Archeal lectins: An identification through a genomic search

Forty‐six lectin domains which have homologues among well established eukaryotic and bacterial lectins of known three‐dimensional structure, have been identified through a search of 165 archeal genomes using a multipronged approach involving domain recognition, sequence search and analysis of binding sites. Twenty‐one of them have the 7‐bladed β‐propeller lectin fold while 16 have the β‐trefoil fold and 7 the legume lectin fold. The remainder assumes the C‐type lectin, the β‐prism I and the tachylectin folds. Acceptable models of almost all of them could be generated using the appropriate lectins of known three‐dimensional structure as templates, with binding sites at one or more expected locations. The work represents the first comprehensive bioinformatic study of archeal lectins. The presence of lectins with the same fold in all domains of life indicates their ancient origin well before the divergence of the three branches. Further work is necessary to identify archeal lectins which have no homologues among eukaryotic and bacterial species. Proteins 2016; 84:21–30. © 2015 Wiley Periodicals, Inc.     

Crystal structure of BinB: A receptor binding component of the binary toxin from Lysinibacillus sphaericus

The binary toxin (Bin), produced by Lysinibacillus sphaericus, is composed of BinA (42 kDa) and BinB (51 kDa) proteins, which are both required for full toxicity against Culex and Anopheles mosquito larvae. Specificity of Bin toxin is determined by the binding of BinB component to a receptor present on the midgut epithelial membranes, while BinA is proposed to be a toxic component. Here, we determined the first crystal structure of the active form of BinB at a resolution of 1.75 Å. BinB possesses two distinct structural domains in its N‐ and C‐termini. The globular N‐terminal domain has a β‐trefoil scaffold which is a highly conserved architecture of some sugar binding proteins or lectins, suggesting a role of this domain in receptor‐binding. The BinB β‐rich C‐terminal domain shares similar three‐dimensional folding with aerolysin type β‐pore forming toxins, despite a low sequence identity. The BinB structure, therefore, is a new member of the aerolysin‐like toxin family, with probably similarities in the cytolytic mechanism that takes place via pore formation. Proteins 2014; 82:2703–2712. © 2014 Wiley Periodicals, Inc.     

从生物大分子结构特征解析植物凝集素的多样性

利用计算机模拟分析了植物凝集素结构与功能的特征。结果显示：(1)植物凝集素在结合糖之前其结构变化是一致的;(2)植物凝集素存在结构上的多样性,且可能与其生物功能的多样性有关;(3)在结合糖的过程中,植物凝集素表面局部结构的构象会有所变化,这种变化有利于其识别不同的糖而结合不同的外来糖缀合物,发挥其防御功能。对于同一家族的植物凝集素,虽然序列同源性较高,但在功能上却表现出强烈的多样性。分析表明：对于生物大分子而言,欲完成同一功能,不一定结构相同;结构相同,不一定功能一样。     

Conserved buried water molecules enable the β‐trefoil architecture

Available high‐resolution crystal structures for the family of β‐trefoil proteins in the structural databank were queried for buried waters. Such waters were classified as either: (a) unique to a particular domain, family, or superfamily or (b) conserved among all β‐trefoil folds. Three buried waters conserved among all β‐trefoil folds were identified. These waters are related by the threefold rotational pseudosymmetry characteristic of this protein architecture (representing three instances of an identical structural environment within each repeating trefoil‐fold motif). The structural properties of this buried water are remarkable and include: residing in a cavity space no larger than a single water molecule, exhibiting a positional uncertainty (i.e., normalized B‐factor) substantially lower than the average Cα atom, providing essentially ideal H‐bonding geometry with three solvent‐inaccessible main chain groups, simultaneously serving as a bridging H‐bond for three different β‐strands at a point of secondary structure divergence, and orienting conserved hydrophobic side chains to form a nascent core‐packing group. Other published work supports an interpretation that these interactions are key to the formation of an efficient folding nucleus and folded thermostability. The fundamental threefold symmetric structural element of the β‐trefoil fold is therefore, surprisingly, a buried water molecule.     

Lectin Receptor Kinases in Plants

Referee: Dr. Philip Becraft, Zoology and Genetics/Agronomy Depts., 2116 Molecular Building, lowa State University, Ames, IA 50011 Forty-two lectin receptor kinase (lecRK)-related sequences and nine related soluble legume lectin sequences were identified in the Arabidopsis thaliana genome. The genes are scattered as a single or gathered copies at different loci throughout the five chromosomes, and four predicted lecRK probably correspond to pseudogenes. Both structural alignments and molecular modeling revealed striking similarities between the lectinlike domain of lecRK, and related A. thaliana soluble lectins and legume lectins. The hydrophobic cavity is extremely conserved, whereas most of the residues forming the monosaccharide-binding site and the bivalent cation-binding site of legume lectins are poorly conserved. LecRK should be unable to bind the simple sugars usually recognized by genuine legume lectins. Molecular modeling of the kinase domain suggests that, except for two apparently inactive receptors, all other lecRK contain a putative functional Ser/Thr kinase catalytic domain. Both the juxtamembrane and C-terminal domains, which are considered important regions for regulating the kinase activity, exhibit a few specific stretches of amino acid residues. Some phylogenetic relationships are inferred from the phylogenetic trees built up from the different lecRK domain sequences. LecRK cluster in three distinct classes (A,B,C), one of them (B) being more closely related to soluble lectins of A. thaliana and legume lectins.     

Single-molecule force spectroscopy of mycobacterial adhesin-adhesin interactions

The heparin-binding hemagglutinin (HBHA) is one of the few virulence factors identified for Mycobacterium tuberculosis. It is a surface-associated adhesin that expresses a number of different activities, including mycobacterial adhesion to nonphagocytic cells and microbial aggregation. Previous evidence indicated that HBHA is likely to form homodimers or homopolymers via a predicted coiled-coil region located within the N-terminal portion of the molecule. Here, we used single-molecule atomic-force microscopy to measure individual homophilic HBHA-HBHA interaction forces. Force curves recorded between tips and supports derivatized with HBHA proteins exposing their N-terminal domains showed a bimodal distribution of binding forces reflecting the formation of dimers or multimers. Moreover, the binding peaks showed elongation forces that were consistent with the unfolding of α-helical coiled-coil structures. By contrast, force curves obtained for proteins exposing their lysine-rich C-terminal domains showed a broader distribution of binding events, suggesting that they originate primarily from intermolecular electrostatic bridges between cationic and anionic residues rather than from specific coiled-coil interactions. Notably, similar homophilic HBHA-HBHA interactions were demonstrated on live mycobacteria producing HBHA, while they were not observed on an HBHA-deficient mutant. Together with the fact that HBHA mediates bacterial aggregation, these observations suggest that the single homophilic HBHA interactions measured here reflect the formation of multimers that may promote mycobacterial aggregation.     

Functional domains present in the mycobacterial hemagglutinin, HBHA

Identification and characterization of mycobacterial adhesins and complementary host receptors required for colonization and dissemination of mycobacteria in host tissues are needed for a more complete understanding of the pathogenesis of diseases caused by these bacteria and for the development of effective vaccines. Previous investigations have demonstrated that a 28-kDa heparin-binding mycobacterial surface protein, HBHA, can agglutinate erythrocytes and promote mycobacterial aggregation in vitro. In this study, further molecular and biochemical analysis of HBHA demonstrates that it has three functional domains: a transmembrane domain of 18 amino acids residing near the N terminus, a large domain of 81 amino acids consistent with an alpha-helical coiled-coil region, and a Lys-Pro-Ala-rich C-terminal domain that mediates binding to proteoglycans. Using His-tagged recombinant HBHA proteins and nickel chromatography we demonstrate that HBHA polypeptides which contain the coiled-coil region form multimers. This tendency to oligomerize may be responsible for the induction of mycobacterial aggregation since a truncated N-terminal HBHA fragment containing the coiled-coil domain promotes mycobacterial aggregation. Conversely, a truncated C-terminal HBHA fragment which contains Lys-Pro-Ala-rich repeats binds to the proteoglycan decorin. These results indicate that HBHA contains at least three distinct domains which facilitate intercalation into surface membranes, promote bacterium-bacterium interactions, and mediate the attachment to sulfated glycoconjugates found in host tissues.     

The first crystal structure of a Mimosoideae lectin reveals a novel quaternary arrangement of a widespread domain

The crystal structures of the apo and mannose-bound Parkia platycephala seed lectin represent the first structure of a Mimosoideae lectin and a novel circular arrangement of beta-prism domains, and highlight the adaptability of the beta-prism fold as a building block in the evolution of plant lectins. The P.platycephala lectin is a dimer both in solution and in the crystals. Mannose binding to each of the three homologous carbohydrate-recognition domains of the lectin occurs through different modes, and restrains the flexibility of surface-exposed loops and residues involved in carbohydrate recognition. The planar array of carbohydrate-binding sites on the rim of the toroid-shaped structure of the P.platycephala lectin dimer immediately suggests a mechanism to promote multivalent interactions leading to cross-linking of carbohydrate ligands as part of the host strategy against phytopredators and pathogens. The cyclic structure of the P.platycephala lectin points to the convergent evolution of a structural principle for the construction of lectins involved in host defense or in attacking other organisms.     

Structure of the Y. pseudotuberculosis adhesin InvasinE

Enteropathogenic Yersinia expresses several invasins that are fundamental virulence factors required for adherence and colonization of tissues in the host. Within the invasin‐family of Yersinia adhesins, to date only Invasin has been extensively studied at both structural and functional levels. In this work, we structurally characterize the recently identified inverse autotransporter InvasinE from Yersinia pseudotuberculosis (formerly InvasinD from Yersinia pseudotuberculosis strain IP31758) that belongs to the invasin‐family of proteins. The sequence of the C‐terminal adhesion domain of InvasinE differs significantly from that of other members of the Yersinia invasin‐family and its detailed cellular and molecular function remains elusive. In this work, we present the 1.7 Å crystal structure of the adhesion domain of InvasinE along with two Immunoglobulin‐like domains. The structure reveals a rod shaped architecture, confirmed by small angle X‐ray scattering in solution. The adhesion domain exhibits strong structural similarities to the C‐type lectin‐like domain of Yersinia pseudotuberculosis Invasin and enteropathogenic/enterohemorrhagic E. coli Intimin. However, despite the overall structural similarity, the C‐type lectin‐like domain in InvasinE lacks motifs required for Ca²⁺/carbohydrate binding as well as sequence or structural features critical for Tir binding in Intimin and β₁‐integrin binding in Invasin, suggesting that InvasinE targets a distinct, yet unidentified molecule on the host‐cell surface. Although the biological role and target molecule of InvasinE remain to be elucidated, our structural data provide novel insights into the architecture of invasin‐family proteins and a platform for further studies towards unraveling the function of InvasinE in the context of infection and host colonization.     

Unusual sugar specificity of banana lectin from Musa paradisiaca and its probable evolutionary origin. Crystallographic and modelling studies

The crystal structure of a complex of methyl-alpha-D-mannoside with banana lectin from Musa paradisiaca reveals two primary binding sites in the lectin, unlike in other lectins with beta-prism I fold which essentially consists of three Greek key motifs. It has been suggested that the fold evolved through successive gene duplication and fusion of an ancestral Greek key motif. In other lectins, all from dicots, the primary binding site exists on one of the three motifs in the three-fold symmetric molecule. Banana is a monocot, and the three motifs have not diverged enough to obliterate sequence similarity among them. Two Greek key motifs in it carry one primary binding site each. A common secondary binding site exists on the third Greek key. Modelling shows that both the primary sites can support 1-2, 1-3, and 1-6 linked mannosides with the second residue interacting in each case primarily with the secondary binding site. Modelling also readily leads to a bound branched mannopentose with the nonreducing ends of the two branches anchored at the two primary binding sites, providing a structural explanation for the lectin's specificity for branched alpha-mannans. A comparison of the dimeric banana lectin with other beta-prism I fold lectins, provides interesting insights into the variability in their quaternary structure.     

The lectin domains of polypeptide GalNAc-transferases exhibit carbohydrate-binding specificity for GalNAc: lectin binding to GalNAc-glycopeptide substrates is required for high density GalNAc-O-glycosylation

Initiation of mucin-type O-glycosylation is controlled by a large family of UDP GalNAc:polypeptide N-acetylgalactosaminyltransferases (GalNAc-transferases). Most GalNAc-transferases contain a ricin-like lectin domain in the C-terminal end, which may confer GalNAc-glycopeptide substrate specificity to the enzyme. We have previously shown that the lectin domain of GalNAc-T4 modulates its substrate specificity to enable unique GalNAc-glycopeptide specificities and that this effect is selectively inhibitable by GalNAc; however, direct evidence of carbohydrate binding of GalNAc-transferase lectins has not been previously presented. Here, we report the direct carbohydrate binding of two GalNAc-transferase lectin domains, GalNAc-T4 and GalNAc-T2, representing isoforms reported to have distinct glycopeptide activity (GalNAc-T4) and isoforms without apparent distinct GalNAc-glycopeptide specificity (GalNAc-T2). Both lectins exhibited specificity for binding of free GalNAc. Kinetic and time-course analysis of GalNAc-T2 demonstrated that the lectin domain did not affect transfer to initial glycosylation sites, but selectively modulated velocity of transfer to subsequent sites and affected the number of acceptor sites utilized. The results suggest that GalNAc-transferase lectins serve to modulate the kinetic properties of the enzymes in the late stages of the initiation process of O-glycosylation to accomplish dense or complete O-glycan occupancy.     

High-resolution crystal structures of the lectin-like xylan binding domain from Streptomyces lividans xylanase 10A with bound substrates reveal a novel mode of xylan binding

Carbohydrate-binding module (CBM) family 13 includes the "R-type" or "ricin superfamily" beta-trefoil lectins. The C-terminal CBM, CBM13, of xylanase 10A from Streptomyces lividans is a family 13 CBM that is not only structurally similar to the "R-type" lectins but also somewhat functionally similar. The primary function of CBM13 is to bind the polysaccharide xylan, but it retains the ability of the R-type lectins to bind small sugars such as lactose and galactose. The association of CBM13 with xylan appears to involve cooperative and additive participation of three binding pockets in each of the three trefoil domains of CBM13, suggesting a novel mechanism of CBM-xylan interaction. Thus, the interaction of CBM13 with sugars displays considerable plasticity for which we provide a structural rationale. The high-resolution crystal structure of CBM13 was determined by multiple anomalous dispersion from a complex of CBM13 with a brominated ligand. Crystal structures of CBM13 in complex with lactose and xylopentaose revealed two distinct mechanisms of ligand binding. CBM13 has retained its specificity for lactose via Ricin-like binding in all of the three classic trefoil binding pockets. However, CBM13 has the ability to bind either the nonreducing galactosyl moiety or the reducing glucosyl moiety of lactose. The mode of xylopentaose binding suggests adaptive mutations in the trefoil sugar binding scaffold to accommodate internal binding on helical polymers of xylose.     

Complete structure determination of N‐acetyl‐D‐galactosamine‐binding mistletoe lectin‐3 from Viscum album L. album

The primary structure of the B chain of the N‐acetyl‐D ‐galactosamine‐recognizing mistletoe lectin‐3 (ML‐3B) has been deduced from proteolytic digest peptides of the purified glycoprotein, their HPLC‐separation and Edman degradation and confirmation of the peptide sequences by MALDI‐MS. ML‐3B consists of 262 amino acid residues including 10 cysteine moieties. The structure and linkage of the carbohydrate side chains, connected to two N‐glycosylation sites at positions Asn⁹⁵ and Asn¹³⁵ of the lectin, were determined by a combination of glycosidase treatment and MALDI‐MS of corresponding glycopeptide fragments. The sequence alignment reveals a high homology with other B chains of type‐II RIPs, although there are remarkable differences in the D ‐galactose‐specific mistletoe lectin‐1B chain. The recently published primary structure of the mistletoe lectin‐3A chain 1 and the now available primary sequence of the 3B chain allowed the construction of a preliminary homology model of ML‐3. The model demonstrates, unequivocally, that ML‐3 is a member of the type‐II RIP family with rigid conservation of the enzymatic active site of the A chain and an identical overall protein fold. Specific amino acid residue exchanges and the different glycosylation pattern in comparison with ML‐1 are discussed and related to the properties of the two glycoproteins. The knowledge of the complete primary structure of mistletoe lectin‐3 is a major contribution towards more insight into the mechanism of the biological activity of commercial mistletoe preparations. Copyright © 2004 European Peptide Society and John Wiley & Sons, Ltd.     

A comparative study of bark lectins from three elderberry (Sambucus) species

Three elderberry lectins isolated from the bark of three different species of the genus Sambucus which are native to Europe (S. nigra), North America (S. canadensis), and Japan (S. sieboldiana) were studied comparatively with regard to their carbohydrate binding properties and some structural features. All three lectins contained two identical carbohydrate binding sites per molecule and showed a very high specificity for the Neu5Ac(alpha 2-6)-Gal/GalNAc sequence. However, relative affinities for various oligosaccharides were significantly different among them, suggesting differences in the detailed structure of the carbohydrate binding sites of these lectins. The three lectins were immunologically related, but not identical, and all were composed of hydrophobic and hydrophilic subunit regions, although the molecular sizes of these subunits were slightly different among the three lectins. N-terminal sequence analysis of the subunits of these lectins suggested that they have a very similar structure in this region but also indicated the occurrence of N-terminal processing such as the deletion of several amino acid residues at the N-termini for both hydrophobic and hydrophilic subunits of all three lectins. Tryptic peptide mapping of the three lectins showed a similar pattern for all of them but also showed the presence of some unique peptides for each lectin.     

Generation of H2O2 by Human Neutrophils and Changes of Cytosolic Ca2+ and pH of Rat Thymocytes in Response to Galactoside-Binding Proteins (Lectins or Immunoglobulins)

In contrast to plant agglutinins, biological activities of animal/human lectins are not well defined yet. Testing a panel of seven mammalian carbohydrate-binding proteins we have found that the dimeric lectin from chicken liver (CL-16) was a stimulator of H₂O₂ release from human neutrophils as well as effector for induction of cytosolic Ca²⁺ and pH increase in rat thymocytes. Activity of this lectin was comparable to potent galactoside-specific plant lectins such as Viscum album L. agglutinin. The activities of the tested plant lectins depended significantly on their nominal carbohydrate specificity as well as on the source. The results indicate that endogenous lectins may be involved in the regulation of neutrophil and lymphocyte functions by elicitation of selective biosignaling reactions.     

Carbohydrate-Binding Proteins in the Leech: I. Isolation and Characterization of Lactose-Binding Proteins

Abstract: Three lactose-binding proteins with apparent molecular masses of 16, 35, and 63 kDa [leech lectin 16, 35, and 63 (LL16, LL35, and LL63, respectively)] were isolated from leech membranes. Polyclonal antibodies raised against LL35 cross-reacted with LL16 and LL63, indicating that all three lectins were immunologically related. These leech lectins, however, can be subdivided into two groups based on their tissue distributions and binding affinities for galactose derivatives. LL16 and LL35 are endogenous to the leech's CNS, whereas LL63 is only present in peripheral organs. LL16 and LL35, found in the CNS, bind both the α and β anomers of methylgalactose, whereas the peripheral lectin LL63 binds only the β form. LL35 and LL63 also differ in their binding affinities for galactosamine and N -acetylgalactosamine. The binding activity of LL35 was calcium independent and active over a wide pH range. Triton X-100 and 2-mercaptoethanol were necessary to recover LL35 binding activity during extraction. These characteristics strongly suggest that LL35 is another member of the calcium-independent galactose/lactose-specific lectins previously described in vertebrates and recently demonstrated in sponges and nematodes. Because a single leech expresses up to 100 µg of LL35, this leech lectin is readily amenable to structural and functional analysis.     

Biochemical, histochemical and cell biological investigations on the actions of mistletoe lectins I, II and III with human breast cancer cell lines

Cytotoxicity of the mistletoe lectins I, II and III towards six human breast cancer cell lines was assessed using the Mossman assay. In addition, binding of the three mistletoe lectins to the separated membrane glycoproteins of these cell lines, the binding and uptake of these lectins into the cells in tissue culture and the binding of the lectins to histological preparations of these cell lines were analysed. The results indicate that there are quantitative differences concerning the toxicity of these three lectins towards the different cell lines. Furthermore, the lectin binding pattern in the cell lines differed. In Western blots, several membrane glycoproteins were labelled by the lectins. Our results indicate subtle differences between the three lectins with regard to the parameters mentioned above; however, the toxicity of all three lectins from mistletoe is so similar that they all seem suitable for the construction of immunotoxins.Dedication: This work is dedicated to one of the discoverers (amongst many other important contributions) ofHelix pomatia agglutinin, which plays an important role in metastasis research, Professor Dr G. Uhlenbruck on the occasion of his 65th birthday.     

Glycoconjugates of the human sperm surface: Distribution and alterations that accompany capacitation in vitro

We have studied changes in the binding of fluoresceinated lectins to human sperm during in vitro capacitation. We first determined the surface labeling pattern of viable sperm obtained by the swim-up procedure. Sperm were labeled with 100 μg/ml FITC-conjugated lectin at 4°C for 30 min. We simultaneously used Hoechst stain 33258 as a supravital stain to help differentiate surface from intracellular lectin labeling. Of 14 lectins studied, six (phytohemagglutinin-E, concanavalin A, Ricinus communis agglutinin-I, and the lectins of wheat germ, Lens culinaris, and Pisum sativum) bound to the entire surface of sperm, sometimes with minor local heterogeneity. Three lectins (from peanut, Maclura pomifera, and soybean) usually bound in a punctate manner, with more label on the tail than on the head. Five lectins (Ulex europaeus, Dolichos biflorus, Helix pomatia, and Vicia villosa lectins, and lectin II of Griffonia simplicifolia) bound very poorly or not at all to the sperm surface. Sperm were also inspected for changes in surface lectin binding patterns after 0, 5, and 23 hr of incubation in a capacitating medium. Two lectins showed reproducible changes. The labeling by Maclura pomifera agglutinin decreased by 5 hr in eight of ten experiments, and among sperm labeled with concanavalin A, the incidence of sperm with a highly fluorescent anterior margin of the sperm head increased by about 3.5-fold between 0 and 5 hr. The labeling pattern of the other lectins did not change.     

Binding and cross-linking properties of galectins

The galectins are a family of animal lectins that possess similar carbohydrate binding specificities and conserved consensus sequences. The biological properties of mammalian galectins include the regulation of inflammation, cell adhesion, cell proliferation and cell death. Evidence suggests that the biological activities of the galectins are related to their multivalent binding properties since most galectins possess two carbohydrate recognition domains and are therefore bivalent. For example, galectin-1, which is dimeric, binds and cross-links specific glycoprotein counter-receptors on the surface of human T-cells leading to apoptosis [J. Immunol. 163 (1999) 3801]. Different galectin-1 counter-receptors associated with specific phosphatase or kinase activities formed separate clusters on the surface of the cells as a result of the lectin binding to the carbohydrate chains of the respective glycoproteins. Importantly, monovalent galectin-1 is inactive in this system. This indicates that the separation and organization of signaling molecules that result from galectin-1 binding is involved in the apoptotic signal. The separation of specific glycoprotein receptors induced by galectin-1 binding was modeled on the basis of molecular and structural studies of the binding of lectins to multivalent carbohydrates resulting in the formation of specific two- and three-dimensional cross-linked lattices [Biochemistry 36 (1997) 15073]. In this article, the binding and cross-linking properties of galectin-1 and other lectins are reviewed as a model for the biological signal transduction properties of the galectin family of animal lectins.     

Structural and binding properties of the PASTA domain of PonA2, a key penicillin binding protein from Mycobacterium tuberculosis

PonA2 is one of the two class A penicillin binding proteins of Mycobacterium tuberculosis, the etiologic agent of tuberculosis. It plays a complex role in mycobacterial physiology and is spotted as a promising target for inhibitors. PonA2 is involved in adaptation of M. tuberculosis to dormancy, an ability which has been attributed to the presence in its sequence of a C‐terminal PASTA domain. Since PASTA modules are typically considered as β‐lactam antibiotic binding domains, we determined the solution structure of the PASTA domain from PonA2 and analyzed its binding properties versus a plethora of potential binders, including the β‐lactam antibiotics, two typical muropeptide mimics, and polymeric peptidoglycan. We show that, despite a high structural similarity with other PASTA domains, the PASTA domain of PonA2 displays different binding properties, as it is not able to bind muropeptides, or β‐lactams, or polymeric peptidoglycan. These results indicate that the role of PASTA domains cannot be generalized, as their specific binding properties strongly depend on surface residues, which are widely variable. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 712–719, 2014.