cDNA cloning and in vitro synthesis of the Dolichos biflorus seed lectin

The Dolichos biflorus seed lectin contains two structurally related subunits. A cDNA library was constructed using RNA isolated from D. biflorus seeds actively synthesizing the seed lectin. The library was expressed in Escherichia coli using a lambda Charon 16 vector, and lectin-specific antiserum was used to isolate a seed lectin cDNA. Hybridization of the D. biflorus seed lectin cDNA to RNA isolated from seeds actively producing both lectin subunits identifies a single-size RNA of 1100 bases. An oligodeoxyribonucleotide probe, constructed from an amino acid sequence common to both lectin subunits, detects the same size RNA. Translation of seed mRNA in vitro and immunoprecipitation of translation products using a lectin-specific antiserum yields a single polypeptide of slightly higher molecular mass than the largest seed lectin subunit. This seed lectin precursor is indistinguishable from a polypeptide synthesized from mRNA hybrid selected by the seed lectin cDNA. These data support the existence of a single polypeptide precursor for both subunit types of the D. biflorus seed lectin and suggest that differences between the subunit types arise by posttranslational processing.     

Production and characterization of a monoclonal antibody against the seed lectin of the Dolichos biflorus plant

Spleen cells from mice immunized with the Dolichos biflorus seed lectin were fused with cells from the mouse myeloma Sp2/O-Ag14 cell line to form hybridomas. Those hybridomas producing antibodies against the seed lectin were cloned at least four times and the monoclonal antibodies from clone C11/64-56.28 were characterized and found to be specific for Subunit I of the lectin; they do not react with the structurally similar Subunit II. In previous studies, we have shown that although these two subunits appear to differ only at their COOH-terminal ends, only Subunit I has carbohydrate binding activity. Using a solid phase enzyme immunoassay, the antigenic determinant fr the monoclonal antibody was found to be located on the COOH-terminal cyanogen bromide fragment of this subunit. The monoclonal antibody inhibits the ability of the lectin to agglutinate erythrocytes and N-acetyl-D-galactosamine, the specific hapten for the lectin, inhibits the ability of the antibody to combine with the lectin. These results suggest that the monoclonal antibody recognizes a determinant that is located either at or near the active site of the lectin or that is conformationally interdependent with the active site.     

Isolation and characterization of a lectin from the roots of Dolichos biflorus

A lectin has been isolated from the roots of 7-day-old Dolichos biflorus plants and has been compared with the D. biflorus seed lectin. The root lectin differs from the seed lectin in molecular weight, subunit stoichiometry, amino acid composition, amino terminal amino acid sequence, and isoelectric focusing pattern. However, the root lectin has in common with the seed lectin a specificity for N-acetyl-D-galactosamine, and upon denaturation the root lectin will react weakly with antiserum made to denatured seed lectin. Distribution studies of this lectin in germinating seedlings show that the highest levels of lectin are found in 1-day-old roots. Upon dissection and analysis of 7-day-old roots, the highest levels of the lectin are in the uppermost segment. In addition, isoforms of this lectin also exist in the stems and leaves of the plant.     

Weak protein-protein interactions in lectins: the crystal structure of a vegetative lectin from the legume Dolichos biflorus

The legume lectins are widely used as a model system for studying protein-carbohydrate and protein-protein interactions. They exhibit a fascinating quaternary structure variation, which becomes important when they interact with multivalent glycoconjugates, for instance those on cell surfaces. Recently, it has become clear that certain lectins form weakly associated oligomers. This phenomenon may play a role in the regulation of receptor crosslinking and subsequent signal transduction. The crystal structure of DB58, a dimeric lectin from the legume Dolichos biflorus reveals a separate dimer of a previously unobserved type, in addition to a tetramer consisting of two such dimers. This tetramer resembles that formed by DBL, the seed lectin from the same plant. A single amino acid substitution in DB58 affects the conformation and flexibility of a loop in the canonical dimer interface. This disrupts the formation of a stable DBL-like tetramer in solution, but does not prohibit its formation in suitable conditions, which greatly increases the possibilities for the cross-linking of multivalent ligands. The non-canonical DB58 dimer has a buried symmetrical alpha helix, which can be present in the crystal in either of two antiparallel orientations. Two existing structures and datasets for lectins with similar quaternary structures were reconsidered. A central alpha helix could be observed in the soybean lectin, but not in the leucoagglutinating lectin from Phaseolus vulgaris. The relative position and orientation of the carbohydrate-binding sites in the DB58 dimer may affect its ability to crosslink mulitivalent ligands, compared to the other legume lectin dimers.     

Dual-function protein in plant defence: seed lectin from Dolichos biflorus (horse gram) exhibits lipoxygenase activity

Plant-pathogen interactions play a vital role in developing resistance to pests. Dolichos biflorus (horse gram), a leguminous pulse crop of the subtropics, exhibits amazing defence against attack by pests/pathogens. Investigations to locate the possible source of the indomitable pest resistance of D. biflorus, which is the richest source of LOX (lipoxygenase) activity, have led to a molecule that exhibits LOX-like functions. The LOX-like activity associated with the molecule, identified by its structure and stability to be a tetrameric lectin, was found to be unusual. The evidence for the lectin protein with LOX activity has come from (i) MALDI-TOF (matrix-assisted laser-desorption ionization-time-of-flight) MS, (ii) N-terminal sequencing, (iii) partial sequencing of the tryptic fragments of the protein, (iv) amino acid composition, and (v) the presence of an Mn2+ ion. A hydrophobic binding site of the tetrameric lectin, along with the presence of an Mn2+ ion, accounts for the observed LOX like activity. This is the first ever report of a protein exhibiting both haemagglutination and LOX-like activity. The two activities are associated with separate loci on the same protein. LOX activity associated with this molecule adds a new dimension to our understanding of lectin functions. This observation has wide implications for the understanding of plant defence mechanisms against pests and the cellular complexity in plant-pathogen interactions that may lead to the design of transgenics with potential to impart pest resistance to other crops.     

cDNA cloning, primary structure, and in vitro biosynthesis of the DB58 lectin from Dolichos biflorus

Previous studies have shown that the Dolichos biflorus plant contains a lectin in its stems and leaves, called DB58, that is closely related to the D. biflorus seed lectin. DB58 is a heterodimer composed of two closely related subunits. Immunoprecipitation of total translation products from D. biflorus stem and leaf mRNA suggests a single polypeptide precursor for both of these subunits. Several identical cDNA clones representing the entire coding region of the DB58 mRNA have been isolated from a D. biflorus stem and leaf cDNA library. The DB58 cDNA represents an mRNA encoding a polypeptide of Mr = 29,545. The predicted polypeptide is equal in length to the larger subunit of DB58 with the addition of a 22-amino acid amino-terminal signal sequence. The sequence of the DB58 lectin exhibits 84% homology to the D. biflorus seed lectin at the amino acid level, suggesting that these lectins are encoded by differentially expressed genes and may have evolved to carry out tissue-specific functions. Comparison of the DB58 sequence to other leguminous seed lectins indicates a high degree of structural conservation.     

Isolation and characterization of subunits from the predominant form of Dolichos biflorus lectin.

The subunits of the two molecular forms (A and B) of the Dolichos biflorus lectin were isolated by ion-exchange chromatography on DEAE-cellulose in 8.0 M urea. Subunits IA and IIA which comprise the predominant molecular form A of the lectin were found to have molecular weights of 27,700 and 27,300, respectively, as determined by sedimentation equilibrium studies in 8.0 M urea. These subunits have similar amino acid compositions and each have alanine at their amino-terminal ends. Comparison of the IA and IIA subunits by immunodiffusion against antisera to the seed extract as well as to subunits IA and IIA showed no antigenic differences between the two subunits. Carboxyl terminal analyses of subunits IA and IIA with carboxypeptidase A produced an essentially simultaneous release of both leucine and valine residues from subunit IA; no detectable amino acids were released from subunit IIA under identical conditions. The data suggest that the molecular form A of the lectin (molecular weight 113,000, Carter and Etzler, 1975) consists of four subunits with a possible stoichiometry of IA2IIA2. Other possible arrangements of the subunits are discussed.     

Receptors to Dolichos biflorus Agglutinin

Dolichos biflorus agglutinin (DBA), a lectin specific to N-acetylgalactosamine residue, identifies cell surface markers on teratocarcinoma cells. These receptors are found in very limited types of adult tissues. In the present investigation, mouse embryos collected on days 1 (2-cell) to 3 (early blastocyst) were shown to be stained with FITC-conjugated DBA. Embryos homozygous for t ^w32 were also positively stained. These results suggest that receptors for DBA on preimplantation embryos include components distinct from Forssman, F9, and SSEA-1 antigens.     

Isolation and characterization of cyanogen bromide fragments and a glycopeptide from the Dolichos biflorus lectin.

The 110000 molecular weight Dolichos biflorus lectin is a glycoprotein composed of four subunits of approximately 27000 molecular weight with one methionine residue per subunit (Carter and Etzler, 1975b). Cyanogen bromide cleavage of the lectin yielded two fragments with approximate molecular weights of 15000 and 12000 as determined by electrophoresis on sodium dodecyl sulfate gels. Only the 15000 molecular weight fragment stained for carbohydrate with the periodic acid-Schiff stain. The two fragments were isolated, and their amino acid compositions were determined. The 15000 molecular weight fragment was identified as the amino terminal segment of the lectin subunits by NH2-terminal amino acid analysis. A glycopeptide with a minimum molecular weight of 1100 was isolated from the lectin by exhaustive Pronase digestion. Complete acid hydrolysis of the glycopeptide yielded aspartic acid, mannose, and N-acetylglucosamine in the ratio of 1:4-5:1-2. Partial acid hydrolysis of the glycopeptide produced a component which had an identical mobility with commercial N-acetylglucosaminylasparagine in high voltage paper electrophoresis. The data indicate that the carbohydrate unit of the lectin is bound to the amino terminal half of the subunits by a glycosylamine linkage between N-acetylglucosamine and asparagine.     

Carbohydrate binding, quaternary structure and a novel hydrophobic binding site in two legume lectin oligomers from Dolichos biflorus

The seed lectin (DBL) from the leguminous plant Dolichos biflorus has a unique specificity among the members of the legume lectin family because of its high preference for GalNAc over Gal. In addition, precipitation of blood group A+H substance by DBL is slightly better inhibited by a blood group A trisaccharide (GalNAc(alpha1-3)[Fuc(alpha1-2)]Gal) containing pentasaccharide, and about 40 times better by the Forssman disaccharide (GalNAc(alpha1-3)GalNAc) than by GalNAc. We report the crystal structures of the DBL-blood group A trisaccharide complex and the DBL-Forssman disaccharide complex.A comparison with the binding sites of Gal-binding legume lectins indicates that the low affinity of DBL for Gal is due to the substitution of a conserved aromatic residue by an aliphatic residue (Leu127). Binding studies with a Leu127Phe mutant corroborate these conclusions. DBL has a higher affinity for GalNAc because the N-acetyl group compensates for the loss of aromatic stacking in DBL by making a hydrogen bond with the backbone amide group of Gly103 and a hydrophobic contact with the side-chains of Trp132 and Tyr104.Some legume lectins possess a hydrophobic binding site that binds adenine and adenine-derived plant hormones, i.e. cytokinins. The exact function of this binding site is unknown, but adenine/cytokinin-binding legume lectins might be involved in storage of plant hormones or plant growth regulation. The structures of DBL in complex with adenine and of the dimeric stem and leaf lectin (DB58) from the same plant provide the first structural data on these binding sites. Both oligomers possess an unusual architecture, featuring an alpha-helix sandwiched between two monomers. In both oligomers, this alpha-helix is directly involved in the formation of the hydrophobic binding site. DB58 adopts a novel quaternary structure, related to the quaternary structure of the DBL heterotetramer, and brings the number of know legume lectin dimer types to four.     

Interaction between Dolichos biflorus lectin and chick embryonic fibroblasts at different stages of development.

The interaction between chick embryo fibroblasts and A1-specific blood group Dolichos biflorus lectin has been studied at various stages of embryo development. The site number ((0.26 plus or minus 0.03)-10-6 sites/cell) remains the same during development whereas the affinity constant apparently decreases from 8-day cells onwards. The effects of cell number, temperature and time course on the Dolichos binding to fibroblasts were not age dependent. Competitive binding experiments revealed that Dolichos receptor sites were distinct from binding sites fo Robina pseudoacacia lectin and concanavalin A, but partially related to binding sites of Ricinus lectin. Thymidine incorporation by fibroblasts in the presence of Dolichos lectin was age dependent. It was inhibited in 6-day cells and weakly stimulated in 16-day cells, but not modified in 12-day cells. Dolichos lectin effects on embryo fibroblasts were very specific because both binding to cells and effect on thymidine incorporation were blocked by N-acetylgalactosamine, the determinant of Dolichos lectin, as well as by Dolichos antiserum.     

Subcellular Localizations of Two Dolichos biflorus Lectins

The subcellular localizations of the Dolichos biflorus seed lectin and the structurally related lectin (cross-reactive material [CRM]) from the stems and leaves of this plant were determined by immunofluorescence, immunocytochemistry, and cell fractionation procedures. Subcellular fractionation of the cotyledons using a nonaqueous procedure to minimize disruption of the protein bodies showed that the majority of the seed lectin was associated with the protein body fraction and some lectin was also present in the starch granules. Immunofluorescence and immunocytochemistry at the light microscopic level showed that the seed lectin was mainly localized at the peripheries of these organelles. Lectin was also found in the cytoplasm of the cells, although the amount appeared to be dependent upon the degree of protein body disruption.

Immunofluorescence and immunocytochemistry studies of the stem and leaf lectin (CRM) indicated that a significant portion of this lectin may be associated with the cell walls, although lectin was also seen in the cytoplasm of plasmolyzed cells. Extraction and cell fractionation studies showed that a large portion of the CRM is readily solubilized and most of the remainder is pelleted at 1000g. The CRM can be extracted from these pellets by treatment with cellulase and pectinase; other reagents such as NaCl, detergents, and EDTA could also release significant amounts of CRM. These studies suggest that the CRM is noncovalently bound to the cell walls. A comparison of the distribution of exogenously supplied [¹²⁵I]CRM with the endogenous CRM during extraction and cell fractionation indicates that soluble CRM is not adsorbed to the 1000g pellet during fractionation.

The different subcellular distributions of these two structurally related lectins suggest that different tissues of the same plant may utilize lectins for different functions.

     

Alternative ultrastructural localization of Dolichos biflorus lectin binding sites in proton secreting parietal cells of mice

Summary High amount of N-acetyl-d-galactosamine specific lectin binding sites were detected on the canalicular membranes of human parietal cells. Our present model investigations on mice showed that the intracellular distribution of the terminal N-acetyl-d-galactosamine containing glycoprotein highly depends on the actual functional state of the parietal cells. In the normal gastric mucosa 40%–60% of parictal cells react positively after staining with horseradish peroxidase or biotin labelled Dolichos biflorus lectin. Ultrastructurally lectin binding sites occur mainly on the basolateral membrane infoldings in fed animals, while they are present exclusively on the canalicular membranes of fasting mice, suggesting that the alternative appearance of lectin binding sites on the opposite membrane areas of parietal cells is tightly coupled to their main function, to H⁺ secretion.     

Alternative ultrastructural localization of Dolichos biflorus lectin binding sites in proton secreting parietal cells of mice

High amount of N-acetyl-D-galactosamine specific lectin binding sites were detected on the canalicular membranes of human parietal cells. Our present model investigations on mice showed that the intracellular distribution of the terminal N-acetyl-D-galactosamine containing glycoprotein highly depends on the actual functional state of the parietal cells. In the normal gastric mucosa 40%-60% of parietal cells react positively after staining with horseradish peroxidase or biotin labelled Dolichos biflorus lectin. Ultrastructurally lectin binding sites occur mainly on the basolateral membrane infoldings in fed animals, while they are present exclusively on the canalicular membranes of fasting mice, suggesting that the alternative appearance of lectin binding sites on the opposite membrane areas of parietal cells is tightly coupled to their main function, to H+ secretion.     

An isoflavone diglycoside from the seeds of Dolichos biflorus

-5-Hydroxy-7,3′,4′-trimethoxy-8-methylisoflavone 5-neohesperidoside has been identified from the seeds of Dolichos biflorus.