MCB3020 Viruses and Other Acellular Infectious Agents (Textbook Chapter 6) PDF

Summary

This chapter from a microbiology textbook introduces viruses and other acellular infectious agents, discussing their structure, multiplication, and significance. It covers different types of capsid symmetry (helical and icosahedral) and examples of viruses with various structures, including the simple virion structure and an example of a complex virus, vaccinia virion.

Full Transcript

6
Viruses and
Other Acellular
Infectious Agents
©Ingram Publishing/age fotostock

Mustard, Ketchup, and Viruses?

T

wenty million hot dogs are sold annually to fans attending games at
major league baseball parks in the United States. Hot dogs and lunch
meats are popular at baseball games and in lunches carried to work or
school. Yet each year in the United States, approximately 1,600 people are
sickened by a bacterium that can contaminate the meat and, worse, survive
and grow even when the meat is properly refrigerated.
The disease culprit is Listeria monocytogenes, a Gram-positive rod
found in soil and many other environmental sites. It is not only cold tolerant
but salt and acid tolerant as well. Although it is in the minor leagues when
compared to some of the big hitters of food-borne disease (e.g., Salmonella
enterica), it is of concern for two reasons: who it kills and how many it kills.
L. monocytogenes targets the young and old, pregnant women, and
immunocompromised individuals; about 15% of those infected die.
Its effect on pregnant women is particularly heartbreaking. The
woman usually only suffers mild, flulike symptoms; however, these
innocuous symptoms belie the fact that the child she carries is in serious
danger. Her pregnancy often ends in miscarriage or stillbirth. Newborns
infected with the bacterium are likely to develop meningitis. Many will die
as a result. Those who survive often have neurological disorders.
Currently, pregnant women are counseled against eating ready-toeat foods unless they have been cooked prior to consumption.
However, L. monocytogenes is known to contaminate many foods
other than hot dogs and these can’t always be heated. In 2006 the
U.S. Food and Drug Administration (FDA) approved a new approach to
prevent listeriosis: spraying viruses that attack and destroy the bacterium
on ready-to-eat cold cuts and luncheon meats. In other words, the viruses
are a food additive! The method is safe because the viruses only attack L.
monocytogenes, not human cells.
Since approval, the use of viruses to control the transmission of listeriosis by
other foods has been studied. Unfortunately, those studies did not include fresh
fruit. In 2011 L. monocytogenes–contaminated cantaloupe caused an outbreak
of listeriosis in 20 U.S. states, which infected over 100 and killed over 20.
Viruses as agents of good will come as a surprise to many. Typically
we think of them as major causes of disease. However, viruses are significant
for other reasons. They are vital members of aquatic ecosystems. There they
interact with cellular microbes and contribute to the movement of organic

matter from particulate forms to dissolved forms. Bacterial viruses are being
used in some European countries to treat bacterial infections, and a number of
animal viruses are being used to target and destroy cancer cells. Finally, they
are important model organisms. In this chapter, we introduce viruses and other
acellular infectious agents.
Marine viruses: mortality at sea (section 30.2);
Microorganisms can be controlled by biological methods (section 8.7)

Readiness Check:
Based on what you have learned previously, you should be able to:

✓ Define the term acellular
✓ Compare and contrast in general terms viruses, viroids, satellites,
and prions (section 1.1)

6.1 Viruses Are Acellular
After reading this section, you should be able to:
a. Define the terms virology, bacteriophages, and phages
b. List organisms that are hosts to viruses

The discipline of virology studies viruses, a group of infectious
agents unique in their simple, acellular organization and pattern
of multiplication. Despite this simplicity, viruses are major
causes of disease. For instance, many human diseases are caused
by viruses, and more are discovered every year, as demonstrated
by the appearance of the H1N1 (swine) influenza virus in 2009,
the H7N9 avian influenza virus in 2013, and the Middle East
respiratory syndrome coronavirus (MERS-CoV) also in 2013.
However, their simplicity also has made them attractive model
organisms. They served as models for understanding DNA replication, RNA synthesis, and protein synthesis. Therefore the study
of viruses has contributed significantly to the discipline of molecular biology. In fact, the field of genetic engineering is based
in large part on the use of viruses and viral enzymes such as the
enzyme reverse transcriptase.
Microbial DNA technologies
(chapter 17)
Viruses can exist either extracellularly or intracellularly.
When extracellular, they are inactive because they possess few, if
any, enzymes and cannot reproduce outside of living cells. When
intracellular, viruses exist primarily as nucleic acids that can, at

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some point in the viral life cycle, commandeer host cells and use
them to synthesize viral components from which progeny virions
are assembled and eventually released.
Viruses can infect all cell types. Numerous viruses infect
bacteria. They are called bacteriophages, or phages for short.
Fewer archaeal viruses have been identified. Most known viruses
infect eukaryotic organisms, including plants, animals, protists,
and fungi. Viruses have been classified into numerous families
based primarily on genome structure, life cycle, morphology, and
genetic relatedness.
Virus phylogeny is difficult to establish
(section 26.1)
In this chapter, we introduce the structure and multiplication
strategies of viruses. Their taxonomic diversity is presented in
chapter 26, their ecological relevance is discussed in chapter 30,
and their role in human disease is the topic of chapter 38.

6.2 Virion Structure Is Defined by

Capsid Symmetry and Presence
or Absence of an Envelope

After reading this section, you should be able to:
a.
b.
c.
d.

State the size range of virions
Identify the parts of a virion and describe their function
Distinguish enveloped viruses from nonenveloped viruses
Describe the types of capsid symmetry

A complete virus particle is called a virion. Virion morphology
has been intensely studied because of the importance of viruses
and the realization that virion structure is simple enough to be
understood in detail. Progress has come from the use of several
different techniques: electron microscopy, X-ray diffraction, biochemical analysis, and immunology. Although our knowledge
is incomplete due to the vast diversity of viruses, we can discuss the general nature of virion structure.

General Structural Properties
Virions can be extraordinarily tiny (about 20 nm in diameter) to
about the same size as a rod-shaped bacterial cell (1.5 × 0.5 µm)
(figure 6.1). The smallest are a little larger than ribosomes, whereas
mimiviruses, among the largest viruses known, can be seen in the
light microscope. However, most virus particles must be viewed
with electron microscopes.
Electron microscopes use beams of
electrons to create highly magnified images (section 2.4)
The simplest virions consist only of a nucleocapsid, which
is composed of a nucleic acid, either DNA or RNA, and a protein
coat called a capsid (figure 6.2). The capsid surrounds the viral
nucleic acid, protects the viral genome, and often aids in its
transfer between host cells. Some virions are covered by a lipid
membrane, and these are termed enveloped viruses, whereas
those lacking a membrane are called nonenveloped or naked viruses. Notice what is missing from viruses: ribosomes for protein
synthesis and a mechanism for generating ATP. Cytoplasm is

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absent, and while a few enzymes may be found, there are not
enough to sustain cellular processes.
Nonenveloped viruses construct a capsid from many copies
of one protein and a few minor proteins. Each subunit is termed a
protomer, and thousands of protomers self-assemble to form the
capsid (figure 6.3). In contrast, enveloped viruses require both
nucleocapsid proteins and additional proteins to anchor the membrane. Some viruses use noncapsid proteins as scaffolding upon
which the capsids are assembled. Probably the most important
advantage of this design strategy is that the viral genome is used
with maximum efficiency. For example, the tobacco mosaic virus
(TMV) capsid is constructed using a single type of protomer.
Recall that the building blocks of proteins are amino acids and
that each amino acid is encoded by three nucleotides. The TMV
protomer is 158 amino acids in length. Therefore only about 474
nucleotides are required to code for the coat protein. The entire
TMV genome consists of only 6,400 nucleotides. Thus only a
small fraction of the genome is used to code for the capsid. Suppose, however, that the TMV capsid were composed of six different protomers, all about 150 amino acids in length. If this were
the case, about 2,700 nucleotides in the TMV genome would be
required just for capsid construction, and much less genetic material would be available for other purposes.

Helical Capsids
Helical capsids are shaped like hollow tubes with protein walls.
Tobacco mosaic virus is a well-studied example of helical capsid
structure (figure 6.3). The self-assembly of TMV protomers into a
helical arrangement produces a rigid tube. The capsid encloses an
RNA genome, which is wound in a spiral and lies within a groove
formed by the protein subunits. Not all helical capsids are as rigid
as the TMV capsid. The nucleocapsids of influenza viruses are
thin and flexible and are enclosed within an envelope (figure 6.4).
Tobacco mosaic virus (section 26.5)
The size of a helical capsid is influenced by both its protomers and the viral genome. The diameter of the capsid is a function
of the size, shape, and interactions of the protomers. The length
of the capsid appears to be determined by the nucleic acid because a helical capsid does not extend much beyond the end of
the viral genome.

Icosahedral Capsids
An icosahedron is a regular polyhedron with 20 equilateral triangular faces and 12 vertices (figure 6.1b,g,h). Icosahedral capsids are the most efficient way to enclose a space. They are
constructed from ring- or knob-shaped assemblages of five or six
protomers; the assemblages are called capsomers (figure 6.5).
Capsomers composed of five protomers are called pentamers
(pentons); hexamers (hexons) are capsomers that possess six
protomers. Pentamers are usually at the vertices of the icosahedron, whereas hexamers generally form its edges and triangular
faces. The virions of some RNA viruses have pentamers and
hexamers constructed with only one type of subunit. Other virions have pentamers and hexamers composed of different proteins.

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(a) Vaccinia virus

(b) Herpesvirus

(c) Rhabdovirus

(d) T-even coliphage

(f ) Sulfolobus spindleshaped virus 1

(e) A flexuoustailed phage

(h) ϕX174 phage

(g) Human
papillomavirus

(i) Tobacco mosaic virus
(j) Mimivirus

(k) Acidianus two-tailed virus
1 µm

Figure 6.1 The Size and Virion Morphology of Selected Viruses. The virions are drawn to scale.
MICRO INQUIRY Which capsids are icosahedral? Which are helical? Which have complex symmetry?

Although many icosahedral capsids contain both pentamers and
hexamers, some have only pentamers.

Capsids of Complex Symmetry
Most viruses have either icosahedral or helical capsids, but some
viruses do not fit into either category. Poxviruses and large bacteriophages are two important examples.
Poxvirus virions are among the largest of the animal viruses
(about 400 by 240 by 200 nm in size) and can be seen with a light
microscope. They possess an exceptionally complex internal

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structure with an ovoid- to brick-shaped exterior. Figure 6.6
shows the virion morphology of the vaccinia virus. Its doublestranded DNA genome is associated with proteins and contained
in the core, a central structure shaped like a biconcave disk and
surrounded by a membrane. Two lateral bodies lie between the
core and the virion’s outer envelope and contain viral enzymes.
Some large bacteriophages have virions that are even more
elaborate than those of poxviruses. The virions of T2, T4, and T6
phages (T-even phages) that infect Escherichia coli are said to
have binal symmetry because they have a head that resembles
an icosahedron and a tail that is helical. The icosahedral head is

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usually arise from the plasma or nuclear membranes of the host
cell. Envelope lipids and carbohydrates are therefore acquired from
the host. In contrast, envelope proteins are coded for by viral genes
and may even project from the envelope surface as spikes, which
are also called peplomers (figure 6.8). In many cases, spikes are
involved in virion attachment to the host cell surface. Because
spikes differ among viruses, they also can be used to identify some
viruses. Many enveloped viruses have virions with a somewhat
variable shape and are called pleomorphic. However, the envelopes
of viruses such as the bullet-shaped rabies viruses are firmly attached to the underlying nucleocapsid and endow the virion with a
constant, characteristic shape (figure 6.8a).
Influenza virus (figure 6.4) is a well-studied enveloped virus with
two types of spikes. Some spikes consist of the enzyme neuraminidase, which functions in the release of mature virions from the host
cell. Other spikes are hemagglutinin proteins, so named because
they bind virions to red blood cells and cause the cells to clump together—a process called hemagglutination. Influenza virus’s hemagglutinins participate in virion attachment to host cells. Most of its
envelope proteins are glycoproteins—proteins that have carbohydrate
attached to them. A nonglycosylated protein, the M1 (matrix) protein,
is found on the inner surface of the envelope and stabilizes both the
lipid envelope and the display of both types of spike.
In addition to enzymes associated with the envelope or capsid (e.g., influenza neuraminidase), some viruses have enzymes
within their capsids. Such enzymes are usually involved in nucleic
acid replication. For example, influenza virus virions have an
RNA genome and carry an enzyme that synthesizes RNA using

Envelope
Spike
Capsid
Capsid

Nucleic acid

Nucleic
acid
(a) Nonenveloped virus

(b) Enveloped virus

Figure 6.2 Generalized Structure of Virions. (a) The simplest virion is
that of a nonenveloped virus, consisting of a capsid assembled around its
nucleic acid (nucleocapsid). (b) Virions of enveloped viruses are composed of
a nucleocapsid surrounded by a membrane called an envelope. The envelope
usually has viral proteins called spikes inserted into it.

elongated by one or two rows of hexamers in the middle and
contains the DNA genome (figure 6.7). The tail is composed of
a collar joining it to the head, a central hollow tube, a sheath surrounding the tube, and a complex baseplate. In T-even phages,
the baseplate is hexagonal and has a pin and a jointed long tail
fiber and a short tail fiber at each corner.
Bacteriophage T4:
a virulent bacteriophage (section 26.2)

Viral Envelopes and Enzymes
The nucleocapsids of many animal viruses, some plant viruses, and
at least one bacterial virus are surrounded by an outer membranous
layer called an envelope (figure 6.8). Animal virus envelopes

Protomer

(a)

0
(b)

RNA

10 nm

20 nm
(c)

Figure 6.3 Tobacco Mosaic Virus (TMV) Virions. (a) An electron micrograph of negatively stained helical capsids. The virions are 15 to 18 nm in
diameter and 300 nm long. (b) Illustration of a TMV nucleocapsid. It is composed of a helical array of protomers with the RNA spiraling on the inside.
(c) A model of a TMV virion.
(a) ©Science History Images/Alamy Stock Photo

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Envelope
Nucleocapsid
80–120 nm
(a)

Figure 6.4 Influenza Virus Virions: An Enveloped Virus with Helical
Nucleocapsids. (a) Schematic view. Influenza viruses have segmented genomes
consisting of seven to eight different RNA molecules. Each is coated by capsid proteins to
create seven to eight flexible nucleocapsids. The envelope has two types of spikes that
project 10 nm from the surface at 7- to 8-nm intervals. (b) Because the nucleocapsids are
flexible, the virions are pleomorphic. Electron micrograph.
(b) Source: CDC/Dr. F.A. Murphy

an RNA template (see figure 26.24). Thus although viruses lack
true metabolism and cannot reproduce independently of living
cells, their virions may carry one or more enzymes essential to
the completion of their life cycles.

Viral Genomes Are Structurally Diverse
One clear distinction between cellular organisms and viruses is
the nature of their genomes. Cellular genomes are always doublestranded (ds) DNA. Viruses, on the other hand, employ all

(b)

four possible nucleic acid types: dsDNA, single-stranded (ss)
DNA, ssRNA, and dsRNA. All four types are used by animal
viruses. Most plant viruses have ssRNA genomes, and most
bacterial and archaeal viruses have dsDNA. The size of viral
genomes also varies greatly. Very small genomes are around
4,000 nucleotides—just large enough to code for three or four
proteins. Some viruses save additional space by using overlapping genes. At the other extreme are the genomes of pandoraviruses, which infect protists. They are about 2.5 × 10 6

(a)

(b)

Figure 6.5 The Icosahedral Capsid of an Adenovirus. (a) Electron micrograph of adenovirus virions,
252 capsomers. (b) Computer-simulated model of an adenovirus virion.
(a) ©Biophoto Associates/Science Source; (b) ©Division of Computer Research & Technology, NIH/Science Source

MICRO INQUIRY What is the difference between a pentamer and a hexamer? Are the capsomers at the vertices

of an adenovirus virion pentamers or hexamers?

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6.2 Virion Structure Is Defined by Capsid Symmetry and Presence or Absence of an Envelope 111

240– 300 nm

DNA

Core
membrane
200 nm

Nucleic acid

Envelope

Outer
envelope
Soluble
protein antigens

Lateral
body

Core membrane

(a)

Lateral body

(b)

Figure 6.6 Morphology of Vaccinia Virus Virions. (a) Diagram of virion structure. (b) Electron cryotomogram of the virion.
(b) ©Marek Cyrklaff

Nucleic acid
Capsid head
Collar
Sheath
Long tail
fibers

Short tail
fibers

Tail
pins

Baseplate

(a)

(b)

Figure 6.7 T4 Phages of E. coli. (a) The structure of T4 bacteriophage virion. (b) Electron micrograph of the virion.
(b) ©Ami Images/Science Source

MICRO INQUIRY Why is T4 said to have binal symmetry?

nucleotides long, exceeding some bacteria and archaea in coding capacity.
Most DNA viruses use dsDNA as their genetic material. However, some have ssDNA genomes (e.g., ϕX174 and M13). In both
cases, the genomes may be either linear or circular. The ends of
linear viral genomes may be covalently closed, attached to a protein, or otherwise masked. Some DNA genomes can switch from
one form to the other. For instance, the E. coli phages lambda has
a linear genome in its capsid, but it becomes circular once it enters
the host cell.
Bacteriophages ϕX174 and Pf1 (section 26.3);
Bacteriophage lambda: a temperate bacteriophage (section 26.2)

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Relatively few RNA viruses have dsRNA genomes. More
common are viruses with ssRNA genomes. Polio, tobacco mosaic,
rabies, influenza, and human immunodeficiency (HIV) are all ssRNA viruses.
Some RNA viruses have segmented genomes—genomes
that consist of multiple pieces (segments) of RNA. In many cases,
each segment codes for one protein and there may be as many as
10 to 12 segments. Usually all segments are enclosed in the same
capsid (figure 6.4). However, the genome of brome mosaic virus,
a virus that infects certain grasses, is composed of three segments distributed among three different virions.

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Envelope spike

Nucleocapsid

Tegument

Envelope
Glycoprotein
β envelope
spikes
(a) Rabies virus

(b) Herpesvirus

Figure 6.8 Examples of Enveloped Viruses. (a) Negatively stained virion of a rabies virus. (b) Herpesvirus virion. Images are artificially colorized.
(a) ©Chris Bjornberg/Science Source; (b) ©Dr. Linda Stannard, UCT/Science Source

Comprehension Check
1. How are viruses similar to cellular organisms? In what fundamental
way do they differ?
2. What is the difference between a nucleocapsid and a capsid?
3. Compare the structure of an icosahedral capsid with that of a helical
capsid. How do pentamers and hexamers associate to form a
complete icosahedron? Which virus would have a longer helical
capsid: a virus with a 7,200 base pair DNA genome or one with an
11,000 base ssRNA genome?
4. What is an envelope? What are spikes (peplomers)? Why do some
enveloped viruses have pleomorphic virions?
5. All four nucleic acid forms can serve as viral genomes. Describe each.
What is a segmented RNA genome?

6.3 Viral Life Cycles Have Five Steps
After reading this section, you should be able to:
a. Describe the five steps common to the life cycles of viruses
b. Discuss the role of receptors, capsid proteins, and envelope
proteins in the life cycles of viruses
c. Describe the two most common methods for virion release from a host cell

In the early years of virology, one of the fundamental questions was
how progeny viruses are made. The one-step growth experiment devised in 1939 by Max Delbrück (1906–1981) and Emory Ellis (1906–
2003) served as an experimental approach to answering this question.
Delbrück and Ellis worked with bacteriophage T4. They knew that T4
lysed its host, Escherichia coli, and released progeny phages. In their
experiment, E. coli cells were mixed with T4. After a short interval,
the mixture was greatly diluted so that any virions released upon host
cell lysis would not encounter and infect other cells. The diluted culture was then incubated, and over time samples were removed to determine the number of infectious phages particles in the culture. This

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was determined using a plaque assay as we describe in section 6.5. A
plot of the number of phages particles versus time shows several distinct periods in the resulting growth curve (figure 6.9, red line). The
latent period occurs immediately following addition of the phages.
During this period, no virions are released. The rise period follows
and is characterized by the rapid release of infective phages. Finally, a
plateau is reached and no more virions are produced.
The one-step growth experiment was important for several reasons. It employed procedures that are still used today to culture and
enumerate viruses, and it ushered in the modern era of phages biology. It also led to another fundamental question: What is occurring
during the latent period? In a subsequent set of experiments, infected cells were artificially lysed during the latent period. This revealed that intracellular virions could not be detected early in the
latent period. In essence, the phages disappeared once inside the
cell. This period is called the eclipse period because the infecting
virions were concealed or eclipsed within the host cell. These experiments also demonstrated that the number of completed, infective phages within the host cell increases after the end of the eclipse
period. Still other experiments eventually showed that a carefully
orchestrated series of events occurs during the latent period. These
events are the focus of this section.
If a virus is to multiply and give rise to new progeny viruses,
it must find and use (and in many cases abuse) a host cell. To accomplish this, a virus must use guile and subterfuge to access an
appropriate host, enter the host, and avoid any defenses the host
might employ to rid itself of the virus or prevent its multiplication. Once inside a host cell, a virus uses a repertoire of clever
tricks to take control of cellular functions, thereby ensuring that
viral genomes, mRNAs, and proteins are synthesized using ATP
generated by the host. There are a plethora of distinctive viral life
cycles (also called viral replicative cycles). Viral strategies are often
related to virion structure, in particular the nature of its genome.
Thus viruses with a similar type of genome (e.g., dsDNA, ssRNA)
often employ similar tactics, as we explore in chapter 26.

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6.3 Viral Life Cycles Have Five Steps 113

Latent period

Rise period
Virus particle

Eclipse

Host cell

Phage count

Attachment of
virion to host cell

Burst size

Entry of viral
nucleocapsid
Time (minutes)

Figure 6.9 The One-Step Growth Curve. The eclipse period is the initial
portion of the latent period in which host cells do not contain any complete,
infective virions. During the remainder of the latent period, an increasing
number of infective virions are present, but none are released. The latent
period ends with host cell lysis and rapid release of virions (rise period). In
this figure the blue line represents the total number of complete virions, both
intracellular and free in the medium. The red line represents the number of
free viruses (virions that were free in the culture and had not infected a host
cell plus those virions that were released from infected cells). The burst size is
the number of progeny viruses produced per infected cell.

Despite the diversity of viral life cycles, a general pattern of
viral replicative cycles can be discerned; it can be divided into five
steps. Because viruses need a host cell in which to multiply, the first
step is usually attachment, often called adsorption (Latin sorbere, to
suck in), to a host (figure 6.10). This is followed by entry of either
the entire nucleocapsid or just the viral nucleic acid into the host. If
the nucleocapsid enters, uncoating of the genome usually occurs
before the life cycle continues. Once inside the host cell, the synthesis stage begins. During this stage, viral genes are transcribed and
translated. This allows the virus to take control of the host cell, forcing it to manufacture viral genomes and viral proteins. Next is the
assembly stage, during which new nucleocapsids are constructed by
self-assembly of coat proteins and nucleic acids are packaged within.
Finally, during the release step, mature virions escape the host.

Attachment (Adsorption)
All viruses, with the exception of plant viruses, must attach to a
potential host cell long enough to gain entry into the cell. Attachment to the host is accomplished by specific interactions between
molecules on the surface of the virion (ligands) and molecules on
the surface of the host cell called receptors. In many cases, the
viral surface ligand is a protein, but some animal viruses use lipids derived from the cell membrane as ligands. A recurring
theme among archaeal viruses is the presence of virion appendages for host cell attachment. These include beardlike fiber

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Viral
proteins

Viral
nucleic
acids

Synthesis of viral
proteins and
nucleic acids

Self-assembly
of virions

Release of progeny
virions

Figure 6.10 Generalized Illustration of Virus Multiplication. The life
cycle of a virus that infects a eukaryotic cell is shown. Figure 6.16 illustrates
the generalized life cycle of many bacterial and archaeal viruses. Virions are
not drawn to scale.

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clusters and structures resembling claws. Bacteriophages attach
to cell wall lipopolysaccharides and proteins as receptors, while
others use teichoic acids, flagella, or pili. Binding of an animal
virus particle to its receptor often causes conformational changes
in virion proteins that facilitate interaction with secondary receptors, entry into the host, and nucleocapsid uncoating.
Receptor specificity is at least partly responsible for the preferences viruses have for a particular host. Bacteriophages not only
infect a particular bacterial species but often infect only certain
strains within a given species. Likewise, animal viruses infect specific animals and, in some cases, only particular tissues within
that host. However, if the receptor recognized by a virus is present
in numerous animals, then the virus will infect more than one animal species. Such is the case with rabies viruses.
Viruses have evolved such that they use host receptors that
are always present on the surface of the host cell and are
important for normal host cell function. In some cases, two or
more host cell receptors are involved in attachment. For instance, human immunodeficiency virus (HIV) particles bind to
two different proteins on human cells (e.g., CD4 and CCR5).
In complex animals like humans, the presence of receptor molecules on a cell surface varies with the organ and tissue. Viruses
have a tropism; that is, particular cell types are infected based on the
distribution of surface receptors in tissues. For example, poliovirus
receptors are found only in the human nasopharynx, gut, and anterior horn cells of the spinal cord. Therefore polioviruses infect these
tissues, causing disease that ranges from milder forms such as gastrointestinal disease to more serious paralytic disease. In contrast,
measles virus receptors are present in most tissues and disease is
disseminated throughout the body. Some viruses, including Ebola,
mimic damaged cells by exposing certain phospholipids on their
surface. This display is a hallmark of dying cells targeted for phagocytosis. By camouflaging themselves as damaged cells, viruses can
gain entry to a wide variety of cell types.
Eukaryotic cell envelopes (section 5.2)
Human diseases caused by viruses and prions (chapter 38)
Plant viruses are a notable exception to attachment based on
receptor binding as no receptors have been identified for plant viruses. Rather, damage of host cells is required for the virus particles
to enter the host. Infection is often achieved by plant-eating insects
that carry virions from one plant to another. The virions are deposited in plant tissues as the insect devours the plant. Interestingly,
some viruses may alter their plant hosts to promote activity of the
insects and thereby foster transmission to new plants.

Entry into the Host
After attachment to the host cell, the virus’s genome or the entire
nucleocapsid enters the cytoplasm. For many bacteriophages
only their nucleic acid enters the host’s cytoplasm, leaving the
capsid outside and attached to the cell. In contrast to phages,
many eukaryotic viral nucleocapsids enter the cytoplasm with
the genome still enclosed. Once inside the cytoplasm, some shed
their capsid proteins in a process called uncoating, whereas others remain encapsidated. Because penetration and uncoating are
often coupled, we consider them together.

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The mechanisms of penetration and uncoating vary with the
type of virus, and for many animal viruses, detailed mechanisms
of penetration are unclear. However, it appears that one of three
different modes of entry is usually employed by animal viruses:
fusion of the viral envelope with the host cell’s plasma membrane,
entry by endocytosis, and release of viral nucleic acid into the
cytoplasm of the host cell (figure 6.11).
Entry of Animal
Viruses into Host Cells
Fusion of viral envelopes with the host cell’s plasma membrane
often involves viral envelope glycoproteins or phospholipids that
interact with proteins in the plasma membrane of the host cell (figure 6.11a). This interaction sets into motion events that allow the
nucleocapsid to enter. For example, after attachment of paramyxovirus virions (e.g., the measles virus), membrane lipids rearrange, the
adjacent halves of the contacting membranes merge, and a proteinaceous fusion pore forms. The nucleocapsid then enters the host cell
cytoplasm, where a viral enzyme carried within the nucleocapsid
begins synthesizing viral mRNA while it is still within the capsid.
Virions of nonenveloped viruses and some enveloped viruses
enter cells by one of the endocytic pathways, including clathrindependent endocytosis and macropinocytosis (figure 6.11b). The
resulting endocytic vesicle contains the virion and fuses with an
endosome; depending on the virus, escape of the nucleocapsid or
its genome from the endocytic vesicle may occur either before or
after fusion with an endosome. Endosomal enzymes can aid in
virion uncoating, and low pH often triggers the uncoating process.
For some enveloped viruses, the viral envelope fuses with the
endosomal membrane, and the nucleocapsid is released into the
cytosol (the capsid proteins may have been partially removed by
endosomal enzymes). Once in the cytosol, the viral nucleic acid
may be released from the capsid upon completion of uncoating or
may function while still attached to capsid components. Nonenveloped animal viruses cannot employ the membrane fusion mechanism for release from the endosome (figure 6.11c). In this case, it
is thought that the low pH of the endosome causes a conformational change in the capsid. The altered capsid contacts the endosome membrane and either releases the viral nucleic acid into the
cytosol or ruptures the membrane to release the intact nucleocapsid.
There are several endocytic pathways (section 5.4)

Synthesis Stage
This stage of the viral life cycle differs dramatically among viruses because the genome of a virus dictates the events that occur. For dsDNA viruses, the synthesis stage can be very similar
to the typical flow of information in cells. That is, the genetic
information is stored in DNA and replicated by enzymes called
DNA polymerases, recoded as mRNA (transcription), and decoded during protein synthesis (translation). Because of this
similarity, some dsDNA viruses have the luxury of depending
solely on their host cells’ biosynthetic machinery to replicate
their genomes and synthesize their proteins.
The same is not true for RNA viruses. Cellular organisms (except for plants) lack the enzymes needed to replicate RNA or to
synthesize mRNA from an RNA genome. Therefore RNA viruses

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6.3 Viral Life Cycles Have Five Steps 115

Spikes
Capsid protein

Nucleic
acid
Envelope
Receptor
Viral envelope spikes
bind to receptors on
surface of host cell.

Lipid bilayer of viral
envelope fuses with host
cell membrane.

Nucleocapsid is released
into the cytoplasm.

(a) Entry of enveloped virus by fusing with plasma membrane
H+

Endosome
Viral envelope spikes
bind to receptors on
the cell’s surface.

Binding to the receptor
triggers receptor-mediated
endocytosis.

Increased acidity
allows nucleocapsid to
escape from the endosome
and enter the cytosol.

(b) Entry of enveloped virus by endocytosis

Capsid

Nucleic
acid

Receptor
Capsid proteins bind to
receptors on cell surface and
trigger receptor-mediated
endocytosis.

Nucleic acid is extruded
from the endosome into
the cytosol.

(c) Entry of nonenveloped virus by endocytosis

Figure 6.11 Animal Virus Entry. Examples of animal virus attachment and entry into host cells. Enveloped viruses can (a) enter after fusion of the
envelope with the plasma membrane or (b) escape from an endosome after endocytosis. (c) Nonenveloped viruses may be taken up by endocytosis and then
insert their nucleic acid into the cytosol through the vesicle membrane. It also is possible that they insert the nucleic acid directly through the plasma
membrane.
MICRO INQUIRY Which of these mechanisms involves the production of a vesicle within the host cell? Which involves the interaction between viral

proteins and host cell membrane proteins?

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Membranes of endoplasmic reticulum

Vesicles of viral replication complex

Figure 6.12 A Viral Replication Complex. An electron tomogram of
cells infected with severe acute respiratory syndrome coronavirus (SARS-CoV).
The vesicles of the viral replication complex have a double membrane derived
from endoplasmic reticulum (ER) membranes. The membranes of vesicles are
connected to the ER.
From “SARS-Coronavirus Replication Is Supported by a Reticulovesicular Network of Modified
Endoplasmic Reticulum” Knoops K, Kikkert M, Worm SH, Zevenhoven-Dobbe JC, van der Meer Y,
Koster AJ, Mommaas AM, Snijder EJ - (2008)

must carry in their nucleocapsids the enzymes needed to complete
the synthesis stage, or the enzymes must be synthesized during the
infection process. This is discussed in more detail in chapter 26.
Some animal and plant viruses carry out the synthesis stage
and subsequent assembly step within the host’s cytoplasm. To protect these processes from host defenses, some viruses bring about
the reorganization of host cell membranes (e.g., membranes of the
endoplasmic reticulum, Golgi apparatus, and lysosomes) to form
membranous structures that enclose the machineries needed for genome replication, transcription, and protein synthesis (figure 6.12).
The structures are called viral replication complexes, and they appear as vesicles, tubular structures, and other forms in electron micrographs of infected cells. Other viruses carry out synthesis and
assembly in defined areas within the cytoplasm that are not enclosed
by membranes. These areas of concentrated viral genomes, mRNAs,
and proteins are called viroplasms, and they are also visible in electron micrographs of infected cells. Both viral replication complexes
and viroplasms are sometimes referred to as virus factories.
One important feature of the synthesis stage is the tight regulation of gene expression and protein synthesis. Genes are often
referred to as early, middle, or late genes based on when they are
expressed. The proteins they encode are likewise referred to as
early, middle, or late proteins. Many early proteins are involved
in taking over the host cell. Middle proteins often participate in
replication of the viral genome or activation of expression of late
genes. Late proteins usually include capsid proteins and other
proteins involved in self-assembly and release.

wil11886_ch06_106-127.indd 116

Assembly
Several kinds of late proteins are involved in the assembly of
mature virions. Some are nucleocapsid proteins, some are not
incorporated into the nucleocapsid but participate in its assembly, and still other late proteins are involved in virion release. In
addition, proteins and other factors synthesized by the host may
be involved in assembling mature virions.
The assembly process can be quite complex with multiple
subassembly lines functioning independently and converging in
later steps to complete nucleocapsid construction. As shown in
figure 6.13, the baseplate, tail fibers, and head components of
bacteriophage T4 are assembled separately. Once the baseplate is
finished, the tail tube is built on it and the sheath is assembled
around the tube. The phages prohead (procapsid) is constructed
with the aid of scaffolding proteins that are degraded or removed
after assembly is completed. DNA is incorporated into the prohead
by a complex of proteins sometimes called the “packasome.” The
packasome consists of a protein called the portal protein, which is
located at the base of the prohead, and an enzyme called terminase, which moves DNA into the prohead. The movement of DNA
consumes energy in the form of ATP, which is supplied by the
metabolic activity of the host bacterium. After the head is completed, it spontaneously combines with the tail assembly.
Baseplate
proteins

Head proteins

Prohead

Baseplate

DNA
Mature head
with DNA

Tube

Tube and sheath
Whiskers
and neck

Long tail fiber
proteins
Collar

Figure 6.13 The Assembly of T4 Virions. Note the subassembly lines
for the baseplate, tail tube and sheath, long tail fibers, and head.

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6.3 Viral Life Cycles Have Five Steps 117

Virion Release

Virus-associated pyramids

Several release mechanisms have been identified. The two most
common are release by lysing the host cell and release by budding.
Release by lysis is especially common for bacterial viruses and some
nonenveloped animal viruses. This process involves the activity of
viral proteins. For instance, lysis of E. coli by T4 requires two specific proteins (figure 6.14a). One is lysozyme, an enzyme that attacks peptidoglycan in the host’s cell wall. The other, called holin,
creates holes in E. coli’s plasma membrane, enabling T4 lysozyme
to move from the cytoplasm to the peptidoglycan.
A novel release mechanism has been elucidated for some
archaeal viruses infecting Sulfolobus spp. The virions are assembled in the cell cytoplasm, and a seven-sided pyramid structure forms near the cell envelope. These virus-associated
pyramids puncture the envelope and open up much like the petals of a flower (figure 6.14b). This allows escape of the progeny
virions, leaving the empty cell ghosts behind.
Budding is frequently observed for enveloped viruses; in fact,
envelope formation and virion release are usually concurrent processes. When virions are released by budding, the host cell may
survive and continue releasing virions for some time. All envelopes of animal viruses are derived from host cell membranes by a
multistep process. First, virus-encoded proteins are incorporated
into the membrane. Then the nucleocapsid is simultaneously released and the envelope formed by membrane budding (figure 6.15).
In several virus families, a matrix (M) protein attaches to the
plasma membrane and aids in budding. Most envelopes arise from
the plasma membrane. The endoplasmic reticulum, Golgi apparatus, and other internal membranes also can be used to form envelopes.
Mechanism for Releasing Enveloped Virions

(a)

(b)

Figure 6.14 Viral Release Mechanisms. (a) Release of T4 virions by
lysis of the host cell. The host cell has been lysed (upper left portion of the
cell) and virions have been released. Progeny virions also can be seen in the
cytoplasm. Empty capsids coat the outside of the cell. (b) Sulfolobus
solfataricus infected with Sulfolobus turreted icosahedral virus (STIV). Virions
are released through pyramid structures that form on the cell surface.
(a) ©Lee D. Simon/Science Source; (b) Courtesy of Susan Brumfield and Mark Young

MICRO INQUIRY Why do the empty capsids remain attached to the

cell after the viral genome enters the host cell?

Budding has been observed as the archaeal SSV1 enveloped
virus exits its host, Sulfolobus shibatae. Recall the structure of an
archaeal cell envelope: a monolayer membrane with ether-linked
lipids and a proteinaceous S-layer. Mature SSV1 particles

Viral nucleocapsid
Hemagglutinin

Budding
virion
Viral
matrix
protein
Viral envelope proteins
are inserted into host
cell's plasma membrane.
The viral matrix protein lines
the cytoplasmic face of
the plasma membrane.

Free infectious
virion with envelope

Neuraminidase
Nucleocapsids (only one
is shown) are directed
to the plasma
membrane by host cell's
microtubules (not
shown).

Plasma membrane
protrudes outward and
nucleocapsids are
surrounded by matrixlined plasma
membrane.

Neck of the protruding
membrane is pinched
off and a mature virion
is released.

Figure 6.15 Release of Influenza Virus Virions by Budding. For simplicity, only one of the seven to eight possible nucleocapsids is shown.

wil11886_ch06_106-127.indd 117

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covered in a host-derived membrane are initially trapped inside
the S-layer but ultimately freed by structural alterations in the
S-layer. Studies on the viral path through the cell envelope may
reveal novel mechanisms for viral budding.
There are many
different types of archaeal cell walls (section 4.2)
Interestingly, some viruses are not released from their
host cell into the surrounding environment. Rather, their virions move from one host cell directly to another host cell. Most
fungal viruses lack an extracellular phase in their replicative
cycles. Instead they are transmitted by cell division, spore
formation, or during mating. Vaccinia viruses elicit the formation of long actin tails that propel nucleocapsids through the
plasma membrane, directly into an adjacent cell. In this way,
the virus avoids detection by the host immune system. The
genomes or nucleocapsids of many plant viruses also move
directly from cell to cell through small connections called
plasmodesmata that link adjacent cells. This spread of the virus typically involves virus-encoded movement proteins.
The eukaryotic cytoplasm contains a cytoskeleton and
organelles (section 5.3)

Comprehension Check
1. Explain why the receptors that viruses have evolved to use are host
surface proteins that serve very important, and sometimes essential,
functions for the host cell.
2. What probably plays the most important role in determining the
tissue and host specificity of viruses? Give some specific examples.
3. How do you think the complexity of the viral assembly process
correlates with viral genome size?
4. In general, DNA viruses can be much more dependent on their host
cells than can RNA viruses. Why is this so?
5. Consider the origin of viral envelopes and suggest why enveloped
viruses that infect plants and bacteria are rare.
6. Why are the proteins involved in virion assembly synthesized late in
the viral life cycle?

6.4 There Are Several Types
of Viral Infections

After reading this section, you should be able to:
a. Compare and contrast the major steps of the life cycles of virulent
phages and temperate phages
b. List examples of lysogenic conversion
c. Differentiate among the types of viral infections of eukaryotic cells
d. Summarize the current understanding of how oncoviruses cause cancer

So far, our discussion has focused on viral structures and modes
of multiplication with little mention of the cost to host cells. The
dependence of viruses on their host cells has many consequences—as anyone who has ever had a cold or the flu well
understands. Next we discuss the interaction between virus and
host cell.

wil11886_ch06_106-127.indd 118

Lytic and Lysogenic Infections Are Common for
Bacterial and Archaeal Cells
Most bacteriophages are either virulent or temperate. A virulent
phages is one that has only one option: to begin multiplying immediately upon entering its bacterial host, followed by release
from the host by lysis. T4 is an example of a virulent phages.
Temperate phages have two options: upon entry into the host,
they can multiply like virulent phages and lyse the host cell, or they
can remain within the host without destroying it (figure 6.16).
Bacteriophage lambda is an example of this type of phages. The
life cycles of both T4 and lambda are described in more detail in
chapter 26.
Steps in the Replication of T4 Phages in E. coli;
Lambda Phages Replication Cycle
The relationship between a temperate phages and its host is
called lysogeny. The form of the virus that remains within its host is
called a prophage. A prophage is simply the viral genome either
integrated into the bacterial chromosome or free in the cytoplasm.
The infected bacteria are called lysogens or lysogenic bacteria.
Lysogenic bacteria reproduce and in most other ways appear to be
perfectly normal. However, they have two distinct characteristics.
The first is that they cannot be reinfected by the same virus; that is,
they have immunity to superinfection. The second is that as they
reproduce, the prophage is replicated and inherited by progeny cells.
This can continue for many generations until conditions arise that
cause the prophage to initiate synthesis of phages proteins and to
assemble new virions, a process called induction. Induction is commonly caused by changes in growth conditions or ultraviolet irradiation of the host cell. As a result of induction, the lysogenic cycle
ends and the lytic cycle commences; the host cell lyses and progeny
phages particles are released.
Another important outcome of lysogeny is lysogenic conversion. This occurs when a temperate phages changes the phenotype
of its host. Lysogenic conversion often involves alteration in surface characteristics of the host. For example, when a member of
the genus Salmonella is infected by epsilon phages, the phages
changes the activities of several enzymes involved in construction
of the carbohydrate component of the bacterium’s lipopolysaccharide. This eliminates the receptor for epsilon phage, so the bacterium becomes immune to infection by another epsilon phages.
Other lysogenic conversions give the host pathogenic properties.
This is the case when Corynebacterium diphtheriae, the cause of
diphtheria, is infected with phages β. The phages genome encodes
diphtheria toxin, which is responsible for the disease. Thus only
those strains of C. diphtheriae that are infected by the phages (i.e.,
lysogens) cause disease.
Diphtheria (section 39.1)
Clearly the infection of a bacterium by a temperate phages
has significant impact on the host, but why would viruses evolve
this alternate cycle? Two advantages of lysogeny have been recognized. The first is that lysogeny allows the viral nucleic acid to
be maintained within its host. Bacteria often become dormant
due to nutrient deprivation, and while in this state, they do not
synthesize nucleic acids or proteins. In such situations, a prophage
would survive but most virulent bacteriophages would not be
replicated, as they require active cellular biosynthetic machinery.

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6.4 There Are Several Types of Viral Infections 119

Phage DNA

Bacterial
chromosome
Phage injects
its DNA into
cytoplasm.

New phages
can bind to
bacterial
cells.
Lytic cycle

Cell lyses
and releases
the new phages.

Exposure to
stress such as
UV light triggers
excision from host
chromosome.
Lysogenic cycle

Phage DNA
directs the
synthesis of
many new
phages.

Phage DNA
integrates
into host
chromosome.

Prophage DNA
is copied when
cell divides.
Prophage

Figure 6.16 Lytic and Lysogenic Cycles of Temperate Phages. Temperate phages have two phases to their life cycles. The lysogenic cycle allows the genome
of the virus to be replicated passively as the host cell’s genome is replicated. Certain environmental factors such as UV light can cause a switch from the lysogenic
cycle to the lytic cycle. In the lytic cycle, new virus particles are made and released when the host cell lyses. Virulent phages are limited to just the lytic cycle.
MICRO INQUIRY Why is a lysogen considered a new or different strain of a given bacterial species?

Furthermore, their genome would be degraded as the host cell
entered dormancy. The second advantage arises when there are
many more phages in an environment than there are host cells, a
situation virologists refer to as a high multiplicity of infection
(MOI). In these conditions, lysogeny enables the survival of infected host cells within a population that has few uninfected cells.
When MOI is high, a virulent phages would rapidly destroy the
available host cells in its environment. However, a prophage will
be replicated as the host cell reproduces.
Archaeal viruses can also be virulent or temperate. In addition, many archaeal viruses establish chronic infections. Unfortunately, little is known about the mechanisms they use to regulate
their replicative cycles.

Comprehension Check
1. Define the terms lysogeny, temperate phages, lysogen, prophage,
immunity, and induction.
2. What advantages might a phages gain by being capable of lysogeny?
3. Describe lysogenic conversion and its significance.

Infections of Eukaryotic Cells
Viruses can harm their eukaryotic host cells in many ways. An infection that results in cell death is a cytocidal infection. As with
bacterial and archaeal viruses, this can occur by lysis of the host
(figure 6.17a). Infection does not always result in lysis of host cells.
Some viruses (e.g., herpesviruses) can establish persistent infections
lasting many years (figure 6.17b,c). Eukaryotic viruses can cause

wil11886_ch06_106-127.indd 119

microscopic or macroscopic degenerative changes or abnormalities
in host cells and in tissues that are distinct from lysis. These are
called cytopathic effects (CPEs). Viruses use a variety of mechanisms to cause cytopathic and cytocidal effects. Some important
examples are noted in chapter 38. One mechanism of particular note
is that some viruses cause the host cell to be transformed into a malignant cell (figure 6.17d). This is discussed next.

Viruses and Cancer
Cancer is one of the most serious medical problems in developed
nations, and it is the focus of an immense amount of research. A
tumor is a growth or lump of tissue resulting from neoplasia—
unregulated abnormal new cell growth and reproduction. Tumor
cells have aberrant shapes and altered plasma membranes that may
contain distinctive molecules (tumor antigens). These changes result from the tumor cells becoming less differentiated. Their unregulated proliferation and loss of differentiation result in invasive
growth that forms unorganized cell masses.
Two major types of tumor growth patterns exist. If the tumor
cells remain in place to form a compact mass, the tumor is benign.
In contrast, cells from malignant or cancerous tumors actively
spread throughout the body in a process known as metastasis. Some
cancers are not solid but cell suspensions. For example, leukemias
are composed of undifferentiated malignant white blood cells that
circulate throughout the body. Indeed, dozens of kinds of cancers
arise from a variety of cell types and afflict all kinds of organisms.
Some viruses have been shown to cause cancer in animals,
including humans; it is estimated that about 10 to 20% of human

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Figure 6.17 Types of Viral Infections and Their Effects on
Animal Cells. (a) Lytic infections of host cells can lead to disease
states in animal hosts called acute infections. There are two types
of persistent infections: (b) latent infections and (c) chronic infections.
(d) Some infections of animal cells cause the cell to be transformed
into a malignant cell, which can cause cancer in the animal host.

Adsorption
to host

Penetration

Rapid
multiplication
Activation of host
proto-oncogene (human
cancers), insertion of
oncogene (cancers in
other animals), or
inactivation of tumor
suppressor protein

Cell death
and virus
release

(a) Acute
infection

Viral components
are present
(e.g., viral genome);
host is not harmed.
Activation

(b) Latent
infection

(c) Chronic
infection
Persistent infections

cancers have a viral etiology. To understand the role viruses play in
cancer, we must begin by considering carcinogenesis when viruses
are not involved. Carcinogenesis is a complex, multistep process
caused by mutations in multiple genes. Some mutations lead to the
unregulated proliferation that is a major characteristic of a cancer
cell. Other mutations prevent cells from repairing DNA damage,
thereby making the cells more inclined to mutate further. This leads
to additional genotypic changes. For example, mutations that promote metastasis may occur, allowing the tumor to invade other tissues.
Mutations: heritable changes in a genome (section 16.1)
Considerable research into the causes of cancer has focused on
the mutations that allow cancerous cells to grow uncontrollably. Those

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Slow release
of virus without
cell death

(d) Transformation
into malignant
cell

studies show that there are two types of genes that must be mutated: proto-oncogenes and tumor suppressor genes. Their names
suggest that these genes are somehow abnormal. But this is not
the case. Proto-oncogenes and tumor suppressor genes are normal
cellular genes. Proto-oncogenes must be expressed if cell division is to occur. However, they normally are expressed only if the
cell receives an appropriate signal, such as the binding of a growth
factor to a receptor on the cell surface. When such a signal is received, the cell initiates the cell cycle, but it cannot continue past
a checkpoint controlled by the activity of proteins encoded by
tumor suppressor genes. These proteins are called tumor suppressor proteins. When tumor suppressor proteins are active,

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they prevent progression through the cell cycle. Thus, for cell division to occur, proto-oncogene proteins (sometimes called protooncoproteins) must be active, and tumor suppressor proteins must
be inactive.
During carcinogenesis, mutations arise that disrupt the normal activity of these two types of genes. The first type of mutation
allows proto-onocogenes or their protein products to function
without an appropriate signal. Thus the proto-oncogene or its protein is active even when it should not be. The second type of mutation prevents expression of tumor suppressor genes, yields
nonfunctional tumor suppressor proteins, or in some other way
leads to inactivation of a tumor suppressor protein. Thus the cell
can continue cell division even when it shouldn’t, such as in the
presence of severe DNA damage. Numerous proto-oncogenes and
tumor suppressor genes have been identified. An important protooncogene encodes a protein called Myc. Myc controls transcription of many genes, including some involved in DNA replication
and other cell-cycle-related functions. Two of the most important
tumor suppressor proteins are Rb and p53. The protein p53 is often
referred to as “the guardian of the genome” because not only does
it cause cell cycle arrest, but it also initiates programmed cell death
in response to DNA damage. Programmed cell death, also called
apoptosis, is a process that causes cells to kill themselves. Thus,
when p53 is inactivated, the cell reproduces in an unregulated fashion, avoiding programmed cell death even when it should destroy
itself. This is a catastrophic event for the cell because it can lead to
the accumulation of additional mutations that contribute to carcinogenesis.
Tumor suppressor genes
We now turn our attention to viruses and their role in causing
cancer. These viruses are called oncoviruses. As you can see in
table 6.1, most human oncoviruses have dsDNA genomes, and most
of these viruses cause cancer in a similar way—by interacting with
and inactivating either Rb or p53. Oncoviruses that are retroviruses
(e.g., HTLV-1) exert their oncogenic powers in a different manner.
Some carry genes called oncogenes that stimulate the activity of
cellular proto-oncogenes. For example, HTLV-1 infects immune
system cells called T cells. During infection HTLV-1 produces a
regulatory protein that activates expression of numerous cellular
proto-oncogenes. Other retroviruses transform cells into cancerous

Table 6.1

wil11886_ch06_106-127.indd 121

cells when the viral genome integrates into the host chromosome
such that strong, viral regulatory elements are near a cellular protooncogene. These elements cause the nearby proto-oncogene to
be transcribed at a high level, causing the cellular gene to be considered an oncogene.

Comprehension Check
1. How does a latent infection differ from a chronic infection?
2. What is a cytocidal infection? What is a cytopathic effect?
3. Define the following terms: tumor, neoplasia, anaplasia, metastasis,
proto-oncogene, oncogene, and tumor suppressor gene.
4. Distinguish the mechanism by which dsDNA viruses cause cancer
from that of retroviruses. Why do you think there is an environmental
component to many kinds of cancer?

6.5 Cultivation and Enumeration
of Viruses

After reading this section, you should be able to:
a. List the approaches used to cult