Generation of a Human Middle East Respiratory Syndrome Coronavirus (HCoV-MERS) Infectious Clone System by Homologous Recombination of Bacterial Artificial Chromosomes by Aidan M. Nikiforuk B.A.Sc. A Thesis submitted to the Faculty of Graduate Studies of The University of Manitoba in partial fulfillment of the requirements of the degree of MASTER OF SCIENCE Department of Microbiology University of Manitoba Winnipeg Copyright © 2015 by Aidan Nikiforuk 1 List of Abbreviations: ACE-2: angiotensin-converting enzyme two ARDS: acute respiratory distress syndrome AUG: codon for methionine and site of translation initiation BAC2: bacterial artificial chromosome number two, a plasmid vector BAC: bacterial artificial chromosome BCV: bovine coronavirus BGT: rabbit beta-globin terminator sequence, stops the transcription of RNA-dependent RNA polymerase BHK-21: baby hamster kidney cells BtCoV: bat coronavirus CD26: cluster of differentiation twenty-six, also identified as dipeptidyl peptidase IV cDNA: complementary DNA, synthesized from RNA by reverse transcriptase PCR CL-3: containment level 3 laboratory CMV: cytomegalovirus promoter CPE: cytopathic effect or cytopathogenic effect CSCHAH: Canadian Science Center for Human and Animal Health CSM-Trp: complete supplement medium without tryptophan DI: defective interfering; may refer to a viral particle or genome DMEM: Dulbecco’s modified Eagle medium DNA: deoxyribonucleic acid dNTPs: deoxynucleotide triphosphates DPP4: dipeptidyl peptidase IV also known as CD26 2 E: coronavirus envelope protein ECDC: European Center for Disease prevention and Control ECMO: extracorporeal membrane oxygenation EMC: Erasmus Medical Center EMC/2012: an isolate of the HCoV-MERS virus ER: endoplasmic reticulum EVD: Ebola virus disease GFP: green fluorescent protein Gpt: guanine phosphoribosyltransferase HA: hemagglutinin, influenza glycoprotein HCoV: human coronavirus HCW: health care worker HDVr: hepatitis delta virus ribozyme HE: hemagglutinin esterase HKU4: bat coronavirus Hong-Kong university isolate four HKU5: bat coronavirus Hong-Kong university isolate five ICTV: International Committee on Taxonomy of Viruses IFN: interferon Kb: kilo-base pairs of DNA KSA: Kingdom of Saudi Arabia LB: Luria-Bertani medium for the growth of bacteria M: coronavirus membrane protein mBAC4: plasmid construct containing the same mutation in HCoV-MERS genome as 3 pYES1L14 mBAC6: final plasmid construct of the HCoV-MERS genome mBACL23: sub-cloning plasmid construct used to correct mutation in mBAC4 MEM: Minimal Essential Medium for mammalian cell culture MERS: Middle East respiratory syndrome MF1: MERS fragment one MF2: MERS fragment two MF3: MERS fragment three MHV: murine hepatitis virus MODS: multiple organ distress syndrome mRNA: messenger ribonucleic acid N: coronavirus nucleoprotein NS6: HCoV-MERS non-structural protein number six Nsp: viral non-structural protein ORF: open reading frame ORF1a/b: first open reading frame in a coronavirus genome ORF1b: a RT-qPCR assay used to detect the HCoV-MERS genome PCR: polymerase chain reaction pYES1L: a bacterial artificial chromosome plasmid used for in vivo homologous assembly of the HCoV-MERS fragments (MF1, MF2 and MF3). pYES1L14: plasmid construct containing the same mutation as mBAC4 RBD: receptor binding domain RDRP: RNA-dependent RNA polymerase 4 RecA: essential protein for the repair and maintenance of DNA in bacteria RFP: red fluorescent protein RGS: reverse genetic system RNA: ribonucleic acid RT-PCR: reverse-transcriptase polymerase chain reaction RT-qPCR: real-time quantitative polymerase chain reaction RTC: coronavirus replication transcription complex S: coronavirus glycoprotein SARS: severe acute respiratory syndrome sBAC: HCoV-SARS infectious cDNA clone system SDS: sodium dodecyl sulfate sgRNA: sub-genomic ribonucleic acid SOC: super optimal catabolite repression broth SOE-PCR: splice by overlap extension polymerase chain reaction SSA: single-strand annealing T7: bacteriophage promoter TAQ: thermus aquaticus polymerase TGEV: transmissible gastroenteritis coronavirus TRS: coronavirus transcription regulatory sequence upE: a RT-qPCR assay used to detect the HCoV-MERS genome UTR: un-translated region vvHCoV: vaccinia virus based coronavirus reverse genetics system 5 Abstract Coronaviruses have caused high pathogenic epidemics within the human population on two occasions; in 2003 a coronavirus (HCoV-SARS) caused severe acute respiratory syndrome and in 2012 a novel coronavirus emerged named Middle East respiratory syndrome (HCoV- MERS). Four other species of coronavirus circulate endemically in the human population (HCoV-229E, HCoV-OC43, HCoV-NL63 and HCoV-HKU1), which cause more benign respiratory disease than either HCoV-SARS or HCoV-MERS. The emergence of HCoV-MERS provides an additional opportunity to study the characteristics of coronaviruses. Reverse genetics can be used to study an organism’s phenotype by logical mutation of its genotype. Construction of an infectious clone construct provides a means to investigate the nature of HCoV-MERS by reverse genetics. An HCoV-MERS infectious cDNA clone system was constructed to use for reverse genetics by homologous recombination of bacterial artificial chromosomes (BACs). This system should aid in answering remaining questions of coronavirus genetics and evolution as well as expedite the development of vaccines and prophylactic treatments for HCoV-MERS. 6 Acknowledgements This work would not have been possible without the support of my family, mentors, colleagues and friends. I would like to particularly acknowledge Dr. Steven Theriault, Dr. Deborah Court, Dr. Darwyn Kobasa and Dr. Karen Brassinga for acting as mentors, providing me with guidance and the opportunity to learn. To Bradley Cook I would like to extend gratitude for teaching me many laboratory fundamentals and being willing to discuss ideas and results on any Sunday. Todd Cutts worked to keep the lab running smoothly and I would like to thank him for training me to work in containment level 3. Anders Leung introduced me to the project, providing much technical knowledge and “encouragement”. Finally, I would like to mention Dr. Charlene Ranadeherra and Mable “wing-sum” Hagan because they played music in the lab, were always keen to share pens and kept Anders in check. 7 Dedication I would like to dedicate this work to all of the people who contributed to my education in school and more importantly in life. Foremost, my parents Doreen Docherty and Andrew Nikiforuk deserve recognition for their sacrifice and love. I would also like to acknowledge Allison Black, Dimitar Kashchiev and the lovely Veronica Izydorcyzk ()..(). I hope that I can contribute to your lives, as you have to mine. 8 Table of Contents List of Abbreviations: …………………………………………………………………………II Abstract: ……………………………………………………………………………………….III Acknowledgments: …………………………………………………………………………….IV Dedication: ……………………………………………………………………………………..V List of Figure and Tables: ……………………………………………………………………XII Copyright Permissions:………………………………………………………………………XIII Chapter One: Literature Review ....................................................................................................... 14 1.0.0.0: The Nature of Zoonotic Disease ..................................................................................................... 14 1.1.1.0 Introduction ...................................................................................................................................................... 15 1.1.2.0 Order: Nidovirales .......................................................................................................................................... 16 1.1.3.0 Families of the Nidovirales: Arteriviridae, Coronaviridae, Mesoniviridae and Roniviridae . 17 1.1.4.0 Subfamily: Coronavirinae ........................................................................................................................... 17 1.1.5.0 Genus and Lineage: Betacoronavirus, Lineage C ................................................................................ 18 1.2.0.0: Epidemiology of the Middle East Respiratory Syndrome (MERS) ...................................... 19 1.2.1.0: Advent of the HCoV-MERS Epidemic: ................................................................................................ 19 1.2.2.0 Zoonotic Epidemiology: ............................................................................................................................... 20 1.2.3.0 Human-to-Human Transmission of HCoV-MERS .............................................................................. 26 1.4.0.0: Biological Structure of Coronaviruses ......................................................................................... 34 1.4.1.0 Genome Organization ................................................................................................................................... 36 1.4.2.0 Translated Regions ......................................................................................................................................... 39 1.4.3.0 ORF 1a/b Proteins .......................................................................................................................................... 39 1.4.4.0 Glycoprotein (Spike Protein) ...................................................................................................................... 40 1.4.5.0 Envelope and Membrane Proteins ............................................................................................................ 43 1.4.6.0 Nucleocapsid Protein..................................................................................................................................... 43 1.4.7.0 Accessory Proteins ......................................................................................................................................... 44 1.4.8.0 Un-Translated Regions ................................................................................................................................. 45 1.4.9.0 The Coronavirus Leader Sequence, 5’ Un-translated Region (UTR) ............................................ 45 1.4.10.0 Coronavirus 3’ Un-translated Region (UTR) ...................................................................................... 48 1.4.11.0 Coronavirus Transcription Regulatory Sequence (TRS) ................................................................. 48 1.5.0.0: Coronavirus Life Cycle .................................................................................................................... 51 1.5.1.0 Viral Entry ........................................................................................................................................................ 51 1.5.2.0 Transcription and Genome Replication ................................................................................................... 53 1.5.3.0 Discontinuous Negative-Strand Transcription ...................................................................................... 56 1.5.4.0 Coronavirus Genome Replication ............................................................................................................. 59 1.5.5.0 Virus Assembly and Release ...................................................................................................................... 60 1.5.6.0 Overview of Coronavirus Replication ..................................................................................................... 61 1.6.0.0: Reverse Genetics Systems ................................................................................................................ 64 1.6.1.0 Coronavirus Reverse Genetic Systems .................................................................................................... 66 1.6.2.0 Homologous Recombination of DNA for Assembly of Plasmid Vectors .................................... 80 1.6.3.0 In vivo Homologous Recombination ........................................................................................................ 80 1.6.4.0 In vitro Homologous Recombination ....................................................................................................... 82 1.6.5.0 Conclusion ........................................................................................................................................................ 84 1.7.0.0 Declaration of Research Intent and Hypothesis .......................................................................... 84 1.7.0.1 Research Intent ................................................................................................................................................ 84 1.7.0.2 Hypothesis ........................................................................................................................................................ 85 9 1.7.0.3 Significance of Research .............................................................................................................................. 85 Chapter Two: Materials and Methods ............................................................................................. 86 2.1.0.0 Materials and Methods ........................................................................................................... 86 2.1.1.0 General Techniques ............................................................................................................................ 86 2.1.1.1 Cell Culture ...................................................................................................................................................... 86 2.1.1.2 Gel-Electrophoresis and Extraction of PCR Products ........................................................................ 87 2.1.1.3 Enzymatic Restriction Digestion of DNA .............................................................................................. 88 2.1.1.4 Amplification of DNA with TAQ Polymerase for TOPO-TA Cloning .................................... 88 2.1.1.5 Screening of Escherichia coli (E.coli) Colonies by Polymerase Chain Reaction ...................... 89 2.1.1.6 Screening of Saccharomyces cerevisiae (S.cerevisiae) Colonies by Polymerase Chain Reaction ........................................................................................................................................................................... 89 2.1.1.7 Electroporation of E.coli cells with Plasmid DNA .............................................................................. 90 2.1.1.8 Glycerol Stock Preparation of E.coli cells .............................................................................................. 91 2.1.1.9 Isolation of Plasmid Vectors from E.coli cells ...................................................................................... 91 2.1.1.10 Sequencing of Polymerase Chain Reaction Amplicons and Plasmid Constructs .................... 92 2.1.2.0 Strategy for Molecular Cloning of the HCoV-MERS cDNA Infectious Clone System ..... 92 2.1.2.1 Overview ........................................................................................................................................................... 92 2.1.2.2 Synthesis of HCoV-MERS Synthetic Gene Fragments ..................................................................... 93 2.1.2.3 Selection of Bacterial Artificial Chromosome Vector ........................................................................ 93 2.1.2.4 Site Directed Mutagenesis of the TrueBlue-BAC2 Vector ............................................................... 94 2.1.2.5 Primer Design .................................................................................................................................................. 97 2.1.2.6 Splice-by-Overlap Extension Polymerase Chain Reaction ............................................................... 97 2.1.2.7 High-Order Genetic Assembly of the HCoV-MERS Genome ..................................................... 101 2.1.2.8 Sub-cloning the HCoV-MERS Genome .............................................................................................. 103 2.1.2.9 Correction of the HCoV-MERS NS6 Mutation in the mBAC4 Vector ..................................... 106 2.1.2.10 Summary of HCoV-MERS cDNA Infectious Clone System Construction ........................... 109 2.1.3.0 Rescue of the HCoV-MERS virus from the cDNA Infectious Clone Construct ................ 111 2.1.3.1 Rescue of Coronavirus Infectious cDNA Clone Systems in Mammalian Cell Culture ........ 111 2.1.3.2 Viral RNA Isolation.................................................................................................................................... 112 2.1.3.3 Production of HCoV-MERS cDNA From Viral Genomes Extracted by RNA Isolation ..... 112 2.1.3.4 Confirmation of HCoV-MERS Virus Rescue by PCR Amplification of the Viral RDRP Gene ............................................................................................................................................... 113 2.1.3.5 Phylogenetic Analysis of the HCoV-MERS RDRP Gene Fragment .......................................... 113 2.2.0.0 Results ...................................................................................................................................... 116 2.2.1.0 Objective One .................................................................................................................................... 116 2.2.1.1 Construction of the HCoV-MERS cDNA Genome From Synthesized Gene Fragments ..... 116 2.2.2.0 Objective Two .................................................................................................................................... 119 2.2.2.1 Assembly of the HCov-MERS cDNA Genome Fragments Using S.cerevisiae ...................... 119 2.2.2.2 Electroporation of HCoV-MERS pYES1L Constructs into E. coli Cells .................................. 123 2.2.2.2 Restriction Digest of HCoV-MERS pYES1L Maxi-Preparations ............................................... 125 2.2.2.3 Site Directed Mutagenesis of the True Blue-BAC2 Vector to Remove PvuI and BstEII Restriction Enzyme Digest Sites ........................................................................................................................... 127 2.2.2.4 Sub-Cloning of the HCoV-MERS Genome Between pYES1L20 and TrueBlue-BAC2 ΔPvuI/ΔBstEII Vectors ............................................................................................................................................ 129 2.2.2.5 In-vitro Homologous Recombination of the HCoV-MERS mBAC4 Plasmid to Correct The NS6 G11194A Mutation .......................................................................................................................................... 132 2.2.3.0 Objective 3 .......................................................................................................................................... 134 10