Provided by the author(s) and NUI Galway in accordance with publisher policies. Please cite the published version when available. Glycosylation and glycoengineering of recombinant antibody Title fragments in Escherichia coli Author(s) O' Connor, Iain Publication 2016-11-14 Date Item record http://hdl.handle.net/10379/6158 Downloaded 2023-03-20T04:00:57Z Some rights reserved. For more information, please see the item record link above. Glycosylation and glycoengineering of recombinant antibody fragments in Escherichia coli A thesis submitted to the National University of Ireland, Galway for the degree of Doctor of Philosophy by: Iain O' Connor, B.Sc. Recombinant Protein Production Laboratory, Discipline of Microbiology, School of Natural Sciences College of Science, National University of Ireland, Galway Research Supervisor: Dr. J. Gerard Wall Head of Discipline: Dr. J. Gerard Wall November 2016 Table of contents Table of contents i List of abbreviations vi List of figures ix List of tables xii Acknowledgements xiii Declaration xiv Abstract xv Chapter 1: General Introduction 1 1.1 Recombinant protein production 2 1.2 Glycosylation in recombinant hosts 4 1.3 E. coli as an expression host 6 1.4 Glycosylation in E. coli 10 1.5 Antibody sources 13 1.6 Antibody structure 15 1.7 Antibody fragments 17 1.8 Antibody fragment isolation and expression in E. coli 19 1.9 Immobilisation approaches 21 1.10 Immobilised antibody fragments 24 1.11 Scope of this thesis 25 Chapter 2: Materials and Methods 27 2.1 Materials 28 2.1.1 Suppliers and reagents 28 2.1.2 Bacterial strains, plasmids and primers 29 2.1.3 Antibiotics 33 2.1.4 Antibodies, lectins and detection reagents 33 2.1.5 Molecular weight markers 33 2.1.6 General multi-component buffers 33 2.1.7 Protein purification buffers 34 i 2.1.8 Culture media 34 2.1.8.1 Lysogeny broth (LB) 34 2.1.8.2 ZYP-5052 34 2.1.8.3 Pichia pastoris media 35 2.2. Methods 35 2.2.1 Bacterial growth and protein expression 35 2.2.2. Electrocompetent cell preparation 35 2.2.3 Transformation by electroporation 36 2.2.4 Transformation by heat-shock 36 2.2.5 Protein expression by induction via IPTG 36 2.2.6 Auto-induction 37 2.2.7 P. pastoris growth and protein expression 37 2.2.8 Protein extraction 37 2.2.8.1 Periplasmic protein extraction from E. coli 37 2.2.8.2 Protein extraction from P. pastoris 38 2.2.9 Protein purification and cleanup 38 2.2.9.1 Affinity chromatography using immobilised nickel 39 2.2.9.2 Affinity chromatography using cobalt resin 39 2.2.10 Protein processing and analysis 40 2.2.10.1 SDS-PAGE 40 2.2.10.2 Protein staining 40 2.2.10.3 Western blotting 40 2.2.10.4 Glycan detection/staining 40 2.2.10.5 Lectin blotting 41 2.2.10.6 Protein quantification 42 2.2.10.7 Glycoprotein oxidation 42 2.2.11 Enzyme-Linked Immunosorbent Assay (ELISA) 42 2.2.11.1 Indirect ELISA 42 2.2.11.2 Inhibition ELISA 43 ii 2.2.12 Protein immobilisation 43 2.2.12.1 Adsorption to microplates 43 2.2.12.2 Covalent attachment to microplates 44 2.2.12.3 Immobilisation on TiO -coated 316L stainless steel 44 2 2.2.12.4 Disk washing, antigen incubation, and imaging 44 2.2.12.5 Densitometry analysis of immobilisations 45 2.2.13 Oligosaccharide extension 45 2.2.14 Lectin array 45 2.2.15 Molecular techniques – DNA 46 2.2.15.1 Plasmid isolation and purification 46 2.2.15.2 Restriction enzyme digestion 46 2.2.15.3 Dephosphorylation and ligation 46 2.2.15.4 Polymerase chain reaction 47 2.2.15.5 Agarose gel electrophoresis 47 2.2.15.6 DNA purification and concentration 47 2.2.15.7 Mutagenesis 47 2.2.15.8 Sequencing 48 2.2.16 Molecular techniques – RNA 48 2.2.16.1 RNA isolation from Pichia pastoris 48 2.2.16.2 cDNA synthesis 48 2.2.17 Computational analyses 49 2.2.17.1 Codon usage analysis 49 2.2.17.2 Sequence alignment and secondary structure prediction 49 Chapter 3: Glycoprotein expression in E. coli and engineering of the glycan chain 50 3.1 Introduction 51 3.2 Production of glycosylated scFvs in E. coli 56 3.2.1 Selection of scFv for glycoengineering 56 iii 3.2.2 Optimisation of glycoprotein production and recovery 57 3.3 Generation of alternative pgl constructs 60 3.3.1 Effect on glycan length of site-directed mutagenesis of pglJ 60 3.3.2 Investigation of pgl locus redundancy by truncation mutagenesis 62 3.3.3 Western blot-based characterisation of glycoprofiles 64 3.3.3.1 DIG-specific analysis of glycoproteins 64 3.4 Functionality of glycoproteins 66 3.4.1 Antigen binding 66 3.4.2 Immobilisation of scFvs using adsorption 67 3.4.2.1 Adsorption - antigen-binding 71 3.4.3 Covalent immobilisation 73 3.4.3.1 Time course of covalent immobilisation of scFvs 75 3.4.3.2 Antigen-binding by covalently immobilised scFvs 78 3.4.4 Analysis of antigen binding by oxidised scFvs 81 3.5 Discussion 83 Chapter 4: Investigation into extension of the established Campylobacter jejuni N-linked glycan in Escherichia coli and additional characterisations of glycosylated scFvs 89 4.1 Introduction 90 4.2 Investigating protein sialylation in E. coli 94 4.3 CgtB-mediated extension and expression in E. coli 96 4.4 cgtB expression in P. pastoris 97 4.5 CgtB purification and oligosaccharide extension 100 4.6 Alternate characterisation of glycoproteins 101 4.6.1 Lectin array analysis 101 4.6.2 Lectin blot analysis of glycoproteins 111 4.7 Glycan-mediated immobilisation of scFvs 113 4.8 Discussion 119 iv Chapter 5: Discussion 127 5.1 Discussion 128 5.2 Conclusion 138 References 140 Appendices 174 Appendix i 175 Appendix ii 177 Appendix iii 178 v List of abbreviations Abbreviations (NH ) SO Ammonium sulfate 4 2 4 * Stop codon 2H12 Anti-domoic acid scFv 4M5.3 Anti-fluorescein scFv AFM Atomic force microscopy Amp Ampicillin AOX1 Alcohol oxidase 1 promoter APTES 3-(aminopropyl) triethoxysilane Asn Asparagine AURIF Auristatin F Bac Bacillosamine BMGY Buffered glycerol-complex medium BMMY Buffered methanol-complex medium BSA Bovine serum albumin Cam Chloramphenicol CDR Complementarity-determining region C Heavy chain constant domain H CHO Chinese hamster ovary cell C Light chain constant domain L C-terminal Carboxyl terminal Cy5 Cyanine5 NHS ester dH O Deionised water 2 DHB 2,5-dihydroxybenzoic acid DIG Digoxigenin DNA Deoxyribonucleic acid DsbA/C Disulfide bond isomerase A/C dsFv Disulfide-stabilised Fv antibody fragment EDA Ethylenediamine EDTA Ethylenediamine tetraacetic acid ELISA Enzyme-linked immunosorbent assay Endo H/F Endoglycosidase H/F Fab Antigen-binding fragment Gal Galactose GalNAc N-Acetylgalactosamine Glc Glucose GlcNAc N-Acetylglucosamine GST Glutathione S-transferase H O Water 2 H SO Sulphuric acid 2 4 HAMA Human anti-mouse antibody HER2 Human epidermal growth factor receptor 2 His tag Hexahistidine tag Hrp Horseradish peroxidase Hsp Heat shock protein IC Half maximal inhibitory concentration 50 vi Ig Immunoglobulin IgG Immunoglobulin G IMAC Immobilised metal ion affinity chromatography IPTG Isopropyl β-D-1-thiogalactopyranoside KH PO Monopotassium phosphate 2 4 LB Luria-Bertani broth LOS Lipooligosaccharide LPS Lipopolysaccharide mAb Monoclonal antibody MALDI-TOF Matrix assisted laser desorption/ionisation time-of- flight Man Mannose MBP Maltose-binding protein MgCl Magnesium chloride 2 MgSO Magnesium Sulphate 4 MS Mass spectrometry MWCO Molecular weight cut off Na HPO .2H O Di-sodium hydrogen phosphate dihydrate 2 4 2 NeuAc Neuraminic acid (Sialic acid) NH Primary amine 2 N-linked/glycosylated Asparagine-linked/glycosylated NMR Nuclear magnetic spectroscopy N-terminal Amino terminal OD Optical density O-linked/glycosylated Serine/threonine-linked/glycosylated Omp Outer membrane protein OST Oligosaccharyltransferase pAb Polyclonal antibody PBS Phosphate buffered saline PelB Pectate lyase B pgl C. jejuni protein glycosylation gene family PNGase F Peptide-N-Glycosidase F PTM Post-translational modification QCM-D Quartz crystal microbalance with dissipation monitoring R2 Coefficient of determination RNA Ribonucleic acid RPP Recombinant protein production SBA Soybean lectin from Glycine Max scFv Single chain variable fragment SDS-PAGE Sodium dodecyl sulphate-polyacrylamide gel electrophoresis Strep tag Streptavidin tag SUMO Small ubiquitin-like modifier protein TBS Tris buffered saline TEV Tobacco etch virus V Heavy chain variable domain H V H Single domain antibodies H V Light chain variable domain L YPDS Yeast extract peptone dextrose medium vii