Interactions between Rhizobia and Lectins of Lentil, Pea, Broad Bean, and Jackbean

A quantitative method was developed to measure the binding of fluorescent-labeled lentil (Lens esculenta Moench), pea (Pisum sativum L.), broad bean (Vicia faba L.), and jackbean (Canavalia ensiformis L., DC.) lectins to various Rhizobium strains. Lentil lectin bound to three of the five Rhizobium leguminosarum strains tested. The number of lentil lectin molecules bound per R. leguminosarum 128C53 cell was 2.1 × 10⁴. Lentil lectin also bound to R. japonicum 61A133. Pea and broad bean lectins bound to only two of the five strains of R. leguminosarum, whereas concanavalin A (jackbean lectin) bound to all strains of R. leguminosarum, R. phaseoli, R. japonicum, and R. sp. tested. Since these four lectins have similar sugarbinding properties but different physical properties, the variation in bindings of these lectins to various Rhizobium strains indicates that binding of lectin to Rhizobium is determined not only by the sugar specificity of the lectin but also by its physical characteristics.     

Crystal Structure of the GalNAc/Gal-Specific Agglutinin from the Phytopathogenic Ascomycete Sclerotinia sclerotiorum Reveals Novel Adaptation of a β-Trefoil Domain

A lectin from the phytopathogenic ascomycete Sclerotinia sclerotiorum that shares only weak sequence similarity with characterized fungal lectins has recently been identified. S. sclerotiorum agglutinin (SSA) is a homodimeric protein consisting of two identical subunits of ∼ 17 kDa and displays specificity primarily towards Gal/GalNAc. Glycan array screening indicates that SSA readily interacts with Gal/GalNAc-bearing glycan chains. The crystal structures of SSA in the ligand-free form and in complex with the Gal-β1,3-GalNAc (T-antigen) disaccharide have been determined at 1.6 and 1.97 Å resolution, respectively. SSA adopts a β-trefoil domain as previously identified for other carbohydrate-binding proteins of the ricin B-like lectin superfamily and accommodates terminal non-reducing galactosyl and N-acetylgalactosaminyl glycans. Unlike other structurally related lectins, SSA contains a single carbohydrate-binding site at site α. SSA reveals a novel dimeric assembly markedly dissimilar to those described earlier for ricin-type lectins. The present structure exemplifies the adaptability of the β-trefoil domain in the evolution of fungal lectins.     

Evidence for Strain-specific Agglutination of Rhizobium by a 45 kD Protein from Chickpea

A 45 kD protein isolated from chickpea seeds was shown to agglutinate Rhizobium specific to chickpea (Cicer arietinum L.) but not the Rhizobium which nodulates peanut and cowpea.     

Isolation and characterization of a fish F-type lectin from gilt head bream (Sparus aurata) serum

A novel fucose-binding lectin, designated SauFBP32, was purified by affinity chromatography on fucose–agarose, from the serum of the gilt head bream Sparus aurata. Electrophoretic mobility of the subunit revealed apparent molecular weights of 35 and 30 kDa under reducing and non-reducing conditions, respectively. Size exclusion analysis suggests that the native lectin is a monomer under the selected experimental conditions. Agglutinating activity towards rabbit erythrocytes was not significantly modified by addition of calcium or EDTA; activity was optimal at 37 °C, retained partial activity by treatment at 70 °C, and was fully inactivated at 90 °C. On western blot analysis, SauFBP showed intense cross-reactivity with antibodies specific for a sea bass (Dicentrarchus labrax) fucose-binding lectin. In addition, the similarity of the N-terminal sequence and a partial coding domain to teleost F-type lectins suggests that SauFBP32 is a member of this emerging family of lectins.     

Isolation and characterization of a jacalin-related mannose-binding lectin from salt-stressed rice (Oryza sativa) plants

A novel plant lectin was isolated from salt-stressed rice (Oryzasativa L.) plants and partially characterized. The lectin occurs as a natural mixture of two closely related isoforms consisting of two identical non-covalently linked subunits of 15 kDa. Both isoforms are best inhibited by mannose and exhibit potent mitogenic activity towards T-lymphocytes. Biochemical analyses and sequence comparisons further revealed that the rice lectins belong to the subgroup of mannose-binding jacalin-related lectins. In addition, it could be demonstrated that the lectins described here correspond to the protein products of previously described salt-stress-induced genes. Our results not only identify the rice lectin as a stress protein but also highlight the possible importance of protein-carbohydrate interactions in stress responses in plants. Received: 27 July 1999 / Accepted: 11 November 1999     

Host-symbiont interactions.I. The lectins of legumes interact with the O-antigen-containing lipopolysaccharides of their symbiont Rhizobia

A specific interaction between the O-antigen-containing lipopolysaccharides of $\text{Rhizobia}$ and the lectins of their legume hosts has been demonstrated. The lectins have been purified from the seeds of four legumes and the lectins covalently attached to Agarose. The lipopolysaccharides were isolated from the four $\text{Rhizobial}$ symbionts of the legumes. These four lipopolysaccharides were passed through the four lectin columns. In each case, the lipopolysaccharide from a $\text{Rhizobium}$ interacts with the lectin column of its symbiont but not with the other lectin columns.     

An Ouchterlony double diffusion study on the interaction between legume lectins and rhizobial cell surface antigens

Acidic exopolysaccharides and O-antigen containing lipopolysaccharides were isolated from Rhizobium japonicum, R. leguminosarum, R. lupini, R. meliloti, R. phaseoli, cowpea Rhizobium sp. and a non-nodulating soil bacterium. Lectins from seeds of soybean (Glycine max), garden pea (Pisum sativum), lentil (Lens culinaris), alfalfa (Medicago sativa), field bean (Phaseolus vulgaris), jackbean (Canavalia ensiformis) and from wheat germ were tested for their capacity to precipitate rhizobial exopolysaccharides and lipopolysaccharides in the Ouchterlony double diffusion test. Soybean lectin precipitated exclusively with the exopolysaccharide of R. japonicum, whereas the lectins from pea and lentil precipitated exopolysaccharides from all the fast growing strains of Rhizobium. Host range specific interactions between lipopolysaccharides and lectins were observed in the pea/lentil-R. leguminosarum and in the alfalfa-R. meliloti systems. Concanavalin A precipitated the exopolysaccharides of all fast growing strains of Rhizobium, the exopolysaccharide of the cowpea strain and several lipopolysaccharides of different Rhizobium species and thus did not show any correlation between polysaccharide binding and symbiotic specificity. Non-leguminous wheat germ agglutinin did not precipitate any of the rhizobial polysaccharides tested and the lipopolysaccharide of the soil bacterium did not precipitate with any of the lectins examined.Abbreviations Con A Concanavalin A - CPC cetylpyridinium chioride - EPS exopolysaccharide - FITC fluorescein isothiocyanate - KDO 2-keto-3-deoxyoctonic acid - LPS lipopolysaccharide - PBS phosphate-buffered saline - PS polysaccharide     

Molecular cloning of the bark and seed lectins from the Japanese pagoda tree (Sophora japonica)

cDNA clones encoding the bark and seed lectins from Sophora japonica were isolated and their sequences analyzed. Screening of a cDNA library constructed from polyA RNA isolated from the bark resulted in the isolation of three different lectin cDNA clones. The first clone encodes the GalNAc-specific bark lectin which was originally described by Hankins et al. whereas the other clones encode the two isoforms of the mannose/glucose-specific lectin reported by Ueno et al.. Molecular cloning of the seed lectin genes revealed that Sophora seeds contain only a GalNAc-specific lectin which is highly homologous to though not identical with the GalNAc-specific lectin from the bark. All lectin polypeptides are translated from mRNAs of ca. 1.3 kb encoding a precursor carrying a signal peptide. In the case of the mannose/glucose-specific bark lectins this precursor is post-translationally processed in two smaller peptides. Alignment of the deduced amino acid sequences of the different clones revealed striking sequence similarities between the mannose/glucose-binding and the GalNAc-specific lectins. Furthermore, there was a high degree of sequence homology with other legume lectins which allowed molecular modelling of the Sophora lectins using the coordinates of the Pisum sativum, Lathyrus ochrus and Erythrina corallodendron lectins.     

Characterization of α-mannosidase from Erythrina indica seeds and influence of endogenous lectin on its activity

α-mannosidase from Erythrina indica seeds is a Zn²⁺ dependent glycoprotein with 8.6% carbohydrate. The enzyme has a temperature optimum of 50 °C and energy of activation calculated from Arrhenius plot was found to be 23 kJ mol^− 1. N-terminal sequence up to five amino acid residues was found to be DTQEN (Asp, Thr, Gln, Glu, and Asn). In chemical modification studies treatment of the enzyme with NBS led to total loss of enzyme activity and modification of a single tryptophan residue led to inactivation. Fluorescence studies over a pH range of 3–8 have shown tryptophan residue to be in highly hydrophobic environment and pH change did not bring about any appreciable change in its environment. Far-UV CD spectrum indicated predominance of α-helical structure in the enzyme. α-Mannosidase from E indica exhibits immunological identity with α-mannosidase from Canavalia ensiformis but not with the same enzyme from Glycine max and Cicer arietinum. Incubation of E. indica seed lectin with α-mannosidase resulted in 35% increase in its activity, while no such activation was observed for acid phosphatase from E. indica. Lectin induced activation of α-mannosidase could be completely abolished in presence of lactose, a sugar specific for lectin.     

Molecular cloning,expression, and cytokinin (6-benzylaminopurine) antagonist activity of peanut (<Emphasis Type="Italic">Arachis hypogaea</Emphasis>) lectin SL-I

Isolation and purification of a α-methyl-mannoside specific lectin (SL-I) of peanut was reported earlier [Singh and Das (1994) Glycoconj J 11:282–285]. Native SL-I is a glycoprotein having ∼31 kDa subunit molecular mass and forms dimer. The gene encoding this lectin is identified from a 6-day old peanut root cDNA library by anti-SL-I antibody and N-terminal amino acid sequence homology to the native lectin. Nucleotide sequence derived amino acid sequence of the re-SL-I shows amino acid sequence homology with the N-terminal and tryptic digests’ amino acid sequence of the native SL-I (nSL-I). Presence of a putative glycosylation (QNPS) site and a hydrophobic adenine-binding (VLVSYDANS) site is also identified in SL-I. Homology modeling of the lectin suggests it to be an archetype of legume lectins. It is expressed as a ~30 kDa apoprotein in E. coli and has the carbohydrate specificity and secondary structure identical to its natural counterpart. The lectin SL-I inhibits cytokinin 6-benzylaminopurine (BA)-induced “delayed leaf senescence” and “cotyledon expansion”. Equilibrium dialysis revealed a single high-affinity binding site for adenine (7.6 × 10⁻⁶ M) and BA (1.09 × 10⁻⁵ M) in the SL-I dimer and thus suggesting that the cytokinin antagonist effect of SL-I is mediated by the direct interaction of SL-I with BA.The nucleotide sequence data reported here are available in the DDBJ/EMBL/GenBank databases under the Accession No. AJ585523     

The effect of lectins on the attachment and invasion of Enteromyxum scophthalmi (Myxozoa) in turbot (Psetta maxima L.) intestinal epithelium in vitro

The involvement of the lectin/carbohydrate interaction in the invasion of the turbot intestinal epithelium by Enteromyxum scophthalmi was studied in vitro using explants of turbot intestine and pre-treatment of parasite stages with the plant lectins of Canavalia ensiformis (Con A) and Glycine max (SBA). Both lectins inhibited the attachment and invasion of E. scophthalmi stages to the intestinal epithelium, though the inhibitory effect was higher for SBA than for Con A. Such results point to the involvement of N-acetyl-galactosamine (GalNAc) and galactose (Gal) residues and also of mannose/glucose residues in the E. scophthalmi-intestinal epithelium interaction. The inhibitory effect of both lectins on the parasite adhesion and penetration points to the interest of further studies to confirm the presence of putative lectins recognising GalNAc-Gal and mannose/glucose residues in turbot intestine. The obtained results demonstrated also the adequacy of turbot intestinal explants as an in vitro model to study the interaction with E. scophthalmi.     

Inoculation of Rhizobium (VR-1 and VA-1) induces an increasing growth and metal accumulation potential in Vigna radiata and Vigna angularis L. growing under fly-ash

Fly-ash-tolerant Rhizobium strains were isolated from plants grown in fly-ash-contaminated soil, axenically under laboratory conditions. Saplings of both plants were raised in N₂-free Jenson medium and inoculated with 2.6 × 10⁸ cell ml⁻¹ and 5.2 × 10⁸ cell ml⁻¹ of culture after 10 d of growth. Plants were transferred into 100% fly-ash under natural condition. Rhizobium-inoculated plants grown on 100% fly-ash showed marked increase in relation to root-shoot length, biomass yield, photosynthetic pigment, protein content and nodulation frequency compared to uninoculated plant grown in control (100% fly-ash). Inoculation of fly-ash-tolerant Rhizobium increased the accumulation of Fe, Zn, Cu Cd and Cr in different tissues vis-à-vis enhanced translocation of metals to the aboveground part of plant. Although inoculation of fly-ash-tolerant Rhizobium strains (VR-1 and VA-1) enhanced the translocation of more Fe to shoot parts, nevertheless, the amount of Rhizobium inoculants supplied to the plant was found to be very important since it has a positive role in increasing plant growth through increased N₂ supply via nitrogenase activity. Results suggest that an integrated approach employing biotechnological means and inoculation of plants with host-specific fly-ash-tolerant Rhizobium strain may prove a stimulus to a fly-ash management programme.     

Evidence for a sugar receptor (lectin) in the peritrophic membrane of the blowfly larva, Calliphora erythrocephala Mg. (Diptera)

For the first time a sugar receptor (lectin) has been localized by electron microscopy in an invertebrate. The peritrophic membrane of the blowfly larva, Calliphora erythrocephala, is shown here to express lectins with high specificity for mannose. The lectin is restricted to the lumen side of the peritrophic membrane. The surface of the midgut epithelium is devoid of mannose-specific lectins. It is suggested that the midgut epithelium has lost these lectins during the course of evolution in favour of the peritrophic membrane which is secreted by specialized cells only at the beginning of the midgut.Peritrophic membranes and the midgut epithelium lack lectins specific for galactose. The lumen side of the peritrophic membrane of the larvae has mannose and/or glucose residues, and it is densely packed with two species of bacteria, Proteus vulgaris and P. morganii. These also have mannose-specific lectins as well as mannose residues on their pili. The existence of mannose-specific receptors and mannose residues on both, peritrophic membranes and bacteria, leads to the assumption of mutual adherence between the two surfaces.     

Magnetic beads-assisted mild enrichment procedure for weak-binding lectins

Investigating unidentified weak-acting lectins is important for understanding glycan-related phenomena. We have developed an improved screening method for weak-acting lectins using glycan-conjugated magnetic beads (or glycobeads) involving a partial washing method and named it the mild enrichment procedure. Weak-acting lectins exist in equilibrium between bound lectin and free lectin produced by dissociation, whereas most tight-binding lectin exists in a bound state. The conventional washing step, in which the solution phase is replaced, may remove dissociated lectin from around the glycobeads; therefore, we attempted to leave a buffer space around the glycobeads to maintain the association–dissociation equilibrium of weak-acting lectins. Our results revealed that our mild enrichment procedure for screening for weak interactions, such as maltose–concanavalin A (K_a ∼ 10⁴ M⁻¹) and lactose–peanut agglutinin (K_a ∼ 10³ M⁻¹) interactions, was more effective than conventional batch methods.     

Lectin binding patterns of Scrippsiella lachrymosa (Dinophyceae) in relation to cyst formation and nutrient conditions

In many dinoflagellates, it has been a challenging task to study the qualitative and quantitative processes leading to encystment because gametes are often not morphologically distinguishable from other vegetative cells. We examined whether sexual differentiation is accompanied by changes in cell surface glycoprotein properties that are reflected in the binding patterns of complementary lectins. Labeling percentages of nine different fluorescein isothiocyanate (FITC)-conjugated lectins were analyzed together with cell and cyst abundance in N-deplete and f/2 control cultures of Scrippsiella lachrymosa Lewis throughout an encystment experiment. Although labeling varied between lectins and treatments and considerable changes occurred through time, no direct correlation was observed between glycoconjugate properties and sexual life cycle processes. A conspicuous decrease in labeling of lectins that are complementary to amino sugars (in particular, with WGA, a lectin that is complementary to N-acetylglucosamine) was observed in the low nitrogen treatment, suggesting a link between the nutrient status of a cell and expression of surface carbohydrates. Presumably, the reduction of N-acetylglucosamine residues was an early indication of N stress in cell populations. Labeling experiments with phosphate-limited cells showed that the decrease in WGA-complementary amino-sugar residues was not specific for N stress, but appeared to be a general response to nutrient limitation. Our findings confirm that glycoconjugate composition of dinoflagellate cells can change depending on their physiological state, which has to be considered when applying lectins for taxonomic differentiation of dinoflagellate species.     

Changing complexity of endogenous lectin activities during juvenile development of Xenopus laevis

Galactoside-binding lectin has been isolated from whole Xenopus laevis embryos and tadpoles at four development stages: st. 24–26, 32, 41 and 47. The main lectin activity at st. 24–26 is -galactoside specific, producing a 34/35.5K doublet on SDS-PAGE. Later in development, lectin activities specific for a wide range of other sugars appear concommitant with the detection of a number of new protein bands on SDS-PAGE gels. The greatest variety of new lectin activities exists at st. 32 when lectins specific for all of the main sugar families found in nature are detected. After this stage and up to st. 47 (the beginning of metamorphosis), fewer different lectin activities are again detected. The results suggest that a complex, developmentally regulated battery of different lectins are present during early Xenopus development, perhaps with stage-specific roles to play in the control of tissue morphogenesis.     

Mass spectrometric characterization of isoform variants of peanut (Arachis hypogaea) stem lectin (SL-I)

Matrix assisted laser desorption/ionization–time-of-flight (MALDI–TOF) mass spectrometric (MS) analysis of purified Arachis hypogaea stem lectin (SL-I) and its tryptic digests suggested it to be an isoformic glucose/mannose binding lectin. Two-dimensional gel electrophoresis of SL-I indicated six isoforms (A1–A6), which were confirmed by Western blotting and MALDI–TOF MS analysis. Comparative analysis of peptide mass spectra of the isoforms matched with A. hypogaea lectins with three different accession numbers (Q43376_ARAHY, Q43377_ARAHY, Q70DJ5_ARAHY). Tandem mass spectrometric (MS/MS) analysis of tryptic peptides revealed these to be isoformic variants with altered amino acid sequences. Among the peptides, the peptide T12 showed major variation. The ¹⁹⁹Val–Ser–Tyr–Asn²⁰² sequence in peptide T12 of A1 and A2 was replaced by ¹⁹⁹Leu–Ser–His–Glu²⁰² in A3 and A4 (T12′) while in A5 and A6 this sequence was ¹⁹⁹Val–Ser–Tyr–Val²⁰² (T12″). Peptide T1 showed the presence of ¹⁰Asn in the isoforms A1–A5 while in A6 this amino acid was replaced by ¹⁰Lys (T1′). Overall amino acid sequence as identified by MS/MS showed a high degree of similarity between A1, A2 and among A3, A4, A5. Carbohydrate binding domain and adenine binding site seem to be conserved.     

Desiccation induced oxidative stress and its biochemical responses in intertidal red alga Gracilaria corticata (Gracilariales, Rhodophyta)

Intertidal alga Gracilaria corticata growing in natural environment experiences various abiotic stresses during the low tides. The aim of this study was to determine whether desiccation exposure would lead to oxidative stress and its effect varies with exposure periods. This study gives an account of various biochemical changes in G. corticata following the exposure to desiccation for a period of 0 (control), 1, 2, 3 and 4 h under controlled conditions. During desiccation, G. corticata thalli showed dramatic loss of water by almost 47% when desiccated for 4 h. The enhanced production of reactive oxygen species (ROS) and increased lipid peroxidation observed during the exposure of 3-4 h were chiefly contributed by higher lipoxygenase (LOX) activity with the induction of two new LOX isoforms (LOX-2, ∼85 kDa; LOX-3, ∼65 kDa). The chlorophyll, carotenoids and phycobiliproteins (phycoerythrin and phycocyanin) were increased during initial 2 h exposure compared to control and thereafter declined in the succeeding exposure. The antioxidative enzymes such as superoxide dismutase (SOD), ascorbate peroxidase (APX), glutathione reductase (GR), glutathione peroxidase (GPX) and the regeneration rate of reduced ascorbate (AsA) and glutathione (GSH) increased during desiccation up to 2-3 h. Further, the isoforms of antioxidant enzymes Mn-SOD (∼150 kDa), APX-4 (∼110 kDa), APX-5 (∼45 kDa), GPX-1 (∼80 kDa) and GPX-2 (∼65 kDa) responded specifically to the desiccation exposure. Compared to control, a relative higher content of both free and bound insoluble putrescine and spermine together with enhanced n-6 PUFAs namely C20:4(n-6) and C20:3(n-6) fatty acids found during 2 h exposure reveals their involvement in defence reactions against the desiccation induced oxidative stress.     

Induction of apoptosis by Polygonatum odoratum lectin and its molecular mechanisms in murine fibrosarcoma L929 cells

Background

The Galanthus nivalis agglutinin (GNA)-related lectins have been reported to bear antiproliferative and apoptosis-inducing activities in cancer cells; however, the precise mechanisms by which GNA-related lectins induce cell death are still only rudimentarily understood.

Methods

In the present study, Polygonatum odoratum lectin (designated POL), a mannose-binding specific GNA-related lectin, possessed a remarkable antiproliferative activity toward murine fibrosarcoma L929 cells. And, this lectin induced L929 cell apoptosis in a caspase-dependent manner. In addition, POL treatment increased the levels of FasL and Fas-Associated protein with Death Domain (FADD) proteins and resulted in caspase-8 activation. Also, POL treatment caused mitochondrial transmembrane potential collapse and cytochrome c release, leading to activations of caspase-9 and caspase-3. Moreover, POL treatment enhanced tumor necrosis factor α (TNFα)-induced L929 cell apoptosis.

Results

Our data demonstrate for the first time that this lectin induces apoptosis through both death-receptor and mitochondrial pathways, as well as amplifies TNFα-induced L929 cell apoptosis.

General significance

These inspiring findings would provide new molecular basis for further understanding cell death mechanisms of the Galanthus nivalis agglutinin (GNA)-related lectins in future cancer investigations.