Určení N-glykomu klíštěte \kur{Ixodes ricinus} a \kur{Dermacentor marginatus}; analýza N-glykanů v tkáních klíštěte a jejich porovnání / Determination of N-glycome of the tick \kur{Ixodes ricinus} and \kur{Dermacentor marginatus}; Analysis of N-glycans in tick tissues and their comparison

ŠIMONOVÁ, Zuzana

January 2011

Glycosylation in vertebrates has a main role in many important processes such as cell transport, protein folding, secretion of proteins etc. What function has glycosylation in arthropods, for example in ticks, is rarely studied. This work was focused on analysis of N-glycans in tick tissues, namely in Ixodes ricinus and Dermacentor marginatus. High-mannose glycans as well as complex glycans with or without core-fucosylation were identified in this study.Furthermore several sialylated glycans were present in the studied samples. Sialic acid is found in arthropods rarely and this is the first study which directly proves its presence in ticks using mass spectrometry.

Humans naturally acquire cross-specific anti-glycan antibodies

Rollenske, Tim

03 November 2017

Bakterielle Glykanantigene sind hoch-divers in ihrer Komposition und Verbindung. Antikörper gegen Glykanantigene können vor bakteriellen Infektionen schützen und sind wichtig um die Homöostase zwischen dem Wirt und seinem Mikrobiom aufrecht zu halten. Typischerweise lösen Glykanantigene jedoch Antikörperantworten aus, die sich durch ein vermindertes B Zell-Gedächtnis und niedrig-affine Antikörper mit geringer Spezifität auszeichnen. In dieser Arbeit konnten, mithilfe von biotinylierten Lipopolysaccharide O-Antigenen des opportunistisch-pathogenen Bakteriums Klebsiella pneumoniae (Kp), O-Antigen-spezifische B Zellen innerhalb peripherer Gedächtnis- und intestinaler Effektor-B Zellen identifiziert werden. Durch Einzel-Zell Immunoglobulin-Sequenzierung und Klonierung bzw. rekombinanter Expression von Antikörpern dieser Zellen wird gezeigt, dass, unter natürlichen Umständen, affinitätsgereifte Antikörper gegen definierte Kp Glykanantigene erzeugt werden. Diese Antikörper binden nicht nur Kp O-Serotyp-spezifisch sondern auch spezifisch an strukturell ähnliche Kp O-Antigene und taxonomisch unterschiedliche Mikroorganismen. Die Ergebnisse zeigen, dass Menschen, bei natürlicher Besiedlung, kreuz-spezifische Antikörper gegen Glykanantigene erzeugen und deuten auf einen Mechanismus hin, wie das humorale Immunsystem auf die Glykandiversität des Mikrobioms reagieren und sich anpassen kann. Weiterhin könnten die hier identifizierten Antikörper nützlich für die Behandlung von nosokomiellen Kp Infektionen sein. / Bacterial glycan antigens are highly diverse in composition and linkage. Antibodies against glycan antigens can protect against bacterial infection and are important in maintaining homeostasis between the host and its microbiome. However, glycan antigens typically elicit B cell responses that have impaired long-term memory formation and are comprised of low-affine antibodies with low specificity. In this work, the use of biotinylated Lipopolysaccharide O-antigens of the opportunistic pathogen Klebsiella pneumonia allowed to identify anti-O-antigen B cells in the peripheral memory and intestinal effector B cell pool in healthy humans. Single B cell Immunoglobulin gene sequencing, antibody cloning, and recombinant expression reveal that, under natural circumstances, humans acquire affinity-matured antibodies against defined Kp glycan antigens. Despite their O-serotype-specificity, the antibodies bind to other structurally similar Kp O-serotypes and taxonomically distinct non-Kp microbes. The findings show that humans, under natural exposure, acquire affinity-matured cross-specific anti-glycan antibodies and provide a mechanistic way how the humoral immune system could adapt to the large microbial glycan diversity present in nature. Further, the antibodies identified in this work might be beneficial in treatment of nosocomial Kp infections.

Antikoerper

Glykan

monoklonal

Gedaechtnis B Zellen

Darm

kreuzreaktiv

Klebsiella pneumoniae

O-antigen

antibody

glycan

monoclonal

human

B cell memory

intestine

crossreactive

Klebsiella pneumoniae

O-antigen

polysaccharide

570 Biowissenschaften; Biologie

WF 9860

ddc:570

HILIC-MS analysis of protein glycosylation using nonporous silica

Rachel E. Jacobson (5929808)

16 January 2019

The objective of this research is to develop and apply a HILIC UHPLC stationary phase that allows for separation of intact glycoproteins. In Chapter 1 I give an overview of the problems of current glycosylation profiling with regards to biotherapeutics, and my strategy to separate the intact glycoprotein with HILIC. Chapter 2 describes the methods used to produce the nonporous packing material and stationary phase. In Chapter 3 I describe previous work in developing a HILIC polyacrylamide stationary phase, and further improvements I have made. Chapter 4 describes development of an assay in collaboration with Genentech of therapeutic mAb glycosylation. In Chapter 5, I show HILIC-MS of digested ribonuclease B as a beginning step to analyze glycosylated biomarkers.

Separation Science

Proteins and Peptides

Colloid and Surface Chemistry

hplc

lcms

uplc

uhplc

liquid chromatography

HILIC

biologics

mAbs

antibodies

protein

glycan

glycosylation

glycoform

MS

mass spectrometry

AGET

ATRP

surface-initiated

Structural Investigation of Processing α-Glucosidase I from Saccharomyces cerevisiae

Barker, Megan

20 August 2012

N-glycosylation is the most common eukaryotic post-translational modification, impacting on protein stability, folding, and protein-protein interactions. More broadly, N-glycans play biological roles in reaction kinetics modulation, intracellular protein trafficking, and cell-cell communications. The machinery responsible for the initial stages of N-glycan assembly and processing is found on the membrane of the endoplasmic reticulum. Following N-glycan transfer to a nascent glycoprotein, the enzyme Processing α-Glucosidase I (GluI) catalyzes the selective removal of the terminal glucose residue. GluI is a highly substrate-specific enzyme, requiring a minimum glucotriose for catalysis; this glycan is uniquely found in biology in this pathway. The structural basis of the high substrate selectivity and the details of the mechanism of hydrolysis of this reaction have not been characterized. Understanding the structural foundation of this unique relationship forms the major aim of this work. To approach this goal, the S. cerevisiae homolog soluble protein, Cwht1p, was investigated. Cwht1p was expressed and purified in the methyltrophic yeast P. pastoris, improving protein yield to be sufficient for crystallization screens. From Cwht1p crystals, the structure was solved using mercury SAD phasing at a resolution of 2 Å, and two catalytic residues were proposed based upon structural similarity with characterized enzymes. Subsequently, computational methods using a glucotriose ligand were applied to predict the mode of substrate binding. From these results, a proposed model of substrate binding has been formulated, which may be conserved in eukaryotic GluI homologs.

Biomolecular structure

Eukaryotic glycosylation

glycosylation

N-glycan

N-linked glycosylation

Carbohydrate

biochemistry

Inhibitor

antiviral therapeutic

Structure-based drug design

glucosidase

glycosidase

glycoside hydrolase

post-translational modification

enzyme

enzyme mechanism

inverting mechanism

structural biology

protein structure

6xHis tag

Crystal packing

sugar

substrate

X-ray crystallography

single anomalous dispersion

PHENIX

heavy-atom phasing

docking

autodock

autodock vina

biophysical methods

tryptophan fluorescence

glucose oxidase

activity assay

enzyme inhibition

Protein expression

Protein purification

Pichia pastoris

Saccharomyces cerevisiae

fondue

AOX1 promoter

glycoside hydrolysis

substrate binding model

molecular dynamics

molecular dynamics

Binding site

Active site cleft

Endoplasmic reticulum

Glycan processing

Glycan trimming

protein-protein interactions

cell-cell communication

X-ray diffraction

crystallization

secreted protein

substrate selectivity

kojibiose

glucotriose

miglitol

deoxynojirimycin

Glc3Man9GlcNAc2

free oligosaccharide species

GluI

Cwh41

Cwh41p

Cwht1p

0306

0307

0760

Structural Investigation of Processing α-Glucosidase I from Saccharomyces cerevisiae

Barker, Megan

20 August 2012

N-glycosylation is the most common eukaryotic post-translational modification, impacting on protein stability, folding, and protein-protein interactions. More broadly, N-glycans play biological roles in reaction kinetics modulation, intracellular protein trafficking, and cell-cell communications. The machinery responsible for the initial stages of N-glycan assembly and processing is found on the membrane of the endoplasmic reticulum. Following N-glycan transfer to a nascent glycoprotein, the enzyme Processing α-Glucosidase I (GluI) catalyzes the selective removal of the terminal glucose residue. GluI is a highly substrate-specific enzyme, requiring a minimum glucotriose for catalysis; this glycan is uniquely found in biology in this pathway. The structural basis of the high substrate selectivity and the details of the mechanism of hydrolysis of this reaction have not been characterized. Understanding the structural foundation of this unique relationship forms the major aim of this work. To approach this goal, the S. cerevisiae homolog soluble protein, Cwht1p, was investigated. Cwht1p was expressed and purified in the methyltrophic yeast P. pastoris, improving protein yield to be sufficient for crystallization screens. From Cwht1p crystals, the structure was solved using mercury SAD phasing at a resolution of 2 Å, and two catalytic residues were proposed based upon structural similarity with characterized enzymes. Subsequently, computational methods using a glucotriose ligand were applied to predict the mode of substrate binding. From these results, a proposed model of substrate binding has been formulated, which may be conserved in eukaryotic GluI homologs.

Biomolecular structure

Eukaryotic glycosylation

glycosylation

N-glycan

N-linked glycosylation

Carbohydrate

biochemistry

Inhibitor

antiviral therapeutic

Structure-based drug design

glucosidase

glycosidase

glycoside hydrolase

post-translational modification

enzyme

enzyme mechanism

inverting mechanism

structural biology

protein structure

6xHis tag

Crystal packing

sugar

substrate

X-ray crystallography

single anomalous dispersion

PHENIX

heavy-atom phasing

docking

autodock

autodock vina

biophysical methods

tryptophan fluorescence

glucose oxidase

activity assay

enzyme inhibition

Protein expression

Protein purification

Pichia pastoris

Saccharomyces cerevisiae

fondue

AOX1 promoter

glycoside hydrolysis

substrate binding model

molecular dynamics

molecular dynamics

Binding site

Active site cleft

Endoplasmic reticulum

Glycan processing

Glycan trimming

protein-protein interactions

cell-cell communication

X-ray diffraction

crystallization

secreted protein

substrate selectivity

kojibiose

glucotriose

miglitol

deoxynojirimycin

Glc3Man9GlcNAc2

free oligosaccharide species

GluI

Cwh41

Cwh41p

Cwht1p

0306

0307

0760