Molecular properties of #alpha#-galactosidasis from Vicia faba and Aspergillus giganteus

Ochugboju, Sheila Kaka

January 1996

No description available.

572

Legume lectins; EL enzyme; Favin

Isolation and characterisation of a galactose-specific lectin from maturing seeds of lonchocarpus capassa and molecular cloning of the lectin gene

Masingi, Nkateko Nhlalala

January 2010

Thesis (M.Sc. (Microbiology)) -- University of Limpopo, 2010 / A 29 kDa lectin that shows specificity for galactose was isolated from Lonchocarpus capassa seeds by a combination of ammonium sulphate precipitation and affinity chromatography on a galactose-sepharose column. The 29 kDa lectin subunit co-purified with a 45 kDa subunit. The N-terminal sequence of the 29 kDa subunit showed homology to other legume lectins while that of 45 kDa subunit was capped. A 360 bp fragment was amplified using degenerate primers designed from internal protein sequences of the 29 kDa subunit and a 5´ RACE system primer. The cDNA fragment was cloned into pTz57R/Tvector and transformed into E. coli. The partial amino acid sequence of the lectin subunit was deduced from the nucleotide sequence of the clone. The 360 bp fragment consisted of 342 bp sequence coding for the start codon, leader sequence, N-Terminal sequence and sequences of the 79 amino acids from N-terminus. Comparison of the deduced amino acid sequence with other legume lectins showed regions of sequence homology with precursor sequences of Robinia pseudoacacia Bark lectin, a non seed lectin from Pisum sativum (pea), and the galactose specific peanut agglutinin (PNA) from Arachis hypogaea. Alignment of these sequences showed conserved regions including the metal binding sites found in all legume lectins. The 5´ end DNA sequence was used to design locus-specific primers which were used with genome walking cassette primers in an attempt to amplify the full L. capassa lectin gene. The cassette primers were designed from restriction enzyme sites on the cassette. Of all the restriction enzymes on the cassette Hind III and the L. capassa gene-specific primers amplified 288 bp of the 342 bp sequence already obtained from sequencing of the cDNA sequence with minor amino acid differences. Although the full lectin sequence was not obtained the study confirmed the presence of a galactose-specific lectin in L. capassa seeds.

Legume lectins

Legumes -- South Africa

Food crops

Structural Studies On Basic Winged Bean Agglutinin

Kulkarni, Kiran A

01 1900

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

Structure Analysis Of Plant Lectin Domains

Shetty, Kartika N

04 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 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