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61	Folding Studies On Peanut Agglutinin : A Lectin With An Unusual Quaternary Structure Dev, Sagarika 12 1900 (has links) The thesis entitled “Folding studies on Peanut Agglutinin: A lectin with an unusual quaternary structure” deals with the several aspects of the folding of the tetrameric legume lectin Peanut Agglutinin (PNA). PNA is a well studied legume lectin and several interesting observations regarding its unfolding have been published from our laboratory. The present thesis is an extension of the same work to enrich our knowledge about the folding behaviour of PNA. The thesis describes both experimental as well as theoretical insight on unfolding of PNA. Chapter 1 is a general discussion on lectins. Lectins are carbohydrate binding proteins of non immune source. Lectins are generally found in all type of organisms- plants, animals as well as micro-organisms. Among the plant lectins “legume lectin” is a very well studied system. Legume lectins share a general tertiary structural fold; “jelly roll fold” while they vary in their quaternary structure. Thus they can be considered as “natural mutants” in the context of quaternary structure. The origin of the lectins, structure and sugar specificity have been discussed with emphasis on legume lectin family. Chapter 2 describes the thermodynamics related to the urea induced denaturation of PNA. PNA shows a very interesting unfolding profile, populating one molten globule like intermediate during thermal as well as chaotrope induced denaturation. The molten globule like intermediate loses most of its tertiary structure but retains sufficient secondary structure. Surprisingly, the molten globule like state retains its carbohydrate binding specificity like the native PNA. A model has been developed to fit the chaotrope induced three state denaturation profile of PNA. The model considers the tetramer to dissociate to monomeric intermediate, which in turn dissociates to complete denatured state. All the relevant thermodynamic parameters (∆G, ∆Cp, Tg) associated in the denaturation process have been extracted. The tetramer is found to be ~30 kcal/Mole more stable compared to the intermediate and the intermediate is ~8 kcal/Mole more stable compared to the denatured. The denaturation process has been followed by the changes in hydrodynamic radii by dynamic light scattering (DLS). The profile of change in hydrodynamic radius and the % intensity clearly identify the generation of two species simultaneously. The analysis shows that the intermediate is ~40 % unfolded in nature. Thus this chapter deals with the detailed study of thermodynamics and dynamic light scattering study of the urea induced denaturation of PNA. Chapter 3 deals with the effect of 2, 2, 2 - trifluoroethanol (TFE) on the structure of PNA at two different pH. TFE is a well known co-solvent and is widely used to induce α- helical structure in a protein. The secondary structures induced by TFE are assumed to reflect conformations that prevail during early stages of protein folding. Thus it was quite interesting to notice the structural changes induced by TFE. The effect of TFE has been studied at two different pH- neutral pH of 7.4 and acidic pH 2.5. The  structure of the protein is accentuated in the presence of TFE at low concentration at both the pH. TFE induces α-helical structure from 40 % (v/v) concentration onwards at both the pH. TFE at 15 % concentration induces a molten globule like structure at low pH. The quenching of acrylamide suggests that the protein at low pH and 15 % TFE concentration has a more compact structure compared to the protein at low pH in absence of TFE as well as 6M guanidine hydrochloride (GdnHCl). Further studies of hydrodynamic radii by dynamic light scattering (DLS) also reveal that the protein undergoes some kind of compaction in presence of 15 % TFE at low pH. The induction of this type of molten globule like state at neutral pH has not been observed. Chapter 4 describes the molecular dynamics simulation of deoligomerization of PNA. The native PNA (PDB code 2PEL), excluding any ligand and metal ions has been simulated at 300 K, 400 K, 500 K and 600 K for 500 ps. The overall destabilisation has been followed by root mean square deviation (RMSD), the radius of gyration (Rg) and the solvent accessible surface area (ASA), while the atomistic details are revealed by residue wise RMSD (RRMS), hydrogen bonds and cluster analysis. The protein shows a quite a dramatic change in RMSD and radius of gyration profile at 600 K. RRMS shows that the residues belonging to the loops, mainly in the metal binding site show quite high flexibility. The relative change in average accessible surface area reveals that the primary core of the protein is exposed at 600 K while it is well buried till 500 K. The hydrogen bond analysis clearly shows that with increase in temperature number of hydrogen bonds starts decreasing. Mainly the hydrogen bonds involving side chain interactions are broken. Surprisingly, not all the monomers behave similarly. Monomers C and D are more perturbed compared to monomers A and B. The asymmetry in the interfaces of the monomers may be the key reason for it. The change in the interfaces has been probed by hydrogen bond analysis and cluster analysis. The GSIV type interfaces (A-D and B-C) have been found out to be the most dynamic in nature compared to the other two interfaces. Thus, this chapter reveals the early stage of unfolding of PNA, where perturbation in secondary and tertiary structural level is quite prominent but the interfaces are still holding weakly and are not completely dissociated. Chapter 5 is the continuation of the molecular dynamics simulation on unfolding of PNA, where the effect of metal ions has been illustrated. The monomeric PNA has been simulated to compare its dynamics with the tetramer. The metal binding loop (125-135) becomes unstable and opens up for the monomer even at 300 K after 800 ps. The monomer at 600 K is completely disorganized. The instability of the metal binding loop of the monomer triggers the urge to study the simulation in presence of metal ions (Ca2+ and Mn2+). The monomer bound with metal ions shows steady fluctuation at 300 K. Binding of metal ions seems to bring stability even at 600 K. Surprisingly binding of metal ions to the metal binding site not only stabilises the metal binding loop but also stabilises residues at back beta sheet which are involved in oligomerization. Hence, another simulation of the tetramer at 600 K bound with metal ions has been done. It has been shown that binding of metal ions increases the stability of the protein without altering the denaturation pathway. Appendix A describes a completely different study from PNA. The initial spectral and kinetic characterization of 7, 8- Diaminopelargonic acid Synthase (DAPA Synthase) has been done from Mycobacterium tuberculosis. The DAPA Synthase gene has been cloned earlier in our laboratory and the same has been used for further studies. This is a well known pyridoxal-5′ phosphate (PLP) dependent enzyme, which converts 8- Amino-7-oxopelargonic Acid (KAPA) to 7, 8-Diaminopelargonic Acid (DAPA) in the second step of biotin biosynthesis. DAPA Synthase uses S-adenosylmethionine (SAM) and KAPA as substrate. The first half of the enzymatic reaction has been followed spectroscopically, both by steady state and stopped flow. The enzyme seems to undergo change in conformation as evident from fluorescence and circular dichroism study. The Km value has been determined using bioassay technique. The detailed characterization of the enzyme has been described in this chapter. Lectin - Plants Legume Lectin Peanut Agglutinin - Folding Peanut Agglutinin - Denaturation Protein Folding Peanut Agglutinin (PNA) Plant Physiology
62	Propriedades físico-químicas da lectina KM+ monitoradas por dicroismo circular (CD) e fluorescência. Estimativa do conteúdo de estrutura secundaria por CD / Physico-chemical properties of lectin KM+ monitored by circular dichroism (CD) and fluorescence. Estimative of secondary structure content by CD Rosemeire Aparecida da Silva de Lucca 01 July 1994 (has links) Uma nova lectina extraída da semente de Artocarpus integrifólia, denominada KM+ foi recentemente descrita. KM+ e haptotática para neutrófilos, promove a aglutinação de hemácias dos grupos A, B, 0, estimula a proliferação de linfócitos do baço de camundongos e liga-se em &#945 D-manose, &#945 metil manosidio e &#945 D-glicose. Esta lectina é composta por quatro monômeros, com peso molecular de 13.150 daltons cada, unidos por interações não covalentes. KM+ contem 1,8% de carboidratos e apresentou quatro isoformas com pontos isoelétricos entre 4,2 e 5,2. Este trabalho teve como objetivos estudar modificações estruturais de KM+ em função de parâmetros como temperatura, força iônica, pH, agentes desnaturantes, ligação com D-manose, monitoradas por dicroísmo circular (CD) e fluorescência. CD também foi utilizado para estimar o conteúdo de estrutura secundaria de KM+, utilizando-se dois programas descritos na literatura: SSE (Secondary Structure Estimation), que utiliza o método dos mínimos quadrados para a estimativa da estrutura secundaria e obtenção dos espectros básicos, baseados nos dados cristalográficos de proteínas de .estrutura resolvida; CCA (Convex Constraint Analisys) que utiliza o algoritmo simplex e a partir dos espectros de CD das proteínas de referencia calcula os espectros das componentes básicas. Para a estimativa das frações de estrutura secundária o segundo método utiliza o programa Lincomb. Os espectros de CD foram registrados no intervalo de 185 a 260 nm. O conteúdo em estrutura secundária, estimado pelo programa SSE foi: 0% de &#945-hélice, 41% de folha &#946, 27% de volta &#946 e 32,3 de estrutura desordenada; pelo programa CCA foi: 1% de &#945-hélice, 35% de folha &#946 anti-paralela, 21% de volta &#946 e/ou folha &#946 paralela, 15% de contribuições de aromáticos e/ou ligações dissulfeto, 28% de estrutura desordenada. Os desvios médios quadráticos para os programas SSE e CCA foram 12% e 1%, respectivamente. Portanto a lectina KM+ é principalmente constituída por estruturas tipo folha &#946 e tipo desordenada. A curva calculada pelo programa CCA foi mais bem estimada, pois tem o desvio médio quadrático 12 vezes menor que o do programa SSE. Este resultado, provavelmente ocorre devido aos seguintes fatores: (i) no programa CCA, o espectro da proteína a ser analisada e alinhado com os espectros das proteínas de referência, influenciando no calculo dos espectros básicos; (ii) maior número de proteínas com estrutura &#946 no grupo de referência do programa CCA. A estabilidade de KM+ em função da temperatura tem comportamento diferente em tampão sódio fosfato (PBS) daquele observado em água. Em PBS, quando a amostra esta a 70&#176C, a forma do espectro de CD mostrou-se consistente com um espectro de proteína desnaturada. Comumente, um espectro de proteína desnaturada caracteriza-se pela perda da estrutura secundaria predominante e aumento da estrutura desordenada. Em água, também a 70&#176C, na região da estrutura &#946 (216 nm) surge uma nova banda e na região da estrutura desordenada (195 nm) aparece uma banda com valores positivos mimetizando um espectro da estrutura &#945-hélice. Esta diferença de comportamento pode ser devida à força iônica. A desorganização promovida na molécula de KM+ por cloreto de guanidina foi típica de desnaturação. o máximo da emissão de fluorescência, da KM+ em PBS pH 7,2, foi a 328 nm, característico de resíduos de triptofano protegidos do solvente. Este máximo mudou para 340 nm em pH 10,5. Este resultado indica mudanças no ambiente químico do triptofano neste pH. O deslocamento para a região do vermelho indica, que em pH. os resíduos de triptofano estio em maior contato com o solvente. O número de sitios ligantes de D-manose J)a molécula de KM+, foi estimado pela supressão da fluorescência promovida pelo D-manose. Esta estimativa foi baseada na suposição de que todos os sítios ligantes de D-manose estivessem próximos aos resíduos de triptofano. A relação encontrada foi de 2 moles de D-manose/mol de KM+ / Recently a new lectin, KM+, isolated from Artocarpus integrifolia seeds was described. KM+ induces neutrophil migration, agglutination of human red blood cells, proliferation of mouse spleen cells and binding with monosacharides D-mannose, D-glicose and &#945-metil mannoside. This glycoprotein is composed of four monomers, assembled by non covalent bonds, has 500 aminoacids residues/mol, with a Molecular Weight of 52,000 Daltons and 1.8% of carbohydrates [27]. In this work structural changes of KM+ was studied as a function of temperature, pH, chemical denaturing agents as well as the binding with D-mannose. These changes were monitored by circular dichroism (CD) and fluorimetry. Circular Dichroism (CD) spectroscopy was used for the analysis of the secondary structure of KM+ in solution due do its capacity to indicate the presence and to estimate the proportion of &#945-helix, &#946-sheet, &#946-turn and unordered conformations. This measurent can be regarded as a function of the relative orientation of the chromophores responsible for their chiroptical activity. CD spectroscopy is also one of the methods of choice for monitorization of conformational changes in proteins as a function of solvents, pH, temperature, ionic strength and specific or non specific binding. Two programs which are in use for estimation of secondary structure: SSE, using the linear least squares method and CCA, using the simplex method, were evaluated in the present work. SSE uses a set of proteins with known X-ray data as the basis for evaluation while CCA uses only pure proteins experimental CD spectra. Fluorescence spectroscopy is very useful to monitore of protein conformational changes in solution due to the presence of intrinsic fluorophores. Fluorescence Measurements were performed at 25&#176C. Samples were excited at 280 nm and the emission was monitored in the range 290-450 nm. The maximum emission as a function of pH was at pH 7.0. The wavelength for maximum emission changed from 328 nm at pH 7.0 to 340 nm at pH 10.5. CD spectra were recorded over the range of 185 up to 260 nm. The Secondary structure content estimated by SSE program was: 0% &#945-helix, 41% &#946-sheet, 26% &#946-turn and 32% random with RMS of 12% and CCA program was: 1% &#945-helix, 35% antiparallel &#946-sheet, 21% &#946-turn and/or parallel B-sheet, 28% random, 15% aromatics contributions and dissulfide linkages with RMS of 1%. The fractions of secondary structure obtained when using CCA program were more consistent than those of SSE program. The simulation by CCA program was better probably due to its desconvolution of the spectral contribution of the common secondary structures using experimental CD curves of proteins. The stability of KM+, in PBS, as a function of temperature changes above 55&#176C but only at 70&#176C the shape of the CD spectrum is consistent with the loss of the native ordered secondary structure that should accompany protein unfolding. CD spectra of KM+ in water showed conformational changes as a function of temperature was not consistent with denaturated proteins. The unfolding of KM+ by GdnCl and SDS resulted in CD spectroscopic changes: consistent with the increased random structure and disappearance of beta sheet. Using the two denaturing agents together GdnCl and temperature, the denaturation was observed at lower decreased both GdnCl concentration and at lower temperature. The estimation of the number of binding sites for D-mannose was obtained through the fluorescence intensity decrease due to a quenching effect of D-mannose and showed that the stoichiometry of binding was 2 moles of D-mannoseimol of lectin Dicroismo Circular Estrutura secundaria Fluorescência de lectinas Lectina Lectina CD Circular Dichroism Lectin Lectin fluorescence Lectins CD Secondary structure
63	Structural, Biophysical And Biochemical Studies On Mannose-Specific Lectins Gupta, Garima 07 1900 (has links) (PDF) 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
64	Les interventions thérapeutiques dans les pathologies inflammatoires et le cancer : compréhension des propriétés immunomodulatrices de Viscum album / Therapeutic intervention in inflammatory pathologies and cancer : understanding the anti-inflammatory properties of Viscum album Hegde, Pushpa 26 June 2013 (has links) Les progrès réalisés en immunologie ont orienté les recherches vers des approches et des stratégies de plus en plus prometteuses et innovantes afin de mieux manipuler la réponse immunitaire. Le but de nos recherches est la prévention et le traitement des maladies liées aux dysfonctionnements du système immunitaire, telles que les maladies auto-immunes, inflammatoires et malignes. Bien que l’inflammation constitue un processus physiologique indispensable au maintien de l’homéostasie suite à une infection ou à une lésion, elle est également associée à des pathologies infectieuses, auto-immunes et tumorales. Les stratégies thérapeutiques les plus utilisées pour traiter l’inflammation sont basées sur la neutralisation des médiateurs inflammatoires par des anticorps, des antagonistes moléculaires, des immunoglobulines intraveineuses, des corticostéroïdes, des médicaments anti-inflammatoires non stéroïdiens. En plus des traitements mentionnés, des produits issus de la phytothérapie ont été largement utilisés afin d’atténuer l'inflammation et la douleur dans plusieurs maladies inflammatoires et dans le cancer. Depuis des décennies, les préparations de Viscum album, connu sous le nom de « gui européen », sont largement utilisées dans le traitement du cancer comme thérapie auxiliaire. Bien que les mécanismes d’action soient partiellement connus, plusieurs hypothèses ont été proposées. En effet, les mécanismes anti-tumoraux du Viscum album impliquent des propriétés induisant une cytotoxicité, l'apoptose, l'inhibition de l'angiogenèse et plusieurs autres mécanismes immunomodulateurs. Ce travail décrit un nouveau mécanisme anti-inflammatoire de Viscum album, qui participe à l’effet thérapeutique de ces préparations. De plus, l’effet bénéfique anti-inflammatoire observé est associé à l’inhibition des voies pro- inflammatoires de COX2 et PGE2 dans les cellules épithéliales issues d’adénocarcinome du poumon. Ce travail a identifié un des mécanismes moléculaires de Viscum album associé à son effet anti-inflammatoire participant à ses bénéfices thérapeutiques. Ainsi, ces préparations pourraient être utilisées en combinaison avec d’autres traitements dans des maladies inflammatoires et dans le cancer. / Recent advances in immunology research have led us towards more promising approaches and strategies to manipulate the immune response to prevent or treat the diseases related to immune dysfunction such as autoimmune, inflammatory pathologies and malignant diseases. Although, immuno inflammation is a basal physiological phenomenon required to eliminate the causative agent and to initiate the healing process, it is a physiopathological symptom in a diverse conditions of infectious, autoimmune and tumoral origin. Various therapeutic strategies have been developed in order to reduce inflammation and pain, including the treatment with cytokine neutralizing antibodies, molecular antagonists, intravenous immunoglobulins, corticosteroids, non-steroid anti-inflammatory drugs (NSAID) and several others. In addition to these well known anti-inflammatory therapeutic strategies, treatment with various phytotherapeutics has also contributed enormously to control inflammation and pain, associated with various severe inflammatory disorders and cancer. Viscum album (VA) preparations, commonly known as European mistletoe, are extensively used as complementary therapy in cancer for decades. However the mechanisms of action have been partially understood. Several mutually non-exclusive mechanisms have been proposed such as anti-tumor properties which involve the cytotoxic properties, induction of apoptosis, inhibition of angiogenesis and several other immunomodulatory mechanisms. This study reveals anti-inflammatory mechanism as another important mechanism of action of these phytotherapeutics, which is responsible for their therapeutic benefit and addresses the molecular mechanisms in the pro-inflammatory axis of COX-2 and PGE2 using in vitro experimental model of human lung adenocarcinoma. The present work contributes for a better understanding of mechanisms of action of Viscum album preparations underlying their therapeutic benefit and allows us to revitalize the therapeutic strategies used in treatment of inflammatory disorders and cancer. Viscum Album Médecine complémentaire Médecine alternative Maladies inflammatoires PGE2 Effet anti-inflammatoire Lectin du gui Complementary and alternative medicine Immunomodulation Anti-inflammatory effect Mistletoe lectin
65	Garlic (Allium Sativum) Agglutinin I: Specificity, Binding And Folding Mechanism Bachhawat, Kiran 11 1900 (has links) Lectins are a class of proteins that bind to carbohydrates with a high degree of specificity. They are involved in various cellular processes such as, host - pathogen interactions, targeting of proteins within cells, cell - cell interaction, cellular segregation and development. They serve as important tools for probing the carbohydrate structures in biological systems such as cell membranes and also as model systems for elucidating protein - carbohydrate interactions. Lectins are distributed ubiquitously in nature ranging from microorganisms to the plants and animals. Plant lectins are a group of proteins that according to a recently updated definition comprise all plant proteins possessing at least one non-catalytic domain that binds reversibly to specific mono- or oligosaccharide. The majority of all currently known plant lectins may be classified into four major groups - (1) Legume lectins, (2) Chitin-binding lectins, (3) Type 2 Ribosome inactivating proteins and the (4) Monocot mannose binding lectins. The monocot mannose binding lectins are an extended superfamily of structurally and evolutionarily related proteins. Till now these proteins have been isolated from the following families, namely, Amaryllidaceae, Affiaceae, Araceae, Orchidaceae, Iridaceae and Li/iaceae. They exhibit marked sequence homology and a unique specificity for mannose. At present there is a wide interest in the monocot mannose-binding lectins because of: (1) their exclusive specificity towards mannose, (2) their anti - retroviral activity and (3) their potent entomotoxic properties. Of particular interest are lectins from the bulbs of garlic (Allium sativum) and ramson (A. ursinum), which contain more than one type of lectin. The first report of the presence of lectins in the bulbs of garlic {Allium sativum agglutinin, ASA) was made by Van Damme et al in 1991. Bulbs of garlic are known to accumulate two types of mannose binding lectins, the heterodimeric, ASAI and the hornodimeric, ASAII. Though these two lectins differ in the lengths of their polypeptide chains, they exhibit marked similarities with respect to their primary sequence, post translational modifications, serological properties, immunochemical attributes as well as carbohydrate binding properties. This thesis describes the successful cloning of the ASAI gene from the garlic genomic DNA and expression of the functional recombinant protein in insect cell lines. ASAI was subsequently characterized for its carbohydrate binding specificity by means of a sensitive enzyme based assay. Finer insights into this sugar binding topology of ASAI for its complementary ligands was obtained from the surface plasmon resonance studies. Lastly, the folding behaviour as well as an estimate of its conformational stability was investigated by differential scanning calorimetric and equilibrium solution denaturation studies. Chapter 1 provides a comprehensive review on lectins pertaining to their definition, historical background, occurrence in nature, three dimensional structure and architecture, modes of bonding, biological functions and implications as well as their applications in biomedical research. Chapter 2 describes the isolation and purification of the heterodimeric lectin, ASAI in two steps using affinity chromatography followed by gel filtration chromatography from the bulbs of garlic. The purified ASAI was then characterized for their serological, physico- and immuno-chemical properties by means of capillary electrophoresis, hemagglutination activity and generation of antisera against ASAI in rabbits. Chapter 3 revolves around the cloning of the gene encoding ASAI by PCR amplification from garlic genomic DNA. The authenticity of the ASA gene was established by means of gene sequencing, which in turn provided us with the primary sequence of this lectin. With the ASAI clone established innumerable attempts, as highlighted in the chapter, were made to express the functional protein in bacteria. All attempts yielded pure recombinant garlic lectin with no detectable activity. This prompted us to shift our efforts into expression of the recombinant protein in the baculovirus expression system using the Sf21 insect cell lines and the Autographa californica nuclear polyhedrosis virus (AcNPV). The choice of this system proved beneficial as we obtained functional recombinant garlic lectin with its hemagglutinating activity comparable to the native protein. Chapter 4 highlights the design of an elegant coupled enzyme-based colorimetric assay (Enzyme Linked Lectin Adsorbent Assay) for elucidation of the carbohydrate binding specificity of ASAI. This expansive and extensive study involved the assay of a wide range of mannooligosaccharides in order to gain an insight into the sugar binding details of ASAI. ASAI recognizes monosaccharides in the mannosyl configuration. The potencies of the ligands for ASAI is shown to increase in the following order: Mannobiose < Mannotriose Mannopentaose Man9 oligosaccharide. Mannononase glycopeptide (Man9GlcNAc2Asn), the highest oligomer studied exhibited the greatest binding affinity suggesting ASAI to possess a preference for cluster of terminal αl-2-linked mannosyl residues at the non-reducing end. This kind of exquisite specificity is unique in the lectins described so far. Among the glycoproteins assayed, invertase, soyabean agglutinin and ovalbumin displayed high binding affinity. Chapter 5 unravels the fine specificity of the mannose containing carbohydrate moieties for binding to ASAI with emphasis on their kinetics of binding. This has been achieved by invoking the principle of surface plasmon resonance allowing measurement of bimolecular interactions in real time. This investigation corroborates our earlier study about the special preference of garlic lectin for terminal a α1-2 linked mannose residues. Increase in binding propensity can be directly correlated to the addition of αl-2 linked mannose to the mannooligosaccharide at its non-reducing end. An analyses of these data reveals that the α1-2 linked terminal mannose on the α1-6 arm to be the critical determinant in the recognition of mannooligosaccharides by the lectin. While kI increases progressively from Man3 to Man7 derivatives, and more dramatically so for Man8 and Man9 derivatives, k-1 decreases relatively much less gradually from Man3 to Man9 structures. An unprecedented increase in the association rate constant for interaction with ASAI with the structure of the oligosaccharide ligand constitutes a significant finding in protein-sugar recognition. Chapter 6 deals with the thermal unfolding of ASAI, characterized by differential scanning calorimetry and circular dichroism which shows it to be highly reversible and can be defined as a two-state process in which the folded dimer is converted directly to the unfolded monomers (A2 2U). Moreover, its conformational stability has been determined as a function of temperature; GdnCl concentration and pH using a combination of thermal and isothermal GdnCl induced unfolding monitored by DSC, far-UV CD and fluorescence, respectively. Analysis of these data yielded the heat capacity change upon unfolding (∆CP) as also the temperature dependence of the thermodynamic parameters, namely, ∆G, ∆H, ∆S. The protein appears to attain a completely unfolded state irrespective of the method of denaturation. The absence of any folding intermediates suggests the quaternary interactions to be the major contributor to the conformational stability of the protein, which correlates very well with its X-ray structure. The final chapter summarizes the findings reported in the thesis. Biochemistry Garlic Allium sativum Agglutinin (ASAI) Agglutinin Garlic Lectin Lectins ASAI Gene - Cloning Enzyme-linked Lectin Adsorbent Assay Surface Plasmon Resonance
66	Structural Studies On Basic Winged Bean Agglutinin Kulkarni, Kiran A 01 1900 (has links) The journey of structural studies on lectins, starting with ConA in the 70s, has crossed many milestones. Lectins, multivalent carbohydrate-binding proteins of non-immune origin, specifically bind diverse sugar structures. They have received considerable attention in recent times on account of the realization of the importance of protein-sugar interactions, especially at the cell surface, in biological recognition. They occur in plants, animals, fungi, bacteria and viruses. Plant lectins constitute about 40% of the lectins of known structure. They can be classified into five structural groups, each characterized by a specific fold. Among them, legume lectins constitute the most extensively investigated group. Basic Winged bean lectin (WBAI) is a glycosylated, homodimeric, legume lectin with Mr 58000. The structure of WBAI complexed with methyl-a-galactose, determined earlier in this laboratory, provided information about the oligomeric state and the carbohydrate specificity of the lectin in terms of lectin-monosaccharide interactions. The present work was initiated to understand the carbohydrate specificity of the lectin, especially at the oligosaccharide level, with special reference to its blood group specificity. The hanging drop method was used for crystallizing WBAI and its complexes. Intensity data were collected on Mar Research imaging plates mounted on Rigaku RU-200 or ULTRAX-18 X-ray generators. The data were processed using DENZO and SCALEPACK of HKL suite of programs. The structure factors from the processed data were calculated using TRUNCATE of CCP4 suite of programs. The molecular replacement program AMoRe was used for structure solution. Structure refinement was carried out using the CNS software package. Model building was done using the molecular graphics program O. INSIGHT II, ALIGN, CONTACT and PROCHECK of CCP4 were used for the analysis and validation of the refined structures. WBAI exhibits differential affinity for different monosaccharide derivatives of galactose. In order to elucidate the structural basis for this differential affinity, the crystal structures of the complexes of basic winged bean lectin with galactose, 2-methoxygalactose, N-acetylgalactosamine and methyl-a-N-acetylgalactosamine have been determined. Lectin-sugar interactions involve four hydrogen bonds and a stacking interaction in all of them. In addition, a N-H O hydrogen bond involving the hydroxyl group substituted at C2 exists in the galactose and 2-methoxygalactose complexes. The additional hydrophobic interaction, involving the methyl group, in the latter leads to the higher affinity of the methyl derivative. In the lectin - N- acetylgalactosamine complex the N-H O hydrogen bond is lost, but a compensatory hydrogen bond involving the oxygen atom of the acetamido group is formed. In addition, the CH3 moiety of the acetamido group is involved in hydrophobic interactions. Consequently, the 2-methyl and the acetamido derivatives of galactose have nearly the same affinity for the lectin. The methyl group, a-linked to the galactose, takes part in additional hydrophobic interactions. Therefore, methyl-a- N-acetylgalactosamine has higher affinity than N-acetylgalactosamine to the lectin. The structures of basic winged bean lectin-sugar complexes provide a framework for examining the relative affinity of galactose and galactosamine for the lectins that bind to them. The complexes also lead to a structural explanation for the blood group specificity of basic winged bean lectin, in terms of its monosaccharide specificity. The Tn-determinant (GalNAc-a-O-Ser/Thr) is a human specific tumor associated carbohydrate antigen. Having epithelial origin, it is expressed in many carcinogenic tumors including breast, prostate, lung and pancreatic cancers. The crystal structure of WBAI in complex with GalNAc-a-O-Ser (Tn-antigen) has been elucidated, in view of its relevance to diagnosis and prognosis of various human cancers. The Gal moiety occupies the primary binding site and makes interactions similar to those found in other Gal/GalNAc specific legume lectins. The nitrogen and oxygen atoms of the acetamido group of the sugar make two hydrogen bonds with the protein atoms whereas its methyl group is stabilized by hydrophobic interactions. A water bridge formed between the terminal oxygen atoms of the serine residue of the Tn-antigen and the side chain oxygen atom of Asn128 of the lectin increase the affinity of the lectin for Tn-antigen compared to that for GalNAc. A comparison with the available structures reveals that while the interactions of the glyconic part of the antigen are conserved, the mode of stabilization of the serine residue differs and depends on the nature of the protein residues in its vicinity. The structure provides a qualitative explanation for the thermodynamic parameters of the formation of the complex of the lectin with Tn-antigen. Modelling studies indicate the possibility of an additional hydrogen bond with the lectin when the antigen is part of a glycoprotein. WBAI binds A-blood group substance with higher affinity and B-blood group substance with lesser affinity. It does not bind the O substance. The crystal structures of the lectin, complexed with A -reactive and B - reactive di and tri saccharides, have been determined. In addition, the complexes of the lectin with fucosylated A- and B-trisaccharides and with a variant of the A-trisaccharide have been modelled. These structures and models provide valuable insights into the structural basis of blood group specificities. All the four carbohydrate binding loops of the lectin contribute to the primary combining site while the loop of variable length contributes to the secondary binding site. In a significant advance to the current understanding, the interactions at the secondary binding site also contribute substantially, albeit in a subtle manner, to determine the blood group specificity. Compared to the interactions of the B- trisaccharide with the lectin, the third sugar residue of the A -reactive trisaccharide forms an additional hydrogen bond with a lysine residue in the variable loop. In the former, the formation of such a hydrogen bond is prevented by a shift in the orientation of the third sugar resulting from an internal hydrogen bond in it. The formation of this bond is also facilitated by an interaction dependent change in the rotamer conformation of the lysyl residue of the variable loop. Thus, the difference in the interactions at the secondary site is generated by coordinated movements in the ligand as well as the protein. A comparison of the crystal structure and the model of the complex involving the variant of the A-trisaccharide results in the delineation of the relative contributions of the interactions at the primary and the secondary sites in determining blood group specificity. At the disaccharide level, WBAI exhibits higher affinity for á1-3 linked Gal/GalNAc containing oligosaccharides, compared to that of other á linked oligosaccharides. With an objective of understanding the preferential binding of WBAI for á 1-3 linked Gal/GalNAc containing oligosaccharides, crystal structure of the complexes of the lectin with Galá1-4Gal, Galá1-4GalâEt and Galá1-6Gal have been determined. The reducing sugar of the disaccharides with linkages other than á1-3 binds to the lectin through a water bridge whereas the same sugar moiety with á 1-3 linkage makes direct interactions with the loop L4 of the protein. The modelling study on the complex of the lectin with Galá1-2Gal further upholds this observation. Different structures involving WBAI, reported earlier and presented here, were used to investigate the plasticity of the lectin. The front curved â-sheet, which nestles the metal binding region and on which the carbohydrate binding loops are perched, is relatively rigid. On the contrary, the flat back â-sheet, involved in the quaternary association in legume lectins, is flexible. This flexibility is probably necessary to account for the variation in quaternary structure. With the results presented in this thesis, 14 crystal structures of WBAI, in the free form and in complex with different sugars, have been reported, all from this laboratory. It is now, perhaps, appropriate to examine the new information and insights gained from these investigations, on the structure and function of the lectin. Earlier X-ray studies of WBAI contributed substantially in establishing that legume lectins are a family of proteins in which small alterations in essentially the same tertiary structure lead to large alterations in quaternary association. Structural studies on WBAI, particularly those reported here, also contributed to the elucidation of the nuances of carbohydrate recognition by lectins. A comparative study of the available structures also revealed the flexible and rigid regions of the protein. The study of the influence of covalently linked sugars on the structure of Erythrina corallodendron lectin (ECorL), a homolog of WBAI, is the content of appendix of the thesis. The three-dimensional structure of the recombinant form of Erythrina Corallodendron lectin(rECorL) complexed with lactose, has been elucidated by X-ray crystallography. Comparison of this non-glycosylated structure with that of the native glycosylated lectin reveals that the tertiary and quaternary structures are identical in the two forms, with local changes observed at one of the glycosylation sites(Asn17). These changes take place in such a way that hydrogen bonds with the neighbouring protein molecules in rECorL compensate those made by the glycan with the protein in ECorl. contrary to an earlier report, this study demonstrates that the glycan attached to the lectin does not influence the oligomeric state of the lectin. Identical interactions between the lectin and the non-covalently bound lactose in the two forms indicate, in line with earlier reports, that glycosylation does not affect the carbohydrate specificity of the lectin. The present study, the first of its kind involving a glycosylated protein with a well defined glycan and the corresponding deglycosylated form, provides insights into the structural aspects of protein glycosylation. Plant Lectins Winged Bean Lectin (WBAI) Protein Plant Proteins Lectin Crystallography Legume Lectins Protein Glycosylation Plant Lectins - Structural Biology Winged Bean Agglutinin Biochemistry
67	Cultura de tecidos e transformação genética da cultivar de arroz Irga 426 com o gene da lectina BVL de Bauhinia variegata / Tissue culture and genetic transformation of cv. IRGA 426 with Bauhinia variegata lectin bvl gene Carvalho, Juliana Oliveira de 27 July 2018 (has links) Submitted by Maria Beatriz Vieira (mbeatriz.vieira@gmail.com) on 2018-11-13T12:41:29Z No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) resumo_dissertacao_juliana_oliveira_de_carvalho.pdf: 19466 bytes, checksum: 575be4d4f71c27a4d8e3c7e3d7bacb3a (MD5) / Approved for entry into archive by Aline Batista (alinehb.ufpel@gmail.com) on 2018-11-13T15:59:33Z (GMT) No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) resumo_dissertacao_juliana_oliveira_de_carvalho.pdf: 19466 bytes, checksum: 575be4d4f71c27a4d8e3c7e3d7bacb3a (MD5) / Made available in DSpace on 2018-11-13T15:59:33Z (GMT). No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) resumo_dissertacao_juliana_oliveira_de_carvalho.pdf: 19466 bytes, checksum: 575be4d4f71c27a4d8e3c7e3d7bacb3a (MD5) Previous issue date: 2018-07-27 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / O Rio Grande do Sul é considerado o maior produtor de arroz irrigado do Brasil. Contudo, devido às condições climáticas da região, o potencial produtivo da lavoura de arroz ainda é limitado pela incidência de doenças fúngicas. A utilização de cultivares resistentes ou tolerantes é uma forma alternativa sustentável para reduzir as perdas na produção orizícola. A transformação genética, aliada a cultura de tecidos, vem auxiliando os programas de melhoramento vegetal na geração de plantas resistentes e tolerantes a estresses bióticos e abióticos, contribuindo para a sustentabilidade da orizicultura. Lectinas são proteínas que se ligam a carboidrados e estão envolvidas em diferentes processos biológicos, inclusive na defesa de plantas contra diversos tipos de patógenos. Desta forma, o objetivo do presente trabalho foi introduzir o gene da lectina bvl de Bauhinia veriegata em diferentes explantes da cultivar IRGA 426 a fim de se obter plantas transformadas geneticamente com o gene bvl. Para a obtenção das plantas transformadas foram usados calos organogênicos, mesocótilos e a técnica de transformação de botões florais. No experimento para a obtenção de calos via organogênese indireta, o 2,4-D na concentração de 2,0 mg L-1 foi efetiva, induzindo uma média de 47,3 calos, sendo 89% calos organogênicos aptos para à regeneração. Na regeneração dos calos, observou-se a formação média de 12,73 brotações no meio com 0,5 mg L-1 de ANA e 2,5 mg L-1 de BAP. Já na regeneração do mesocótilo, o incremento de BAP no meio de cultivo reduziu diretamente o comprimento das brotações primárias, no entanto esse efeito foi compensado pelo aumento da multiplicação dos explantes, principalmente com 5 mg L-1 de BAP, onde observou-se uma média de 21,16 brotações. Após o processo de infecção com o vetor pH7WGD2::bvl e seleção com antibiótico, os calos da cv. IRGA 426 apresentaram hiperhidricidade e não foram regenerados. Dos mesocótilos que passaram pela transformação, 20,66% sobreviveram ao meio de seleção. A análise de PCR revelou uma eficiência de transformação de 6,35% em relação ao total de brotos e, a partir do Western Blot, confirmou-se que 3 plantas estavam expressando a lectina BVL. No método de transformação imersão floral, em todas as sementes putativamente transformadas o gene gfp estava ativo, sendo observada a expressão transiente. De acordo com os resultados obtidos, os protocolos de regeneração dos explantes foram eficientes. Análises moleculares das plantas transformadas deverão ser realizadas para determinar o número de cópias do transgene no gDNA e o papel da lectina BVL na fisiologia vegetal e defesa da planta de arroz. / Rio Grande do Sul is the largest producer of irrigated rice in Brazil. However, due to the region's climate, the productive potential of crop farms is still limited by fungal diseases. The use of tolerant or resistant cultivars is a sustainable alternative to reduce loss in rice production. Genetic transformation, coupled with tissue culture, has been assisting vegetable breeding in the production of crops resistant and tolerant to abiotic/biotic stress, contributing to the sustainability of rice culture. Lectins are proteins that bind to carbohydrates and are involved in several biological processes, including defense against diseases in plants. The main goal of this study was the insertion of the Bauhinia variegata BVL Lectin gene in different explants of cultivar IRGA 426 to obtain transformed plants with the BVL gene. To obtain the transformed plants, organogenic callus, mesocotyls and flower buds transformation technique were used. In the experiment for obtaining callus through indirect organogenisis, 2,4-D at 2,0 mg L-1 was effective, inducing the formation of an average of 47,3 calluses, of which 89% of embriogenic callus were apt for regeneration. In the regeneration step, an average of 12,73 sprouts in medium with 0,5 mg L-1 of ANA and 2,5 mg L-1 of BAP was observed. In the mesocotyls regeneration, the BAP increment in the growing medium directly reduced the length of primary shoots; however, this effect was compensated by the increse of explant multiplication, mainly with 5 mg L-1 of BAP, where an average of 21,16 sprouts were observed. After infection with the pH7WGD2::bvl vector and antibiotic selection, the callus of cv. IRGA 426 showed hyperhydricity and were not regenerated. Of the mesocotyls that went through transformation, 20,66% survived the selection medium. PCR analysis revealed a transformation efficiency of 6,35% in all sprouts and, through Western Blot, 3 plants were confirmed to express the BVL lectin. In the floral immersion transformation method, in all transformed seeds the GFP gene was active, with transient expression being observed. Based on the results obtained, the explant regeneration protocols were efficient. Molecular analysis of the transformed plants should be made to determine the number of copies of the transgene in gDNA and the role of BVL lectin in the plant physiology and its role in the plant's defense. Fisiologia vegetal Arroz irrigado Lectina BVL Transformação genética IRGA 426 Fungos Plant physiology Bauhinia variegata lectin Irrigated rice Lectin Genetic transformation Fungi
68	Structure Analysis Of Plant Lectin Domains Shetty, Kartika N 04 1900 (has links) (PDF) 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 leading to wide use in research and biomedical applications. Seeds of leguminous plants are mainly rich sources of lectins, but lectins 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. This thesis primarily concerns with structure solution and analysis of lectins from the legume and β-prism II fold families using X-ray crystallography. Apart from having the property of specifically and reversibly binding to carbohydrates, lectins are also interesting models to study sequence-structure relationships, especially of how minor change in the sequence may bring about major changes in oligomerization and binding. Chapter 1 gives an overview of different structural types of plant lectins and describes in detail, their carbohydrate binding features. The details of the various experimental procedures employed during the course of this research, are explained in Chapter 2. Chapter 3 describes the crystal structure of a β-prism II fold lectin (RVL), from Remusatia vivipara, an epiphytic plant of traditional medicinal value, and analysis of its binding properties. This lectin was established to have distinct binding properties and has nematicidal activity against a root-knot nematode with the localization site identified as the high-mannose displaying gut-lining in the nematode. The crystal structure of RVL revealed a new quaternary association of this homodimeric lectin, different from those of reported β-prism II lectins. Functional studies on RVL showed that it fails to bind to simple mannose moieties yet showed agglutination with rabbit blood cells (which have mannose moieties on the surface) and some high mannose containing glycoproteins like mucin and asialofetuin. Further, ELISA and glycan array experiments indicated that RVL has high affinity to N-glycans like trimannose pentasaccharide such as in gp120, a capsid glycoprotein of HIV virus, necessary in virus-association with the host cell. The structural basis for this N-glycan binding was revealed through structure analysis and molecular modelling, and it was demonstrated that there are two distinct binding sites per monomer, making RVL a truly multivalent lectin. Evolutionary phylogeny revealed the divergence in the β-prism II fold proteins with regards to the number of sugar-binding regions per domain, oligomerization and specificity. Chapter 4 deals with the structural studies on a galactose-specific legume lectin (DLL-II) from Dolichos lablab, a leguminous plant. The lectin was found to be a planar tetramer in the crystal structures of the native and ligand bound forms, as expected from our solution studies and phylogenetic analysis. The protein is a heterotetramer with subunits differing only in the presence or absence of a C-terminal helical region at the core of the tetramer. Due to the static disorder in all the crystals, the central helix could be oriented in either direction. Structure analysis of DLL-II proved to be an interesting endeavour as static disorder compounded with twinning in the crystal made the data processing and structure solution a challenging process. Subsequent structure and sequence alignments led to the identification of an adenine-binding pocket in the hydrophobic core of the tetramer. Based on this, DLL-II lectin was co-crystallized with adenine and the structure revealed the presence of adenine at the predicted binding site. Chapter 5 describes the identification and analysis of potential plant lectins/lectin-like domains in the genome of Oryza sativa, using bioinformatics approaches. This project was initiated to study the occurrence of legume-lectin like domains (a predominant dicot feature) in O. sativa, which is a monocot. Later, a large scale genome analysis for all types of lectin domains was carried out through exhaustive PSI-BLAST, profile matching by HMMer, CDD and MulPSSM. The final validation was carried out by assessing the carbohydrate binding potential of the domain by examining the sugar binding sites. The primary interest in undertaking this work was to find the occurrence of association of these domains with other domains as in protein receptor kinases, where lectin is the receptor domain. Though primarily initiated as a bioinformatics project, further structural characterization was attempted by cloning, expression and purification of some of the annotated lectin proteins using prokaryotic expression systems. The protein expression was attained in reasonable amounts for a few of the annotated legume lectin homologs, however purification is yet to be achieved as the expressed proteins are insoluble. A part of the results described in this thesis and the other related projects that the author was involved are reported in the following publications. 1) Purification, characterization and molecular cloning of a monocot mannose-binding lectin from Remusatia vivipara with nematicidal activity Bhat GG, Shetty KN, Nagre NN, Neekhra VV, Lingaraju S, Bhat RS, Inamdar SR, Suguna K, Swamy BM. 2010. Glycoconjugate J. 27(3):309-320 2) Modification of the sugar specificity of a plant lectin: structural studies on a point mutant of Erythrina corallodendron lectin Thamotharan S, Karthikeyan T, Kulkarni KA, Shetty KN, Surolia A, Vijayan M & Suguna K. 2011. Acta Crystallographica D 67(3):218-227 3) Crystal structure of a β-prism II lectin from Remusatia vivipara Shetty KN, Bhat GG, Inamdar SR, Swamy BM, Suguna K. 2012. Glycobiology 22(1): 56-69. 4) Structure of a galactose binding lectin from Dolichos lablab Shetty KN, Lavanyalatha V, Rao RN, SivaKumar N & Suguna K (Under review) 5) Occurrence of lectin-like domains: Oryza sativa genome analysis. Shetty KN & Suguna K. (Manuscript in preparation) Lectins Carbohydrates Proteins Plant Lectins Legume Lectins Beta Prism Lectins (RVL) Galactose-Specific Lectins (DLL) Lectin-like Domains Lectin Domains G25265
69	The lectin pathway of complement activation Krarup, Anders January 2007 (has links) The complement system is an important immune system mechanism involved in both the recognition and elimination of invading pathogens. It is activated by three different pathways: The classical pathway, which relies on binding of C1, and results in the cleavage of C4 and C2 through activation of C1r and C1s; the alternative pathway that relies on the spontaneous hydrolysis of C3 and the lectin pathway. The lectin pathway is activated by binding of Mannan-binding lectin (MBL) or the ficolins (L-ficolin, H-ficolin and M-ficolin) to microbial binding motifs, and the subsequent activation of the MBL-associated serine proteases (MASP) 1/ 2/ 3. Of these MASP2 has been identified as the enzyme responsible for the activation of complement by C4 and C2 cleavage. The work presented here will focus on four different aspects of the lectin pathway: specificity and stoichiometry of the L-ficolin protein complex, expression of H-ficolin, substrate characterization for MASP1 and investigation of the prothrombin activation potential of MASP2. L-ficolin binding specificity was investigated using glycan array technology, and it was found that L-ficolin, instead of recognizing single monosaccharides like MBL, instead binds to extended oligosaccharide structures. The binding to these was dependent not only on the presence of acetyl groups, but also on their orientation in space. It was also found that L-ficolin in serum is found as a multimeric protein complex composed of 18 polypeptide chains and associated with one MASP dimer. The expression of H-ficolin resulted in the generation of a stable mammalian cell line producing oligomerized and biologically functional H-ficolin. MASP1 substrate specificity was investigated by two different procedures. Firstly fractionated plasma was subjected to MASP1 treatment in an attempt to identify a plasma protein substrate. This did not yield any substrate candidates, since only cleavage of the protease inhibitor α-2-macroglobulin could be detected. Additionally the thrombin-like activity of MASP1 was investigated through cleavage experiments done with factor XIII and fibrinogen. These experiments showed that the factor XIII cleavage site for MASP1 and thrombin is identical. This was also found for the fibrinogen β-chain but not for the α-chain showing that MASP1 interaction with fibrinogen is distinct from that of thrombin. An earlier observation that MASP2 was capable of activating prothrombin and generating thrombin was further characterized. Here it was shown that the activation of prothrombin by MASP2 is identical to that by factor Xa, which is the enzyme undertaking this role in the coagulation system, and that the activation can result in deposition of fibrin on the surface upon which MASP2 is bound. The prothrombin activation potential of MASP2 was also utilized to develop a new MASP2 activity assay, which was shown to be capable of measuring MASP2 activity, when MASP2 is bound, via MBL (or L-ficolin) to appropriate surfaces. 571.96
70	Mise au point de nouvelles méthodes de conjugaison oligonucléotide/sucre et développement d'un microsystème d'analyse des interactions lectine/sucre / Development of new methods for carbohydrate/oligonucleotide conjugation and of a microarray to study the lectin/carbohydrate interactions Pourceau, Gwladys 25 November 2010 (has links) Les interactions entre les sucres et les lectines sont généralement l'étape clé dans de nombreux phénomènes biologiques et pathologiques. Malgré leu r importance cruciale, ces interactions sont paradoxalement caractérisées par des constantes d'affinité faibles et nécessite une multiprésentation des motifs saccharidiques pour être significatives. Cette augmentation est appelée "effet cluster". En outre, les techniques d'analyse actuellement utilisées en laboratoire nécessitent des quantités importantes de produits, ce qui est difficilement compatible avec les méthodes de synthèse actuelle. Pour pallier ces difficultés, une approche originale basée sur l'utilisation conjointe de glycooligonucléotide et de puces à ADN a été proposée. Les glycoconjugués basés sur des squelettes phosphodiesters et couplés à des séquences d'ADN ont été synthétisés en utilisant la chimie des oligonucléotides, couplée à la "click chemistry". La séquence d'ADN quant à elle a permis l'ancrage sur une puce à ADN et donc la mesure de leur affinité vis-à-vis de différentes lectines. Ce manuscrit rapporte le développement des nouvelles méthodologies de synthèse des glycooligonucléotides ainsi que la préparation de nombreux glycoconjugués originaux, dont l'affinité pour différentes lectines a été mesurée via l'utilisation de la puce à ADN. L'influence de plusieurs paramètres a été étudiée: le nombre de résidus, l'arrangement spatial, la lipophilie etc. Il s'avère que l'arrangement spatial semble être l'un des points les plus importants dans la mise au point d'un glycoconjugué. / The interactions between carbohydrates and lectins are generally the "key step" in many biological and pathological phenomena. Despite their importance, these interactions are paradoxically characterized by low affinity constants and requires multipresence of saccharide to be significant. This increase is called "cluster effect". In addition, the analysis techniques currently used in the laboratory requires large quantities of products, which is hardly compatible with the current methods of synthesis. To circumvent these difficulties, a original approach based on the combined use of glycooligonucleotides and DNA microarrays has been proposed. Glycoconjugates based on phosphodiester skeletons linked to DNA sequences have been synthesized using the chemistry of oligonucleotides, coupled with the "click chemistry". The DNA sequence has allowed the anchoring on a DNA chip and therefore the measurement of their affinity versus different lectins.This manuscript reports the development of new synthetic methodologies for the glycooligonucleotides synthesis and the preparation of many original glycoconjugates, whose affinity for various lectins was measured through the use of DNA microarray. The influence of several parameters was studied: the number of residues, the spatial arrangement, etc. lipophilicity. The spatial arrangement appears to be one of the most important parameters in the development of a glycoconjugate. Bioconjugaison Oligonucléotide Saccharide Lectine Click chemistry Glycopuce Bioconjugation Oligonucleotide Saccharide Lectin Click chemistry Glycoarray

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