Clavaspirin, an antibacterial and haemolytic peptide from Styela clava.

We cloned the precursor of a novel peptide from a cDNA library prepared from pharyngeal tissues of the tunicate, Styela clava. Its sequence predicted a histidine-rich, amidated 23-residue peptide (FLRF(IG)SVIHGIGHLVHHIGVAL-NH2) that we named clavaspirin. A synthetic clavaspirin was prepared and it was found that it killed Gram-positive and Gram-negative bacteria, permeabilized the outer and inner membranes of Escherichia coli, lysed phosphatidylglycerol (POPG) liposomes, and was potently haemolytic towards human and bovine erythrocytes. Each of these activities was performed more effectively at an acidic pH. Circular dichroism measurements of synthetic clavaspirin revealed a largely alpha-helical structure and polarized and residue-specific FTIR spectrometry showed that its association with phospholipid membranes was influenced by pH. Peptides such as clavaspirin may equip tunicate haemocytes to mediate cytotoxicity and participate in antimicrobial defence.     

Investigation on the occurrence of soluble lectins in mammalian nervous tissue extracts

Five brain or retina crude extracts obtained from adult mammalians and nine fractions of brain extracts prepared by chromatography were screened for their lectin activities. All crude extracts and several fractions contained agglutinins reacting with neuraminidase-treated rabbit red blood cells. Hemagglutination activity varied widely with the method of preparation of the extracts. Hemagglutination inhibition tests were carried out to look for possible differences in the specificities of the agglutinins. All were found to be D-galactosyl specific. Each crude extract was found to contain a second lectin activity, which was detected using ethanol-treated rabbit erythrocytes known to react with heparin-binding lectins. Hemagglutination and inhibition studies showed that they completely differ from the galactoside-binding lectins detected previously. The possible functions of these lectins are discussed.     

Isolation of lectins of different specificities on a single affinity adsorbent.

Affinity chromatography on Sepharose-fetuin columns was used in a single step procedure to isolate the lectins concanavalin A, Favin, phytohemagglutinin, wheat germ agglutinin, and Limulus hemagglutinin. New lectins with unknown binding specificities were also purified by the same procedure from extracts of small California white beans, Idaho red beans, and white pea beans. The purified lectins exhibited different cell surface mapping properties on erythrocytes, lymphocytes, and sperm cells. It was particularly striking that neither 131I-labeled concanavalin nor 125I-labeled wheat germ agglutinin had any effect on the binding of the other to mouse spleen cells. In accord with this observation, gel electrophoretic analysis of radiolabeled lymphocyte receptors for these two lecithins yielded different patterns. These results indicate that highly purified lectins prepared by affinity chromatography on the same adsorbent can possess strikingly different binding specificities for cell surface receptors.     

Sialic acid-binding lectins in the “whip scorpion” (Mastigoproctus giganteus) serum

Sialic acid-specific lectins have been detected in the serum of the “whip scorpion,” Mastigoproctus giganteus. When compared to Limulus lectins, Mastigoproctus agglutination profiles for a panel of untreated and enzyme-treated vertebrate erythrocytes were almost identical except for the agglutination of nonhuman primate erythrocytes. However, both chelicerate species exhibited heterogeneous serum lectins which showed some differences in their serological reactivity. At least three distinct specific fractions could be demonstrated in Mastigoproctus serum by crossed absorption and hemagglutination-inhibition experiments. These fractions are specific for sialic acids and/or sialoconjugates but also bind substances such as N-acetylglutamic acid, N-acetylmuramic acid, chitobiose, and chitotriose. These adjunct specificities are important clues in the interpretation of the possible biological role of chelicerate lectins.     

Characterization of the acidic lectins from winged bean seed (Psophocarpus tetragonolobus(L.)DC)

The seeds of winged bean, Psophocarpus tetragonolobus(L.)DC, contain two distinct groups of lectins characterized by different erythrocyte hemagglutinating specificities and isoelectric points. Three acidic lectins (I, II, and III) (pI approximately 5.5) were purified to apparent homogeneity by chromatography on Ultrogel AcA44 and SP-Sephadex C-25. These lectins are glycoproteins with relative molecular mass of 54,000. The total carbohydrate content of the acidic lectins was 7% and was comprised of mannose, N-acetylglucosamine, fucose, and xylose in amounts corresponding to 9.2, 4.8, 1.6, and 7.0 mol/54,000 g, respectively. Electrophoresis in dodecyl sulfate, in the presence and absence of 2-mercaptoethanol, gave a single subunit of apparent relative molecular mass 30-32,000, somewhat higher than expected from the native relative molecular mass. On isoelectric focusing in 8 M urea the subunits of the acidic lectins did not show any significant charge heterogeneity as found for the winged bean basic lectins. The acidic lectins have very similar amino acid compositions. They contain essentially no half-cystine, 1-2 methionine residues, and are rich in acidic and hydroxy amino acids. The amino-terminal sequences of lectins II and III were identical while the amino-terminal sequence of lectin I contained five differences in the first 25 residues; the acidic lectins showed extensive sequence homology with the winged bean basic lectins, the other one-chain subunit lectins and the beta subunit of the two-chain subunit legume lectins. The acidic lectins agglutinated trypsinized human (type A, B, AB, and O) erythrocytes but not trypsinized rabbit erythrocytes. They were inhibited by various D-galactose derivatives and D-galactose-containing disaccharides and trisaccharides. N-Acetylgalactosamine was the best inhibitor, and the specificity appears to be directed to beta-D-galactosides. However, compared with winged bean basic lectins and soybean lectin, the winged bean acidic lectins show a low affinity for the inhibitory sugars.     

Comparative studies of the haemagglutination of adult and umbilical cord erythrocytes by animal lectins

1. The sugar specificities of four lactose-binding lectins were studied through the agglutination of adult and/or umbilical cord human erythrocytes (AHRBC and/or CHRBC). 2. Rana catesbeiana egg lectin specifically agglutinated both intact blood group A-AHRBC and intact blood group A-CHRBC. 3. Rana catesbeiana liver lectin agglutinated intact A-AHRBC much more strongly than intact A-CHRBC. 4. Xenopus laevis skin lectin nonspecifically agglutinated AHRBC and CHRBC. 5. Plecoglossus altivelis egg lectin specifically agglutinated intact B-AHRBC, but weakly agglutinated intact B-CHRBC. 6. Comparative studies of lectin-induced AHRBC or CHRBC agglutination clarified the sugar-binding specificities of these lectins.     

A versatile immunoadsorbent capable of binding lectins of various specificities and its use for the separation of cell populations

A procedure for cell fractionation using lectin-affinity chromatography is described. It consists of a single affinity adsorbent, hog gastric mucin blood group A+H substance covalently coupled to Sephadex or Sepharose, to which lectins of various specificities can bind. The complex formed, lectin in equilibrium hog A+H substance-Sephadex, then serves as an affinity probe for isolating and fractionating cells. The lectins from Ulex europaeus, Lotus tetragonolobus, Helix pomatia, Dolichos biflorus, and Phaseolus lunatus were used with the same blood group substance as adsorbent. The affinity columns retained erythrocytes with blood group specificity for the adsorbed lectin and thus fractionate cells in mixtures. Cells as well as lectins are eluted by specific sugar inhibitors. Mixtures of two kinds of cells can be separated when the proportion of the adsorbed cells is not too low.     

A novel C-type lectin regulating cell growth, cell adhesion and cell differentiation of the multipotent epithelium in budding tunicates

We have isolated two Ca(2+)-dependent, galactose-binding polypeptides from the budding tunicate, Polyandrocarpa misakiensis. Based on their partial amino acid sequences, full-length cDNAs were cloned. One of them was identical with a tunicate C-type lectin (TC14-2) reported previously. The other was a novel C-type lectin, referred to as TC14-3. In living animals, they appeared to be coupled. This complex of lectins, when applied in vitro to tunicate multipotent cells of epithelial origin, blocked cell proliferation and induced cell aggregation. The aggregates expressed a homolog of the integrin alpha-chain and other differentiation markers specific for epithelial cells. Recombinant TC14-3 could reproduce all the activities of native lectins by itself, which was accelerated by recombinant TC14-2. The inhibitory activity of TC14-3 on cell growth was completely abolished by the addition of 50 microM D-galactose. Anti-TC14-3 monoclonal antibody showed that the antigen was expressed constitutively by the multipotent epithelial and mesenchymal cells. These results provide evidence that in P. misakiensis a C-type lectin plays a novel, cytostatic role in regulating cell growth, cell adhesion and cell differentiation during asexual reproduction.     

Carbohydrate and glycoprotein specificity of two endogenous cerebellar lectins

Two endogenous cerebellar mannose binding lectins have been isolated in an active form by immunoaffinity chromatography employing their respective immobilized antibodies. One of them, termed cerebellar soluble lectin (CSL), was extracted in the absence of detergents, whereas the other, called Receptor 1 (R1), was soluble only in the presence of detergents. Tests of inhibition of agglutination of erythrocytes were performed with mono-, oligo and polysaccharides, as well as glycoconjugates of known structures. On the basis of agglutinating activities these 2 lectins are different from the previously reported lectins in brain, since they were not inhibited by galactosides and lactosides and were only marginally inhibited by glycosaminoglycans. CSL and R1 were better inhibited by mannose-rich glycopeptides as compared to the corresponding oligosaccharides. The different inhibition patterns obtained with glycans of known structures indicated that these lectins are very discriminative. Although CSL and R1 have similar specificities, they differed in their binding properties towards glycopeptides of ovalbumin. Both lectins showed considerable affinity for endogenous cerebellar glycopeptides, also rich in mannose. These glycopeptides belong to a few endogenous Con A-binding cerebellar glycoprotein subunits and are not present on other endogenous Con A-binding glycoproteins. In the forebrain, where CSL and R1 were also present, at least some of the glycoproteins interacting with the lectins were different from that observed in the cerebellum. Our data overall suggest that specific cell recognition in the nervous system could be invoked via the interactions between widely distributed lectins and cell-specific glycoproteins.     

A C-type lectin from the tunicate, Styela plicata, that modulates cellular activity

Previous studies have identified proteins from tunicates (invertebrate members of the Phylum Chordata) that have physicochemical and functional properties similar to those of the inflammatory cytokine, interleukin 1 (IL-1). Here we characterize one of those proteins from the tunicate, Styela plicata, that can stimulate tunicate and mammalian cell proliferation, activate phagocytosis, increase interleukin 2 (IL-2) secretion by mammalian peripheral blood mononuclear cells and enhance IL-2 receptor (IL-2R) expression by mammalian EL-4.IL-2 cells. Partial amino acid sequence data showed that the S. plicata protein resembles three C-type lectins (TC14, TC14-1 and TC14-2) from a closely related tunicate species, Polyandrocarpa misakiensis. Its similarity to carbohydrate recognition domains (CRDs) from P. misakiensis lectins suggests that the S. plicata protein modulates the activities of mammalian immunocompetent cells by interacting with carbohydrate moieties of glycosylated cell surface receptors.     

Interactions of plant lectins with glycolipids in liposomes

A panel of five plant lectins with different binding specificities was used to determine if plant lectins could bind specifically to membrane-associated glycolipids. $\text{Ricinis communis}$ and wheat germ agglutinins both bound specifically to mixed brain gangliosides and globoside I from human erythrocytes. Wheat germ agglutinin also bound to ganglioside G_M1 and human erythrocyte ceramide trihexoside, but not to ceramide dihexoside, mono-, or digalactosyl diglycerides. Concanavalin A bound to liposomes with or without glycolipid substituents, and this binding was partially inhibited by α-methyl mannoside. This study indicates that lectins can specifically recognize and bind to certain glycolipids in membranes.     

Galactosyl-binding lectins from the tunicate Didemnum candidum. Carbohydrate specificity and characterization of the combining site

The plasma of the ascidian Didemnum candidum possesses lectin activity directed toward galactosyl moieties. We report the characterization of the affinity chromatography-purified galactosyl-binding lectins from the plasma of this protochordate species in terms of their hemagglutination patterns, temperature stability, saccharide specificities, divalent cation requirements, and the comparison of the properties of their combining sites to those of other characterized lectins. The major galactosyl-specific lectin, termed DCL-I, has an apparent mass of 14,500 daltons and a minor lectin (DCL-II) has an apparent subunit mass of 15,500 daltons. The two molecules differed somewhat in their hemagglutination profiles with untreated and enzyme-treated erythrocytes: a 10-fold increase in DCL-II concentration is required to obtain agglutination titers comparable to those of DCL-I. Although both DCL-I and DCL-II will agglutinate neuraminidase-treated erythrocytes from all vertebrate species tested and most Pronase-treated erythrocytes, DCL-I will agglutinate some untreated erythrocytes which are not agglutinated by DCL-II. Both lectins required divalent cations, were inactivated by temperatures above 70 degrees C, and both exhibited optimal agglutinating activity over a wide range of pH (from 5 to 11). The DCL-I molecule was characterized for its saccharide specificity by binding and inhibition assays using characterized sugars and glycoproteins. Galactose and oligosaccharides bearing nonreducing terminal galactose were the best inhibitors. The inhibition analysis indicated that the DCL-I combining site is small, interacts only with hydroxyls on carbons 2, 3, and 4 of galactose, and exhibits moderate steric hindrance for voluminous groups on carbon 6 and the alpha-anomeric linkage. The data suggest that the combining site would be smaller than the peanut lectin combining site for galactose since DCL-I does not interact with the subterminal monosaccharide hydroxyls for C4 and C6 as does peanut agglutinin. To our knowledge, this is the first isolation and detailed characterization of a lectin from a protochordate species.     

Protochordate immunity. I. Primary immune response of the tunicate Ciona intestinalis to vertebrate erythrocytes

Serum from the tunicate Ciona intestinalis contains a low titer, natural agglutinin for a variety of vertebrate erythrocytes. Primary injections of 8.5 × 10³ human erythrocytes or 7.0 × 10² duck erythrocytes into the tunic tissues or perivisceral cavity were agglutinated and then cleared by phagocytosis within 24 hr. Higher concentrations of human or duck erythrocytes injected into the tunic tissues were encapsulated. Concomitant with clearance or encapsulation, serum agglutinin levels decreased and then returned to normal within 24 hr. Tunicates are classified taxonomically with the vertebrates in the phylum Chordata. Since phagocytosis and encapsulation reactions are typical of most invertebrates, the results of this study suggest that tunicate internal defense mechanisms are more closely allied to invertebrates than to vertebrates.     

Humoral lectins in the scorpion Vaejovis confuscius: a serological characterization

Serum of the scorpion Vaejovis confuscius (Vaejovidae) exhibited agglutinating activity when tested with a variety of untreated and enzyme-treated vertebrate erythrocytes. Bird and reptile erythrocytes were no longer agglutinated by V. confuscius as well as Centruroides sculpturatus (Buthidae) and Limulus polyphemus sera after treatment with neuraminidase. Crossed absorption experiments revealed the presence of multiple lectins in V. confuscius serum and this was confirmed by hemagglutination-inhibition experiments. Sialic acids, their derivatives, and sialoconjugates were the best inhibitors for both V. confuscius and C. sculpturatus lectins although other N-acylamino compounds (N-acetyl-d-galactosamine, N-acetyl-d-glucosamine, and N-acetylmuramic acid) also inhibited. C. sculpturatus exhibited an additional lectin fraction specific for galactans. These specificities for substances widely distributed in procaryotic cells might give clues about the biological role of chelicerate lectins.     

Lectins in the hemolymph of Japanese horseshoe crab, Tachypleus tridentatus

The hemolymph of the Japanese horsehoe crab, Tachypleus tridentatus contains lectins which agglutinate mammalian erythrocytes. Affinity chromatographic purification of the lectins using bovine submaxillary gland mucin-conjugated Sepharose resulted in the separation of the lectins into four fractions; one major and three minor lectins. Protein subunits revealed by polyacrylamide gel electrophoresis and the immunoprecipitin line of these lectins against antiserum to crude lectins were unique to each fraction. The activities of all the lectins were optimal at pH values between 6 and 8, and were destroyed by heating at 60°C. Calcium chloride augumented the activities of three lectins, but the major lectin was not influenced by the salt. Bovine erythrocytes were not agglutinated by any of the lectins and comparative agglutination titers for other erythrocytes from various sources were different among these lectins. The activities of all the lectins were inhibited by N-acetylamino sugars. They were more effectively inhibited by glycoproteins which contain sialic acid.     

Differential recognition of natural and remodeled glycotopes by three Diocleae lectins

The carbohydrate specificities of Dioclea grandiflora lectins DGL-I¹ and DGL-II, and Galactia lindenii lectin II (GLL-II) were explored by use of remodeled glycoproteins as well as by the lectin hemagglutinating activity against erythrocytes from various species with different glycomic profiles. The three lectins exhibited differences in glycan binding specificity but also showed overlapping recognition of some glycotopes (i.e. Tα glycotope for the three lectins; IIβ glycotope for DGL-II and GLL-II lectins); in many cases the interaction with distinct glycotopes was influenced by the structural context, i.e., by the neighbouring sugar residues. Our data complement and expand the existing knowledge about the binding specificity of these three Diocleae lectins, and taken together with results of previous studies, allow us to suggest a functional map of the carbohydrate recognition which illustrate the impact of modification of basic glycotopes enhancing, permiting, or inhibiting their recognition by each lectin.     

Thermodynamic binding studies of galectin-1, -3 and -7

The carbohydrate binding specificities of the galectin family of animal lectins has been the source of intense recent investigations. Isothermal titration microcalorimetry (ITC) provides direct determination of the thermodynamics of binding of carbohydrates to lectins, and has provided important insights into the fine carbohydrate binding specificities of a wide number of plant and animal lectins. Recent ITC studies have been performed with galectin-1, galectin-3 and galectin-7 and their interactions with sialylated and non-sialylated carbohydrates. The results show important differences in the specificities of these three galectins toward poly-N-acetyllactosamine epitopes found on the surface of cells.     

Thermodynamic binding studies of galectin-1, -3 and -7

The carbohydrate binding specificities of the galectin family of animal lectins has been the source of intense recent investigations. Isothermal titration microcalorimetry (ITC) provides direct determination of the thermodynamics of binding of carbohydrates to lectins, and has provided important insights into the fine carbohydrate binding specificities of a wide number of plant and animal lectins. Recent ITC studies have been performed with galectin-1, galectin-3 and galectin-7 and their interactions with sialylated and non-sialylated carbohydrates. The results show important differences in the specificities of these three galectins toward poly-N-acetyllactosamine epitopes found on the surface of cells. Published in 2004.     

Extensive sequence homologies among lectins from leguminous plants

The first twenty five residues of the amino terminal sequence of the β chains from lentil and pea lectins, of soybean and peanut agglutinins, and of the R and L subunits of phytohemagglutinin (PHA) were compared. Extensive homologies were found, ranging from near identity in the case of the β chains of lentil and pea lectins, to 24% identity between soybean agglutinin and L-PHA (assuming two deletions in the latter). Despite different sugar binding specificities, a common ancestry for the genes coding for leguminous lectins appears to be very likely.     

Mucin-lectin interactions assessed by flow cytometry

The O-glycosylated domains of mucins and mucin-type glycoproteins contain 50-80% of carbohydrate and possess expanded conformations. Herein, we describe a flow cytometry (FCM) method for determining the carbohydrate-binding specificities of lectins to mucin. Biotinylated mucin was immobilized on streptavidin-coated beads, and the binding specificities of the major mucin sugar chains, as determined by GC-MS and MALDI-ToF, were monitored using fluorescein-labeled lectins. The specificities of lectins toward specific biotinylated glycans were determined as controls. The advantage of flexibility, multiparametric data acquisition, speed, sensitivity, and high-throughput capability makes flow cytometry a valuable tool to study diverse interactions between glycans and proteins.