding, Neu5Ac alpha2-->3/6Galbeta1-->4Glc was the best and about 4, 14.6 and 27.7 times more active than Galbeta1-->4GlcNAc(II), Galbeta1-->3GalNAc(T) and Gal, respectively. From these results, it is suggested that this agglutinin is specific for terminal or internal polyvalent Galbeta1-->4GlcNAcbeta1-->, terminal Neu5Ac alpha2-->3/6Galbeta1-->4Glc and cluster forms of Galbeta1-->3GalNAc alpha residues. The unusual affinity of TKA for terminal and internal Galbeta1-->glycotopes may be used to explain the possible attachment roles of this agglutinin in this folk medicine to target cells.