Related mannose-specific lectins from different species of the family Amaryllidaceae

Bulbs from three species of the plant family Amaryllidaceae ( Narcissus pseudonurcissus L., Leucojum aestivum L. and Leucojum vernum L.) were found to contain mannose-specific lectins. These lectins were serologically identical to a previously reported Amaryllidaceae lectin from Galanthus nivalis L. bulbs, but had a different molecular structure. The lectins described in this paper are dimeric proteins composed of subunits of 13 kDa, which are not held together by disulphide bridges. In hapten-inhibition assays Amaryllidaceae lectins exhibited exclusive specificity towards mannose. Furthermore, they all had a high specific agglutination activity with trypsin-treated rabbit erythrocytes, whereas human red blood cells were not agglutinated.     

Nordic equiseticolous Pyrenomycetes

The Pyrenomycete flora on Equisetum has been studied, mainly on Nordic material. With regard to frequency and host specificity these fungi can be divided into three groups, viz. 1) true Equisetum fungi; 2) common species but not restricted to Equisetum; 3) accidental species. An annotated list is given of the two first categories which comprise the following taxa. 1: Didymosphaeria equiseti–hiemalis, Phaeosphaeria berlesei, P. equiseti, Mycosphaerella equiseti, M. equiseticola, Scirrhia castagnei, S. silvalica , and probably Didymella equisetina. 2: Phaeosphaeria eustoma, P. fuckelii, Mycosphaerella cf. aspidii.
Two new taxa and one new combination are published, viz. Phaeosphaeria equiseti (Karst.) L. & K. Holm comb, nov., P. equiseti var. lindii L. & K. Holm var. nov., Scirrhia silvalica L. & K. Holm sp. nov.     

Purification and properties of two lectins from the latex of the euphorbiaceous plants Hura crepitans L. (sand-box tree) and Euphorbia characias L. (Mediterranean spurge).

1. From the latex of two members of the plant family Euphorbiaceae, Hura crepitans L. (sand-box tree) and Euphorbia characias L. (Mediterranean spurge), two lectins were purified by affinity chromatography on acid-treated Sepharose 6B followed by elution with D-galactose. 2. The lectin from E. characias is a single molecular species with Mr 80 000, made up of two identical subunits with Mr 40 000, and is a glycoprotein containing 11% carbohydrate. 3. The lectin from H. creptians appears as a mixture of three isolectins with Mr 140 000, consisting of four different subunits with Mr values 37 500, 35 500, 31 000, and 29 000. 4. Both lectins have haemagglutinating activity, with no specificity for human blood groups. The haemagglutinating activity is inhibited by D-galactose and by galactose-containing oligosaccharides. 5. The lectin from H. crepitans is mitogenic to human T-, but not to B-, lymphocytes. The latex of E. characias is mitogenic to T- and, to a lesser extent, to B-, lymphocytes, but the purified E. characias lectin has no mitogenic activity. 6. The lectin from H. crepitans, but not that from E. characias, inhibits protein synthesis by a rabbit reticulocyte lysate.     

三种水生植物内生真菌多样性及其抗真菌活性

从华凤仙(Impatiens chinensis L.)、问荆(Equisetum arvense L.)和轮叶狐尾藻(Myriophyllum verticillatum L.) 3种植物中共分离到内生真菌155株。经鉴定, 它们分属于26个不同的分类单元。以杨桃炭疽菌(Colletotrichum gloeosporioides)、香蕉疫霉(Phytophthora nicotianae)和腐皮镰刀菌(Fusarium solani)等6种植物病原真菌为指示菌, 对3种水生植物内生真菌代谢产物进行抗菌活性研究。结果表明, 有37株内生真菌(占分离菌株总数的23.9%)显示出对一种或多种病原菌的抑菌活性。来自华凤仙、问荆和轮叶狐尾藻的抗菌活性菌株比例分别为29.2%、13.9%及37.1%, 都远低于已报道的陆生植物内生真菌中活性菌株的比例。抗菌活性菌株主要分布于枝孢属(Cladosporium)、木霉属(Trichoderma)和地霉属(Geotrichum)等5个属中。     

Substructural specificity and polyvalent carbohydrate recognition by the Entamoeba histolytica and rat hepatic N- acetylgalactosamine/galactose lectins

Both the Entamoeba histolytica lectin, a virulence factor for the causative agent of amebiasis, and the mammalian hepatic lectin bind to N-acetylgalactosamine (GalNAc) and galactose (Gal) nonreducing termini on oligosaccharides, with preference for GalNAc. Polyvalent GalNAc- derivatized neoglycoproteins have >1000-fold enhanced binding affinity for both lectins (Adler,P., Wood,S.J., Lee,Y.C., Lee,R.T., Petri,W.A.,Jr. and Schnaar,R.L.,1995, J. Biol. Chem ., 270, 5164-5171). Substructural specificity studies revealed that the 3-OH and 4-OH groups of GalNAc were required for binding to both lectins, whereas only the E.histolytica lectin required the 6-OH group. Whereas GalNAc binds with 4-fold lower affinity to the E.histolytica lectin than to the mammalian hepatic lectin, galactosamine and N-benzoyl galactosamine bind with higher affinity to the E. histolytica lectin. Therefore, a synthetic scheme for converting polyamine carriers to poly-N-acyl galactosamine derivatives (linked through the galactosamine primary amino group) was developed to test whether such ligands would bind the E.histolytica lectin with high specificity and high affinity. Contrary to expectations, polyvalent derivatives including GalN6lys5, GalN4desmosine, GalN4StarburstTMdendrimer, and GalN8StarburstTMdendrimer demonstrated highly enhanced binding to the mammalian hepatic lectin but little or no enhancement of binding to the E.histolytica lectin. We propose that the mammalian hepatic lectin binds with greatest affinity to GalNAc "miniclusters," which mimic branched termini of N-linked oligosaccharides, whereas the E.histolytica lectin binds most effectively to "maxiclusters," which may mimic more widely spaced GalNAc residues on intestinal mucins.      

Mutational analysis of the sugar-binding site of pea lectin

Comparison of x-ray crystal structures of several legume lectins, co-crystallized with sugar molecules, showed a strong conservation of amino acid residues directly involved in ligand binding. For pea (Pisum sativum) lectin (PSL), these conserved amino acids can be classified into three groups: (I) D81 and N125, present in all legume lectins studied so far; (II) G99 and G216, conserved in almost all legume lectins; and (III) A217 and E218, which are only found in Vicieae lectins and are possibly determinants of sugar-binding specificity. Each of these amino acids in PSL was changed by site-directed mutagenesis, resulting in PSL molecules with single substitutions: for group I D81A, D81N, N125A; for group II G99R, G216L; and for group III A217L, E218Q, respectively. PSL double mutant Y124R; A126S was included as a control. The modified PSL molecules appeared not to be affected in their ability to form dimeric proteins, whereas the sugar-binding activity of each of the PSL mutants, with the exception of the control mutant (as shown by haemagglutination assays), was completely eliminated. These results confirm the model of the sugar-binding site of Vicieae lectins as deduced from X-ray analysis.     

The structural basis of oscillation damping in plant stems - biomechanics and biomimetics

1 Introduction Dynamic wind loads can excite potentially de-structive oscillations in plants. Without dissipation ofmechanical energy a resonance catastrophe is likely tooccur in dynamic winds with frequency componentsclose to the resonant frequencies of the plant. Four modesof oscillation damping are considered [1] ? Friction with other members of the plant commu-nity as for instance in the dense stand of bamboos. ? Structural damping: other than in the engineeringscien…     

Isolation and cloning of a C-type lectin from the hexactinellid sponge Aphrocallistes vastus: a putative aggregation factor

Among the sponges (Porifera), the oldest group of metazoans in phylogenetic terms, the Hexactinellida is considered to have diverged earliest from the two other sponge classes, the Demospongiae and Calcarea. The Hexactinellida are unusual among all Metazoa in possessing mostly syncytial rather than cellular tissues. Here we describe the purification of a cell adhesion molecule with a size of 34 kDa (in its native form; 24 kDa after deglycosylation) from the hexactinellid sponge Aphrocallistes vastus. This adhesion molecule was previously found to agglutinate preserved cells and membranes in a non-species-specific manner (Müller, W. E. G., Zahn, R. K, Conrad, J., Kurelec, B., and Uhlenbruck, G. [1984] Cell adhesion molecules in the haxactinellid Aphrocallistes vastus: species-unspecific aggregationfactor. Differentiation, 26, 30--35). The fact that the aggregation process required Ca(2+) and was inhibited by bird's nest glycoprotein and D-galactose but not by D-mannose or N-acetyl-D-galactosamine suggests that this cell adhesion molecule is a C-type lectin. To test this assumption, two highly similar C-type lectins were cloned from A.vastus. The deduced polypeptides of the two cDNA species isolated classified these molecules as C-type lectins. The calculated M(r) of the 191 aa long sequences were 22,022 and 22,064, respectively. The C-type lectins showed highest similarity to C-type lectins (type-II membrane proteins) from higher metazoan phyla; these molecules are absent in non-Metazoa. The two sponge C-type lectins contain the conserved domains known from other C-type lectins (e.g., disulfide bonds, the amino acids known to be involved in Ca(2+)-binding, as well as the amino acids involved in the specificity of binding to D-galactose) and a hydrophobic N-terminal region. The N-terminal part of the purified C-type lectin was identical with the corresponding region of the deduced polypeptide from the cDNA. It is proposed that the A.vastus lectins might bind to the cell membrane by their hydrophobic segment and might interact with carbohydrate units on the surface of the other cells/syncytia.     

Purification and properties of d-galactose-binding lectins from some erythrina species: Comparison of properties of lectins from E. indica,E. arborescens,E. suberosa, and E. lithosperma

The lectins of the seeds of four species of the genus Erythrina, namely E. indica, E. arborescens, E. lithosperma, and E. suberosa were isolated by affinity chromatography on acid-treated ECD-Sepharose 6B. The lectins were found homogeneous in polyacrylamide gel electrophoresis and immunochemical tests. In SDS-gel electrophoresis, E. indica and E. lithosperma lectins each gave two bands with subunit molecular weights of 30,000 and 33,000 in the case of the former and 26,000 and 28,000 in the case of the latter. E. arborescens and E. suberosa gave single bands corresponding to polypetide chain molecular weight of 28,000. The lectins were found to be glycoproteins with their neutral sugar contents ranging from 4–9%. In carbohydrate specificity all the lectins were d-galactose specific. Their close similarity was also demonstrated by their homologous cross-reaction against the antiserum to E. indica lectin. In hemagglutinating activity toward human erythrocytes, E. indica and E. suberosa lectins showed higher activity toward the O group and E. arborescens toward the B group. The results show the similarity of the lectins derived from different species of the same genus in respect of immunochemical properties and carbohydrate specificity. In studies on E. indica lectin, the protein was found homogeneous by electrophoretic, immunochemical, and sedimentation experiments. Its molecular weight of 68,000 determined from sedimentation and diffusion data indicated that the molecule was a dimer of two noncovalently bound unequal subunits whose SDS-gel electrophoretic molecular weights are noted above. The lectin was devoid of cysteine and methionine and contained valine as its N-terminal amino acid. It had 9% neutral sugars and 1.5% glucosamine. Equilibrium dialysis studies with lactose showed that the values of the association constant K at different temperatures were of similar orders of magnitude to other lectins and the dimeric molecule possessed two noninteracting binding sites.     

Formation of highly ordered cross-linked lattices between asparagine-linked oligosaccharides and lectins observed by electron microscopy

The interaction of asparagine-linked carbohydrates (N-linked) with carbohydrate binding proteins called lectins has been demonstrated to be involved in a variety of cellular recognition processes. Certain N-linked carbohydrates have been shown to be multivalent and capable of binding, cross-linking, and precipitating lectins (Bhattacharyya, L., Ceccarini, C., Lorenzoni, P., and Brewer, C. F. (1987) J. Biol. Chem. 262, 1288-1293; Bhattacharyya, L., Haraldsson, M., and Brewer, C. F. (1987) J. Biol. Chem. 262, 1294-1299; Bhattacharyya, L., Haraldsson, M., and Brewer, C. F. (1988) Biochemistry 27, 1034-1041). Recent data have further suggested that certain oligomannose and bisected hybrid-type N-linked glycopeptides form homogeneous cross-linked lattices with concanavalin A (Bhattacharyya, L., Khan, M. I., and Brewer, C. F. (1988) Biochemistry 27, 8762-8767). In the present study, evidence has been obtained from electron microscopy for the formation of highly ordered and distinct lattices for two bivalent complex type oligosaccharides cross-linked with soybean lectin (Glycine max) and isolectin A from Lotus tetragonolobus, respectively. The results indicate a new source of specificity for interactions of N-linked carbohydrates with lectins, namely their ability to form highly ordered homogeneous aggregates.     

Evidence for the existence of an intracellular root-lectin in soybeans

Soybean (Glycine max (L.) Merr.) root lectin, identified as extractable agglutination activity, was shown to reappear following 15-h incubations of roots that had previously been stripped of all extractable lectin activity. Additional lectin activity was released following disruption of the root tissues and cellular fractionation. These lectin activities were shown to have binding specificity an antibody cross-ractivity similar to soybean seed and root lectins previously described. Thus, it is possible that this intracellular lectin represents the source of extracellular root lectins.     

Deterrent activity of plant lectins on cowpea weevil Callosobruchus maculatus (F.) oviposition

A set of 14 plant lectins was screened in a binary choice bioassay for inhibitory activity on cowpea weevil Callosobruchus maculatus (F.) oviposition. Coating of chickpea seeds (Cicer arietinum L.) with a 0.05% (w/v) solution of plant lectins caused a significant reduction in egg laying. Control experiments with heat inactivated lectin and BSA indicated that the observed deterrent effects are specific and require carbohydrate-binding activity. However, no clear correlation could be established between deterrent activity and sugar-binding specificity/molecular structure of the lectins. Increasing the insect density reduced the inhibitory effect of the lectins confirming that female insects are capable of adjusting their oviposition rates as a function of host availability.     

C-type lectins L-SIGN and DC-SIGN capture and transmit infectious hepatitis C virus pseudotype particles

The molecular mechanisms involved in the hepatic tropism of hepatitis C virus (HCV) have not been identified. We have shown previously that liver-expressed C-type lectins L-SIGN and DC-SIGN bind the HCV E2 glycoprotein with high affinity (Lozach, P. Y., Lortat-Jacob, H., de Lacroix de Lavalette, A., Staropoli, I., Foung, S., Amara, A., Houles, C., Fieschi, F., Schwartz, O., Virelizier, J. L., Arenzana-Seisdedos, F., and Altmeyer, R. (2003) J. Biol. Chem. 278, 20358-20366). To analyze the functional relevance of this interaction, we generated pseudotyped lentivirus particles presenting HCV glycoproteins E1 and E2 at the virion surface (HCV-pp). High mannose N-glycans are present on E1 and, to a lesser extent, on E2 proteins of mature infectious HCV-pp. Such particles bind to both L-SIGN and DC-SIGN, but they cannot use these receptors for entry into cells. However, infectious virus is transmitted efficiently when permissive Huh-7 cells are cocultured with HCV-pp bound to L-SIGN or to DC-SIGN-positive cell lines. HCV-pp transmission via L-SIGN or DC-SIGN is inhibited by characteristic inhibitors such as the calcium chelator EGTA and monoclonal antibodies directed against lectin carbohydrate recognition domains of both lectins. In support of the biological relevance of this phenomenon, dendritic cells expressing endogenous DC-SIGN transmitted HCV-pp with high efficiency in a DC-SIGN-dependent manner. Our results support the hypothesis that C-type lectins such as the liver sinusoidal endothelial cell-expressed L-SIGN could act as a capture receptor for HCV in the liver and transmit infectious virions to neighboring hepatocytes.     

Comparative morphology of the gametophytes of Equisetum subgenus Hippochaete and the sexual behaviour of E. ramosissimum subsp. debile, (Roxb.) Hauke, E. hyemale var. affine (Engelm.) A.A., and E. laevigatum A. Br.

Gametophytes of Equisetum , subgenus Hippochaete , species E. hyemale, E. ramosissimum, E. laevigatum, E. variegatum and E. scirpoides are morphologically distinct. Lamellae from female branches and the archegonial neck cells provide a range of diagnostic features but antheridia are uniform throughout this subgenus, unlike the subgenus Equisetum , in which antheridial morphology is the most reliable criterion for specific identification of gametophytes. The classification of Equisetum into two subgenera based on sporophytic features is supported by gametophyte morphology: column lamellae and sunken antheridia with two opercular cells occur in Hippochaete whereas plate lamellae and projecting antheridia prevail in subgenus Equisetum. The absence of well-marked discontinuities in gametophyte morphology in Hippochaete reinforces cytologica! and hybridization data indicating that the taxa are more closely interrelated man in the subgenus Equisetum. No differences in gametophyte morphology were detected at the intraspecific level. Neither gametophyte morphology nor sexuality provide any definitive data to support me theory that Hippochaete contains the most primitive extant horsetails.
Sexuality in E. ramosissimum subsp. debile, E. hyemale var. affine and E. laevigatum is far more labile than in other taxa of Equisetum. Both male and female secondary gametophytes may be derived from initially male or female individuals as a result of lamellar proliferation.     

The high specificities of Phaseolus vulgaris erythro- and leukoagglutinating lectins for bisecting GlcNAc or beta 1-6-linked branch structures, respectively, are attributable to loop B

Despite very similar tertiary structures based upon a common framework, legume lectins exhibit an amazing variety of sugar binding specificities. While most of these lectins recognize rather discrete sugar linkages, Phaseolus vulgaris erythroagglutinating and leukoagglutinating lectins (E(4)- and L(4)-PHA) are unique in recognizing larger structures. E(4)- and L(4)-PHA are known to recognize complex type N-glycans containing bisecting GlcNAc or a beta1,6-linked branch, respectively. However, the detailed mechanisms of molecular recognition are poorly understood. In order to dissect the contributions of different portions of each lectin, we carried out region-swapping mutagenesis between E(4)- and L(4)-PHA. We prepared six chimeric lectins by exchanging different combinations of loop B and the central portion of loop C, two of four loops thought to be important for the recognition of monosaccharides (Sharma, V., and Surolia, A. (1997) J. Mol. Biol. 267, 433-445). The chimeric lectins' sugar binding activities were evaluated quantitatively by surface plasmon resonance. These comparisons indicate that the high specificities of E(4)- and L(4)-PHA toward bisecting GlcNAc and beta1,6-linked branch structures are almost solely attributable to loop B. The contribution of the central portion of loop C to the recognition of those structural motifs was found to be negligible. Instead, it modulates affinity toward LacNAc residues present at the nonreducing terminus. Moreover, some of the chimeric lectins prepared in this study showed even higher specificities/affinities than native E(4)- and L(4)-PHA toward complex sugar chains containing either a bisecting GlcNAc residue or a beta1,6-linked branch.     

Isolation and characterization of lectins specific for mannose/fucose/N-acetylglucosamine from rat peritoneal macrophages

Rat peritoneal macrophages were shown to have two distinct mannose/fucose/N-acetylglucosamine-specific lectins. The major lectin of 180 kDa, which is similar in size to the mannose receptor first isolated from alveolar macrophages (Wileman, T.E., Lennartz, M.R., & Stahl, P.D. (1986) Proc. Natl. Acad. Sci. U.S. 83, 2501-2505), was shown to occur as a dimer under nondenaturing conditions. The 29 and 32 kDa lectins were identified as members of the liver mannan-binding protein family on the basis of their immunochemical crossreactivity, collagenase sensitivity, and molecular sizes (Oka, S., Ikeda, K., Kawasaki, T., & Yamashina, I. (1988) Arch. Biochem. Biophys. 260, 257-266). Despite the similarity in the sugar binding specificity, these two types of lectin were clearly differentiated with regard to the binding to IgM molecules. The 29 and 32 kDa lectins bound to IgM most likely through high-mannose type oligosaccharides on IgM, whereas the 180 kDa lectin did not.     

Humoral Recognition Factors in the Arthropoda. The Specificity of Chelicerata Serum Lectins

Arthropods have the capacity of recognizing self from non-selfin various defense phenomena including hemolymph clotting, phagocytosis,encapsulation, melanization and clearance of the foreign matterwhich must be initiated by a first step of molecular recognition."Natural" and experimentally induced humoral factors have beendescribed which act as hemagglutinins, bacterial agglutinins,precipitins, bactericidal factors, bacteriolysins, hemolysins,opsonins, clotting factors, and lysozymes. Their exact rolein recognition functions has not been fully explored and theirfunction remains unclear. Among these factors, the carbohydrate-bindingmolecules (lectins) are the best characterized in their specificity,physicochemical properties and molecular structure. Arthropodlectins are multimeric, high molecular weight protein (glycoprotein)molecules with a certain degree of heterogeneity in their specificityand structure. In particular, serum lectins from chelicerates(horseshoe crabs, scorpions and spiders) share a common property:the specificity for sialic acids. Arachnids and merostomes divergedin the earliest Cambrian. Since they occupy markedly differenthabitats, the sialic acid specific lectins most probably area relict rather than an adaptative character. In addition tothis common feature of specificity, lectins from cheliceratesand other arthropods represent heterogeneous populations whichcan bind a wide variety of carbohydrates, many of them presenton bacteria as D-galactose, 2-keto-3-deoxyoctonate, glucuronicacid, N-acetylmuramic acid, and colominic acid. Multiplicityin specificity suggests that serum lectins might contributeas a carbohydrate-based recognition system for the non-self.The requirement for avoiding self recognition would be thatcarbohydrate structures potentially recognized by the systemwould be absent, masked or out of reach of this humoral factoror cell associated recognition factors.     

Intracellular lectins of Lentinus edodes at various developmental stages of the fungus

A number of lectins varying in polypeptide composition and carbohydrate specificity were isolated from Lentinus edodes at different stages of its morphogenesis: nonpigmented mycelium, brown mycelium film, and fruiting body. Three lectins were identified at the nonpigmented mycelium stage, two of them being dimers consisting of 16 and 45 kDa and 16 and 42 kDa subunits; the third is a tetramer of 16, 39, 42, and 45 kDa subunits. The fractions with lectin activity obtained at the brown mycelium film stage contained polypeptides of 24, 30, and 38 kDa, characteristic of this morphological structure. The fruiting body was shown to contain two lectins of 43 and 55 kDa. All of the isolated lectins expressed the highest affinity towards L,D-melibiose, D-lactose, and D-galactose.     

Dynamic of lectin activity during germination of bean seeds (Phaseolus vulgaris L.)

PHA quantity and activity dynamics during early germination of bean seed were investigated. Electrophoretic characteristics, subunits composition and carbohydrate-binding specificity of lectin extracted from white kidney bean cv. Bilozerna were studied. It was shown that investigated lectin consisted of 2 subunits E and L with molecular weight 34 and 36 kDa, respectively, analogously to purified PHA ("Serva", Germany), and specifically bound N-acetyl-D-galactosamin and galactose. During germination both quantity and activity of PHA were dramatically decreasing in embryonic axes and in cotyledons, possibly, as a result of the lectin release from seeds to the environment. It is very likely that one of the defence mechanisms of germinating seeds is related with the releasing of lectins that are able to bind components of the bacterial cell wall and to inhibit their growth.     

Molecular basis of recognition by Gal/GalNAc specific legume lectins: influence of Glu 129 on the specificity of peanut agglutinin (PNA) towards C2-substituents of galactose

The ability to discriminate between galactose and N- acetylgalactosamine, observed in some lectins, is crucial for their biological activity as well as their usefulness as tools in biology and medicine. However, the molecular basis of differential binding of lectins to these two sugars is poorly understood. Peanut agglutinin (PNA) is one of the few galactose-specific legume lectins which does not bind N- acetylgalactosamine at all and is, therefore, ideal for the study of the basis of specificity towards C-2 substituted derivatives of galactopyranosides. Examination of the three-dimensional structure of PNA in complex with lactose revealed the presence of both a longer loop and bulkier residues in the region surrounding the C-2 hydroxyl of the galactopyranoside ring, which can sterically prevent the accommodation of a bulky substituent in this position. One such residue, is a glutamic acid at position 129 which protrudes into the binding site and perhaps directly obstructs any substitution at the C-2 position. Two mutants in bacterially expressed PNA were therefore constructed. These were E129D and E129A, in which Glu129 was replaced by Asp and Ala, respectively. The specificity of the mutants for galactose, galactosamine, and N- acetylgalactosamine was examined through observing the inhibition of hemagglutination and binding of the lectin to immobilized asialofetuin. The results showed that the affinity of E129A and E129D for C-2-substituted derivatives of the galactose varies. The mutant E129D showed significant binding towards N- acetylgalactosamine, suggesting that the residue Glu 129 is crucial in imparting exclusive galactose-specificity upon PNA. This study not only attempts to provide an explanation for the inability of PNA to accommodate C-2-substituted derivatives at its primary subsite, but also seeks to present a basis for engineering lectins with altered specificities.