TY - BOOK AU - Acheson,N.H. TI - Fundamentals of molecular virology SN - 0471351512 (pbk.) U1 - 616.9101 22 PY - 2007///] CY - Hoboken, NJ PB - Wiley KW - Molecular virology KW - Viruses KW - Viral Physiology N1 - Includes bibliographical references and index; I. INTRODUCTION 1. Introduction to Virology 1 THE NATURE OF VIRUSES 2 Viruses consist of a nucleic acid genome packaged in a protein coat 2 Viruses are dependent on living cells for their replication 2 Virus particles break down and release their genomes inside the cell 2 Virus genomes are either RNA or DNA, but not both 2 WHY STUDY VIRUSES? 3 Viruses are important disease-causing agents 3 Viruses can infect all forms of life 3 Viruses are the most abundant form of life on Earth 4 The study of viruses has led to numerous discoveries in molecular and cell biology 4 A BRIEF HISTORY OF VIROLOGY: THE STUDY OF VIRUSES 5 The scientific study of viruses is very recent 5 Viruses were first distinguished from other microorganisms by filtration 5 The crystallization of tobacco mosaic virus challenged conventional notions about genes and the nature of living organisms 5 The ?phage group? stimulated studies of bacteriophages and helped found the field of molecular biology 7 Study of tumor viruses led to discoveries in molecular biology and understanding of the nature of cancer 7 DETECTION AND TITRATION OF VIRUSES 8 Most viruses were first detected and studied by infection of intact organisms 8 The plaque assay arose from work with bacteriophages 8 Eukaryotic cells cultured in vitro have been adapted for plaque assays 8 Hemagglutination is a convenient and rapid assay for many viruses 9 Virus particles can be seen and counted by electron microscopy 10 The ratio of physical virus particles to infectious particles can be much greater than 1 10 THE VIRUS REPLICATION CYCLE: AN OVERVIEW 10 The single-cycle virus replication experiment 10 An example of a virus replication cycle: mouse polyomavirus 11 Analysis of viral macromolecules reveals the detailed pathways of virus replication 12 xiii STEPS IN THE VIRUS REPLICATION CYCLE 12 1. Virions bind to receptors on the cell surface 12 2. The virion (or the viral genome) enters the cell 12 3. Early viral genes are expressed: the Baltimore classification of viruses 13 The six groups in the Baltimore classification system 13 4. Early viral proteins direct replication of viral genomes 14 5. Late messenger RNAs are made from newly-replicated genomes 15 6. Late viral proteins package viral genomes and assemble virions 15 7. Progeny virions are released from the host cell 15 2. Virus Structure 17 The molecular structure of virus particles 17 How virus structure is studied: viruses come in a variety of sizes and shapes 18 Small viruses come in simple, symmetrical packages 18 Many virus capsids have icosahedral symmetry 18 Some examples of virions with icosahedral symmetry 21 The concept of quasi equivalence 21 How many subunits can be accomodated on the capsid surface? 22 Other structures, large and small, display icosahedral symmetry 23 Many virus capsids are organized as helical tubes 23 Larger viruses come in more complex packages 24 Specific packaging signals direct incorporation of viral genomes into virions 25 Core proteins may accompany the viral genome inside the capsid 25 Scaffolding proteins help in virion assembly but are not incorporated into the mature virion 25 Viral envelopes are made from lipid bilayer membranes 26 Viral glycoproteins are inserted into the lipid membrane to form the envelope 26 Budding is driven by interactions between viral proteins 27 Assembly and disassembly of virions: the importance of an irreversible step 27 3. Virus Classification: The World of Viruses 30 VIRUS CLASSIFICATION 30 Many viruses, infecting virtually all known life forms, have been discovered 30 Virus classification is based on molecular architecture, genetic relatedness, and host organism 31 Contents xiv Contents Viruses are grouped into species, genera, and families 31 Distinct naming conventions and classification schemes have developed in different domains of virology 32 MAJOR VIRUS GROUPS 32 Study of the major groups of viruses leads to understanding of shared characteristics and replication pathways 32 Viruses with single-stranded DNA genomes are small and have few genes 33 Viruses with double-stranded DNA genomes include the largest known viruses 34 Most plant viruses and many viruses of vertebrates have positive-strand RNA genomes 35 All viruses with negative-strand RNA genomes have helical nucleocapsids and some have fragmented genomes 36 Viruses with double-stranded RNA genomes have fragmented genomes packaged in capsids with icosahedral symmetry 37 Viruses with a reverse transcription step in their replication cycle can have either RNA or DNA genomes 38 Satellite viruses and satellite nucleic acids require a helper virus to replicate 39 Viroids do not code for proteins, but replicate independently of other viruses 39 THE EVOLUTIONARY ORIGIN OF VIRUSES 40 The first steps in the development of life on earth: the RNA world 40 Viroids and RNA viruses may have originated in the RNA world 40 The transition to the DNA-based world 40 Small and medium-sized DNA viruses could have arisen as independently-replicating genetic elements in cells 41 Large DNA viruses could have evolved from cells that became obligatory intracellular parasites 41 4. Virus Entry 43 How do virions get into eukaryotic cells? 43 Enveloped and nonenveloped viruses have distinct penetration strategies 44 Some viruses can pass directly from cell to cell 44 A variety of cell surface proteins can serve as specific virus receptors 45 Receptors interact with viral glycoproteins, surface protrusions, or ?canyons? in the surface of the virion 45 Many viruses enter the cell via receptor-mediated endocytosis 45 Passage from endosomes to the cytosol is often triggered by low pH 47 Membrane fusion is mediated by specific viral ?fusion proteins? 47 Fusion proteins undergo major conformational changes that lead to membrane fusion 48 Nonenveloped viruses penetrate by membrane lysis or pore formation 49 Virions and capsids are transported within the cell in vesicles or on microtubules 49 Import of viral genomes into the nucleus 50 ; The many ways in which viral genomes are uncoated and released 50 5. Single-Stranded RNA Bacteriophages 53 The discovery of RNA phages stimulated research into messenger RNA function and RNA replication 53 RNA phages are among the simplest known organisms 54 Two genera of RNA phages have subtle differences 54 RNA phages bind to the F-pilus and use it to insert their RNA into the cell 55 Phage RNA is translated and replicated in a regulated fashion 55 RNA secondary structure controls translation of lysis and replicase genes 56 Ribosomes translating the coat gene disrupt secondary structure, allowing replicase translation 57 Ribosomes terminating coat translation can reinitiate at the lysis gene start site 57 Replication versus translation: competition for the same RNA template 58 Genome replication requires four host cell proteins plus the replicase 58 A host ribosomal protein directs polymerase to the coat start site 59 Polymerase skips the first A residue but adds a terminal A to the minus strand copy 59 Synthesis of plus strands is less complex and more efficient than that of minus strands 59 The start site for synthesis of maturation protein is normally inaccessible to ribosomes 61 Synthesis of maturation protein is controlled by delayed RNA folding 61 Assembly and release of virions 62 6 Bacteriophage _X 174 63 _X174: a tiny virus with a big impact 63 Overlapping reading frames allow efficient use of a small genome 64 _X174 binds to glucose residues in lipopolysaccharide on the cell surface 65 _X174 delivers its genome into the cell through spikes on the capsid surface 66 Stage I DNA replication generates double-stranded replicative form DNA 66 Gene expression is controlled by the strength of promoters and transcriptional terminators 66 Replicative form DNAs are amplified via a rolling circle mechanism 67 Summary of viral DNA replication mechanisms 67 Procapsids are assembled by the use of scaffolding proteins 67 Contents xv Scaffolding proteins have a flexible structure 68 Single-stranded genomes are packaged into procapsids as they are synthesized 68 Role of the J protein in DNA packaging 69 Cell lysis caused by E protein leads to release of phage 69 Did all icosahedral ssDNA virus families evolve from a common ancestor? 69 7. Bacteriophage T7 71 T7: a model phage for DNA replication, transcription, and RNA processing 71 T7 genes are organized into three groups based on transcription and gene function 72 Entry of T7 DNA into the cytoplasm is powered by transcription 73 Transcription of class II and III genes requires a novel T7-coded RNA polymerase 73 Class II genes code for enzymes involved in T7 DNA replication 74 T7 RNAs are cleaved by host cell ribonuclease III to smaller, stable mRNAs 74 Regulation of class III gene expression 74 DNA replication starts at a unique internal origin and is primed by T7 RNA polymerase 75 Large DNA concatemers are formed during replication 76 Concatemers are processed and packaged into preformed proheads 76 Special features of the T7 family of phages 76 8. Bacteriophage Lambda: A PiƱata of Paradigms 79 In the beginning . . . 80 Uptake of _DNA depends on cellular proteins involved in sugar transport 80 The _lytic transcription program is controlled by termination and antitermination of RNA synthesis at specific sites on the genome 81 The CI repressor blocks expression of the lytic program by regulating three nearby promoters: PL, PR, and PRM 82 Cleavage of CI repressor in cells with damaged DNA leads to prophage induction 83 The Cro repressor suppresses CI synthesis and regulates early gene transcription 83 Making the decision: Go lytic or lysogenize? 83 A quick review 85 Breaking and entering: The insertion of _DNA into the bacterial chromosome 85 The great escape: The liberation of _DNA from the bacterial chromosome 86 Int synthesis is controlled by retroregulation 86 _DNA Replication is directed by O and P, but carried out by host cell proteins 87 Assembly of _heads involves chaperone and scaffolding proteins 87 DNA is inserted into preformed proheads by an ATPdependent mechanism 87 Host cell lysis 88 9. Parvoviruses 89 Parvoviruses have very small virions and a linear, singlestranded DNA genome 89 Parvoviruses replicate in cells that are going through the cell cycle 90 Discovery of mammalian parvoviruses 90 Parvoviruses have one of the simplest known virion structures 91 Parvoviruses have very few genes 91 Single-stranded parvovirus DNAs have unusual terminal structures 92 Uncoating of parvovirus virions takes place in the nucleus and is cell-specific 92 DNA replication begins by extension of the 3_ end of the terminal hairpin 93 The DNA ?end replication? problem 93 Steps in DNA replication 93 Non-structural proteins are multifunctional 95 Adenovirus functions that help AAV replication 96 In the absence of helper virus, AAV DNA can integrate into the cell genome 96 Parvovirus pathogenesis: the example of B19 virus 96 10. Polyomaviruses 98 Mouse polyomavirus was discovered as a tumor-producing infectious agent 98 Simian virus 40 was found as a contaminant of Salk poliovirus vaccine 99 Polyomaviruses are models for studying DNA virus replication and tumorigenesis 99 Polyomavirus capsids are constructed from pentamers of the major capsid protein 99 The circular DNA genome is packaged with cellular histones 100 Circular DNA becomes supercoiled upon removal of histones 100 ; Supercoiled DNA can be separated from relaxed or linear DNA molecules 101 Polyomavirus genes are organized in two divergent transcription units 102 Virions enter cells in caveolae and are transported to the nucleus 102 The viral minichromosome is transcribed by cellular RNA polymerase II 103 Four early mRNAs are made by differential splicing of a common transcript 104 T antigens share common N-terminal sequences but have different C-terminal sequences 105 T antigens bring resting cells into the DNA synthesis (S) phase of the cell cycle 105 xvi Contents Small T antigen inhibits protein phosphatase 2A and induces cell cycling 105 Middle T antigen stimulates protein tyrosine kinases that signal cell proliferation and division 105 Large T antigen activates or suppresses transcription of cellular genes by binding to a number of important cellular regulatory proteins 107 Large T antigen hexamers bind to the origin of DNA replication and locally unwind the two DNA strands 108 Large T antigen hexamers assemble cellular DNA synthesis machinery to initiate viral DNA replication 110 High levels of late transcripts are made after DNA replication begins 111 Three late mRNAs are made by alternative splicing 112 How do polyomaviruses transform cells in vitro and cause tumors in vivo? 112 11. Papillomaviruses 114 Papillomaviruses cause warts and other skin and mucosal lesions 114 Oncogenic human papillomaviruses are a major cause of genital tract cancers 115 Papillomaviruses are not easily grown in cell culture 115 Papillomavirus genomes are circular, double-stranded DNA 116 The infectious cycle follows differentiation of epithelial cells 116 Viral mRNAs are made from two promoters and two polyadenylation signals 117 Viral E1 and E2 proteins bind to the replication origin and direct initiation of DNA replication 118 Viral E7 protein interacts with cell cycle regulatory proteins, particularly Rb 118 Viral E6 protein controls the level of cellular p53 protein 120 Synergism between E6 and E7 and the predisposition to cancer 121 Cells transformed by papillomaviruses express E6 and E7 gene products from integrated viral DNA 121 Future prospects for diagnosis and treatment of diseases caused by papillomaviruses 121 12. Adenoviruses 123 Adenoviruses cause respiratory and enteric infections in humans 124 Adenoviruses can be oncogenic, but not in humans 124 Virions have icosahedral symmetry and are studded with knobbed fibers 124 Fibers make contact with cellular receptor proteins to initiate infection 124 Expression of adenovirus genes is controlled at the level of transcription 126 E1A proteins are the kingpins of the adenovirus growth cycle 127 E1A proteins bind to the retinoblastoma protein and activate E2F, a cellular transcription factor 127 E1A proteins also activate other cellular transcription factors 128 E1A proteins indirectly induce apoptosis by activation of cellular p53 protein 128 E1B proteins suppress E1A-induced apoptosis, allowing viral replication to proceed 128 The preterminal protein primes DNA synthesis carried out by viral DNA polymerase 129 Single-stranded DNA is circularized via the inverted terminal repeat 130 The major late promoter is activated after DNA replication begins 131 Five different poly(A) sites and alternative splicing generate multiple late mRNAs 131 The tripartite leader ensures efficient transport of late mRNAs to the cytoplasm 132 The tripartite leader directs efficient translation of late adenovirus proteins 132 Adenoviruses kill cells by apoptosis, aiding virus release 132 Cell transformation and oncogenesis by human adenoviruses 132 13. Herpes Simplex Virus 134 Herpesviruses are important human pathogens 135 Most herpesviruses can establish latent infections 135 Herpes simplex virus genomes contain both unique and repeated sequence elements 135 Nomenclature of herpes simplex virus genes and proteins 137 The icosahedral capsid is enclosed in an envelope along with tegument proteins 137 Entry by fusion is mediated by envelope glycoproteins and may occur at the plasma membrane or in endosomes 138 Viral genes are sequentially expressed during the replication cycle 138 Tegument proteins interact with cellular machinery to activate viral gene expression and to degrade cellular messenger RNAs 139 Immediate early ( _) genes regulate expression of other herpesvirus genes 140 _gene products set the stage for viral DNA replication 140 Herpesvirus begins with bidirectional DNA replication 141 Rolling-circle replication subsequently produces multimeric concatemers of viral DNA 141 DNA replication leads to activation of _1 and _2 genes 142 Viral nucleocapsids are assembled on a scaffold in the nucleus 143 Envelopment and egress: three possible routes 143 Many viral genes are involved in blocking host responses to infection 143 The establishment and maintenance of virus latency 145 Latency-associated transcripts include stable introns 145 Contents xvii 14. Baculoviruses 147 Insect viruses were first discovered as pathogens of silkworms 148 Baculoviruses are used for pest control and to express eukaryotic proteins 148 Baculoviruses produce two kinds of particles: ?budded? and ?occlusion-derived? virions 149 Baculoviruses have large, circular DNA genomes and encode many proteins 150 Insects are infected by ingesting occlusion bodies; infection spreads within the insect via budded virions 151 Viral proteins are expressed in a timed cascade regulated at the transcription level 152 Immediate early gene products control expression of early genes 152 Early gene products regulate DNA replication, late transcription, and apoptosis 153 Late genes are transcribed by a novel virus-coded RNA polymerase 153 Baculoviruses are widely used to express foreign proteins 156 15. Poxviruses 157 Smallpox was a debilitating and fatal worldwide disease 158 Variolation led to vaccination, which has eradicated smallpox worldwide 158 Poxviruses remain a subject of intense research interest 159 Linear vaccinia virus genomes have covalently sealed hairpin ends and lack introns 159 Two forms of vaccinia virions have different roles in spreading infection 160 Poxviruses replicate in the cytoplasm 162 Poxvirus genes are expressed in a regulated transcriptional cascade controlled by viral transcription factors 162 Virus-coded enzymes packaged in the core carry out early RNA synthesis and processing 162 Enzymes that direct DNA replication are encoded by early mRNAs 163 Poxviruses produce large concatemeric DNA molecules that are resolved into monomers 164 Postreplicative mRNAs have 5_ end poly(A) extensions and 3_ end heterogeneity 164 Mature virions are formed within virus ?factories? 165 Extracellular virions are extruded through the plasma membrane by actin tails 166 Poxviruses make several proteins that target host immune defenses 167 16. Picornaviruses 169 Picornaviruses cause a variety of human and animal diseases including poliomyelitis and the common cold 170 Poliovirus: a model picornavirus for vaccine development and studies of replication 170 Picornavirus virions bind to cellular receptors via depressions or loop regions on their surface 171 Genome RNA may pass through pores formed in cell membranes by capsid proteins 171 Translation initiates on picornavirus RNAs by a novel internal ribosome entry mechanism 172 Essential features of picornavirus IRES elements 173 Interaction of picornavirus IRES elements with host cell proteins 175 Picornavirus proteins are made as a single precursor polyprotein that is autocatalytically cleaved by viral proteinases 176 Picornaviruses make a variety of proteinases that cleave the polyprotein and some cellular proteins 176 Replication of picornavirus RNAs is initiated in a multiprotein complex bound to proliferated cellular vesicles 176 RNA synthesis is primed by VPg covalently bound to uridine residues 177 Virion assembly involves cleavage of VP0 to VP2 plus VP4 178 Inhibition of host cell macromolecular functions 179 17. Flaviviruses 181 Flaviviruses cause several important human diseases 182 Yellow fever is a devastating human disease transmitted by mosquitoes 182 A live, attenuated yellow fever virus vaccine is available and widely used 183 Hepatitis C virus: a recently discovered member of the Flaviviridae 183 The flavivirus virion contains an icosahedral nucleocapsid wrapped in a tightly fitted envelope 183 Flavivirus E protein directs both binding to receptors and membrane fusion 184 Flaviviruses enter the cell by pH-dependent fusion 185 Flavivirus genome organization resembles that of picornaviruses 185 The polyprotein is processed by both viral and cellular proteinases 186 Nonstructural proteins organize protein processing, viral RNA replication, and capping 187 Flavivirus RNA synthesis is carried out on membranes in the cytoplasm 188 Virus assembly also takes place at intracellular membranes 189 18. Togaviruses 191 Most togaviruses are arthropod borne, transmitted between vertebrate hosts by mosquitoes 192 Togavirus virions contain a nucleocapsid with icosahedral symmetry wrapped in an envelope of the same symmetry 192 Togaviruses enter cells by low pH-induced fusion inside endosome vesicles 193 xviii Contents Nonstructural proteins are made as a polyprotein that is cleaved by a viral protease 193 Partly-cleaved nonstructural proteins catalyze synthesis of full-length antigenome RNA 194 Replication and transcription: synthesis of genome and subgenomic RNAs 196 Structural proteins are cleaved during translation and directed to different cellular locations 196 Assembly of virions and egress at the plasma membrane 197 Effects of mutations in viral proteins on cytopathic effects and on pathogenesis 198 Alphaviruses have been modified to serve as vectors for the expression of heterologous proteins 199 Alphavirus vectors have multiple potential uses 199 ; 19. CORONAVIRUSES 201 Coronaviruses cause common colds in humans and important veterinary diseases 202 A newly emerged coronavirus caused a worldwide epidemic of severe acute respiratory syndrome (SARS) 202 The SARS coronavirus may have passed from animals to humans via direct contact 202 Coronaviruses have large, single-stranded, positive sense RNA genomes 203 Coronaviruses fall into three groups based on genome sequences 203 Coronaviruses have enveloped virions containing helical nucleocapsids 204 Coronavirus virions contain multiple envelope proteins 204 Coronavirus spike proteins bind to a variety cellular receptors 205 The virus envelope fuses with the plasma membrane or an endosomal membrane 206 The replicase gene is translated from genome RNA into a polyprotein that is processed by viral proteinases 206 RNA polymerase, RNA helicase, and RNA modifying enzymes are coded by the replicase gene 207 Replication complexes are associated with cytoplasmic membranes 207 Genome replication proceeds via a full-length negativestrand intermediate 208 Transcription produces a nested set of subgenomic mRNAs 208 Subgenomic mRNAs are most likely transcribed from subgenomic negative-sense RNA templates 208 The alternative model of discontinuous transcription of antigenome RNA is unlikely to be correct 209 Assembly of virions takes place at intracellular membrane structures 211 Adaptability of Coronaviruses 212 20. Paramyxoviruses and Rhabdoviruses 214 The mononegaviruses: a group of related negative-strand RNA viruses 215 Rabies is a fatal human encephalitis caused by a rhabdovirus 215 Measles is a serious childhood disease caused by a paramyxovirus 215 Paramyxovirus and rhabdovirus virions have distinct morphologies 216 Viral envelope proteins are responsible for receptor binding and fusion with cellular membranes 217 Genome RNA is contained within helical nucleocapsids 218 Paramyxoviruses enter the cell by fusion with the plasma membrane at neutral pH 218 Gene order is conserved among different paramyxoviruses and rhabdoviruses 219 Viral messenger RNAs are synthesized by an RNA polymerase packaged in the virion 220 Viral RNA polymerase initiates transcription exclusively at the 3? end of the viral genome 220 The promoter for plus-strand RNA synthesis consists of two sequence elements separated by one turn of the ribonucleoprotein helix 220 mRNAs are synthesized sequentially from the 3? to the 5? end of the genome RNA 222 The P/C/V gene codes for several proteins by using alternative translational starts and by mRNA ?editing? 223 Functions of P, C and V proteins 224 N protein levels control the switch from transcription to genome replication 224 Virions are assembled at the plasma membrane 224 21. Filoviruses 226 Marburg and Ebola viruses: sporadically emerging viruses that cause severe, often fatal disease 227 Filoviruses are related to paramyxoviruses and rhabdoviruses 228 Filoviruses cause hemorrhagic fever 228 Filovirus genomes contain seven genes in a conserved order 228 Filovirus transcription, replication and assembly 230 Cloned cDNA copies of viral mRNAs and viral genome RNA are used for study of filoviruses 230 Multi-plasmid transfection systems allow recovery of infectious filoviruses 230 Filovirus glycoprotein mediates both receptor-binding and entry by fusion 231 Ebola virus uses RNA editing to make two glycoproteins from the same gene 232 Does the secreted glycoprotein play a role in virus pathogenesis? 232 Minor nucleocapsid proteinVP30 activates viral mRNA synthesis in Ebola virus 233 Matrix protein VP40 directs budding and formation of filamentous particles 234 Most filovirus outbreaks have occurred in equatorial Africa 234 Contents xix Filovirus infections are transmitted to humans from an unknown animal origin 235 Spread of filovirus infections among humans is limited to close contacts 235 Pathogenesis of filovirus infections 236 Clinical features of infection 236 22. Bunyaviruses 238 Most bunyaviruses are transmitted by arthropod vectors, including mosquitoes and ticks 239 Some bunyaviruses cause severe hemorrhagic fever, respiratory disease, or encephalitis 240 Bunyaviruses encapsidate a segmented RNA genome in a simple enveloped particle 240 Bunyavirus protein coding strategies: negative-strand and ambisense RNAs 240 L RNA codes for viral RNA polymerase 241 M RNA codes for virion envelope glycoproteins 242 S RNA codes for nucleocapsid protein and a nonstructural protein 243 After attachment via the virion glycoproteins, bunyaviruses enter the cell by endocytosis 243 Bunyavirus mRNA synthesis is primed by the capped 5? ends of cellular mRNAs 243 Coupled translation and transcription may prevent premature termination of mRNAs 244 Genome replication begins once sufficient N protein is made 244 Virus assembly takes place at Golgi membranes 245 Evolutionary potential of bunyaviruses via genome reassortment 246 23. Orthomyxoviruses 248 Influenza viruses cause serious acute disease in humans, and occasional pandemics 249 Influenza virus infections of the respiratory tract can lead to secondary bacterial infections 249 Orthomyxoviruses are negative-strand RNA viruses with segmented genomes 249 Eight influenza virus genome segments code for a total of ten different viral proteins 251 Hemagglutinin protein binds to cell receptors and mediates fusion of the envelope with the endosomal membrane 252 M2 is an ion channel that facilitates release of nucleocapsids from the virion 252 Nucleocapsids enter the nucleus, where mRNA synthesis and RNA replication occur 253 Capped 5_ ends of cellular pre-messenger RNAs are used as primers for synthesis of viral mRNAs 254 Viral mRNAs terminate in poly(A) tails generated by ?stuttering? transcription 255 Two influenza A mRNAs undergo alternative splicing in the nucleus 255 Genome replication begins when newly synthesized NP protein enters the nucleus 255 Nucleocapsids are exported from the nucleus in a complex with matrix protein and NS2 256 The NS1 protein interferes with polyadenylation of cellular mRNAs 256 NS1 also inhibits activation of PKR, an important antiviral pathway induced by interferon 257 Viral envelope proteins assemble in the plasma membrane and direct budding of virions 257 Neuraminidase cleaves sialic acid, the cellular receptor that binds to HA 257 Influenza virus strains vary in both transmissibility and pathogenicity 257 Genetic variability generates new virus strains that can cause pandemics 258 The 1918 pandemic influenza A virus was probably not a reassortant virus 258 Genome sequences from some previous influenza A virus strains confirm the antigenic shift hypothesis 258 Highly pathogenic influenza A strains in poultry farms could lead to a new pandemic 259 24. Reoviruses 261 Reoviruses were the first double-stranded RNA viruses discovered 262 Some members of the Reoviridae are important pathogens 262 Reoviridae have segmented genomes made of doublestranded RNA 262 Reovirus virions contain concentric layers of capsid proteins 263 The attachment protein binds to one or two cellular receptors 265 During entry, the outer capsid is stripped from virions and the core is released into the cytoplasm 265 Enzymes in the viral core synthesize and cap messenger RNAs 266 Translation of reovirus mRNAs is regulated 267 Interferon and PKR: effects on viral and cellular protein synthesis 267 Synthesis of progeny double-stranded genomes occurs within subviral particles 268 Reoviruses induce apoptosis via activation of transcription factor NF- _B 269 Studies of reovirus pathogenesis in mice 270 25. Retroviruses 272 Retroviruses have a unique replication cycle based on reverse transcription and integration of their genomes 273 Viral proteins derived from the gag, pol and env genes are incorporated in virions 273 Retroviruses enter cells by the fusion pathway 274 xx Contents Viral RNA is converted into a double-stranded DNA copy by reverse transcription 275 A copy of proviral DNA is integrated into the cellular genome at a random site 277 Sequence elements in the long terminal repeats direct transcription and polyadenylation by host cell enzymes 277 Differential splicing generates multiple mRNAs 279 The Gag/Pol polyprotein is made by suppression of termination and use of alternative reading frames 279 Virions mature into infectious particles after budding from the plasma membrane 280 Acute transforming retroviruses express mutated forms of cellular growth signalling proteins 281 Retroviruses lacking oncogenes can transform cells by insertion of proviral DNA near a proto-oncogene 282 26. Human Immunodeficiency Virus Type 1 284 Human immunodeficiency virus type 1 (HIV-1) and acquired immunodeficiency syndrome 285 HIV-1 infection leads to a progressive loss of cellular immunity and increased susceptibility to opportunistic infections 285 HIV-1 is a complex retrovirus 287 HIV-1 targets cells of the immune system by recognizing CD4 antigen and chemokine receptors 287 Virus mutants arise rapidly because of errors generated during reverse transcription 288 Unlike other retroviruses, HIV-1 directs transport of proviral DNA into the cell nucleus 288 Latent infection complicates the elimination of HIV-1 289 The Tat protein increases HIV-1 transcription by stimulating elongation by RNA polymerase II 289 The Rev protein mediates cytoplasmic transport of viral mRNAs that code for HIV-1 structural proteins 290 Together, the Tat and Rev proteins strongly upregulate viral protein expression 291 The Vif protein increases virion infectivity by counteracting a cellular deoxcytidine deaminase 291 The Vpr protein enables the preintegration complex to be transported to the nucleus 291 The Vpu protein enhances release of progeny virions from infected cells 291 The Nef protein is an important mediator of pathogenesis 292 27. Human T-Cell Leukemia Virus Type 1 294 Discovery of the first human retrovirus 294 Like lentiviruses, HTLV-1 codes for regulatory proteins by producing doubly-spliced mRNAs 295 HTLV-1 Rex regulates polyadenylation, splicing, and nuclear export of viral RNAs 296 HTLV-1 Tax regulates transcription of viral and cellular genes 297 Cell transformation by HTLV-I is mediated by Tax 299 The interleukin-2?autocrine loop stimulates T-cell proliferation 299 Activation of the Jak-Stat pathway by p12I mimics interleukin-2 stimulation 299 ; Cell Cycle Progression: p16INK4A and cyclin-dependent kinases 300 The mitotic spindle checkpoint and MAD1 300 Downregulation of p53 activity by Tax allows T cell proliferation 301 Diseases caused by HTLV-1 develop slowly and can be severe 301 Coinfection by HIV-1 and HTLV-1 is an emerging problem 302 Antiviral therapy of disease caused by HTLV-1 has not met with great success 302 28. Hepadnaviruses 303 At least seven distinct viruses cause human hepatitis 304 The discovery of hepatitis B virus 304 Dane particles are infectious virions; abundant noninfectious particles lack nucleocapsids 305 The viral genome is a circular, partly single-stranded DNA with overlapping reading frames 305 Nucleocapsids enter the cytoplasm via fusion and are transported to the nucleus 305 Transcription of viral DNA gives rise to several mRNAs and a pregenome RNA 307 The roles of hepatitis B virus proteins 308 The pregenome RNA is packaged by interaction with polymerase and core proteins 309 Genome replication occurs via reverse transcription of pregenome RNA 309 Virions are formed by budding in the endoplasmic reticulum 311 Hepatitis B virus can cause chronic or acute hepatitis, cirrhosis, and liver cancer 312 Hepatits B virus is transmitted by blood transfusions, contaminated needles, and unprotected sex 313 A recombinant vaccine is available 313 Antiviral drug treatment has real but limited success 313 29 Viroids and Hepatitis Delta Virus 315 Viroids are small, circular RNAs that do not encode proteins 316 Group A and group B viroids have distinct properties 316 Viroids replicate via linear multimeric RNA intermediates 317 Three enzymatic activities are needed for viroid replication 317 Contents xxi How do viroids cause disease? 318 Interaction of viroid RNA with cellular RNAs or proteins may disrupt cell metabolism 318 Plant satellite RNAs resemble viroids but are encapsidated 320 Hepatitis delta virus is a human viroid-like satellite virus 320 Hepatitis delta virus may use two different cellular RNA polymerases to replicate 320 RNA editing generates two forms of hepatitis delta antigen 322 Conclusion: viroids may be a link to the ancient RNA world 322 30. Prions 323 Prions are proteins that cause fatal brain diseases 323 Prion diseases were first detected in domestic ruminants 324 Human prion diseases can be either inherited or transmitted 324 The infectious agent of prion diseases contains protein but no detectable nucleic acid 325 PrPSc is encoded by a host cell gene 325 Differences between PrPC and PrPSc 326 The prion hypothesis: formation of infectious and pathogenic prions from normal PrPC 326 Is the prion hypothesis correct? 327 Pathology and diagnosis of prion diseases 330 Genetics of prion diseases 330 Prion diseases are not usually transmitted among different species 330 Strain variation and crossing of the species barrier 331 The nature of the prion infectious agent 331 31. Interferons 333 Virus-infected cells secrete interferons, which protect nearby cells against virus infection 334 Interferons are a first line of host defense against viruses but therapeutic use has been limited 334 Interferons _, _, and _are made by different cells and have distinct functions 335 Transcription of interferon genes is activated by virus infection or double-stranded RNA 335 Transcriptional activation occurs by binding of transcription factors to interferon gene enhancers 335 Interferon signal transduction is carried out via the Jak-Stat pathway 337 Antiviral activities induced by interferon 338 Interferons have diverse effects on the immune system 340 The adaptive immune system 340 Interferons stimulate antigen processing and presentation 342 Interferon and the development of CD4-positive helper T-cells 342 The role of interferon in macrophage activation and cellular immunity 343 Effects of interferons on antibody production 343 Interferons regulate cell growth and apoptosis 343 Viruses have developed numerous strategies to evade the interferon response 343 Conclusion: interferons are a first line of defense against virus infection 344 32 Antiviral Chemotherapy 346 The discovery and widespread use of antiviral compounds began only recently 346 Importance of antiviral drugs for basic science 347 How are antiviral drugs obtained? 347 Targeting drugs to specific steps of virus infection 347 Capsid-binding drugs prevent attachment and entry of virions 348 Amantadine blocks ion channels and inhibits uncoating of influenza virions 349 Nucleoside analogues target viral DNA polymerases 349 Acyclovir is selectively phosphorylated by herpesvirus thymidine kinases 350 Acyclovir is preferentially incorporated by herpesvirus DNA polymerases 351 Cytomegalovirus encodes a protein kinase that phosphorylates ganciclovir 351 HIV-1 reverse transcriptase preferentially incorporates azidothymidine into DNA, leading to chain termination 354 Nonnucleoside inhibitors selectively target viral replication enzymes 354 Protease inhibitors can interfere with virus assembly and maturation 354 Ritonavir: a successful protease inhibitor of HIV-1 that was developed by rational methods 354 Neuraminidase inhibitors suppress release and spread of influenza virus 355 Antiviral chemotherapy shows promise for the future 357 33. Eukaryotic Virus Vectors 358 Many viruses can be engineered to deliver and express specific genes 358 Virus vectors are used to produce high levels of specific proteins in cultured cells 359 Gene therapy is an expanding application of virus vectors 360 Virus vectors are produced by transfection of cells with plasmids containing deleted genomes 360 Virus vectors are engineered to produce optimal levels of gene products 361 xxii Contents ADENOVIRUS VECTORS 362 Adenovirus vectors are widely used in studies of gene transfer and antitumor therapy 362 Replication-defective adenovirus vectors are propagated in complementing cell lines 362 Replication-competent adenovirus vectors are useful tools in antitumor therapy 363 Advantages and limitations of adenovirus vectors 363 RETROVIRUS VECTORS 364 Retrovirus vectors incorporate transgenes into the cell chromosome 364 Packaging cell lines express retrovirus enzymatic and structural proteins 364 Strategies for controlling transgene transcription 364 Lentivirus vectors are used for gene delivery to nondividing cells 365 Production of lentivirus vectors requires additional cis-acting sequences 366 Applications of retrovirus vectors: treatment of blood disorders 367 Advantages and limitations of retrovirus vectors 367 ADENO-ASSOCIATED VIRUS VECTORS 367 Adeno-associated virus vectors can insert transgenes into a specific chromosomal locus 367 Production of AAV vectors usually requires a helper virus 367 Applications of adeno-associated virus vectors: treatment of hemophilia 368 Advantages and limitations of AAV vectors 368 34. Viral Vaccines 370 A brief history of viral vaccines 371 Early vaccine technology was crude but effective 372 Embryonated chicken eggs and cell culture played major roles in recent vaccine development 373 Major categories of viral vaccines 373 Advantages and drawbacks of vaccine types 374 How do viral vaccines work? 375 The role of the immune system in fighting viral infections 375 Some vaccines target mainly antibody production; others target the cellular immune response 376 New approaches to vaccine development show great promise 376 The changing vaccine paradigm 378 Vaccine-associated adverse events 378 Ethical issues in the use of viral vaccines 380 UR - http://www.loc.gov/catdir/toc/ecip071/2006030744.html UR - http://www.loc.gov/catdir/enhancements/fy0740/2006030744-d.html ER -