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Copyright © 2010 Pearson Education, Inc. Lectures prepared by Christine L. Case Chapter 13 Viruses, Viroids, and Prions

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Page 1: Start-here Ch13 Lecture

Copyright © 2010 Pearson Education, Inc.Lectures prepared by Christine L. Case

Chapter 13

Viruses, Viroids, and Prions

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Q&A

Researchers converted skin cells into embryonic stem cells. They first inserted RNA complementary for four embryonic genes into a virus; the resulting provirus inserted the genes into the skin cells’ DNA. What virus can do this?

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General Characteristics of Viruses

13-1 Differentiate a virus from a bacterium.

Learning Objective

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General Characteristics of Viruses

Obligatory intracellular parasites Contain DNA or RNA Contain a protein coat Some are enclosed by an envelope Some viruses have spikes Most viruses infect only specific types of cells

in one host Host range is determined by specific host

attachment sites and cellular factors

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Copyright © 2010 Pearson Education, Inc. Figure 13.1

Virus Sizes

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Check Your Understanding How could the small size of viruses have helped

researchers detect viruses before the invention of the electron microscope? 13-1

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Viral Structure

13-2 Describe the chemical and physical structure of both an enveloped and a nonenveloped virus.

Learning Objective

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Virion Structure

Figure 13.2a

Nucleic acid DNA or RNA

Capsid Capsomeres

Envelope Spikes

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Copyright © 2010 Pearson Education, Inc. Figure 13.2

Morphology of a Polyhedral Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.16a

Polyhedral Viruses

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Copyright © 2010 Pearson Education, Inc. Figure 13.3

Morphology of an Enveloped Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.16b

Enveloped Viruses

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Morphology of a Helical Virus

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Morphology of a Complex Virus

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Check Your Understanding Diagram a nonenveloped polyhedral virus that has

spikes. 13-2

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13-3 Define viral species.

13-4 Give an example of a family, genus, and common name for a virus.

Taxonomy of Viruses

Learning Objectives

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Taxonomy of Viruses

Family names end in -viridae. Genus names end in -virus. Viral species: A group of viruses sharing the same

genetic information and ecological niche (host). Common names are used for species.

Subspecies are designated by a number.

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Taxonomy of Viruses

Herpesviridae Herpesvirus Human herpes virus

HHV-1, HHV-2, HHV-3

Retroviridae Lentivirus Human

immunodeficiency virus HIV-1, HIV-2

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Check Your Understanding How does a virus species differ from a bacterial

species? 13-3 Attach the proper endings to Papilloma- to show the

family and genus that includes HPV, the cause of cervical cancer. 13-4

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Isolation, Cultivation, and Identification

13-5 Describe how bacteriophages are cultured.

13-6 Describe how animal viruses are cultured.

13-7 List three techniques used to identify viruses.

Learning Objectives

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Copyright © 2010 Pearson Education, Inc. Figure 13.6

Growing Viruses

Viruses must be grown in living cells Bacteriophages

form plaques on a lawn of bacteria

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Copyright © 2010 Pearson Education, Inc. Figure 13.7

Growing Viruses

Animal viruses may be grown in living animals or in embryonated eggs

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Copyright © 2010 Pearson Education, Inc. Figure 13.8

Growing Viruses

Animal and plant viruses may be grown in cell culture Continuous cell lines may be maintained indefinitely

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Virus Identification

Cytopathic effects Serological tests

Detect antibodies against viruses in a patient Use antibodies to identify viruses in neutralization tests,

viral hemagglutination, and Western blot

Nucleic acids RFLPs PCR

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Copyright © 2010 Pearson Education, Inc. Figure 13.9

Virus Identification

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Check Your Understanding What is the plaque method? 13-5 Why are continuous cell lines of more practical use than

primary cell lines for culturing viruses? 13-6 What tests could you use to identify influenza virus in a

patient? 13-7

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Viral Multiplication

13-8 Describe the lytic cycle of T-even bacteriophages.

13-9 Describe the lysogenic cycle of bacteriophage lambda.

Learning Objectives

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The Lytic Cycle

Attachment: Phage attaches by tail fibers to host cell

Penetration: Phage lysozyme opens cell wall; tail sheath contracts to force tail core and DNA into cell

Biosynthesis: Production of phage DNA and proteins

Maturation: Assembly of phage particles Release: Phage lysozyme breaks cell wall

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Copyright © 2010 Pearson Education, Inc. Figure 13.10

A Viral One-Step Growth Curve

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Lytic Cycle of a T-Even Bacteriophage

1

2

3

Figure 13.11

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4

Figure 13.11

Lytic Cycle of a T-Even Bacteriophage

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Results of Multiplication of Bacteriophages Lytic cycle

Phage causes lysis and death of host cell

Lysogenic cycle Prophage DNA incorporated in host DNA Phage conversion Specialized transduction

ANIMATION Viral Replication: Temperate Bacteriophages

ANIMATION Viral Replication: Virulent Bacteriophages

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Copyright © 2010 Pearson Education, Inc. Figure 13.12

The Lysogenic Cycle

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2

3

4

5

6

Figure 8.28

Generalized Transduction

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Specialized Transduction

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2

3

4

5

6

Specialized Transduction

ANIMATION Transduction: Specialized Transduction

ANIMATION Transduction: Generalized Transduction

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Check Your Understanding How do bacteriophages get nucleotides and

amino acids if they don’t have any metabolic enzymes? 13-8

Vibrio cholerae produces toxin and is capable of causing cholera only when it is lysogenic. What does this mean? 13-9

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Viral Multiplication

13-10 Compare and contrast the multiplication cycle of DNA- and RNA-containing animal viruses.

Learning Objective

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Multiplication of Animal Viruses

Attachment: Viruses attach to cell membrane Penetration by endocytosis or fusion Uncoating by viral or host enzymes Biosynthesis: Production of nucleic acid and

proteins Maturation: Nucleic acid and capsid proteins

assemble Release by budding (enveloped viruses) or rupture

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Copyright © 2010 Pearson Education, Inc. Figure 13.14a

Attachment, Penetration, Uncoating

By pinocytosis

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Attachment, Penetration, Uncoating

By fusion

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Copyright © 2010 Pearson Education, Inc. Figure 13.20

Budding of an Enveloped Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.20

Budding of an Enveloped Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.15

Multiplication of DNA Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.17a

Sense Strand (+ Strand) RNA Virus

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Antisense Strand (– Strand) RNA Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.17c

Double-Stranded RNA Virus

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Copyright © 2010 Pearson Education, Inc. Figure 13.17

Multiplication of RNA-Containing Viruses

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Copyright © 2010 Pearson Education, Inc. Figure 13.19

Multiplication of a Retrovirus

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ANIMATION Viral Replication: Animal Viruses

ANIMATION Viral Replication: Overview

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Check Your Understanding Describe the principal events of attachment, entry,

uncoating, biosynthesis, maturation, and release of an enveloped DNA-containing virus. 13-10

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Viruses and Cancer

13-11 Define oncogene and transformed cell.

13-12 Discuss the relationship between DNA- and RNA-containing viruses and cancer.

Learning Objectives

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Cancer

Activated oncogenes transform normal cells into cancerous cells

Transformed cells have increased growth, loss of contact inhibition, tumor-specific transplant antigens, and T antigens

The genetic material of oncogenic viruses becomes integrated into the host cell's DNA

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Oncogenic Viruses

Oncogenic DNA viruses Adenoviridae Herpesviridae Poxviridae Papovaviridae Hepadnaviridae

Oncogenic RNA viruses Retroviridae Viral RNA is

transcribed to DNA, which can integrate into host DNA

HTLV-1 HTLV-2

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Check Your Understanding What is a provirus? 13-11 How can an RNA virus cause cancer if it doesn’t

have DNA to insert into a cell’s genome? 13-12

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Latent and Persistent Viral Infections

13-13 Provide an example of a latent viral infection.

13-14 Differentiate persistent viral infections from latent viral infections.

Learning Objectives

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Copyright © 2010 Pearson Education, Inc. Figure 13.21

Latent and Persistent Viral Infections

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Virus remains in asymptomatic host cell for long periods Cold sores,

shingles

Latent Viral Infections

Figure 13.21

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Disease processes occurs over a long period; generally is fatal Subacute

sclerosing panencephalitis (measles virus)

Persistent Viral Infections

Figure 13.21

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Check Your Understanding Is shingles a persistent or latent infection?

13-13, 13-14

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Prions, Viroids, and Plant Viruses

13-15 Discuss how a protein can be infectious.

13-16 Differentiate virus, viroid, and prion.

13-17 Describe the lytic cycle for a plant virus.

Learning Objectives

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Prions

Proteinaceous Infectious particle Inherited and transmissible by ingestion, transplant,

and surgical instruments Spongiform encephalopathies: Sheep scrapie, Creutzfeldt-

Jakob disease, Gerstmann-Sträussler-Scheinker syndrome, fatal familial insomnia, mad cow disease

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Prions

PrPC: Normal cellular prion protein, on cell surface PrPSc: Scrapie protein; accumulates in brain cells,

forming plaques

ANIMATION Prion: Diseases

ANIMATION Prion: Characteristics

ANIMATION Prion: Overview

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Copyright © 2010 Pearson Education, Inc. Figure 13.22

How a Protein Can Be Infectious

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Copyright © 2010 Pearson Education, Inc. Figure 13.23

Plant Viruses and Viroids

Plant viruses: Enter through wounds or via insects

Viroids: Infectious RNA; e.g., potato spindle tuber disease

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Check Your Understanding Contrast viroids and prions, and for each name a

disease it causes. 13-15, 13-16 How do plant viruses enter host cells? 13-17

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Virus Families That Affect Humans

13-10 Compare and contrast the multiplication cycle of DNA and RNA containing animal viruses.

Learning Objective

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Parvoviridae

Single-stranded DNA, nonenveloped viruses Fifth disease Anemia in

immunocompromised patients

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Adenoviridae

Double-stranded DNA, nonenveloped viruses Respiratory infections in humans Tumors in animals

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Papovaviridae

Double-stranded DNA, nonenveloped viruses Papillomavirus

Human wart virus Polyomavirus

Cause tumors; some cause cancer

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Copyright © 2010 Pearson Education, Inc. Figure 13.5b

Poxviridae

Double-stranded DNA, enveloped viruses Orthopoxvirus (vaccinia

and smallpox viruses) Molluscipoxvirus Smallpox Molluscum

contagiosum Cowpox

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Double-stranded DNA, enveloped viruses Simplexvirus (HHV-1 and

HHV-2) Varicellovirus (HHV-3) Lymphocryptovirus (HHV-4) Cytomegalovirus (HHV-5) Roseolovirus (HHV-6) HHV-7 Kaposi's sarcoma (HHV-8)

Some herpesviruses can remain latent in host cells

Figure 13.16b

Herpesviridae

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Hepadnaviridae

Double-stranded DNA, enveloped viruses Hepatitis B virus Use reverse

transcriptase

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Single-stranded RNA, + strand, nonenveloped Enterovirus

Poliovirus and coxsackievirus

Rhinovirus Hepatitis A virus

Table 13.2

Picornaviridae

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Caliciviridae

Single-stranded RNA, + strand, nonenveloped Hepatitis E virus Norovirus causes

gastroenteritis

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Single-stranded RNA, + strand, enveloped Alphavirus

Transmitted by arthropods; includes EEE and WEE

Rubivirus (rubella virus)

Table 13.2

Togaviridae

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Single-stranded RNA, + strand, enveloped Arboviruses can

replicate in arthropods; include yellow fever, dengue, SLE, and West Nile viruses

Hepatitis C virus

Clinical Focus, p. 223

Flaviviridae

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Single-stranded RNA, + strand, enveloped Upper respiratory

infections Coronavirus SARS

Table 13.2

Coronaviridae

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Single-stranded RNA, – strand, one RNA strand Vesiculovirus Lyssavirus

(rabies virus) Cause numerous

animal diseases

Figure 13.18a

Rhabdoviridae

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Filoviridae

Single-stranded RNA, – strand, one RNA strand Filovirus Enveloped,

helical viruses Ebola and Marburg

viruses

Figure 23.21

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Paramyxoviridae

Single-stranded RNA, – strand, one RNA strand Paramyxovirus Morbillivirus Parainfluenza Mumps Newcastle disease

(chickens)

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Single-stranded RNA, – strand, one RNA strand Hepatitis D virus Depends on coinfection

with hepadnavirus

Table 13.2

Deltaviridae

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Single-stranded RNA, – strand, multiple RNA strands Envelope spikes can

agglutinate RBCs Influenzavirus (influenza

viruses A and B) Influenza C virus

Table 13.2

Orthomyxoviridae

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Avian Influenza

Clinical Focus, p. 371

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Bunyaviridae

Single-stranded RNA, – strand, multiple RNA strands Bunyavirus (CE virus) Hantavirus

Table 13.2

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Arenaviridae

Single-stranded RNA, – strand, multiple RNA strands Helical capsids contain

RNA-containing granules Lymphocytic

choriomeningitis VEE and Lassa fever

Table 13.2

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Retroviridae

Single-stranded RNA, 2 RNA strands, produce DNA Use reverse

transcriptase to produce DNA from viral genome

Lentivirus (HIV) Oncogenic viruses

Includes all RNA tumor viruses

Figure 19.13

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Reoviridae

Double-stranded RNA, nonenveloped Reovirus (respiratory

enteric orphan) Rotavirus (mild respiratory

infections and gastroenteritis)

Colorado tick fever

Table 13.2

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Q&A

Researchers converted skin cells into embryonic stem cells. They first inserted RNA complementary for four embryonic genes into a virus; the resulting provirus inserted the genes into the skin cells’ DNA. What virus can do this?