Isolation of a human milk sialyloligosaccharide by affinity chromotography with wheat germ agglutinin (WGA)

Tarrago-Trani, Maria T.

January 1986

Lectin affinity chromatography has been applied to the separation of the sialyloligosaccharides of human milk. A human milk sialyloligosaccharide fraction was tritium labeled and applied to a highly substituted WGA-agarose column (20 mg/ml). Only a single component from the complete sialyloligosaccharide fraction was retarded in the WGA-agarose column. The WGA-bound fraction when applied to paper chromatography migrated with identical mobility as the sialylhexasaccharide fraction (S-5) of human milk, previously isolated and described by Kobata and Ginsburg in 1972 [Arch. Biochem. Biophys., 150:273-281]. A purified sialylhexasaccharide fraction (S-5), isolated according to the method of Kobata and Ginsburg, was radiolabeled and applied to the WGA-agarose column. The WGA-bound (60%) and WGA-unbound (40%) sialylhexasaccharide fractions were isolated. The WGA-bound sialylhexasaccharide fraction was subjected to neuraminidase digestion to remove sialic acid, and the resulting neutral oligosaccharide had more affinity for the WGA-agarose column. Sequential exoglycosidase digestion of the asialo derivative of the WGA-bound fraction with jack bean β -galactosidase and β -hexosaminidase demonstrated the presence of a lacto-N-neohexaose core. The position of sialic acid in the sialyllacto-N-neohexaose was determined by simultaneous digestion of the sialylhexaose with jack bean β -galactosidase and β -hexosaminidase, which removed the non-sialylated branch from the sialylhexaose and produced a sialyltetraose. The sialyltetraose was found to be sialyltetrasaccharide c as demonstrated by its elution time on HPLC and direct binding to monospecific anti-sialyltetrasccharide c serum. The structural data indicated that the WGA-bound sialylhexaose is a sialyl derivative of lacto-N-neohexaose with sialic acid linked to the 3 branch of this core structure which represents a previously undescribed sialyloligosaccharide in human milk. The structure of the WGA-bound sialylhexaose is, / M.S.

LD5655.V855 1986.T375

Lectins

Breast milk

Oligosaccharides

Structural Studies On Winged Bean Agglutinins

Manoj, N

07 1900

Lectins are multivalent carbohydrate binding proteins that specifically recognise diverse sugar structures and mediate a variety of biological processes, such as cell-cell and host-pathogen interactions, serum glycoprotein turnover and innate immune responses. Lectins have received considerable attention in recent years on account of their properties which have led to their wide use in research and biomedical applications. Seeds of leguminous plants are rich sources of lectins, but they are also found in all classes and families of organisms. Legume lectins have similar tertiary structures, but exhibit a large variety of quaternary structures. The carbohydrate binding site in them is made up of four loops, the first three of which are highly conserved in all legume lectins. The fourth loop, which is variable, is implicated in conferring specificity. Legume lectins which share the same monosaccharide specificity often exhibit markedly different oligosaccharide specificities. The introductory chapter gives a broad overview of lectins from a structural point of view. The rest of the thesis is primarily concerned with structural studies on lectins from seeds of the winged bean (Psophocarpus tetragonolobus). Winged bean seeds contain a basic lectin (WBAI) (pi > 9.5) and an acidic lectin (WBAII) (pi -5.5). Both these lectins are N-glycosylated homodimers with about 240 amino acid residues per monomer. They show a high affinity for methyl-a-D-galactose at the monosaccharide level but have entirely different affinities for oligosaccharides. WBAI agglutinates human type A and B erythrocytes but not O type, while WBAII binds specifically to the terminally monofucosylated H-antigenic (responsible for O blood group reactivity) determinants on the cell surface. In this context, the current study seeks to characterise the carbohydrate binding site of a saccharide-free form of WBAI and determine the structural basis of carbohydrate recognition in WBAII. The study also aims to identify the factors responsible for the differences in carbohydrate specificities between WBAI and WBAII. Diffraction data from a saccharide-free crystal form of WBAI and two crystal forms (Form I and II) of WBAII complexed with methyl-a-D-galactose were collected on a MAR imaging plate system mounted on a Rigaku RU200 rotating anode X-ray generator. The data were processed using the MAR-XDS and DENZO/SCALEPACK suites of programs. The structures were solved by the molecular replacement method using AMoRe. The model used in the case of WBAI and Form I of WBAII was the structure of WBAI in complex with methyl-a-D-galactose (PDB coderlWBL), while the structure of Form II of WBAH was solved using a partially refined model of Form I. The refinements and model building were performed using the programs X-PLOR/CNS and O respectively. A comparison of the structures of the saccharide-free and bound forms of WBAI revealed three water molecules occupying the carbohydrate binding site, which mimic the hydrogen bonded interactions made by the saccharide in the structure of the complex. Also a shift of -0.6 A in the variable loop, towards the saccharide in the structure of the complex was observed. Significant differences in the conformation of a loop involved in crystal packing interactions were also observed. An analysis of protein hydration demonstrates, among other things, the role of water molecules in stabilising the structure of the loops around the carbohydrate binding site. The crystal structures of the two forms of WBAH were solved at 3.0 A and 3.3. A resolution. The structure of the complex revealed the role of the length of the variable loop in generating the difference in oligosaccharide specificity between WBAI and WB All. The difference in the pi values between the two lectins is caused by substitutions occurring in loops and edges of sheets. A distinct structural difference between WBAH and all the other legume lectins of known structure is in the new disposition of the 34-45 loop with an r.m.s deviation of -6.0A in Coc positions compared to its position in other lectins. This change in conformation is caused by the formation of salt bridges by amino acid residues unique to WB All in the 34-45 loop and its neighbourhood. Thermodynamic studies on the binding of H-antigenic determinant to WBAII showed a predominance of entropic contribution suggesting a hydrophobically driven binding, not yet observed in lectin-sugar interactions. An analysis involving the docking of H-type II trisaccharide (Fuca(l-2)Galf}(l-4)GlcNAc) into the carbohydrate binding site and a comparison with the binding sites of other legume lectins revealed the role of a Tyr in the variable loop and an Asn in the second loop that are unique to WBAII in generating this unique binding property. Earlier work on peanut lectin and WBAI demonstrated that the modes of dimerisation of legume lectins are governed by features intrinsic to the protein. A phylogenetic analysis of the sequences of all legume lectins whose structures are available has been performed to examine the relationship among the various classes of oligomers and classes of sugar specificity. The information thus obtained showed that groups of legume lectins that share a common mode of dimerisation cluster together. A sequence alignment based on structures revealed amino acid residues unique to each of these clusters that may be important in determining the modes of observed dimerisation. While pursuing structural studies on WBAI and WBAII, the author has also been involved in an ongoing small molecule project in the laboratory, which involves preparation and X-ray structure determination of the complexes of carboxylic acids with amino acids and peptides. The work carried out in the project is described in the appendix.

Plant Morphology

Lectins

WBAI

WBAII

Galectins

S-Lectins

Pentraxine

Tachylectins

Structural, Biophysical And Biochemical Studies On Mannose-Specific Lectins

Gupta, Garima

07 1900

For a long time, the scientific community underestimated the value of carbohydrates and the approach of most scientists to the complex world of glycans was apprehensive. The scenario, however, has changed today. With the development of new research tools and methodologies the study of carbohydrates and glycoconjugates has progressed rapidly, increasing our understanding of these molecules. Carbohydrates are most abundant amongst biological polymers in nature and vital for life processes. In their simplest form, they serve as a primary source of energy to most living organisms. In generalis, they exist as complex structures (glycans), and as conjugates of protein (glycoproteins, proteoglycans), lipids (glycolipids) and nucleosides (UDP-Glucose). Defined in the broadest sense, the study of glycans in all their forms and their interacting partners is termed “Glycobiology”. Glycans are ubiquitously found in nature decorating cells of almost all types with a “sugar coat”. They are also present within the cytoplasm, as well as in the extra-cellular matrix. They have key roles in a broad range of biological processes, including signal transduction, cell development and immune responses. All living organisms have evolved to express proteins that recognize discrete glycans and mediate specific physiological or pathological processes. One major class of such proteins is “Lectins”. Found in all forms of life, they are characterized by their ability to recognize carbohydrates. They are proteins of non-immune origin that bind glycans reversibly with a high degree of stereo-specificity in a non-catalytic manner. It must be emphasized that they are a different class from glycan-specific antibodies. Lectins were first discovered in plants and a large amount of work has been carried out on plant lectins to decipher their structural organization, mode of interaction with substrate and as models to study protein stability and folding. Study on animal and microbial lectins, on the other hand, gathered momentum only recently. In spite of this, more is known about their function in animals and micro-organisms rather than in plants. Lectin-glycan binding is implicated in several important biological processes such as protein folding, trafficking, host-pathogen interactions, immune cell responses and in malignancy and metastasis. Most lectins have one or more carbohydrate recognition domains (CRDs) which often share either 3-D structural features or amino acid sequence. New members of a family can be identified using either sequence or structural homology. Interestingly, it turns out that several plant and microbial lectins have structural or sequential similarity with animal lectins , revealing that these CRDs are evolutionarily related. This thesis, entitled “Structural, Biophysical and Biochemical Studies on Mannose-specific Lectins”, focuses on three lectins, Banana lectin (Banlec), Calreticulin (CRT) and Peptide-N-Glycanase (PNGase). Although all three lectins have distinct biological functions, they share a common ligand specificity at the monosaccharide level i.e. mannose. This thesis, besides characterizing these lectins, studies in detail, the difference in the mode of interaction with their ligands. Chapter 1 is a general introduction on lectins, glycan-lectin interactions and the various techniques that are employed to characterize these interactions. Several principles have emerged about the nature of glycan–lectin interactions. It has been observed that the binding sites for low molecular weight glycans are of relatively low affinity (Kd values in the high micromolar to low millimolar range). Selectivity is mostly achieved via a combination of hydrogen bonds and by van der Waals packing of the hydrophobic faces of monosaccharide rings against aromatic amino acid side chains. Further selectivity and enhanced affinity can be achieved by additional contacts between the glycan and the protein. It is notable that the actual region of contact between the saccharide and the polypeptide typically involves only one to three monosaccharide residues. As a consequence of all of the above, these lectin-binding sites tend to be of relatively low affinity, although they can exhibit high specificity. It is intriguing to observe that such low-affinity sites have the ability to mediate biologically relevant interactions. There are many different ways to study binding of glycans to proteins, and each approach has its advantages and disadvantages in terms of thermodynamic rigor, amounts of protein and glycan needed, and the speed of analysis. In examining these interactions, two broad categories of techniques are applied: (1) kinetic and near-equilibrium methods, such as titration calorimetry; and (2) non-equilibrium methods such as glycan microarray screening and ELISA-based approaches. Two of the most widely used biophysical approaches for examining glycan-lectin interactions at the molecular level are X-ray crystallography and nuclear magnetic resonance (NMR). However, as small molecules often co-crystallize with a lectin better than large molecules, a lot of our knowledge about glycan–lectin interactions at the atomic level is based on co-crystals of lectins with unnatural ligands. Thus, a great challenge exists in attempting to understand glycan–lectin interactions in the context of natural glycans present as glycoproteins, glycolipids, or proteoglycans. Chapter 2 introduces Banana lectin and describes the stability studies carried out. The unfolding pathway of Banlec was determined using GdnCl induced denaturation. Analysis of isothermal denaturation provided information on its conformational stability and the high values of ΔG of unfolding at various temperatures indicated the strength of inter-subunit interactions. It was found that Banlec is a very stable protein and denatures only at high chaotrope concentrations. The basis of the stability may be attributed to strong hydrogen bonds at the dimeric interface along with the presence of water bridges. This is a very unique example in proteins where subunit association is not a consequence of the predominance of hydrophobic interactions. High temperature molecular dynamics simulations have been utilized to monitor and understand early stages of thermally induced unfolding of Banlec. The present study investigates the behavior of the dimeric protein at four different temperatures. The process of unfolding was monitored by monitoring the radius of gyration, the rms deviation of each residue, change in relative solvent accessibility and the pattern of inter- and intra-subunit interactions. The overall study demonstrates that the Banlec dimer is a highly stable structure, the stability in most part contributed by interfacial interactions. The pattern of hydrogen bonding within the subunits and at the interface across different stages has been analyzed and has provided the rationale for its intrinsic high stability. In Chapter 3 the conformational and dynamic behaviour of three mannose containing oligosaccharides, a tetrasaccharide with α1→2, and α1→3, and a penta- and a heptasaccharide with α1→2, α1→3, and α1→6 linkages has been evaluated. Molecular mechanics, molecular dynamics simulations and NMR spectroscopy methods were used for evaluation. It is found that they display a fair amount of conformational freedom, with one major and one minor conformation per glycosidic linkage. The evaluation of their recognition by Banlec has been performed by STD NMR methods and a preliminary view of their putative interaction mode has been carried out by means of docking procedures. In Chapter 4 the conformational behaviour of three mannose containing oligosaccharides, namely, the α1→3[α1→6] trisaccharide, the heptasaccharide with α1→2, α1→3, and α1→6 linkages and the tetrasaccharide consisting of α1→3 and α1→2 linkages, when bound to Banlec has been evaluated by trNOE NMR methods and docking calculations. It is found that the molecular recognition event involves a conformational selection process, with only one of the conformations, among those available to the sugar in free state, being recognised at the lectin binding site. It is known that many proteins, including members of the Jacalin-related lectin family (of which Banlec is a member), bind the high-mannose saccharides found on the surface of the HIV-associated envelope glycoprotein, gp120, thus interfering with the viral life cycle, potentially providing a manner of controlling a variety of infections, including HIV. These proteins are thought to recognize the high-mannose type glycans with subtly different structures, although the precise specificities are yet to be clarified. This study was carried out to gain a better understanding of these protein-carbohydrate recognition events. Chapter 5 reports interactions of Calreticulin (CRT) with the trisaccharide Glcα1-3Manα1-2Man. Previously in our laboratory it was established using modeling studies the residues in CRT important for sugar binding. Here, the relative roles of Trp-319, Asp-317 and Asp-160 for sugar binding have been explored by using site-directed mutagenesis and isothermal titration calorimetry (ITC). Residues corresponding to Asp-160 and Asp-317 in calnexin (CNX) are known to play important roles in sugar binding. The present study demonstrates that Asp-160 is not involved in sugar binding, while Asp-317 plays a crucial role. Further, it is also validated that hydroxyl-pi interactions of the sugar with Trp-319 dictate sugar binding in CRT. This study defines further the binding site of CRT and also highlights its subtle differences with that of CNX. Additionally, mono-deoxy analogues of the trisaccharide unit Glcα1-3Manα1-2Man have been used to determine the role of various hydroxyl groups of the sugar substrate in sugar-CRT interactions. Using the thermodynamic data obtained by carrying out ITC of CRT with these analogues, it is demonstrated that the 3-OH group of Glc1 plays an important role in sugar-CRT binding, whereas the 6-OH group does not. Also, the 4-OH, 6-OH of Man2 and 3-OH, 4-OH of Man3 in the trisaccharide are involved in binding, of which 6-OH of Man2 and 4-OH of Man3 have a more significant role to play. Therefore, the interactions between the substrate sugar of glycoproteins and the lectin chaperone CRT are further delineated. Chapter 6 introduces Peptide-N-Glycanase (PNGase) and delineates the various interactions involved in the binding of oligomannose structures of glycoproteins to the C-terminal domain (the carbohydrate recognition module) of PNGase. ITC is used to characterize the interaction to oligosaccharides in terms of affinity, stoichiometry, enthalpy, entropy and heat capacity changes with the mouse PNGase C-terminal domain. Using the thermodynamic data obtained, it was determined that PNGase requires the tri-mannoside moiety of the native glycan on glycoproteins as the basic minimum entity for recognition and binding. Additional mannose moieties on the glycan do not significantly interact with PNGase and therefore no enhancement in binding affinity is observed (unlike CRT) which is in concordance with its role of stripping glycans from misfolded glycoproteins targeted for degradation via the ERAD (Endoplasmic reticulum assisted degradation) pathway. Chapter 7 briefly summarizes all the findings of the research carried out and presents a comparative analysis of the three lectins studied. Appendix A: Protein folding in the ER is assisted by molecular chaperones. Lectin chaperones such as CRT and CNX assist the folding of glycoproteins by their N-linked oligosaccharide chains. Dynamic processing of the original glycan chain of (GlcNAc)2(Man)9(Glc)3 to remove the terminal glucose moieties is essential for accurate folding. Proteins that attain their native conformation are then transported to the Golgi complex for further glycan modifications. In case of aberrant folding the proteins are retrotranslocated into the cytosol, ubiquitinated, deglycosylated and degraded by the proteasome. Peptide-N-glycanase is a cytosolic enzyme that releases N-glycans from glycoproteins and glycopeptides. PNGase is now widely recognized as a major participant in protein quality control machinery for ERAD or the proteasomal degradation of retrotranslocated glycoproteins. It is therefore desirable to synthesize fluorescently labeled glycoprotein substrates which will provide direct understanding of how, when and where, the interaction between the substrate and the enzyme occurs. Towards this goal, cloning of GFP and RFP tagged full length mouse and human PNGase and CRT was carried out which is described in this section.

Lectins

Oligomannosides

Proteins

Glycan-Lectin Interactions

Banana Lectin (Banlec)

Calreticulin (CRT)

Peptide-N-Glycanase (PNGase)

Mannose-Specific Lectins

Biochemistry

Synthèse de néoglycoconjugués et dendrimères glycomimétiques utilisés pour le développement de puces à lectines de type C et leur validation / Synthesis of neoglycoconjugate and glycomimetic clusters used for CLR lectin array development and validation

Didak, Blanka

14 November 2018

Les lectines de type-C (CLR) sont des protéines de liaison au glycane qui reconnaissent les sucres de manière dépendante du Ca2+. Ils ont des rôles divers dans l'organisme humain. Ils sont responsables des interactions et de l'internalisation d'agents pathogènes tels que Candida albicans, Mycobacterium tuberculosis, le VIH ou le virus Ebola. Ils sont également impliqués dans le développement ou la prévention du cancer par la reconnaissance de glycanes spécifiques exprimés à la surface des cellules tumorales.L'importance cruciale est de trouver des ligands pour les CLR qui induiront une réponse immunitaire ou des inhibiteurs pour les lectines impliquées dans la promotion des infections dans l'organisme. L'objectif du réseau IMMUNOSHAPE était d'examiner de près les rôles, les spécificités et les différences entre les CLR et d'essayer de trouver des molécules appropriées pour stimuler la réponse immunitaire. Au cours de cette thèse, les néoglycoprotéines (NGP) contenant des glycodendrons de différentes valences ont été synthétisées. Pour la synthèse ont été utilisés BSA et OVA comme porteurs de protéines sur lesquels sont couplés des composés monovalents et des dendrons avec αMan et Manα1-2Man de trois et neuf valences. Tous les NGP ont été synthétisés par la chimie click avec deux équivalents de glycodendron / BSA. De plus, des NGP avec des glycomimétiques sur la base de fucose et de Manα1-2Man ont été préparés.L'affinité des molécules synthétisées a été analysée avec GLYcoPROFILE, la plateforme technologique développée par GLYcoDiag dans le but de mieux étudier les interactions glycobiologiques. Il a été évalué que tous les composés testés présentaient un effet multivalent fort sur quatre lectines spécifiques du mannose, y compris deux CLR : DC-SIGN et Langerin. La néoglycoprotéine avec 11 dendrons Manaαl-2 Man nonavalés a obtenu la meilleure avidité pour toutes les lectines testées. Les IC50 obtenues pour la Langerine et le DC-SIGN sont respectivement de l’ordre du nanomolaire et picomolaire, c’est une des valeurs les plus faibles obtenues pour ces deux lectines.L'étude des interactions glycobiologiques a été élargie par l'analyse des différences entre les glycanes avec les liaisons O, C et S et leurs interactions avec les lectines. Il a été observé que les C-glycanes n'ont pas le même mode de liaison que les O-glycanes et, par la suite, ne présentent pas le même effet multivalent attendu, que les O-glycanes. Dans le contexte des glycosides, nous montrons que l’O-glucoside présente de meilleures interactions avec les lectines purifiées que le S-glucoside, tandis que le S-galactoside offre une inhibition significativement meilleure entre les kératinocytes humains normaux et les néoglycoprotéines correspondantes. En outre, une étude intéressante a porté sur les interactions entre les thio-sialosides et la sialidase NanA. Cette analyse a montré que la multivalence a un effet important non seulement sur la lectine, mais également sur la liaison de l’enzyme. Les NGP synthétiques thio-sialylés ont mis en évidence un inhibiteur multivalent efficace de l'enzyme NanA.Au final, cette thèse présente des résultats intéressants sur l'influence significative des composés multivalents sur les interactions glycobiologiques entre les glycanes et les lectines ainsi que sur les enzymes. Cette connaissance pourrait être utilisée dans la conception future des vaccins et de leurs adjuvants pour le traitement des infections,du cancer et, en général, pour la formation de la réponse immunitaire. / C-type lectins (CLRs) are glycan binding proteins which recognize sugars in Ca2+ dependent manner. They have diverse roles in human organism. They are responsible for interactions and internalization of pathogens like Candida albicans, Mycobacterium tuberculosis, HIV or Ebola virus. They are also involved in development or prevention of cancer through recognition of specific glycans expressed on surface of tumor cells.The crucial importance is to find ligands for CLRs which will induce immune response or inhibitors for lectins which are involved in promotion of infections in organism. The goal of IMMUNOSHAPE network was to closely examine roles, specificities and differences between CLRs and try to find appropriate molecules for driving immune response. During this thesis, neoglycoproteins (NGPs) containing glycodendrons with different valences were synthetized. For synthesis were used BSA and OVA as protein carriers on which are coupled monovalent compounds and dendrons with αMan and Manα1-2Man in three and nine valences. All NGPs were synthetized with click chemistry with two ratios of glycodendron/BSA. Additionally, NGPs with glycomimetics on the basis of fucose and Manα1-2Man were prepared.The affinity of synthetized molecules was analyzed with GLYcoPROFILE, technology platform developed in GLYcoDiag with the aim of better and more precise investigation of glycobiological interactions. It was evaluated that all tested compounds showed strong multivalent effect on four mannose specific lectins, including two CLRs: DC-SIGN and Langerin. Neoglycoprotein with 11 nonavalent Manα1-2Man dendrons achieved the best avidity for all tested lectins. Obtained IC50 for Langerin and DC-SIGN are of nanomolar and picomolar range respectively, which are one of the lowest values obtained for these two lectins.Studying glycobiological interactions was expanded by analysis of differences between glycans with O-, C- and S-linkage and their interactions with lectins. It was observed that C-glycans does not have the same mode of binding like O-glycans and subsequently, do not show the same expected multivalent effect such as O-glycans. In the context of glycosides, we show that even O-glucoside achieved slithly better interactions with purified lectins in comparison with S-glucoside, S-galactoside provide significantly better inhibition between normal human keratinocytes and corresponding neoglycoproteins in comparison with O-galactoside. Furthermore, interesting study was investigation of interactions between thio-sialosides and sialidase NanA. This analysis showed that multivalency has a strong effect not only on lectin, but also on enzyme binding. Synthetized thio-sialylated NGPs showed as efficient, multivalent inhibitor of NanA enzyme.Altogether, this thesis presents interesting results of significant influence of multivalent compounds on glycobiological interactions between glycans and lectins as well as enzymes. This knowledge could be used in future design of vaccines and their adjuvants for infection and cancer treatment and in general, for shaping immune response.

Néoglycoprotéines

Lectines de type C

Puces à lectines de type C

Glycoimmunologie

Neoglycoconjugate

CLR lectins

CLR lectins arrays

Glycoimmunology

570

Approche multivalente des interactions saccharides - lectines : synthèse de glycoclusters et analyse de la reconnaissance biomoléculaire / Multivalency in carbohydrate-lectins interactions : glycoclusters synthesis and analysis of biomolecular recognition events.

Cecioni, Samy

13 December 2010

L'interaction non-covalente entre un ligand et un récepteur selon un modèle clé-serrure constitue une des bases essentielles de tout système biologique. La présence de multiples clés et serrures sur les biomolécules conduit à des interactions multivalentes. Les lectines sont très fréquemment structurées en homo-multimères et sont donc des cibles de choix pour l'étude des interactions avec des structures multivalentes glycosylées. Ligands et récepteurs multivalents peuvent obéir à plusieurs mécanismes d'association conduisant à des profils thermodynamiques et cinétiques permettant de rationnaliser les améliorations spectaculaires d'affinité souvent observées. L'utilisation de ligands de faible valence et de petite taille permet une présentation contrôlée des sucres au travers d'une structure unique bien définie. Ces glycoclusters sont des plateformes adaptées à l'étude de l'influence de la topologie de la présentation des sucres sur l'interaction. La synthèse de glycoclusters a été optimisée selon une voie convergente de glycosylation puis de couplage par CuAAC permettant la synthèse de structures multi-glycosylées telles que des calix[4]arènes de différentes conformations, des peptoïdes linéaires et cycliques ou encore des porphyrines. Ces ligands ont été évalués par quatre techniques d'analyse des interactions (HIA, ELLA, SPR, ITC) principalement en présence de la lectine PA-IL de Pseudomonas aeruginosa mais également avec la Galectine-1 humaine et la lectine d'Erythrina cristagalli (légumineuse). Des glycoclusters de seconde génération ont été ensuite été préparés avec l'objectif d'optimiser les composantes enthalpiques et entropiques de l'interaction. Les résultats indiquent que de légères modifications de la présentation des sucres peuvent induire des mécanismes d'association différents. La conception de structures rigidifiées a révélé des profils thermodynamiques contre-intuitifs qui ont pu être modélisés. Par cette étude, plusieurs ligands ont montré des affinités sans précédent pour la lectine PA-IL. Le meilleur ligand multivalent de première génération a confirmé un potentiel thérapeutique prometteur in vivo. / Following Fischer's “lock-key“ concept, non-covalent interactions between a ligand and its receptor is one of the most fundamental process of any biological system. The presence of multiple keys and locks at the surface of many biomolecules leads to multivalent interactions. Lectins are appropriate partners for the study of multivalent interactions with multivalent glycoconjugates since lectins are generally organized as homomultimers. Association of ligands and receptors can occur through several mechanisms leading to distinct thermodynamic and kinetic patterns. Thermodynamic and kinetic parameters often rationalize the impressive affinity improvement observed in the context of multivalent interactions. Small and low valency multivalent ligands provide a neat organization of carbohydrates through a single well-defined structure. These glycoclusters are appropriate probes for studying the influence of the overall topology on the interaction. Glycocluster synthesis was optimized according to a convergent strategy consisting of a glycosidation reaction followed by multiple CuAAC couplings. This strategy yielded a library of glycoclusters based on conformers of calix[4]arenes, linear and cyclic peptoids and porphyrins scaffolds. Glycoclusters were evaluated thanks to a combination of four biochemical techniques (HIA, ELLA, SPR, ITC) mainly versus PA-IL, a tetrameric lectin from Pseudomonas aeruginosa. Further investigations of these ligands were performed with a plant lectin from Erythrina cristagalli and with human galectin-1. Second generation glycoclusters were prepared in order to optimize enthalpic and entropic contributions to the interaction. Results indicate that a slight modification of the glycocluster topology could induce different mechanisms. The design of glycoclusters with stiffened linkers highlights unexpected entropic patterns. Molecular modeling of these linkers provided rationalization of these entropic patterns on the basis of Boltzmann distribution. This work present glycoclusters with an unprecedented affinity for PA-IL. The best first generation glycocluster confirmed promising therapeutic potentialities in vivo.

Interactions protéine – sucre

Multivalence

Glycochimie

Click-Chemistry

Glycoclusters

Pseudomonas aeruginosa

Lectins

Thermodynamic

Topology

Protein-carbohydrate interactions

Multivalency

Glycochemistry

Click-Chemistry

Glycoclusters

Pseudomonas aeruginosa

Lectins

Thermodynamic

Topology

540

Biochemical and biological characterization of lectins, hemagglutinin and antifungal proteins from seeds. / CUHK electronic theses & dissertations collection

January 2010

Lectins and hemagglutinins are carbohydrate binding proteins present in a diversity of organisms including humans, vertebrate and invertebrate animals, plants, fungi, and bacteria. They are usually the abundant storage proteins in leguminous plants. They display a host of biological activities such as antitumor, antifungal, antiviral, insecticidal, and antibacterial activities. / The biological properties of isolated proteins, including hemagglutinating, antifungal, anti-tumor and HIV-1 reverse transcriptase inhibitory activities, were examined. Their biochemical and biological properties were compared with other purified proteins. / The seeds contain an abundance of proteins, some of which are storage proteins but may play a role of protection from pathogenic microbes and phytophagous insects. Antifungal peptides/proteins, antiviral proteins, ribosome-inactivating proteins, proteinase inhibitors, chitinases, proteinases, and defensins, are some examples of the myriad of seed proteins. The aforementioned proteins are collectively called plant defense proteins in view of their antipathogenic activities. These antifungal proteins exhibit a wide range of molecular masses and amino acid sequences. / Two lectins with potentially exploitable activities were purified from Capparis spinosa seeds and Hibiscus mutabilis seeds, respectively. A hemagglutinin was isolated from Phaselous vulgaris , cultivar "French bean 35", and detailed apoptotic pathway in breast cancer cells, MCF-7 cells, was investigated. A novel dimeric beta-lactoglobulin-like antifungal protein and an antifungal amidase were purified from Passiflora edilus seeds and Peltophorum pterocarpum, respectively. / Lam, Sze Kwan. / Adviser: Tsi Bun Ng. / Source: Dissertation Abstracts International, Volume: 72-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 188-204). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Plant lectins

Plant proteins

Seed proteins

Hemagglutinins

Hélicènes et architectures polyaromatiques soufrés et glycosylés : applications en nanoscience et en biologie

Peresutti, Romain

19 December 2011

Les composés polyaromatiques polysoufrés représentent une classe de molécules peu étudiées, malgré leurs propriétés intéressantes. La présence du soufre influence les propriétés redox, photophysiques et de complexation. Nous avons préparé une série de ces composés par des réactions de substitution nucléophile aromatique. Ceux-ci peuvent être fonctionnalisés par des unités polyaromatiques, tels que l’anthracène ou le pyrène, ou par des glycosides. Leurs propriétés de luminescence ont été étudiées en particulier sous l’angle de l’émission induite par l’agrégation, où les composés deviennent émissifs lorsqu’ils sont immobilisés en phase solide ou fortement refroidis. Ils permettent également de stabiliser des nanoparticules de fer/platine, où une forte densité d’atomes de soufre divalent joue un rôle important en nanosciences. Les dérivés glycosylés ont été testés chez différentes lectines comme ConA, PAIL, PAIIL et Bc2lA, les trois dernières étant impliquées dans les infections bactériennes chez les patients atteints de mucoviscidose. Les études comprennent les propriétés photophysiques, de réticulation et des mesures d’affinité par des méthodes biophysiques (SPR, ITC et HIA). Ceci a ammené à la production de nouveaux biocapteurs ou sondes luminescentes basés sur des interactions sélectives lectine-sucre dans l’éventualité future de dispositifs de diagnostics et de détection à partir d’expression de lectines (ex. cancer, infections bactériennes, etc.).Une autre classe de composés polyaromatiques a été étudiée, les hélicènes. Ces molécules hélicoïdales chirales sont retrouvées sous deux formes énantiomériques, selon le pas d’hélice. Nous présentons ici une nouvelle méthode de synthèse des hélicènes par une voie organométallique de réactions d’annulation et d’insertions C-H. Une étude poussée des conditions réactionnelles a été réalisée. Nous avons préparé des hélicènes fonctionnalisés. Les dérivés bromés et cyanés du [5]-hélicène ont été déposés sur la surface de Suzuki, afin d’étudier par nc-AFM les propriétés de structuration de ces produits sur une surface isolante. Le [5]-hélicène a aussi été fonctionnalisé par des unités mannosylés, dans les mêmes perspectives que pour les astérisques soufrés glycosylés. Ces hélicènes glycosylés sont les premiers de la sorte décrit dans la littérature. Ils ont présenté des propriétés convenables vers des sondes luminescentes chirales et d’autres biocapteurs, qui sont basés sur les interactions lectine-sucre. / Polysulfurated polyaromatic compounds represent a class of molecules that are not extensively studied, despite their interesting properties. The presence of sulfur affects their redox, photophysical and complexation properties. We prepared a series of these compounds by using some aromatic nucleophilic substitutions. They can be further functionalized by some polyaromatic units, such as anthracene or pyrene, or by some glycosides.Their luminescence properties have been especially studied for their agregation induced emission properties, where the emission of the compounds is turned on when they are immobilized in solid phase or strongly cooled. These compounds can also be used to stabilize iron/platinum nanoparticles, where a high density of divalent sulfur atoms play an important role in nanosciences. Glycosylated derivatives have been tested with different lectins like ConA, PAIL, PAIIL and Bc2lA, the last three being involved in bacterial infections found in patient suffering from cystic fibrosis. Studies include photophysical and reticulation properties, and also affinitiy assays by using biophysical methods (SPR, ITC, and HIA). It provided some novel biosensors or luminescent sensors based on some selective lectin-carbohydrate interactions, in the event of future diagnostic devices and biological detection originating from lectins expressions (ex. cancer, bacterial infection, etc.).Another class of polyaromatic compounds has been studied, the helicenes,. Those chiral helical molecules can be found under two enantiomeric forms, according to the sense of the helical pitch.We herein present a new synthetic method of helicenes based on an organometallic route for some annulation reactions and C-H insertions. An exhaustive study of reaction conditions has been performed. We have prepared some functionnalized helicenes. Brominated and cyanated [5]-helicene derivatives have been deposited on a Suzuki surface, in order to study their structuration properties by nc-AFM on a non conductive surface. [5]-helicene was further functionnalized with some mannosylated units, with the same perspectives as for the glycosylated sulfurated asterisks. Those glycosylated helicenes are the first of their kind described in the literature. They provided some adequate properties toward new chiral and luminescent sensors, as well as other biosensors, which are based on lectin-carbohydrate interactions.

Lectines

Hélicènes

Pseudomonas aeruginosa

Fluorescence

Lectins

Helicenes

Pseudomonas aeruginosa

Fluorescence

Struktura a funkce C-lektinových receptorů NK buněk studovaná pomocí rekombinantní exprese a proteinové krystalografie / Structure and function of C-type lectin NK cell receptors studied by recombinant expression and protein crystallography

Vaněk, Ondřej

January 2010

Department of Biochemistry, Faculty of Science, Charles University in Prague 2010 Structure and function of C-type lectin NK cell receptors studied by recombinant expression and protein crystallography Abstract of Ph.D. thesis Ondřej Vaněk Supervisor: Prof. RNDr. Karel Bezouška, DSc. Natural killer cells (NK cells) were found out for their ability to spontaneously kill certain allogeneic tumour cell lines, without any previous sensitization. NK cells are part of non- adaptive immune response with very short reaction time against pathogens such as viruses, intracellular bacteria, parasites, and they are responsible for elimination of certain tumour cells and thus they are able to fight against malignancy and formation of metastasis. Activity of NK cells is regulated by the balance between activation and inhibitory signals mediated by the NK cell surface receptors. From the structural point of view, the majority of NK cell surface receptors could be classified as the C-type lectin or immunoglobulin-like receptors. One of many C-type lectin subgroups are type II lymphocyte receptors that are expressed on the NK cell surface. This study had two main aims. The first one was to find suitable expression and purification systems for selected C-type lectin receptors of NK cells and the other one was to perform their...

"Purificação, caracterização e estudos estruturais de duas lectinas ligantes de quitina das sementes do gênero Artocarpus" / Purification, Characterization and Structural Studies of Two Novel Chitin-Binding Lectins from the Seeds of Artocarpus Genus

Trindade, Melissa Barbano

29 April 2005

Este trabalho trata da purificação em escala preparativa por técnicas cromatográficas, determinação de seqüência primária parcial, caracterização espectroscópica por dicroísmo circular, fluorescência, infravermelho e investigação de atividades biológicas de duas lectinas ligantes de quitina dos extratos salinos de Artocarpus integrifolia, jaca, e Artocarpus incisa, fruta-pão. Nossos resultados revelaram que as lectinas quitina-ligantes das sementes de jaca e fruta-pão, jackina e frutackina respectivamente, são homólogas entre si, constituindo-se por monômeros de cerca de 14 kDa formados por três subunidades, unidas por pontes S-S. Elas possuem 62% de identidade entre si, são ricas em cisteínas, aminoácidos básicos e serinas e não possuem similares identificadas até o momento, podendo constituir um novo grupo de lectinas na superfamília de lectinas quitina-específicas. Os espectros de dicroísmo circular de jackina e frutackina são similares: ambas são proteínas de estrutura toda-beta, com máximo em torno de 230 nm e mínimo em torno de 214 nm, este último, bastante distorcido por estruturas desordenadas. Os espectros de fluorescência de jackina e frutackina apresentaram máximos de emissão acima de 340 nm, sugerindo que os N-terminais de duas das 3 cadeias de jackina e frutackina (onde os triptofanos estão localizados) estão expostos. Frente a condições extremas de pH e temperatura, monitoradas por CD e fluorescência, observou-se que a estrutura de jackina é vulnerável a pH ácido e termicamente estável. Quanto às atividades biológicas, jackina e frutackina mostraram atividade inibitória de crescimento para Saccharomyces cerevisiae; jackina também mostrou promoção de adesão da linhagem de células de eritroleucemia K562, atividade inibitória para Fusarium moniliforme na concentração de 2,25 mg/mL e atividade hemaglutinante frente a células sangüíneas humanas do sistema ABO e de coelhos, que não foi inibida nem por N-acetilglicosamina, indicando sua preferência por quitina ou seus fragmentos. / This work deals with the preparative-scale purification by chromatographic techniques, the partial primary sequence determination, the spectroscopic characterization by circular dichroism, fluorescence, FT-IR and the investigation of biological activities of two novel chitin-binding lectins from the saline extracts of the seeds of Artocarpus integrifolia, jackfruit, and Artocarpus incisa, breadfruit. Our results revealed that the chitin-binding lectins from jackfruit and breadfruit, jackin and frutackin respectively, are homologous to each other, consiting of monomers of 14 kDa, made up of 3 subunits, linked by S-S bridges. They have 62% of identity between each other; they are rich in cysteines, serines and basic amino acids and they are no homologous to any other known protein, probably constituting a new group of lectins in the chitin-binding lectin superfamily. The CD spectra of jackin and frutackin are similar: both present a beta profile spectra, presenting a maximum about 230 nm and a minimum around 214 nm, this later one, distorted by unordered structures. The fluorescence spectra of jackin and frutackin presented maxima above 340 nm, suggesting that the N-terminals of the 2 up 3 chains of jackin and frutackin (where the tryptophans are) are exposed. Regarding the pH and temperature exposure, monitored by CD and fluorescence, it was observed that the structure of jackin is vulnerable to acid pH and thermally stable. When considered the biological activities, jackin and frutackin presented growth inhibition activity towards Saccharomyces cerevisiae; jackin also promoted the adhesion of the erythroleukemic cell line K562, presented growth inhibition activity towards Fusarium moniliforme at 2,25mg/mL and hemaggluting activity towards rabbit and human red cells from the system ABO, that was not inhibited even by N-acetilglucosamine, suggesting itspreference by oligomers of N-acetilglicosamine or chitin.

antifungal activity

Artocarpus

Artocarpus

atividade antifúngica

chitin-binding lectins

dicroísmo circular

homologia

lectinas ligantes de quitina

Modulação da expressão de galectina-3 frente às pressões seletivas de pH e oxigenação: um mecanismo para a heterogeneidade intratumoral? / Modulation of galectin-3 expression regarding to pH and oxygenation selective pressures: a mechanism for intratumoral heterogeneity?

Cardoso, Ana Carolina Ferreira

31 October 2014

A heterogeneidade intratumoral é um fenômeno extremamente importante para entender a progressão tumoral e a resposta à intervenção terapêutica. A galectina-3 pertence à família das lectinas, possuem a função de reconhecimento e ligação à ?-galactosídeos ramificados de glicolipídeos e glicoproteínas, e está envolvida em processos fisiológicos e patológicos como o câncer. Nesse trabalho, a heterogeneidade intratumoral em relação à expressão de galectina-3 foi observada em amostras de diferentes lesões melanocíticas de pacientes. Além disso, o inóculo de células de melanoma murino negativas para galectina-3 em animais gal3-/- gerou tumores constituídos por uma fração de células tumorais que passaram a expressar de novo galectina-3, sugerindo que pressões do microambiente tumoral modulam a expressão dessa lectina em melanomas. A acidose extracelular atuou como regulador negativo de galectina-3 in vitro, diminuindo a expressão dessa lectina tanto em células de melanoma murino e humano quanto em melanócito murino. Entretanto, a hipóxia, seja pela exposição aguda ou intermitente, não alterou a expressão in vitro de galectina-3 em células de melanoma humano. Por fim, tumores originados pelo inóculo de células tumorais positivas e negativas para galectina-3 (mimetizando tumores heterogêneos) obtiveram a maior taxa de crescimento tumoral comparados aos tumores constituídos por uma única população de células, seja positiva ou negativa para galectina-3. Portanto, foram apresentadas evidências de que a heterogeneidade intratumoral em relação à galectina-3 parece estar envolvida com o sucesso evolutivo do melanoma e que a acidose é indicada como uma das pressões microambientais que contribuem para o estabelecimento e manutenção da fração de células tumorais negativas para galectina-3 dentro da massa tumoral / The intratumoral heterogeneity observed in human tumors is extremely important to understand tumor progression and its therapeutic response. Galectin-3 belongs to animal lectin family and it is a ?-galactosidase binding protein which is involved in physiological and pathological processes, including cancer. In this work, an intratumor heterogeneous galectin-3 expression was observed in tissue sessions containing different human melanocytic lesions. Moreover, negative galectin-3 murine cells injected into gal3-/- mice were able to generate tumors composed of a positive galectin-3 cell fraction, suggesting that selective forces in tumor microenvironment modulate galectin-3 expression in melanoma. Extracellular acidosis acts as a negative regulator to galectin-3 in vitro, decreasing its expression in murine and human melanoma cells and even in murine melanocytes. However, intermittent or acute hypoxia exposure did not alter galectin-3 expression in human melanoma cells in vitro. In addition, tumors originated from a mixture of positive and negative galectin-3 cells (mimicking heterogeneous tumors) showed higher growth rate compared to those derived from only galectin-3 positive or negative cells. Therefore, we showed evidences that galectin-3 intratumoral heterogeneity seems to be involved with the evolutionary success of melanoma and that acidosis may be the microenvironmental pressure responsible for the establishment and maintenance of galectin-3 negative cell fraction into the tumor bulk

Acidose

Acidosis

Galectin-3

Galectina-3

Hipóxia

Hypoxia

Lectinas

Lectins

Melanoma

Melanoma