Concanavalin A binds to a mannose-containing ligand in the cell wall of some lichen phycobionts.

Concanavalin A, the lectin from Canavalia ensiformis, develops arginase activity depending on Mn(2+). The cation cannot be substituted by Ca(2+) which, in addition, inhibits Mn(2+)-supported activity. Fluorescein-labeled Concanavalin A is able to bind to the cell wall of algal cells recently isolated from Evernia prunastri and Xanthoria parietina thalli. This binding involves a ligand, probably a glycoprotein containing mannose, which can be isolated by affinity chromatography. Analysis by SDS-PAGE reveals that the ligand is a dimeric protein composed by two monomers of 54 and 48 kDa. This ligand shows to be different from the receptor for natural lichen lectins, previously identified as a polygalactosylated urease.     

A Lichen Lectin Specifically Binds to the α-1,4-Polygalactoside Moiety of Urease Located in the Cell Wall of Homologous Algae

A lectin from the lichen Evernia prunastri developing arginase activity (EC. 3.5.3.1) binds to the homologous algae that contain polygalactosilated urease (EC. 3.5.1.5) in their cell walls acting as a lectin ligand. The enzyme bound to its ligand shows to be inactive to hydrolyze of arginine. Hydrolysis of the galactoside moiety of urease in intact algae with α-1,4-galactosidase (EC. 3.2.1.22) releases high amount of D-galactose and impedes the binding of the lectin to the algal cell wall. However, the use of β-,4-galactosidase (EC.3.2.1.23) releases low amounts of D-galactose from the algal cell wall and does not change the pattern of binding of the lectin to its ligand. The production of glycosilated urease is restricted to the season in which algal cells divide and this assures the recognition of new phycobiont produced after cell division by its fungal partner.Key Words: arginase, cell wall, evernia prunastri, lectin ligand, phycobiont, urease     

Correlationships between Enzymatic Activity of Lectins, Putrescine Content and Chloroplast Damage in Xanthoria parietina Phycobionts

Lectins from the lichen Xanthoria parietina develop arginase activity. One of these lectins behaves as a secreted arginase whereas another is an endocellular enzyme. Both enzymes are glycosylated proteins differing in the occurrence of galactose instead of N-acetyl-D-glucosamine in secreted arginase. The affinity for the algal ligand (glycosylated cell wall urease) of secreted arginase is higher than that shown for the endocellular enzyme. When the lectin ligand is absent from the algal cell wall, both endocellular and secreted arginases seem to be able to enter algal cells. This uptake promotes the increase in the amount of algal putrescine, preferently as free polyamine, and the chloroplast is rapidly damaged. Induction of cell wall urease retains lectins outside the cells, on the cell wall, and chloroplast remains healthy.     

Assay and characterization of carbohydrate binding by the lectin discoidin I immobilized on nitrocellulose

Discoidin I is the most abundant galactose binding lectin produced by the cellular slime mold Dictyostelium discoideum and has been implicated in cell-substratum adhesion. We have developed an assay of carbohydrate binding activity utilizing binding of 125I-asialofetuin to discoidin I, or to other lectins, immobilized on nitrocellulose. Among the proteins examined, only lectins exhibited the ability to bind asialofetuin. Specificity of asialofetuin binding was demonstrated by competition with monosaccharides, which inhibited binding consistent with the known sugar specificity of the lectins examined. Experiments with fetuin and derivatives differing in their oligosaccharide structure indicated a requirement for terminal galactosyl residues for probe binding to discoidin I. We have used this assay to characterize the carbohydrate binding behavior of discoidin I. The extent of asialofetuin binding to discoidin I was dependent on the concentrations of both lectin and ligand. Interpretation of equilibrium binding data suggested that, under saturating conditions, 1 mol of oligosaccharide was bound per mole discoidin I monomer. Furthermore, discoidin I in solution and discoidin I on nitrocellulose were equally effective at competing for soluble asialofetuin, suggesting that immobilization had no effect on the carbohydrate binding behavior of discoidin I. Binding was strongly inhibited by ethylenediaminetetraacetic acid; both Ca2+ and Mn2+ could overcome that inhibition, but Mg2+ could not. Preincubation of discoidin I at 60 degrees C stimulated asialofetuin binding 2-fold by increasing the affinity, while preincubation at higher temperatures resulted in a complete loss of activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Preparation and properties of metal ion derivatives of the lentil and pea lectins

Lentil lectin (LcH) and pea lectin (PSA) belong to the class of D-glucose/D-mannose binding lectins and resemble concanavalin A (Con A) closely in physicochemical, structural, and biological properties. LcH and PSA, like Con A, are Ca2+-Mn2+ metalloproteins that require the metal ions for their saccharide binding and biological activities. Studies of the relationship between the metal ions binding and saccharide binding activity in LcH and PSA have been difficult due to the problem of metal ion replacement in these proteins. We now report a method of metal ion replacement in both lectins that allows substitution of the Mn2+ in the native proteins with a variety of transition metal ions, as well as substitution of the Ca2+ with Cd2+ in a particular complex. The following metal ion derivatives of both LcH and PSA have been prepared: Ca2+-Zn2+, Ca2+-Co2+, Ca2+-Ni2+, and Cd2+-Cd2+. All of these derivatives are as active as the native lectins, as demonstrated by precipitation with specific polysaccharides, saccharide inhibition of precipitation, and hemagglutination assays. The yields of these derivatives are good (generally greater than 70%), and the degree of metal ion incorporation is high (generally greater than 90%). The method of preparation is quite different from that for metal ion substitution in Con A, which proceeds via the apoprotein. In contrast, the apoproteins of LcH and PSA are unstable, aggregate above pH 4.0, and cannot be remetallized once formed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Divalent cation regulation of the function of the leukocyte integrin LFA-1

The integrin lymphocyte function-associated antigen-1 (LFA-1) expressed on T cells serves as a useful model for analysis of leukocyte integrin functional activity. We have assessed the role of divalent cations Mg2+, Ca2+, and Mn2+ in LFA-1 binding to ligand intercellular adhesion molecule-1 (ICAM-1) and induction of the divalent cation-dependent epitope recognized by mAb 24. Manganese strongly promoted both expression of the 24 epitope and T cell binding to ICAM-1 via LFA-1, suggesting that Mn2+ is able to directly alter the conformation of LFA-1 in a manner that favors ligand binding. Since Mn2+ also promotes functional activity of other integrins, parallels in mechanism of ligand binding may span the integrin family. In contrast, induction of 24 epitope expression by Mg2+ required removal of Ca2+ from T cell LFA-1 with EGTA. Furthermore, binding of mAb 24 to T cell LFA-1 in the presence of either Mn2+ or Mg2+ was found to be specifically inhibited by Ca2+, suggestive of a negative regulatory role for Ca2+ in the control of leukocyte integrin function. Analysis of T cell binding to ICAM-1 via LFA-1 in the presence of Mg2+ or Mn2+, confirmed that Ca2+ exerted inhibitory effects upon LFA-1 function. The implication of our findings is that Ca2+ bound with relatively high affinity to LFA-1 may serve to maintain an inactive state. Thus induction of function and 24 epitope expression may occur as a result of displacement of Ca2+ from leukocyte integrins or alternatively, such activators may be able to impose the required conformational change in the presence of bound Ca2+.     

Proton and deuteron nuclear magnetic relaxation dispersion studies of Ca2+-Mn2+-lentil lectin and Ca2+-Mn2+-pea lectin: evidence for a site of solvent exchange in common with concanavalin A

Measurements of the magnetic field dependence of the longitudinal magnetic relaxation rates (NMRD profiles) of solvent protons and deuterons led to the discovery of two classes of solvent binding sites in Ca2+-Mn2+-concanavalin A (CMPL) [Koenig, S. H., Brown, R. D., III, & Brewer, C. F. (1985) Biochemistry (second of three papers in this issue)]. In this paper, we compare proton and deuteron NMRD profiles of Ca2+-Mn2+-lentil lectin (CMLcH) and Ca2+-Mn2+-pea lectin (CMPSA) with those of CMPL. All three metalloproteins are D-mannose/D-glucose-specific lectins that have a high degree of structural similarity and require the metal ions for their biological activities. We have developed a method for the preparation of fully active metal ion derivatives of lentil lectin (LcH) and pea lectin (PSA), including the diamagnetic derivatives Ca2+-Zn2+-LcH and Ca2+-Zn2+-PSA [Bhattacharyya, L., Brewer, C. F., Brown, R. D., III, & Koenig, S. H.(1984) Biochem. Biophys. Res. Commun. 124, 857-862]. The behavior of these two lectins with regard to their NMRD profiles is essentially identical, for both the paramagnetic and diamagnetic forms. Together with CMPL, all three lectins have a common paramagnetic contribution with a negative temperature dependence of the rates, while CMPL contributes an additional component with a positive temperature dependence. The common contribution derives from the class of fast exchanging water molecules observed in the proton NMRD profile of CMPL (Koenig et al., 1985); their protons are calculated to be relatively remote from the Mn2+ ions (4.4 A for CMPL and 5.5 A for LcH and PSA).(ABSTRACT TRUNCATED AT 250 WORDS)     

The binding of fucose-containing glycoproteins by hepatic lectins. The binding specificity of the rat liver fucose lectin

The parameters that affect the interaction of ligands with a fucose-binding lectin from rat liver have been examined. 125I-Fucosyl-bovine serum albumin (Fuc-BSA) containing 50 residues of fucose/molecule was used as the standard ligand. At low initial concentrations of ligand (10 ng/ml) and lectin (140 ng/ml), the reaction reaches equilibrium at pH 7.8, 23 degrees C, within 40 min. The binding of ligands is Ca2+ dependent with half-maximal binding occurring at 54 microM Ca2+; of several metal ions tested, only Sr2+ partially replaced Ca2+. Binding was maximal between pH 7.6 and 8.6, fell slightly up to pH 10, but fell markedly below pH 7. The lectin-ligand complexes dissociated at low pH, on removal of Ca2+, or in the presence of a large excess of competing ligand. The apparent association constant (Ka) for Fuc-BSA was 1.75 X 10(8) M-1. The fucose content of the Fuc-BSA also influenced binding, with little apparent binding below 24 fucose residues/molecule and maximal binding from 40 to 50 fucose residues/molecule. With knowledge of the parameters influencing binding, sensitive reproducible assays for the lectin were developed. The binding specificity of the lectin was examined by measuring the inhibition of 125I-Fuc-BSA binding by neoglycoproteins, monosaccharides, and glycosides or by direct binding of neoglycoproteins. Galactosides and beta-linked fucosides were the best ligands among the neoglycoproteins, with much weaker binding by mannosyl- or N-acetylglucosaminyl-BSA. On the basis of the pattern of inhibition of Fuc-BSA binding by various monosaccharides and glycosides, it is possible to propose the conformations of saccharides that best fit the lectin-binding site. The C1 conformation of N-acetyl-D-galactosamine fits best, although other not obviously related monosaccharides such as L-fucose, L-arabinose, and D-mannose can also assume conformations that permit them to be effective inhibitors. The pattern of binding of neoglycoproteins to the lectin differs from that of other pure hepatic lectins. Thus, the fucose lectin has a high affinity for Fuc-BSA and galactosyl-BSA but a low affinity for N-acetylglucosaminyl-BSA. The galactose lectin binds only galactosyl-BSA and shows little binding with either N-acetylglucosaminyl-BSA or Fuc-BSA. In contrast, the mannose/N-acetylglucosamine lectin binds N-acetylglucosaminyl-BSA and Fuc-BSA but not galactosyl-BSA.     

Anti-inflammatory effect of glucose-mannose binding lectins isolated from Brazilian beans

Selectins are essential for leukocyte recruitment in inflammation. Because of a lectin domain present in the selectin structure, we investigated the anti-inflammtory activity of six mannose-glucose binding lectins from brazilian beans: Dioclea guianensis-DguiL; D. grandiflora-DgL; Cratylia floribunda-CfL; D. violacea-D.vL; D. virgata-DvirL and Canavalia brasiliensis-ConBr. The lectins were injected intravenously (i.v.) into rats (0.1 and 1.0 mg/kg; 30 min before irritants) and its activities compared to E. coli endotoxin (LPS,30 mug/kg i.v.). Three lectins (DvL, CfL and DguiL), although less intense than LPS, inhibited the neutrophil migration induced by carrageenan (Cg, 300 mug) in a dose-dependent manner (0.1 and 1.0 mg/kg). DvL activity was reversed by 0.1 M alpha-D-methyl-mannoside (alpha-CH3), but not by 0.1 M alpha-D-galactose. The fMLP (44 ng)-induced neutrophil migration was also reduced by these lectins. Endotoxin contamination of lectin samples could be excluded since alpha-CH3 treatment reversed the DvL effect, but did not modify LPS inhibitory activity. Carrageenan (300 mug)-induced paw oedema was also reduced by LPS or lectin treatments. Conversely, none of the tested lectins inhibited dextran (Dex, 300 mug)-induced paw oedema, a classical leukocyte independent model, or zymosan (Zy, 1.0 mg)-induced peritonitis and paw oedema. LPS showed no effect upon Dex-induced paw oedema and barely reduced (25%) the oedematogenic effects of zymosan. As proposed for LPS, the lectin inhibitory activity was better observed on neutrophil-mediated inflammatory reactions. We speculate that the plant lectin antiinflammatory activity is probably due to a competitive blockage of a common leukocyte and/or endothelial selectin carbohydrate ligand.     

Binding of human liver hydrolases by immobilized lectins.

The binding of 22 human liver hydrolase activities by immobilized lectins of six different carbohydrate specificities, namely alpha-D-mannose (glucose), D-N-acetylglucosamine, D-N-acetylgalactosamine, L-fucose, alpha-D-galactose and beta-D-galactose, were examined. Differences in binding among these enzymes and within specific enzymes were observed. For example, the neutral forms of alpha-mannosidase and beta-xylosidase were bound by the Ulex europaeus lectin I (specific for L-fucose), whereas the acidic forms were not. Bandierea simplicifolia lectin (specific for alpha-galactose) bound 65% of beta-glucuronidase activity; recycling experiments demonstrated complete binding of the enzyme that had been eluted with the competitor D-galactose and no binding of the fraction that was not initially bound. These results suggested the presence of two forms of this enzyme. Similar data were obtained for acidic beta-galactosidase activity. These experiments may provide the basis for the expanded use of immobilized lectins for purification and characterization of hydrolases and other glycoproteins.     

Evidence for lectin activity of a plant receptor-like protein kinase by application of neoglycoproteins and bioinformatic algorithms

Detection of genes for putative receptor-like protein kinases, which contain an extracellular domain related to leguminous lectins, in plant genomes inspired the hypothesis that this part acts as sensor. Initial support for this concept came from proof for protein kinase activity. The next step, focusing on the protein of lombardy poplar (Populus nigra var. italica), is scrutiny for lectin activity. Consequently, we first pinpointed sets of high-scoring sequence pairs by extensive databank search. The calculations resulted in P-values in the range from 10(-14) to 10(-18) exclusively for leguminous lectins, the Pterocarpus angolensis agglutinin being front runner with P=3 x 10(-18) and thus most suitable template for modeling. The superimposition of the two folds gave notable similarity in the region responsible for binding carbohydrate and Ca(2+)/Mn(2+)-ions. Binding activity toward carbohydrates was detected by assaying a panel of (neo)glycoproteins as polyvalent probes, especially for alpha-l-rhamnose and glycans of asialofetuin. It was strictly dependent on Ca(2+)-ions, enhanced by Mn(2+)-ions and reached a K(D)-value of 34.3 nM for the neoglycoprotein with rhamnose as ligand. These results give further research direction to define physiological ligands, plant/bacterial rhamnose-containing saccharides and rhamnose-mimetic glycans or peptides being potential candidates.     

Marine algal lectins: new developments

Lectins can be extracted more readily from marine algae if the plant material is freeze-dried or frozen in liquid nitrogen prior to homogenisation. The addition of detergents, such as Tween 80, to the extraction medium and diluents, enhances extraction and detection of the lectins. Marine algal lectins can be isolated by affinity chromatography using a general affinity complex such as yeast mannan-Cellulofine which facilitates the isolation of purified lectin for biochemical characterisation. Red algal lectins exist as three types: low molecular weight molecules which bind glycoproteins, but not monosaccharides and have no requirement for divalent cations; lectins which bind monosaccharides and related small molecules, but have no divalent cation requirements; larger lectins (M.W. > 64000) which bind monosaccharides in the presence of divalent cations. No green algal lectin characterised so far requires divalent cations for haemagglutination. Possibly, only green algal lectins capable of forming oligomers have the capacity to bind monosaccharides.     

Manganese ion elicits a binding activity of placenta vitronectin receptor to fibronectin cell-binding domain.

Some members of the integrin family recognize the RGD sequence which is common to cell adhesive proteins in a divalent cation-dependent manner. In the presence of Ca2+ and Mg2+, the fibronectin receptor of placenta recognizes the RGD sequence of fibronectin, but not that of vitronectin, while the vitronectin receptor of placenta recognizes the RGD sequence of vitronectin, but not that of fibronectin, although both receptors recognize the same RGD sequence. We have found by performing an enzyme-linked immunosorbent assay (ELISA) using receptor-specific monoclonal antibodies and by electrophoretic analysis that in the presence of Mn2+ a vitronectin receptor of placenta binds to an affinity column coupled with the cell-binding domain of fibronectin. By replacing divalent cations from Mn2+ to Ca2+ and Mg2+, the vitronectin receptor was completely eluted from the column. When the synthetic peptides GRGDSP and GRGESP were applied to the column as competitors, the Mn(2+)-dependent binding was inhibited by both peptides. These results suggest that Mn2+ elicits a binding activity of the placenta vitronectin receptor to the RGD site of fibronectin. The modulation of ligand specificity by Mn2+ will provide an important clue in the elucidation of the cause of individual ligand specificity of RGD-recognizing integrins.     

Nuclear magnetic resonance investigation of cadmium 113 substituted pea and lentil lectins

The lentil (LcH) and pea (PSA) lectins, which are members of the class of D-glucose/D-mannose binding lectins, are Ca2+ X Mn2+ metalloproteins that require the metal ions for their saccharide binding and biological activities. We have prepared a variety of Cd2+ derivatives of PSA and LcH, with Cd2+ in either the transition metal (S1) or calcium (S2) sites, or in both. Thus, Cd2+ X Zn2+, Cd2+ X Mn2+, and Ca2+ X Cd2+ derivatives were prepared, in addition to the Cd2+ X Cd2+ derivatives which we have recently reported. This is the first report of stable mixed metal Cd2+ complexes of lectins. The physical and saccharide binding properties of the Cd2+ derivatives of both lectins were characterized by a variety of physiochemical techniques and found to be the same as those of the corresponding native proteins. 113Cd NMR spectra of mono- and disubstituted 113Cd2+ complexes of LcH and PSA were recorded and compared with 113Cd NMR data for concanavalin A (ConA) (Palmer, A.R., Bailey, D.B., Behnke, W.D., Cardin, A.D., Yang, P.P., and Ellis, P.D. (1980) Biochemistry 19, 5063-5070). The data for the PSA and LcH derivatives were found to be very similar, indicating close homology of their metal ion binding sites. 113Cd resonances at 44.6 ppm and -129.4 ppm for 113Cd2+ X 113Cd2+ X LcH, and at 46.6 and -130.4 for the corresponding PSA derivative, are chemical shifts very similar to those observed for 113Cd2+ X 113Cd2+ X ConA. Assignment of the resonances to the transition metal (S1) and calcium (S2) sites were unambiguous since the Ca2+ X 113Cd2+ and 113Cd2+ X Zn2+ derivatives of both lectins showed single resonances characteristic of the S1 and S2 sites, respectively. The results indicate that, unlike ConA, 113Cd2+ binds tightly to PSA and LcH. Binding of monosaccharide to both lectins induce small (2 ppm) upfield shifts in their S2 113Cd resonances, in contrast to the larger shift (8 ppm) observed in ConA. The 113Cd2+ X Mn2+ complexes of PSA and LcH fail to show a 113Cd resonance characteristic of these derivatives, which provides evidence for the close proximity of the metal ions in the two proteins. The present findings indicate that the coordinating ligand atoms to the metal ions at the S1 and S2 sites in LcH, PSA, and ConA are the same.     

Agglutination and fusion of globoside GL-4 containing phospholipid vesicles mediated by lectins and calcium ions

We have investigated the interaction of five N-acetylgalactosamine (GalNAc) specific lectins with the glycosphingolipid globoside GL-4, inserted into phospholipid vesicles composed of phosphatidyl-ethanolamine and phosphatidic acid, with respect to their ability to induce vesicle agglutination, fusion, and destabilization. The following lectins were used: soybean agglutinin (SBA); Sophora japonica agglutinin (SJA); Helix pomatia agglutinin (HPA); Ricinus communis agglutinin II (RCAII); and Codium fragile agglutinin (CFA). SBA and SJA caused rapid vesicle agglutination while HPA, CFA, and RCAII were ineffective. However, in the presence of RCAII, but not HPA and CFA, the addition of Ca2+ caused vesicle agglutination which was specifically inhibited by the haptenic sugar GalNAc, while ethylenediaminetetraacetic acid (EDTA) dissociated the vesicle complex. RCAII/Ca2+-induced vesicle agglutination was accomplished by binding of Ca2+ to RCAII after the lectin/receptor interaction. The rate of SBA-induced vesicle agglutination was increased in the presence of Ca2+, independent of the order of Ca2+ addition, and was not reversed by EDTA, indicating that the mechanism by which Ca2+ stimulated agglutination in this case was different from that observed in the presence of RCAII. In contrast to RCAII/Ca2+, SBA/Ca2+ induced of the vesicles, which occurred only when Ca2+ was added after lectin addition. Close approach of adjacent bilayers was accomplished by nonspecific interactions of SBA with the bilayer after lectin binding to the receptor as revealed by a limited extent of SBA-induced fusion and an enhanced membrane permeability upon lectin binding. The phenomena observed can be explained in terms of a Ca2+-modulated reorientation of the carbohydrate head group, causing it to adopt a more perpendicular orientation with respect to the plane of the bilayer.(ABSTRACT TRUNCATED AT 250 WORDS)     

The cell recognition model in chlorolichens involving a fungal lectin binding to an algal ligand can be extended to cyanolichens

Leptogium corniculatum, a cyanolichen containing Nostoc as photobiont, produces and secretes arginase to culture medium containing arginine. This secreted arginase was pre‐purified by affinity chromatography on beads of activated agarose to which a polygalactosylated urease, purified from Evernia prunastri, was attached. Arginase was eluted from the beads with 50 mm α‐d ‐galactose. The eluted arginase binds preferentially to the cell surface of Nostoc isolated from this lichen thallus, although it is also able to bind, to some extent, to the cell surface of the chlorobiont isolated from E. prunastri. Previous studies in chlorolichens have shown that a fungal lectin that develops subsidiary arginase activity can be a factor in recognition of compatible algal cells through binding to a polygalactosylated urease, which acts as a lectin ligand in the algal cell wall. Our experiments demonstrate that this model can now be extended to cyanolichens.     

Characterization of surface sugars on algal cells with fluorescein isothiocyanate-conjugated lectins

Summary. We used qualitative and quantitative fluorescence microscopy of the fluorescein isothiocyanate-conjugated lectins Concanavalin A, phytohaemagglutinin-erythroagglutinin, pokeweed mitogen, and peanut agglutinin to examine sugar composition on the cell surface and cell-associated mucilage (where present) in a number of cultured and environmental algae. Lectin-binding activity was markedly different between laboratory-cultured and environmental samples of the same species. Sugar composition of the cyanobacterium Anabaena cylindrica varied with growth cycle, although no clear pattern of change was observed. Akinetes typically showed lectin-binding activity higher than that of the vegetative cells or heterocysts throughout the growth cycle. Algae with mucilage showed greater lectin binding, indicating that mucilage contained more surface sugars accessible to the lectin probe compared with the cell wall surface. A low level of galactose and N-acetyl galactosamine (detected by peanut agglutinin) was associated with the surface mucilage of most algal species. Relatively high amounts of mannose, glucose, and N-acetyl glucosamine (detected by Concanavalin A, phytohaemagglutinin, and pokeweed mitogen) were also present. Lectin binding was shown to be a highly specific and sensitive approach to the examination of cell surface chemistry of both cultured and environmental algae and to the study of biodiversity in phytoplankton. Correspondence: School of Biological Sciences, University of Manchester, 3.614 Stopford Building, Oxford Road, Manchester M13 9PT, U.K.     

Contribution of lectin sugar-binding peptides structure determines specificity of rhizobium-legume symbiosis in Galega orientalis and G. officinalis

A significant heterogeneity between bacteria Rhizobium galegae bv. officinalis and R. galegae bv. orientalis forming the nitrogen-fixing symbiosis with Galega officinalis and G. orientalis, respectively, and not forming any single cross-inoculation group, was found by means of RAPD and RFEL methods. The high level of sequence similiraty between lectins of these plants indicates at their close relationship. However the sequences of lectin sugar binding peptides (SBP) of G. orientalis (TYCNPGWDPRDR) and G. officinalis (TFYNEEWDLVIKDEH) were highly diverged. Amino acids of SBP which are involved in linkage of Ca2+ and Mn2+ ions responsible for stabilization of spatial structure of carbohydrate-binding "pocket", keep their position in peptide. It suggests that lectins participate in Rhizobium-legume symbiosis and that carbohydrate-binding site plays a key role in this process.     

Heparin binding lectin of human placenta as a tool for histochemical ligand localization and isolation

Biotinylated heparin has been used to detect the presence of specific binding sites in sections of human placenta, which has prompted demonstration of expression of lectin activity for this proteoglycan. Purification of this lectin from full-term placenta facilitates the synthesis of its biotinylated derivative, using biotin-amidocaproyl hydrazide, without affecting its activity. It also enables immunization to obtain antibodies. The labeled lectin is shown to bind specifically to nuclear and cytoplasmic locations in various cell types of human placenta, nuclear expression of lectin binding sites being more pronounced at the full-term stage than after 8 weeks of development. The structurally related histone H2B exhibits obvious differences in its binding pattern. The presence of ligands accessible to the lectin whose binding activity can be inhibited by addition of an excess of heparin correlates in most instances with the level of lectin expression detected immunohistochemically. Biochemical information on the nature of the glycohistochemically inferred lectin-specific ligand(s) is obtained by affinity chromatography on resin-immobilized lectin. It leads to isolation of a proteoglycan with similar electrophoretic mobility in agarose-polyacrylamide gel electrophoresis relative to the independently purified heparan sulfate-containing fibronectin binding proteoglycan from human placenta. Both fractions inhibit binding of heparin to the lectin and contain immunologically detected co-purified lectin, emphasizing their ligand properties. Application of labeled tissue lectins in conjunction with lectin-specific antibodies is proposed to obtain valuable insights into the expression of the receptor as well as the ligand part of protein-carbohydrate recognition.