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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Glycosylated green fluorescent protein for carbohydrate binding protein analysis

Martin, Andrew January 2015 (has links)
The interactions of glycoconjugates with carbohydrate binding proteins are responsible for a wide range of recognition events in vivo; including immune response, cell adhesion and signal transduction. Glycoconjugates have already found many medicinal uses as therapeutic and diagnostic agents, but their full potential is yet to be realised. Access to a variety of homogeneously glycosylated glycoproteins is essential for the study of these important carbohydrate binding events. This requires the chemical synthesis and attachment of biologically relevant glycans to unglycosylated protein scaffolds in a site selective manner. Here we describe the use of a range of glycosyl iodoacetamides to glycosylate proteins selectively via their cysteine residues. We have chosen the green fluorescent protein mutant GFPuv for use as a protein scaffold due its known tolerance of two cysteine mutations (E6C and I229C) and the previous successful derivatisation of these cysteines with iodoacetamides.1 The inherent fluorescence of GFPuv also makes it a useful candidate for fluorescence based binding assays or cell labelling studies.16 active, mutants of GFPuv were created using a mixture of site directed mutagenesis and DNA shuffling (including one mutant containing six reactive cysteine residues). This was achieved by producing random combinations of two synthetic variants of GFPuv, one of which contained 33 surface cysteines. 94 bacterial colonies expressing active GFPuv were then sequenced and the new chimeric genes analysed. Four monosaccharides and one trisaccharide (N-glycan core mimic) suitable for the chemical glycosylation via cysteines were synthesised and successfully used to create a selection of homogeneous neoglycoproteins. These neoglycoproteins were demonstrated to interact differently with different lectins (including ConA, GNL and Jacalin) in a qualitative fluorescence based assay. Interactions were shown to vary with glycan structure, position of glycosylation sites and the number of glycosylation sites.
2

Putting the Pieces Together Again: Characterizing Trisaccharides by the Energetics of Their Primary Fragmentation Pathways and Their Ion Mobility

Overton, Sean 10 November 2021 (has links)
Identification of polysaccharides is not a straightforward task due to the high degree of stereochemistry present in their isobaric monomers. Their isobaric nature causes traditional mass spectrometry to fall short when trying to differentiate not only the conformation of the monomers but the position of the glycosidic bonds that bind them. This structural information is important for biochemists as they study the role of different glycans in biological processes. Tandem mass spectrometry (MS/MS) allows the study of the fragment ions formed during collision induced dissociation (CID), the fragments formed depend on the structure and stability of the precursor molecule and can be used to identify the compounds. These fragmentation pathways will be as complex as the species that form them. To date, typical saccharide fragments are separated into three groups that represent the major fragments: Cross-ring cleavages (A/X), and those resulting from cleaving different sides of the glycosidic bond (B/Y) and (C/Z). Ion mobility separation (IMS) has shown to have some success at discerning polysaccharide conformers and those of other biopolymers such as proteins and polynucleotides. Ion mobility separates gas-phase ions by colliding them with non-reactive gases and relating respective increase in flight time to their collision cross-section (CCS). In this study, the relative energetics of the first steps of the cross-ring cleavage and both glycosidic bond cleavage channels for isomaltotriose [glc(α1-6)glc(α1-6)glc] as well as a minor water loss channel were explored using density functional theory (DFT) calculations at the B3LYP/6-31+g(d) level of theory. It was demonstrated that charge-remote mechanisms are a viable alternative to charge-directed mechanisms when under the high energy short time scale conditions present during an ESI-MS/MS experiment. To verify the efficiency of ion mobility for isomeric separation, the relative experimental CCS of isomaltotriose [glc(α1-6)glc(α1-6)glc], maltotriose [glc(α1-4)glc(α1-4)glc], panose [glc(α1-6)glc(α1-4)glc] and raffinose [gal(α1-6)glc(α1-2)fru] were determined by comparison with literature CCS values for dextran, a variable-length oligomer of α1-6 linked glucose was used as an external calibrant. The experimental CCS of the precursor ions were compared to literature values when available as well as the calculated effective values of the optimized DFT geometries using the trajectory method of the MOBCAL computational suite. As phosphate is often used as an adducting agent to increase the intensity of the precursor ion when running an IMS experiment, the effect of its presence on the fragmentation of isomaltotriose and large isomaltooligosaccharides was studied. It was seen that depending on the location of the phosphate ion, it will preferentially dissociate leaving behind a neutral glycan. This explains the low abundance of fragment ions observed when selecting a phosphate-adducted precursor ion during an MS/MS experiment. IMS and MS-MS are complementary methods that can be used to identify monomers within a polysaccharide and how they are bound.
3

Synthesis, Structural and Biophysical Studies of Oligosaccharide Glycolipids and Glycosidic Bond Expanded Cyclic Oligosaccharides

Maiti, Krishnagopal January 2016 (has links) (PDF)
Pathogenesis originating from mycobacterial invasion on host cells is prevalent and is a major challenge in efforts towards overcoming the burden of mycobacterial diseases. Complex architecture of mycobacterium cell wall includes an assortment of glycolipids, phospholipids, glycopeptidolipids (GPLs), peptidoglycans, arabinogalactans, lipoarabinomannans and mycolic acid. Aided by thick cell wall envelope, mycobacteria are known to survive in hostile environment. As most antibiotics target the log phase of the bacteria, bacterial survival is also largely dependent on its stationary phase. Mycobacteria have evolved colonization by means of biofilm formation in the stationary phase, so as to survive under stress and hostile conditions. Biofilms are the specialized form of phenotype which makes bacteria several fold resistant to antibiotics. Development of inhibitors against biofilms remains a challenge due to the poor permeability of molecules and coordination among cells. The first part of Chapter 1 of the thesis describes the details of formation of biofilm in the stationary phase of bacteria and understanding the molecular level details for making the strategies to overcome antidrug resistance of mycobacteria. Among the cyclic hosts, cyclodextrins are prominent. Due to their unique structural and physical properties, cyclodextrins can form inclusion complexes with a wide range of guest molecules. Although synthetic modifications of cyclodextrins through hydroxy groups are very common, modifications at backbone continue to be a challenge. Backbone modified cyclodextrins using different organic moieties were developed and their altered cavity properties were explored in many instances. Chemical synthesis of cyclic oligosaccharides is, in general, involved (i) a cyclo-oligomerization of linear oligosaccharide precursor and (ii) an one-pot polycondensation of appropriately designed monomer under suitable reaction conditions. The second part of Chapter 1 deals with a literature survey of skeletal modification of cyclodextrins, their synthesis and binding abilities with different guest molecules. In my research programme, synthesis and studies of oligosaccharide glycolipids relevant to mycobacterial cell wall were undertaken. Arabinofuranoside trisaccharide glycolipids, containing β-anomeric linkages at the non-reducing ends and double hexadecyloxy lipid moieties, interconnected to the sugar moiety through a glycerol core, were synthesized (Figure 1). Arabinan trisaccharides 1 with lipidic chain and 3 without lipidic chain comprise β-(1→2), β-(1→3) anomeric linkages at the non-reducing end, whereas in the case of arabinan trisaccharides 2 and 4, β-(1→2), β-(1→5) linkages are present between the furanoside units. In the scheme of synthesis of trisaccharide glycolipids, monosaccharide derivative and lipidic portions were individually prepared first and were assembled subsequently to secure the target glycolipids. Incorporation of β-arabinofuranoside linkages in trisaccharide arabinofuranosides 1-4 was achieved by low temperature activation of silyl group protected conformationally locked thioglycoside donor 5 (Figure 1), in the presence of N-iodosuccinimide (NIS) and silver trifluoromethanesulfonate (AgOTf). Figure 1. Molecular structures of trisaccharides 3, 4 and glycolipids 1, 2 with β-arabinofuranoside linkages at the non-reducing end and glycosyl donor 5. Following the synthesis, the efficacies of synthetic glycolipids to interact with surfactant protein A (SP-A) were assessed by using surface plasmon resonance (SPR) technique, from which association-dissociation rate constants and equilibrium binding constants were derived. SP-A, a lung innate immune system component, is known to bind with glycolipids present in the cell surface of a mycobacterial pathogen. From the analysis of SPR studies with glycolipids 1, 2 and SP-A, the association rate constants (ka) were found to be in the range of 0.3 to 0.85 M−1 s−1, whereas the dissociation rate constants (kd) were varied between 2.21 and 3.2×10−3 s−1. The equilibrium constants (Ka) values were in the range of 93 and 274 M−1. Trisaccharides 3 and 4, without lipidic chains, were also assessed for their efficacies to interact with SP-A. The association constants for 3 were found to be in the range of 2,470 to 9,430 M−1, whereas for the derivative 4, Ka values varied between 25,600 and 76,900 M−1. The association and equilibrium binding constants for 3 and 4 were found to be significantly higher when compared to glycolipids 1 and 2. In conjunction with our previous report, the present study shows that arabinofuranoside glycolipids, with β-anomeric linkages bind to SP-A with lesser extent as compared to α-anomers. Further, the studies of trisaccharides and glycolipids in mycobacterial growth and sliding motility assays were performed with model organism M. smegmatis and it was found that the synthetic compounds affected both growth and motility and the extent was lesser than that of α-anomeric glycosides and glycolipids. Chapter 2 of the thesis describes the details of synthesis, biophysical and biological studies of arabinan trisaccharide glycolipids, with β-anomeric linkages at the non-reducing end. Continuing the synthesis and studies of arabinan oligosaccharides, a linear arabinomannan pentasaccharide and heptasaccharide glycolipids 6 and 10, containing α-(1→2) and α-(1→3) linkages between core arabinofuranoside units, as well as, a branched arabinomannan pentasaccharide and heptasaccharide glycolipids 7 and 11, with α-(1→2) and α-(1→5) linkages between core arabinofuranoside units, were synthesized (Figures 2 and 3). Figure 2. Molecular structures of arabinomannan glycolipids 6 and 7 and the corresponding oligosaccharides 8 and 9. In addition to glycolipids, arabinomannan pentasaccharides without lipidic chain 8 and 9 and arabinomannan heptasaccharides without lipidic chain 12 and 13, were also synthesized. Synthesis was performed using trichloroacetimidate and thioglycosides as glycosyl donors. A block condensation methodology was adopted by which disaccharide donor and monosaccharide acceptor were chosen to assemble the pentasaccharide, by a two-fold glycosylation. Monosaccharide acceptors with and without lipidic chain were used in the glycosylations for the synthesis of glycolipids and pentasaccharides, respectively. Similarly, a trisaccharide thioglycoside donor and monosaccharide acceptors were chosen for the double glycosylation to synthesize heptasaccharides in the presence of NIS and AgOTf. Figure 3. Molecular structures of arabinomannan heptasaccharide glycolipids 10, 11 and corresponding heptasaccharides 12 and 13. Subsequent to synthesis, activities of pentasaccharide glycolipids were assayed on M. smegmatis bacterial growth, sliding motilities and also the effects on mycobacterial biofilms. Profound effects were observed with the synthetic compounds, to reduce the mycobacterial growth, sliding motilities and biofilm structures. Whereas reduction up to ~50% occurred on mycobacterial growth, as much as, 70% reduction in the motilities of the bacteria was observed in the presence of the synthetic glycolipids, at 100 µg mL-1 concentration. At the same concentration, 80–85% reduction in the biofilm was observed. These effects were more pronounced with branched glycolipids than linear analogues. Chapter 3 of the thesis presents the synthesis of linear and branched arabinomannan penta- and heptasaccharide glycolipids and biological studies of arabinomannan pentasaccharide glycolipids with M. smegmatis. Cyclodextrins, the most abundant naturally-occurring cyclic oligosaccharides, are valuable synthetic hosts, primarily as a result of their properties to form inclusion complexes with guest molecules. In spite of voluminous literature on the application of cyclodextrins, through modifications of hydroxy groups, modifications at the backbone continue to be a challenge. Skeletal modifications using aromatic, triazole, diyne, thioether and disulfide moieties were developed, that helped to alter the cavity properties of cyclodextrins. A programme was undertaken to synthesize backbone modified cyclic oligosaccharide, which was achieved using a monomer wherein a one carbon insertion is conducted at C4 of a pyranose, such that the hydroxy moiety at C4 is replaced with a hydroxymethyl moiety. In an approach, a linear trisaccharide monomer was anticipated to provide cyclic oligosaccharides in multiples of such a monomer. In the event, a trisaccharide linear monomer 14 was found to afford a cyclic trisaccharide macrocycle 15, as the major cyclo-oligomer (Scheme 1). Subsequent solid state structural studies show that the molecule confers a perfect trigonal symmetry in the P3 space group, in a narrow cone shape and a brick-wall type arrangement of molecules, such a geometry is hither-to unknown to a cyclic oligosaccharide (Figure 4). Furthermore, binding abilities of cyclic trisaccharide with few organic bases, such as 1-aminoadamantane and hexamethylenetetramine, was evaluated by the means of isothermal titration calorimetry and it was found that such a cyclic trisaccharide exhibits strong binding affinities towards 1-aminoadamantane in aqueous solutions, as compared to the same with naturally-occurring β-cyclodextrin. Scheme 1 Apart from cyclic trisaccharide, synthesis of cyclic tetrasaccharide 17, containing alternative anomeric α-(1→4) and β-(1→4) linkages was also undertaken by one-pot cyclo-oligomerization in the suitable reaction condition, from an activated disaccharide thioglycoside monomer 16, having β-(1→4) linkage at the non-reducing end (Scheme 2). Chapter 4 describes the synthesis of cyclic oligosaccharides 15 and 17, as well as, the details of solid state structure and binding studies of cyclic trisaccharide 15. Scheme 2 Figure 4. (a) Stick model of the crystal structure of 15, as viewed along the crystallographic c-axis; (b) trigonal view from crystal packing; (c) packing diagram crystal lattice, as viewed along the crystallographic b-axis, and without solvent inclusion and (d) packing diagram included with methanol (grey) and water (red) solvents, as viewed along the crystallographic c-axis. Hydrogen atoms are omitted for clarity in (c and d). In summary, the thesis presents (i) synthesis, biophysical and biological studies of synthetic arabinan and arabinomannan glycolipids, and (ii) synthesis, solid-state structural analysis and binding studies of glycosidic bond expanded cyclic oligosaccharides. Synthetic trisaccharide arabinofuranoside glycolipids containing β-anomeric linkages at the non-reducing end showed binding affinity towards pulmonary surfactant protein A, as assessed by surface plasmon resonance technique, with comparatively lower extent as compared to synthetic glycolipids having α-anomeric linkages. Linear and branched arabinomannan penta- and heptasaccharide glycolipids, having α-anomeric linkages were synthesized and biological studies with non-pathogenic strain M. smegmatis were conducted with pentasaccharide glycolipids. It was found that arabinomannan glycolipids inhibited the growth and sliding motility of mycobacteria. Importantly, disruption of biofilm and significant reduction in biofilm formation was observed in the presence of the synthetic glycolipids. Glycosidic bond expanded cyclic trisaccharide with anomeric α-(1→4) linkages and cyclic tetrasaccharide with alternative anomeric α-(1→4) and β-(1→4) linkages were prepared from suitably designed trisaccharide and disaccharide monomer, respectively, by cyclo-oligomerization. Solid-state structural analysis and binding studies of cyclic trisaccharide in solution by isothermal titration calorimetry were also conducted. Cyclic trisaccharide possessed a bowl shape and brick-wall type of arrangement in the solid-state structure, whereas it exhibited stronger binding affinity towards 1-aminoadamantane as compared to β-cyclodextrin in aqueous solution. Overall, the results presented in the thesis provide a possibility to develop new types of synthetic glycolipids that can act as inhibitors of biofilm formation of mycobacteria, as well as, to develop newer types of cyclic oligosaccharide synthetic hosts that can modify binding abilities towards various guest compounds.

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