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.     

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.     

The role of amino acids and sugars in supporting of osmotic homeostasis in maize seedlings under salinization conditions and treatment with synthetic growth regulators

Stress state in plants caused by salinization conditions is characterized by the disturbance of ionic and osmotic homeostasis. The maintenance of the latter is reached by accumulation of osmolytes including free amino acids and soluble sugars in cells. The free amino acid level in the 8-day-old control seedling leaves was higher, than in the roots, whereas the contrary picture was observed in 17-day-old plant tissues. At the same time 8-day-old seedling roots contained more total sugars, than leaves, although the reduced sugar content was nearly a half of the total sugar content. A decrease of both total and reduced sugar levels was observed in 17-day-old seedling tissues. One-day exposure of 7-day-old seedlings to 0.1 M NaCl increased the free amino acid content especially in roots, than in leaves, and the total sugar content in maize leaves, whereas in roots this level remained without changes. The prolongation of salt exposure to 10 days leads to osmolyte content decrease. The seed treatment with Methyure and Ivine intensified accumulation of free amino acids and soluble sugars in the root and leaf tissues under salinization conditions.     

Isolation and characterization of a lectin from peanut roots.

A glucose-specific lectin has been purified to apparent homogeneity from 7-day-old peanut (Arachis hypogaea) roots by affinity chromatography on a Sephadex G-50. The lectin has a 66 kDa native molecular mass and a 33 kDa subunit molecular mass as revealed by native and denaturing sodium dodecyl sulphate-polyacrylamide gel electrophoresis, respectively. The purified lectin, gives a single precipitin line with the antiserum produced against 7-day-old root extract and shows 5 bands in the pH range of 4.4-5.4 in the isoelectric focusing gel. The glucose-specific lectin activity in the peanut roots appears from the fourth day onwards. Lipopolysaccharides isolated from the host specific Rhizobium strain are a 68-fold more potent inhibitor of the lectin as compared to glucose.     

Primary structure of the Dolichos biflorus seed lectin

The Dolichos biflorus seed lectin is a tetramer composed of equal amounts of two subunit types. The subunit types are structurally very similar, yet only the larger subunit exhibits the ability to bind carbohydrate. A cDNA clone representing the entire coding region of the D. biflorus lectin mRNA has been sequenced. This cDNA represents 1075 nucleotides of seed lectin mRNA encoding a polypeptide of Mr = 29,674. Analysis of the deduced sequence indicates that the NH2 termini and COOH termini of both lectin subunits are present within the mRNA coding region. This information supports previous data indicating that both subunits of the lectin are encoded by a single mRNA and that the difference between the subunit types apparently arises by the proteolytic removal of a 10-amino acid sequence from the COOH terminus of the larger subunit. Comparison of the D. biflorus seed lectin sequence to the sequence of other leguminous seed lectins indicates regions of extensive homology. The residues of concanavalin A involved in metal binding are highly conserved in the D. biflorus lectin, but those involved in saccharide binding show a much lower degree of conservation. Prediction of the secondary conformation of the D. biflorus polypeptide suggests that structures involved in the formation of quaternary structure in concanavalin A are also conserved.     

Isolation and characterization of a cDNA clone encoding the lima bean lectin

The complete amino acid sequence of the lima bean (Phaseolus lunatus) lectin was deduced from the nucleotide sequence of a cDNA clone. The lectin appears to be synthesized as a prepeptide consisting of a signal sequence of 21 residues and a mature protein of 241 amino acids. Comparison of the lima bean lectin sequence to the sequences of other leguminous seed lectins indicates regions of extensive homology. Northern blot analysis showed absence of lectin mRNA in the leaves, roots, or stems of 16-day-old lima bean plants.     

Lectin-gene expression in pea (Pisum sativum L.) roots

The expression of a lectin gene in pea (Pisum sativum L.) roots has been investigated using the copy DNA of a pea seed lectin as a probe. An mRNA which has the same size as the seed mRNA but which is about 4000 times less abundant has been detected in 21-d-old roots. The probe detected lectin expression as early as 4 d after sowing, with the highest level being reached at 10 d, i.e. just before nodulation. In later stages (16-d- and 21-d-old roots), expression was substantially decreased. The correlation between infection by Rhizobium leguminosarum and lectin expression in pea roots has been investigated by comparing root lectin mRNA levels in inoculated plants and in plants grown under conditions preventing nodulation. Neither growth in a nitrate concentration which inhibited nodulation nor growth in the absence of Rhizobium appreciably affected lectin expression in roots.Abbreviation cDNA copy DNA - poly(A)⁺RNA polyadenylated RNA     

Isolation and properties of a lectin from sainfoin (Onobrychis viciifolia, Scop.)

A glycoprotein capable of binding simple carbohydrates and causing hemagglutination has been isolated from seeds of the legume plant sainfoin (Onobrychis viciifolia, Scop. var Eski). The phytolectin was prepared by affinity chromatography of pH 7.0 sodium phosphate extracts on columns of Sepharose-4B containing covalently attached D-mannose. Molecular weight determinations showed the lectin to be a dimer consisting of 26 000 dalton, non-covalently associated monomers. Amino acid analyses indicated high amounts of aspartate, glutamate, threonine and serine which accounted for 41% of all amino acids. One residue of cysteine was present and methionine was totally absent. The lectin contained 2.6% (w/w) neutral carbohydrate and two residues of N-acetylglucosamine/monomer. Carbohydrate-binding specificity was directed toward D-mannose and D-glucose and their alpha-glycosidic derivatives. The purified protein agglutinated cat erythrocytes at 5 micrograms/ml. Antiserum to seed lectin showed a single common immunoprecipitation line in Ouchterlony double diffusion against both the seed and root antigen. Lectin isolated from sainfoin seedling roots showed molecular weight, amino acid and carbohydrate values similar to that of the seed lectin.     

Development and trifoliin A-binding ability of the capsule of Rhizobium trifolii.

The age-dependent lectin-binding ability of Rhizobium trifolii 0403 capsular polysaccharide (CPS) was examined by following the development of the capsule and its ability to interact with the white clover lectin trifoliin A. Bacteria grown on agar plates for 3, 5, 7, 14, and 21 days were examined by electron microscopy and immunofluorescence microscopy with antibodies prepared against either R. trifolii 0403 CPS or trifoliin A after pretreatment with the lectin. The capsule began to develop at one pole by day 3 and completely surrounded the cells in cultures incubated for 5 days or longer. The capsular polysaccharide on cells cultured for 3 and 5 days was completely reactive with trifoliin A, became noticeably less reactive by day 7, and was only reactive with the lectin at one pole of a few cells after that time. The quantity and location of lectin receptors on bacteria of different ages directly correlated with their attachment in short-term clover root hair-binding studies. Cells from 3- or 21-day-old cultures attached almost exclusively in a polar fashion, whereas cells grown for 5 days attached to root hairs randomly and in the highest numbers. CPS isolated from a 5-day-old culture had higher lectin-binding ability than CPS from 3- and 7-day-old cultures, whereas the CPS from a 14-day-old culture had the lowest. Chemical analyses of the isolated CPS showed changes in the levels of uronic acids (as glucuronic acid), pyruvate, and O-acetyl substitutions with culture age, but the neutral sugar composition remained relatively constant. These results provide evidence that the age-dependent distribution of lectin receptors dictates the level and orientation of attachments of R. trifolii 0403 to clover root hairs.     

Purification of Cajanus cajan root lectin and its interaction with rhizobial lipopolysaccharide as studied by different spectroscopic techniques.

A lectin present in roots of Cajanus cajan seedlings was isolated and purified by affinity chromatography. Sugar specificity assayed by hemagglutination-inhibition activity indicated that lectin belongs to glucose/mannose-specific group. The root lectin was found to be mannose-specific from the second day onwards as it was reconfirmed by specific elution of different days' sample from mannose agarose matrix. The maximum interaction of lectin with goat IgM was obtained in 10-day-old sample, indicating the highest crude lectin content. Lectin (total amount of eluted protein) from different days soil sample showed a maximum amount in 10-day-old sample. For further studies, the lectin has been isolated from the roots of 10-day C. cajan seedlings and purified on mannose-CL agarose column by affinity chromatography. Lectin was found to be a dimer of 18.5-kDa subunit as revealed by SDS-PAGE. Tryptophan quenching fluorescence was studied for C. cajan root lectin. Secondary structure of C. cajan root lectin as studied by circular dichroism was found to be a typical beta-pleated sheet structure. The interaction of purified root lectin with C. cajan-specific rhizobial lipopolysaccharide and its inhibition by specific and nonspecific sugars was demonstrated by fluorescence and circular dichroism. Results discussed in this paper were studied for the first time by different spectroscopic methods, suggesting that C. cajan root lectin-lipopolysaccharide interaction is specific.     

Localization of peanut (Arachis hypogaea) root lectin (PRA II) on root surface and its biological significance

The glucose-specific peanut root lectin, PRA II, is localized on the surface of 7-day-old peanut seedling root and in root cortical parenchymatous cells. The lectin is eluted from intact roots upon washing with buffer containing glucose. Rabbit erythrocytes bind to the root surface and the cortical cells; the binding is inhibited by antibodies raised against PRA II, peanut-specificRhizobium cells and by glucose. Lipopolysaccharides isolated from host-specificRhizobium strain inhibit the haemagglutinating activity of PRA II and are precipitated by the lectin. Our results suggest that PRA II might be involved in recognition ofRhizobium by peanut roots.     

Isolation,characterization and molecular cloning of the mannose-binding lectins from leaves and roots of garlic (Allium sativum L.)

Two novel lectins were isolated from roots and leaves of garlic. Characterization of the purified proteins indicated that the leaf lectin ASAL is a dimer of two identical subunits of 12 kDa, which closely resembles the leaf lectins from onion, leek and shallot with respect to its molecular structure and agglutination activity. In contrast, the root lectin ASARI, which is a dimer of subunits of 15 kDa, strongly differs from the leaf lectin with respect to its agglutination activity. cDNA cloning of the leaf and root lectins revealed that the deduced amino acid sequences of ASAL and ASARI are virtually identical. Since both lectins have identical N-terminal sequences the larger Mr of the ASARI subunits implies that the root lectin has an extra sequence at its C-terminus. These results not only demonstrate that virtually identical precursor polypeptides are differently processed at their C-terminus in roots and leaves but also indicate that differential processing yields mature lectins with strongly different biological activities. Further screening of the cDNA library for garlic roots also yielded a cDNA clone encoding a protein composed of two tandemly arrayed lectin domains. Since the presumed two-domain root lectin has not been isolated yet, its possible relationship to the previously described two-domain bulb lectin could not be studied at the protein level.     

An anti-A1 lectin in the seeds of Amphicarpaea bracteata

An anti-A1 lectin has been isolated from the extract of Amphicarpaea bracteata seeds by affinity chromatography on Epoxy-activated Sepharose 6B coupled to N-acetyl-D-galactosamine. The yield of the purified lectin was 86 microgram/g of seeds. The purified lectin shows one main band on electrophoresis in sodium dodecyl sulfate-polyacrylamide. The amino acid and neutral sugar composition indicate that this lectin is an acidic glycoprotein with a neutral sugar content of approx. 2%. The composition of the lectin is different from that of the Dolichos biflorus lectin but the two lectins have some common characteristics. The most powerful inhibitors of the agglutination of A1 red blood cells by the A. bracteata lectin is N-acetyl-D-galactosamine. Much weaker inhibitors of the agglutination are alpha-lactose, D-fucose, and five other sugars.     

Localization of a Nod factor-binding protein in legume roots and factors influencing its distribution and expression

The roots of the legume Dolichos biflorus contain a lectin/nucleotide phosphohydrolase (Db-LNP) that binds to the Nod factor signals produced by rhizobia that nodulate this plant. In this study we show that Db-LNP is differentially distributed along the surface of the root axis in a pattern that correlates with the zone of nodulation of the root. Db-LNP is present on the surface of young and emerging root hairs and redistributes to the tips of the root hairs in response to treatment of the roots with a rhizobial symbiont or with a carbohydrate ligand. This redistribution does not occur in response to a non-symbiotic rhizobial strain or a root pathogen. Db-LNP is also present in the root pericycle where its level decreases upon initiation of nodule formation. Maximum levels of Db-LNP are found in 2-d-old roots, and the expression of this root protein is increased when the plants are grown in the absence of NO(3)(-) and NH(4)(+). These results support the possibility that Db-LNP is involved in the initiation of the Rhizobium legume symbiosis.     

Isolation and properties of a lectin from the roots of Pisum sativum (Garden pea)

Abstract The roots of pea (Pisum sativum L. ev. Feltham First) seedlings contained haemagglutinating activity and a protein which reacted with antibodies directed against pea seed lectin. This protein was shown to be present on the surface of root hairs and in the root cortical cells by immunofluorescence. Lectin (haemagglutinin) was purified from pea seedling roots by both immunoaffinity chromatography and affinity chromatography on Sephadex G-100. The pea root lectin was similar to the seed lectin when analysed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis, and was antigenically identical: however, the isoelectric focussing band patterns of the proteins differed. The sugar specificity of the root lectin differed from that of the seed lectin, and the haemagglutinating activity of the root lectin was less than the seed lectin. These results are discussed with reference to the hypothesis that lectins mediate in the symbiotic association of legume and Rhizobium through their carbohydrate-binding properties.     

Distribution of glucose/mannose-specific isolectins in pea (Pisum sativum L.) seedlings

We report on the distribution and initial characterization of glucose/mannose-specific isolectins of 4- and 7-d-old pea (Pisum sativum L.) seedlings grown with or without nitrate supply. Particular attention was payed to root lectin, which probably functions as a determinant of host-plant specificity during the infection of pea roots by Rhizobium leguminosarum bv. viciae. A pair of seedling cotyledons yielded 545±49 g of affinity-purified lectin, approx. 25% more lectin than did dry seeds. Shoots and roots of 4-d-old seedlings contained 100-fold less lectin than cotyledons, whereas only traces of lectin could be found in shoots and roots from 7-d-old seedlings. Polypeptides with a subunit structure similar to the precursor of the pea seed lectin could be demonstrated in cotyledons, shoots and roots. Chromatofocusing and isoelectric focusing showed that seed and non-seed isolectin differ in composition. An isolectin with an isoelectric point at pH 7.2 appeared to be a typical pea seed isolectin, whereas an isolectin focusing at pH 6.1 was the major non-seed lectin. The latter isolectin was also found in root cell-wall extracts, detached root hairs and root-surface washings. All non-seed isolectins were cross-reactive with rabbit antiserum raised against the seed isolectin with an isolectric point at pH 6.1. A protein similar to this acidic glucose/mannose-specific seed isolectin possibly represents the major lectin to be encountered by Rhizobium leguminosarum bv. viciae in the pea rhizosphere and at the root surface. Growth of pea seedlings in a nitrate-rich medium neither affected the distribution of isolectins nor their hemagglutination activity; however, the yield of affinity-purified root lectin was significantly reduced whereas shoot lectin yield slightly increased. Agglutination-inhibition tests demonstrated an overall similar sugar-binding specificity for pea seed and non-seed lectin. However root lectin from seedlings grown with or without nitrate supplement, and shoot lectin from nitrate-supplied seedlings showed a slightly different spectrum of sugar binding. The absorption spectra obtained by circular dichroism of seed and root lectin in the presence of a hapten also differed. These data indicate that nutritional conditions may affect the sugar-binding activity of non-seed isolectin, and that despite their similarities, seed and non-seed isolectins have different properties that may reflect tissue-specialization.Abbreviations IEF isoelectric focusing - MW molecular weight - pI isoelectric point - Psl1, Psl2 and Psl3 pea isolectins - SDSPAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis The authors wish to thank Professors L. Kanarek and M. van Poucke for helpful discussions.     

Distribution of Lectins in the Jumbo Virginia and Spanish Varieties of the Peanut, Arachis hypogaea L

Peanut lectin was purified from seed meal of the Spanish and Jumbo Virginia varieties of peanut (Arachis hypogaea L.) by affinity chromatography on lactose coupled to Sepharose 4B. Polyacrylamide gel isoelectric focusing resolved the lectin preparation from Jumbo Virginia seeds into seven isolectins (pI 5.7, 5.9, 6.0, 6.2, 6.3, 6.5, and 6.7). Seed meal from the Spanish variety contained six isolectins which were indistinguishable from the pI 5.7, 5.9, 6.2, 6.3, 6.5, and 6.7 isolectins from Jumbo Virginia. Quantitative, lactose-specific hemagglutination was used to examine the lectins in tissues of both peanut varieties. In young (3- to 9-day-old) seedlings of each variety, more than 90% of the total amount of lectins detected in the plants was in the cotyledons. Most of the remainder was in hypocotyls, stems, and leaves; young roots contained no more than 4 micrograms of lectin per plant. Lectins were present in all nonroot tissues of 21- to 30-day-old seedlings, except 27-day-old Spanish hypocotyls. As cotyledons of each variety senesced, several of the more basic isolectins decreased to undetectable levels, but the acidic isolectins remained until at least 15 days after planting. Some of the seed isolectins and several apparently new lactose-binding lectins were also identified in affinity-purified extracts of 5-day-old roots and hypocotyls. Rabbit antibodies raised against the Jumbo Virginia seed isolectin preparation reacted with seed, cotyledon, and hypocotyl lectin preparations from both varieties. Analysis of seed lectin preparations from seven varieties of A. hypogaea and of a related species (A. villosulicarpa) indicated that isolectin composition in Arachis may be a characteristic of both the species and the subspecies (botanical type) to which the variety belongs.     

Detection and characterization of a lectin from non-seed tissue ofPhaseolus vulgaris

The distribution of lectin in various tissues ofPhaseolus vulgaris L. (cv. red) has been investigated using a sensitive solid-phase enzyme immunoassay. Roots, leaves and stems from 3- to 4-week-old plants were screened for their lectin content; low levels could be detected in all organs, with a relative distribution of 37% in roots, 20% in leaves and 43% in stems. The lectin from stemsleaves and roots was then isolated from 5- to 6-week-old plants using extraction, salt fractionation and affinity chromatography on immobilized porcine thyroglobulin. A comparative study of the seed lectin and the lectin isolated from 5- to 6-week-old plants was made using hemagglutination, inhibition of hemagglutination, immunodiffusion, polyacrylamide and agarose electrophoresis. The results showed that lectin isolated from the different tissues was immunologically identical and exhibited the same subunit structure and similar isolectin composition as the seed lectin.Abbreviations EDTA ethylenediaminetetraacetic acid - PHA phytohemagglutinin - SDS sodium dodecyl sulfate     

Host recognition in the Rhizobium-soybean symbiosis

Polar binding of Rhizobium japonicum to roots and root hairs of Glycine soja (L.) Sieb. and Zucc. is specifically inhibited by d-galactose and N-acetyl-d-galactosamine, haptens of Glycine max seed lectin. A protein, immunologically cross-reactive with the G. max seed lectin, is present in G. soja seed extracts. Peptide mapping of the purified G. max and G. soja lectins indicates that the two are similar in structure. Soybean lectin can be localized on the surface of both G. max and G. soja roots by indirect immunolatex techniques. These observations indicate that the Rhizobium-binding lectin, previously isolated from seeds, also is present on the root surface-the site of the initial steps in the infection. This lectin is capable of binding Rhizobium japonicum to the root.