Membrane interactions of glycosyltransferases

Liebau, Jobst

January 2015

Many important biological processes occur near or in membranes. The role of membranes is not merely confined to compartmentalization, they also form the matrix for membrane associated proteins and are of functional importance. Membrane associated proteins on the other hand require specific membrane properties for proper function. The interactions between membranes and proteins are thus of paramount importance and are at the focus of this work. To draw valid conclusions about the nature of such interactions the membrane mimetics required in biophysical methods must faithfully mimic crucial properties of biological membranes. To this end, new types of small isotropic bicelles which mimic plant and bacterial membranes were characterized by their size and lipid dynamics using solution-state NMR. Small isotropic bicelles are specifically well suited for solution-state NMR studies since they maintain a bilayer while being sufficiently small to conduct interpretable experiments at the same time. Monogalactosyl diacylglycerol and digalactosyl diacylglycerol, which are highly abundant in thylakoid membranes, were successfully incorporated into bicelles. Also, it was possible to make bicelles containing a lipid mixture extracted from Escherichia coli cells. A fundamental physical property of lipids in bilayers is their phase behaviour and thus the dynamics that lipids undergo in a membrane. Here, the dynamics of 13C-1H bonds in lipids were studied by nuclear spin relaxation. From such studies it was found that the glycerol backbone of lipids in bicelles is rigid while the flexibility of the acyl chain increases towards its end. Bulky head groups are rigid, while smaller head groups are more dynamic than the glycerol backbone. Acyl chain modifications, like unsaturations or cyclopropane moities, that are typically found in E. coli lipids, locally increase the rigidity of the acyl chain. Membrane interactions of a putative membrane anchor of the glycosyltransferase WaaG, MIR-WaaG, were studied by fluorescence methods, circular dichroism and solution-state NMR. It was found that MIR-WaaG binds to vesicles that mimic the anionic charge of E. coli inner membranes and that α-helical structure is induced upon interaction. The NMR-structure of MIR-WaaG agrees well with the crystal structure and from paramagnetic relaxation enhancement studies it could be concluded that a central part of MIR-WaaG is immersed in the membrane mimetic. Based on these results a model of the membrane interaction of WaaG is proposed where MIR-WaaG anchors WaaG to the cytosolic leaflet of the E. coli inner membrane via electrostatic interactions. These are potentially enhanced by membrane interactions of Tyr residues at the membrane interface and of hydrophobic residues inside the membrane.

Lipid

bicelle

glycosyltransferase

NMR

Biophysics

Biofysik

Glucurono(Arabino)Xylan Biosynthesis in Wheat

Zeng, Wei

21 September 2009

No description available.

Molecular Biology

GAX

wheat

glycosyltransferase

proteomics

Une nouvelle approche pour étudier le mécanisme des glycosyltransférases / Kinetic crystallography to probe for catalytic mechanism and protein loop mouvement in galactosyltransferases

Batot, Gaëlle

11 December 2013

Les glycosyltransferases sont les enzymes responsables de la synthèse d'oligosaccharides, de polysaccharides et de glycoconjugués. Elles catalysent le transfert d'un saccharide à partir d'un substrat donneur, en général un nucléotide sucre, vers un substrat accepteur. Le mécanisme de réaction des glycosyltransférases peut avoir lieu avec une inversion ou une rétention de l'anomérie de liaison du sucre transféré. De nombreuses incertitudes subsistent au sujet du mécanisme des glycosyltransférases transférant avec rétention de l'anomérie. L'élucidation de ce mécanisme aiderait à la conception d'inhibiteurs ciblés afin de soigner des maladies allant des infections virales et bactériennes au cancer. De nombreuses protéines sont actives à l'état cristallin, ce qui fait de la cristallographie aus rayons X un outil de choix pour étudier le mécanisme d'enzymes. La « cristallographie cinétique » est un terme qui regroupe l'ensemble des techniques permettant d'initier une activité biologique in crystallo pour générer et piéger une quantité significative d'un état intermédiaire de réaction, afin de résoudre sa structure par cristallogrpahie aux rayons X. Le but de mon projet était d'étudier le mécanisme catalytique d'une glycosyltransférase transférant avec rétention de l'anomérie, par cristallographie cinétique. De cette façon, j'ai étudié une enzyme du groupe sanguin responsable du transfert d'un galactose à partir d'UDP-Gal vers l'antigène H. J'ai étudié les effets de la cryoprotection sur la structure de la protéine, et j'ai effectué les études préalables nécessaires à l'application de deux techniques issues de la cristallographie cinétique à l'étude de ces enzymes : « Déclencher-tremper »et « Tremper-déclencher ». / Glycosyltransferases are a large class of enzymes responsible for the synthesis of oligosaccharides, polysaccharides and glycoconjugates. They catalyze the transfer of a saccharide from a donor substrate, usually a nucleotide sugar, to an acceptor. Glycosyltransferase reactions can occur with either retention or inversion of the anomeric configuration of the transferred sugar. Many uncertainties remain concerning the catalytic mechanisms of retaining glycosyltransferases even though the elucidation of this mechanism would help in the rationale design of potent inhibitors to treat diseases ranging from viral and bacterial infections to cancer. Many proteins function in the crystalline state which makes X-ray crystallography a potential powerful tool for studying enzymatic mechanisms. ‘Kinetic crystallography' is a term coined to name the ensemble of techniques to initiate a biological turnover in crystallo in order to generate and trap a significant amount of a given intermediate reaction state, and then solve its X-ray structure. The aim of my project was to investigate the catalytic mechanism of a retaining glycosyltransferase, by kinetic crystallography methods. In this way, I studied a human blood group synthase responsible for the transfer of a galactose from UDP-Gal to the H antigen. I investigated the effects of the cryoprotectant on the structure of the protein, and I made preliminary studies to apply two kinetic crystallography techniques to the enzyme: freeze-trigger and trigger freeze experiments.

Glycosyltransferase

Cristallographie

Mecanisme catalytique

Galactosyltransferase

Glycosyltransferase

Crystallography

Catalytic mechanism

Galactosyltransferase

620

Genetic and epigenetic factors controlling the expression of sialyltransferase gene ST6GAL1

Lee, Hing-leung, Eric., 李慶亮.

January 2008

published_or_final_version / Pathology / Master / Master of Philosophy

Glycosyltransferase genes.

Nucleotide sequence.

Gene expression.

Genetic regulation.

Characterization of Friable1-like Homologues in Arabidopsis using Bioinformatics and Reverse Genetics

Hsieh, Chih-Cheng Sherry

10 August 2009

The FRIABLE1 (FRB1) gene is identified to be a novel glycosyltransferase involved in cell adhesion, based on reverse genetics and immunocytochemistry studies. A total of 31 FRB1 paralogues were found in Arabidopsis thaliana using a bioinformatics approach. The following expression analysis has revealed 6 FRB1 paralogues to be pollen-specific. One pollen-specific FRB1 paralogue, At1g14970, exhibits longer silique lengths when exposed to higher than normal temperature at 28oC in its T-DNA insertional knockout when compared to Columbia wildtype plants. This may be due to the loss of temperature sensing and the continuous stimulated pollen tube cell wall growth or the up-regulation of genes that encode other glycosyltransferases. Thus, the identification of FRB1 paralogues and homologues in both rice and poplar may have tremendous potential to increase their yield in global warming for agricultural and industrial benefits.

FRIABLE1

Pectin

Glycosyltransferase

Pollen

Cell adhesion

0309

0369

0715

Next generation approaches to polysaccharide preparation for Burkholderia pseudomallei vaccine development

Baldwin, Victoria Mae

January 2016

Burkholderia pseudomallei is the aetiological agent of melioidosis and a potential bioterror threat. Infections are difficult to treat due to extensive antibiotic resistance and there is no prophylactic vaccine available. Studies have shown that the capsular polysaccharide (CPS) of B. pseudomallei is a virulence factor, immunogen and candidate antigen for a glycoconjugate vaccine. However, polysaccharides are complex to synthesise. One approach is to genetically engineer Escherichia coli to express the CPS; however, previous attempts at cloning the CPS coding locus from B. pseudomallei into E. coli were unsuccessful. This project proposes to clone only the essential genes from B. pseudomallei and to use native E. coli mechanisms to complete CPS synthesis. This would contribute to development of a new platform for the expression of any bespoke polysaccharide in E. coli. Six biosynthetic genes for the nucleotide sugar precursor were successfully expressed in E. coli. The structure of the precursor was verified by mass spectrometry. Precursor synthesis was also performed in an in vitro microfluidics system. This minimised the quantity of substrates and enzymes required, in preparation for the characterisation of glycosyltransferases required for CPS assembly. A novel assay for characterising glycosyltransferase activity was also developed, as current available options are prohibitively expensive and require significant quantities of glycosyltransferase which are difficult to purify. Finally, plasmids for the expression of additional glycosyltransferases to link the nascent B. pseudomallei CPS to truncated polysaccharides in E. coli were constructed. The aim of this project was to contribute to the development of a platform for the expression of bespoke polysaccharides in E. coli. The CPS of B. pseudomallei was chosen as the model polysaccharide as it has a simple structure and its manufacture is desirable for use in a vaccine against melioidosis.

570

Idenfitication and characterization of Tft1, a glycosyltransferase necessary for cell wall β,3-1,4-Glucan synthesis in Aspergillus fumigatus

Samar, Danial

01 December 2012

Aspergillus fumigatusis a ubiquitous environmental soil fungus. With recent development and advancement in medical treatments leading to immunosuppression, there has been an increase in incidence in aspergillosis. With the emergence of antifungal resistance isolates and the continued high mortality rate for invasive aspergillosis, the hunt for new antifungal drug targets is critical. Research on A. fumigatus is still in its infancy, partly due to the relatively recent rise of A. fumigatus as a clinically significant pathogen. The cell wall has been demonstrated to be critical for survival of this fungal organism, with interference of cell wall construction leading to cell death or reduced growth. This, coupled with the lack of shared mechanisms in humans, makes targeting cell wall synthesis for antifungal therapy a reasonable possibility. The cell wall of A. fumigatus shares a few similarities to S. cerevisiae. However, major differences exist, including the presence of β-1,3;1,4-glucan in the cell wall of A. fumigatus. In fact, the presence of β-1,3;1,4-glucan was never previously described in fungi before Latge's group reported it a number of years ago. It comprises about 10% of the glucans in the cell wall of A. fumigatus, but its role in the cell wall is unknown. In 2006 and 2009, two papers were published that demonstrated the role of CslF and CslH(Cellulose like synthases) in the production of β-1,3;1,4-glucan of the cell wall in rice and barley, respectively. Taking both protein sequences for these genes, we blasted it against the A. fumigatus database for any possible orthologues. A single orthologue, albeit with weak homology, was identified that named TFT1. We hypothesize that TFT1a plays a direct role in A. fumigatus β-1,3;1,4-glucan synthesis. Through Agrobacterium tumefaciens mediated transformation, an A. fumigatus strain lacking this enzyme (tft1Δ) was generated. From tft1Δ a revertant strain (revtft1) was created where the gene was reintroduced. Immunofluorescence staining with antibodies against β-1,3;1,4-glucan and biochemical quantification both demonstrated complete loss of β-1,3;1,4-glucan within the cell wall of the tft1Δ strain, with recovery detected in revtft1. This strongly suggests that this enzyme does indeed play a role in β-1,3;1,4-glucan synthesis in A. fumigatus. Growth experiments, spore size determination and an in vitro model of virulence also indicated that the loss of TFT1 leads to additional phenotypes. While the precise mechanism for β-1,3;1,4-glucan synthesis is unknown, the results shown herein indicate a pivotal role forTFT1 in its biosynthesis, and resulting phenotypes upon loss of mixed linkage glucan adds some clues to its role in the cell wall of A. fumigatus.

Cell Wall

fumigatus

Fungal

glucan

glycosyltransferase

lichenin

Pathology

The advantages of being small : Glycosyltransferases in many dimensions and glycolipid synthesis in <i>Mycoplasma Pneumoniae</i>

Rosén Klement, Maria

January 2007

<p>The synthesis and breakdown of sugars is one of the most important functions in Nature. Consequently, sugar structures are used both as energy storage and as building blocks to stabilise and protect the cell. The formation of these structures is performed by glycosyltransferases (GT), an enzyme group structurally conserved within all kingdoms. Until now, only two different folds have been discovered by crystallisation of GTs, i.e. GT-A and GT-B. A third fold family has however been proposed by fold predictions. In this thesis, a multivariate data analysis was successfully used in classifying and predicting both fold and reaction mechanism (inverting or retaining) of GTs. This method was also used to obtain information about the separating parameters for the reaction mechanism classification. This information could be traced back to the amino acid sequence. The method could as well be used to analyse and identify the properties of membrane binding regions of GTs, and subsequently distinguish soluble from membrane-associated enzymes. Most functionally characterised enzymes only use one substrate, synthesising one product. <i>Mycoplasma pneumoniae</i>, a common human pathogen with a small genome has only three proposed GTs. The bacterium was, however expected to have a greater number of GTs, due to its ability to make both glycolipids and capsule. Here we have determined the function of one of these enzymes, MPN483 and discovered its ability to both use different acceptors, and make elongated glycolipids with up to three galactose residues, with both DAG and ceramide as the base. Many of the synthesised glycolipids were also found to be immunogenic, hence showing their biological importance. The properties of lipids are known to be important for the function of a biological membrane. We have here shown that not only the charge but also the shape of the lipids are important for several protein mediated membrane processes in <i>Echerichia coli</i>, such as the function of the LacY.</p>

Glycosyltransferase

lipid

membrane

glycolipid

ACC

PLS-DA

Biochemistry

Biokemi

The advantages of being small : Glycosyltransferases in many dimensions and glycolipid synthesis in Mycoplasma Pneumoniae

Rosén Klement, Maria

January 2007

The synthesis and breakdown of sugars is one of the most important functions in Nature. Consequently, sugar structures are used both as energy storage and as building blocks to stabilise and protect the cell. The formation of these structures is performed by glycosyltransferases (GT), an enzyme group structurally conserved within all kingdoms. Until now, only two different folds have been discovered by crystallisation of GTs, i.e. GT-A and GT-B. A third fold family has however been proposed by fold predictions. In this thesis, a multivariate data analysis was successfully used in classifying and predicting both fold and reaction mechanism (inverting or retaining) of GTs. This method was also used to obtain information about the separating parameters for the reaction mechanism classification. This information could be traced back to the amino acid sequence. The method could as well be used to analyse and identify the properties of membrane binding regions of GTs, and subsequently distinguish soluble from membrane-associated enzymes. Most functionally characterised enzymes only use one substrate, synthesising one product. Mycoplasma pneumoniae, a common human pathogen with a small genome has only three proposed GTs. The bacterium was, however expected to have a greater number of GTs, due to its ability to make both glycolipids and capsule. Here we have determined the function of one of these enzymes, MPN483 and discovered its ability to both use different acceptors, and make elongated glycolipids with up to three galactose residues, with both DAG and ceramide as the base. Many of the synthesised glycolipids were also found to be immunogenic, hence showing their biological importance. The properties of lipids are known to be important for the function of a biological membrane. We have here shown that not only the charge but also the shape of the lipids are important for several protein mediated membrane processes in Echerichia coli, such as the function of the LacY.

Glycosyltransferase

lipid

membrane

glycolipid

ACC

PLS-DA

Biochemistry

Biokemi

Structural characterization of post-PKS enzymes involved in spinosyn biosynthesis

Isiorho, Eta Amauche

07 April 2015

Saccharopolyspora spinosa is a rare actinomycete that synthesizes the secondary metabolite spinosyn A, which is an active ingredient in several important commercial insecticides. Spinosyn aglycone formation occurs via a type I polyketide synthase. After release of the polyketide chain from the synthase, various tailoring enzymes modify the aglycone core. These unique enzyme transformations result in unusual structural characteristics found in spinosyn A. The enzymes SpnG, SpnP, SpnF and SpnL each perform a key reaction during post-PKS processing. The work presented in this dissertation focuses on the structural determination and analysis of SpnG, SpnP, SpnF and SpnL. SpnG, which naturally catalyzes the 9-OH rhamnosylation of spinosyn, is capable of adding diverse sugars to the spinosyn aglycone from TDP-hexoses, such as TDP-glucose. However, the substitution of UDP-glucose for TDP-glucose as the donor substrate is known to result in a >60,000-fold reduction in k [subscript cat]. The structure of SpnG at 1.65 Å resolution, the 1.86 Å resolution structure of SpnG bound to TDP, and the 1.70 Å resolution structure of SpnG bound to AGL were determined. The SpnG-TDP complex reveals how SpnG employs N202 to discriminate between TDP- and UDP-sugars. The SpnG-AGL complex shows that SpnG binds the acceptor substrate primarily through hydrophobic interactions and implicates H13 as the potential catalytic base. A model for how rhamnose binds in the active site was constructed to elucidate which features enable SpnG to transfer diverse hexoses. SpnP transfers forosamine from a TDP-D-forosamine donor substrate to a spinosyn pseudoaglycone acceptor substrate. The structures of SpnP and its complex with TDP were determined to 2.50 Å and 3.15 Å resolution, respectively. SpnP possesses a structural feature that has only been previously observed in a related glycosyltransferase, which employs an auxiliary protein that aids in its catalysis. This unique feature may be a used as a predictive motif of glycosyltransferases that interact with an auxiliary protein. SpnF and SpnL are two novel S-adenosyl-L-methionine dependent cyclases. Structural data was utilized in order to gain insight into the unusual cycloaddition catalyzed by the putative Diels-Alderase and Rauhut-Currierase, SpnF and SpnL, respectively. Together these structures provide valuable insights into the unusual mechanisms involved in spinosyn biosynthesis. / text

Biosynthesis

Spinosyn

Structural

X-ray

Polyketide

Cyclase

Glycosyltransferase