Lectin-enzyme assay as a method of estimation of immunoglobulins' glycosylation

The mechanism of interaction of lectins with IgG molecules by the method of the lectin-enzyme assay has been described that allows to register a degree of human serum IgG molecules' glycosylation (mannosylation in case of lectin of Pisum sativum) in norm and at pathology. To detect an authentic difference in a glycosylation degree between control and pathological IgG, the wells of an ELISA plate were coated with an antibody in concentration of 1 microg/ml. Introducing alpha-D-mannose between the stages of incubation of immunoglobulin and lectin showed, that alpha-D-mannose inhibits the affinity of lectins for IgG. The preliminary incubation of lectin with IgG molecules stabilizes the activity of horseradish peroxidase, which labeled the lectins. Lectin-enzyme assay, in which Fab and Fc fragments of IgG were used, showed that lectin of Pisum sativum possesses a higher affinity for Fab regions. These findings and the glycosylation analysis of paraproteins and Bence-Jones proteins of multiple myeloma patients help to understand the details of interaction of immunoglobulins and lectins.     

Quantification of lectin receptors on B, T, T-gamma and T-mu lymphocytes. I. Concanavalin A, Pisum sativum, Lens culinaris and wheat-germ agglutinin

The immune system is formed of different lymphocyte subpopulations, each one having a defined role to defend the organism. Their plasma membranes present differences in the glycoproteinic or/and glycolipidic composition, as detected with labelled 125I-lectins. B lymphocytes have a greater number of receptors for the Pisum sativum, Lens culinaris and WGA lectins than T lymphocytes. On the other hand, T lymphocytes bind a greater number of Concanavalin A molecules than B lymphocytes. WGA lectin appeared to be more specific for T mu subpopulation, while Con A and Pisum sativum lectins were bound preferentially to T gamma lymphocytes while no significant differences were observed between both subpopulations for Lens culinaris lectin. From the affinity of each lectin to each lymphocyte population it could be deduced that the receptor structure, conformation and arrangement on the membrane was optimal in B lymphocytes for Con A and WGA binding, and T lymphocytes for Lens culinaris and Pisum sativum binding.     

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.     

Immunochemical analysis of lectin acceptors in the structure of the fertility alpha 2-microglobulin

Fertility alpha 2-microglobulin reacts with 3 out of 8 lectins, which possess affinity to monosaccharides (glucose and mannose) and acetylamino sugar. The affinity is most marked to concanavalin A and is considerably weaker to Pisum sativum and Vicia faba lectins, whereas the protein gives no reaction with other lectins.     

Synthesis of sorbent from cross-linked starch for affinity purification of glucose(mannose)-specific lectins]

Cross-linked starch gel for the affinity chromatography of D-glucose (D-mannose)-specific lectins is suggested. In order to optimize hydrodynamic properties of gel 30% starch has been hydrolysed by HCI at 70 degrees C during 60 min and then cross-linked by epichlorohydrin under alkaline conditions. Every 100 g of starch require 18 ml of epichlorohydrin and 36 ml of 8 N KOH. The gel obtained has been successfully used for the purification of lectins from Pisum sativum L., Lens culinaris L., Vicia sativa L., and Vicia faba L. seeds. These lectins, purified on starch gel do not differ from sephadex-purified samples.     

Magnetic sorting in plant tissue: immunoseparation of pea nuclei with an antibody against nucleoporin

Nuclei were magnetically separated from root extracts of Pisum sativum L. by means of a MiniMACS separation unit after indirect labelling with the antibody mAb414 (raised against rat liver nucleoporin p62) and a secondary anti-mouse antibody labelled with superparamagnetic MACS Microbeads.     

The binding of lectins to components of plasma membranes from porcine submaxillary lymph node lymphocytes

By sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis the plasma membranes from porcine lymphocytes contain at least 30--35 glycopolypeptides and one or more glycolipids to which one or more of 12 purified lectins bind. The specificities of binding generally followed the same pattern as those of the reaction of the lectin with intact pig lymphocytes. Some lectins (e.g., the isolectin pair, Agaricus bisporus lectins A and B and a group consisting of the Lens culinaris A and B isolectins and the closely related Pisum sativum lectins) bind to almost identical populations of plasma membrane components and compete with each other for all their binding sites. Others (e.g., Concanavalin A and the Lens culinaris-Pisum sativum group and a group consisting of phytohemagglutinin-L, Ricinus communis lectin-60 and Ricinus communis lectin-120 bind in a cross reactive manner to some common binding moieties but, in addition, to certain nonshared ones. Still others (e.g., soybean agglutinin, peanut agglutinin and wheat germ agglutinin) do not share any common binding moieties with the other lectins. The amount of lectin binding and the number of membrane components to which a lectin binds is directly related to the Ka of binding of the lectin to the intact lymphocyte. Those with high Ka (Cocanavalin A Lens culinaris lectins, Pisum sativum lectins, phytohemagglutinin-L), bind to 20-30 different components giving very complex binding patterns while those with lower Ka (Agaricus bisporus lectins, wheat germ agglutinin, peanut agglutinin, and soybean agglutinin) bind to 8--13 components with easily distinguishable patterns. Soybean agglutinin binds almost exclusively to a glycolipid fraction while for the others one or more glycopolypeptides served as the major lectin-binding molecule. The Ricinus lectins, two lymphocyte toxins, bind to essentially every plasma membrane component to which the mitogen phytohemagglutinin-L binds, in fact competing for most of those plasma membrane moieties which bind phytohemagglutinin-L.     

Role of capsule in serotypic differences and complement fixation by Lactococcus garvieae

Seventeen geographically distinct isolates of Lactococcus garvieae, isolated from diseased fish, were compared serologically using antiserum raised against the various isolates in rainbow trout. Sera raised against a capsule deficient isolate did not agglutinate capsulated isolates, regardless of origin. In contrast, all antisera raised against capsulated isolates cross reacted strongly with non-capsulated isolates. Antisera raised against capsulated Japanese isolates cross reacted with other capsulated Japanese isolates including isolates from geographically distinct prefectures within Japan (Ehime and Oita). However, antisera against these virulent capsulated isolates did not cross react with European capsulated isolates. Antisera raised against European capsulated isolates cross reacted with other European isolates, regardless of origin within Europe (UK, Italy, Spain), but did not cross-react with Japanese capsulated isolates. Agglutination assays performed with a range of fifteen lectins revealed differences in surface carbohydrate structure: capsule deficient isolates agglutinated with concanavalin A, Ricinis communis agglutinin, Pisum sativum agglutinin, Lens culinaris agglutinin, wheat germ agglutinin and succinylated wheat germ agglutinin. European capsulated isolates agglutinated with concanavalin A only. The Japanese capsulated isolates were not agglutinated by any of the lectins used in this study. Representative isolates from each group (Japanese capsulated and non-capsulated, European capsulated and non-capsulated) were investigated for their ability to fix complement. Non-capsulated isolates fixed complement regardless of origin, and antibody did not markedly enhance complement fixation. In contrast, the capsulated isolates were less efficient at fixing complement, but complement fixation was markedly increased by homologous antibody.     

Reactivity with legume lectins of three monoclonal antibodies made against the Lathyrus odoratus lectin

Three murine IgG1 monoclonal antibodies (MoAb) were produced against the glucose/mannose-specific two-chain mitogen from seeds of Lathyrus odoratus (sweet pea) belonging to the Vicieae tribe of the Leguminosae family. Their antigenic specificities were tested against subunits of two-chain and one-chain legume lectins separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and electrotransferred to nitrocellulose filters. Different binding to native and detergent-treated lectins in dot-blots indicated that two of the antibodies bound to conformational epitopes which by immunoblotting were shown to be expressed on the heavy subunits from all the five tested two-chain lectins and on the six one-chain lectins, including PHA (Phaseolus vulgaris) and Con A (Canavalia ensiformis). However, ELISA cross-inhibition studies showed that these two antibodies bound to different epitopes on the lectin molecules. The third MoAb reacted with a continuous epitope not revealed by classical taxonomy since only three of five heavy subunits of the two-chain lectins stained with the antibody. Comparison of the known amino-acid sequences of the chains indicates eight positions as possible binding sites for this antibody.     

Amine oxidase from Lathyrus cicera and Phaseolus vulgaris: purification and properties

Cu-Amine oxidases (amine oxygen oxidoreductase deaminating, copper containing E.C. 1.4.3.6.) are found in all forms of life (1). They catalyze the following general reaction: R-CH2-NH2 + O2 + H2O----R-CHO + NH3 + H2O2. Cu-amine oxidases (Cu-AOs) have been extracted from different leguminosae: Pisum sativum (2-3), Lathyrus sativus (4), Lens esculenta (5), Vicia faba (6), Cicer arietinum (7), Glycine max (8) but not from Phaseolus vulgaris. Palavan and Galston (9), in a study of polyamine biosynthesis during developmental stages of Phaseolus vulgaris, did not detect diamine or polyamine oxidase activity in Phaseolus. The present paper describes the purification of Phaseolus vulgaris seedlings amine oxidase (PhSAO) and also compares the properties of this enzyme to the Lathyrus cicera enzyme (LcSAO), obtained with the same method of purification.     

Lectin-associated proteins from the seeds of Leguminosae

The seeds of Pisum sativum (pea), Canavalia ensiformis, Vicia faba, Vicia sativa, and Ricinus communis were shown to contain proteins which are associated to the respective lectins (lectin binders). The lectin binders from Pisum sativum and Canavalia ensiformis were studied more closely. Both are single proteins not resembling the variety of membrane glycoproteins found in animals and plants which bind to lectins. The pea lectin binder is a tetrameric glycoprotein composed of identical subunits of the Mr 51 000. Its interaction with the lectin is abolished by acidic buffers or by glucose. The Concanavalin A binder, which does not contain sugar, is composed of one kind of subunit, Mr of 35 000. As in the case of the pea lectin binder, glucose and acid dissociate the lectin-lectin binder complex, but in contrast to the pea lectin binder low NaCl concentrations also cause this effect. During germination and growth, the Concanavalin A binder appears in the roots.     

The Rate of Morphogenesis of Embryos and Seeds in Four Species of Grain Legumes

Comparative embryo development has been studied histologicallyin Lupinus albus, Lupinus mutabilis, Vicia faba, Pisum sativumand Latkyrus latifolius. The detailed histology of the stagesof embryo formation up to the early differentiation of tissuesof the seed is reported. The rate of embryogenesis has beentimed through 15 stages of development from anthesis and comparativerates of tissue formation established between the species. Themain observation was the slow rate of morphogenesis of embryosand seeds in Lupinus albus in comparison with the very rapidrate observed in Pisum sativum. A long period at the globularembryo stage, when embryo morphogenesis was inactive contributedto the extended development time of embryos and seeds in Lupinusalbus. Slow differentiation of reproductive tissues in L. albusdetermines late maturity in seeds and pods. Lupinus albus, white lupin, L. mutabilis, tarwi, Vicia faba, faba bean, Pisum sativum, pea, Lathyrus latifolius, everlasting pea, embryo development     

The use of lectins to characterize and separate living canine spermatozoa: A preliminary study

This study was designed as a preliminary attempt to develop a methodology for relating the glucidic structure of the sperm membrane to sperm morphology. Differences in plasma membrane glycoconjugates between motile and nonmotile spermatozoa were studied by using 7 lectins. Fresh spermatozoa from 3 dogs were analyzed by fluorescein isothiocyanate (FITC) labeled lectins. The binding of lectins to the sperm membrane and the capability of the lectins to agglutinate spermatozoa were estimated semi-quantitatively by observation with either an epifluorescence or a phase contrast microscope, respectively. All the lectins tested bound to non motile spermatozoa, with Helix pomatia , Pisum sativum and Arachis hypogaea showing intense fluorescence, Triticum vulgare and Glycine maxima showing moderate fluorescence, and Phaseolus vulgaris and Phytolacca americana showing low fluorescence. However, Helix pomatia . and Triticum vulgare also bound to rapid and slow moving spermatozoa, and were the only 2 lectins that induced sperm agglutination. These results suggest that lectins could be a possible tool for characterizing and separating spermatozoa with different rates of motility.     

The lectin-binding protein from the pea (Pisum sativum); properties and interactions

The lectin-binding protein (lectin binder) from the garden pea (Pisum sativum) was studied. It is a glycoprotein composed of four subunits of about 50 000 Da. Its amino-acid composition and molecular mass differ from those of lectin and of storage proteins. The interaction between lectin and lectin binder is demonstrated and quantified by several different methods and is shown to be specifically sugar-dependent. A biological function of lectin binders and lectins is discussed.     

An Immunoglobulin M Monoclonal Antibody, Recognizing a Subset of Acetylcholinesterase Molecules from Electric Organs of Electrophorus and Torpedo, Belongs to the HNK-1 Anti-Carbohydrate Family

An immunoglobulin M (IgM) monoclonal antibody (mAb Elec-39), obtained against asymmetric acetylcholinesterase (AChE) from Electrophorus electric organs, also reacts with a fraction of globular AChE (amphiphilic G2 form) from Torpedo electric organs. This antibody does not react with asymmetric AChE from Torpedo electric organs or with the enzyme from other tissues of Electrophorus or Torpedo. The corresponding epitope is removed by endoglycosidase F, showing that it is a carbohydrate. The subsets of Torpedo G2 that react or do not react with Elec-39 (Elec-39+ and Elec-39-) differ in their electrophoretic mobility under nondenaturing conditions; the Elec-39+ component also binds the lectins from Pisum sativum and Lens culinaris. Whereas the Elec-39- component is present at the earliest developmental stages examined, an Elec-39+ component becomes distinguishable only around the 70-mm stage. Its proportion increases progressively, but later than the rapid accumulation of the total G2 form. In immunoblots, mAb Elec-39 recognizes a number of proteins other than AChE from various tissues of several species. The specificity of Elec-39 resembles that of a family of anti-carbohydrate antibodies that includes HNK-1, L2, NC-1, NSP-4, as well as IgMs that occur in human neuropathies. Although some human neuropathy IgMs that recognize the myelin-associated glycoprotein did not react with Elec-39+ AChE, mAbs HNK-1, NC-1, and NSP-4 showed the same selectivity as Elec-39 for Torpedo G2 AChE, but differed in the formation of immune complexes.     

Genome size variation in Pisum sativum.

Pisum sativum L. is one of the plant species where infraspecific genome size variation, up to 1.29-fold between cultivars, has been reported. The present investigation deals with a Feulgen cytophotometric analysis of this phenomenon in 25 wild accessions, landraces, and cultivars of widely different geographic origin. Differences between accessions were maximally 1.054-fold in single experiments but proved to be nonreproducible upon repeated measurements. Seedlings of the same accession often differed significantly, up to 1.056-fold, but values from root and shoot tips in one individual were not significantly correlated, indicating the absence of true genome size variation between plants. Upon calibration against Allium cepa a 1C value of 4.42 pg is estimated for Pisum sativum. Altogether the data suggest that, contrary to the divergence in the literature data and recent reports on DNA content variation, the pea has a stable genome size.     

Interaction with lectin of kappa opioid binding sites solubilized from human placenta

Kappa opioid binding sites from human placenta, prelabeled with 3H-etorphine and solubilized, were retained on wheat germ agglutinin (WGA) agarose and specifically eluted with N-acetylglucosamine. No significant retention was found with other immobilized lectins, including Concanavalin A (Con A), soybean seed lectin (SBA), Pisum sativum lectin (PsA), Lens culinaris Medik. lectin (LcA), and Lathyrus tingitanus lectin(LtA). About 23% of applied kappa sites were specifically eluted from WGA agarose, less than half of the proportion of rat brain opioid binding sites eluted from the same lectin (55%). Receptors from placental extracts were compared with those from other tissues enriched in either kappa or mu sites. The proportion of applied kappa sites from guinea pig cerebellum eluted specifically from WGA agarose was 36%, whereas elution of binding sites from rat thalamus and rabbit cerebellum (enriched in mu sites) was at a level of 55%. This difference in the level of retention on and elution from WGA may reflect differences in the sugar composition of the glycoproteins of the two types of receptors. Succinylation of WGA abolished its ability to retain opioid binding sites, consistent with involvement of sialic acid. However, currently available evidence suggests that differences in retention on WGA between kappa and mu sites may be due to differences in either sialic acid or N-acetylglucosamine content or both.     

Efficient intergeneric fusion of pea (Pisum sativum L.) and grass pea (Lathyrus sativus L.) protoplasts

Large numbers of viable protoplasts of pea (Pisum sativum) and grass pea (Lathyrus sativus) were efficiently and reproducibly obtained and, for the first time, fused. Different procedures for fusion were compared, based either on electrofusion (750, 1000, 1250 or 1500 V cm(-1)), or on the use of macro or micromethods with a polyethylene glycol (PEG 6000 or PEG 1540), or a glycine/high pH solution. Over 10% of viable heterokaryons were obtained, with PEG as the most efficient and reproducible agent for protoplast fusion (>20% of viable heterokaryons). Both the division of heterokaryons and the formation of small calluses were observed.     

Isolation of lectin and albumin from Pisum sativum var. macrocarpon ser. cv. sugar snap

A mannose- and glucose-binding lectin bearing considerable sequence similarity to other legume lectins was isolated using a simple procedure, from legumes of the sugar snap Pisum sativum var. macrocarpon. The lectin was unadsorbed on Affi-gel blue gel and Q-Sepharose in 10 mM Tris-HCl buffer (pH 7.2) and adsorbed on SP-Toyopearl in 50 mM NaOAc buffer (pH 5). An albumin could also be purified at the same time. It was unadsorbed on Affi-gel Blue gel, adsorbed on Q-Sepharose and unadsorbed on SP-Toyopearl under the aforementioned chromatographic conditions. The lectin was almost identical in N-terminal sequences of its alpha- and beta-subunit to lectin from P. sativum L. var. Feltham First except for the 19th N-terminal residue of the beta-subunit. The lectin was devoid of antifungal activity. Out of the 15 N-terminal amino acids examined in pea albumin, three were different between the two varieties of P. sativum.     

Fractionation of lymphocytes using affinity chromatography with 9 lectins

Lymphocyte subclasses from normal peripheral blood have been fractionated by affinity chromatography with lectins. Concanavalin A (Con A), Lens culinaris lectin (LC), Pisum sativum lectin (PS), Phaseolus vulgaris lectin (PHA), Dolichos biflours lectin (DB), Glicine max lectin (SBA), Ricinus communis lectin (RCA II), Tetragonolobus purpureus lectin (TP) and Triticum vulgaris lectin (WGA), were coupled to Sepharose 6MB, and lymphocytes labelled with 125I were eluted through the chromatographic columns. The binding of lymphocytes to WGA and SBA lectins was 32% and 13% respectively. The binding to the other lectins tested were found to be between 32% and 13%. When solutions of increasing concentrations of specific sugar were added to the columns a progressive elution of bound lymphocytes was observed. These results indicate the existence of a large range of lymphocyte subclasses, with different binding capacity to lectins, which was a function of the receptor number or/and receptor affinity to each lectin. Furthermore, these two parameters were found to vary in each functional population. Even though all the lymphocytes had lectin receptors, T lymphocytes showed higher affinity for Con A, PHA and TP lectins, while B lymphocytes appeared to be more specific for LC, PS, SBA, DB, RCAII and WGA lectins.