Unit 7 (Ch 19) Viruses PDF Notes

Summary

These notes from December 5, 2014 cover Chapter 19 on viruses, including their structure, reproduction, and various properties. Topics include viral infection mechanisms, types of viruses, and the importance of viruses in biology.

Full Transcript

Ch 19 ­ Virus.notebook December 05, 2014

Ch 19 ­ Viruses

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Ch 19 ­ Virus.notebook December 05, 2014

CHAPTER 18
MICROBIAL MODELS: THE GENETICS OF
VIRUSES AND BACTERIA

Section A: The Genetics of Viruses
1. Researchers discovered viruses by studying a plant disease

2. A virus is a genome enclosed in a protective coat

3. Viruses can only reproduce within a host cell:an overview

4. Phages reproduce using lytic or lysogenic cycles

5. Animal viruses are diverse in their modes of infection and replication

6. Plant viruses are serious agricultural pests

7. Viroids and prions are infectious agents even simpler than viruses.

8. Viruses may have evolved from other mobile genetic elements

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Introduction
Viruses and bacteria are the simplest biological systems ­ microbial
models where scientists find life’s fundamental molecular
mechanisms in their most basic, accessible forms.

Microbiologists provided most of the evidence that genes are made
of DNA, and they worked out most of the major steps in DNA
replication, transcription, and translation.

Viruses and bacteria also have interesting, unique genetic features
with implications for understanding diseases that they cause.

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Bacteria are prokaryotic organisms.

Their cells are much smaller and more simply organized that those of
eukaryotes, such as plants and animals.

Viruses are smaller and
simpler still, lacking the
structure and most meta­
bolic machinery in cells.

Most viruses are little
more than aggregates of
nucleic acids and protein
­ genes in a protein coat.

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2. A virus is a genome enclosed in a
protective coat
Stanley’s discovery that some viruses could be crystallized was
puzzling because not even the simplest cells can aggregate into
regular crystals.

However, viruses are not cells.

They are infectious particles consisting of nucleic acid encased in a
protein coat, and, in some cases, a membranous envelope.

Viruses range in size from only 20nm in diameter to that barely
resolvable with a light microscope.

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The genome of viruses includes other options than the
double­stranded DNA that we have studied.

Viral genomes may consist of double­stranded DNA,
single­stranded DNA, double­stranded RNA, or single­
stranded RNA, depending on the specific type of virus.

The viral genome is usually organized as a single linear or
circular molecule of nucleic acid.

The smallest viruses have only four genes, while the largest
have several hundred.

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The capsid is a protein shell enclosing the viral genome.

Capsids are build of a large
number of protein subunits
called capsomeres, but
with limited diversity.

The capsid of the tobacco
mosaic virus has over 1,000
copies of the same protein.

Adenoviruses have 252
identical proteins arranged
into a polyhedral capsid ­
as an icosahedron.

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Some viruses have viral
envelopes, membranes cloaking
their capsids.

These envelopes are derived from
the membrane of the host cell.

They also have some viral
proteins and glycoproteins.

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The most complex capsids are
found in viruses that infect
bacteria, called bacteriophages or
phages.

The T­even phages that infect
Escherichia coli have a 20­sided
capsid head that encloses their
DNA and protein tail piece that
attaches the phage to the host and
injects the phage DNA inside.

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3. Viruses can reproduce only
within a host cell: an overview
Viruses are obligate intracellular parasites.

They can reproduce only within a host cell.

An isolated virus is unable to reproduce ­ or do anything else,
except infect an appropriate host.

Viruses lack the enzymes for metabolism or ribosomes for
protein synthesis.

An isolated virus is merely a packaged set of genes in transit
from one host cell to another.

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Each type of virus can infect and parasitize only a limited
range of host cells, called its host range.

Viruses identify host cells by a “lock­and­key” fit between
proteins on the outside of virus and specific receptor molecules
on the host’s surface.

Some viruses (like the rabies virus) have a broad enough host
range to infect several species, while others infect only a single
species.

Most viruses of eukaryotes attack specific tissues.

Human cold viruses infect only the cells lining the upper
respiratory tract.

The AIDS virus binds only to certain white blood cells.

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A viral infection begins when the
genome of the virus enters the
host
cell.

Once inside, the viral genome
commandeers its host,
reprogramming the cell to copy
viral nucleic acid and
manufacture
proteins from the viral genome.

The nucleic acid molecules and
capsomeres then self­assemble
into viral particles and exit the
cell.

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4. Phages reproduce using lytic or
lysogenic cycles

While phages are the best understood of all viruses, some of
them are also among the most complex.

Research on phages led to the discovery that some double­
stranded DNA viruses can reproduce by two alternative
mechanisms: the lytic cycle and the lysogenic cycle.

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In the lytic cycle, the phage reproductive cycle culminates in the
death of the host.

In the last stage, the bacterium lyses (breaks open) and releases
the phages produced within the cell to infect others.

Virulent phages reproduce only by a lytic cycle.

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While phages have the potential to wipe out a bacterial colony in
just hours, bacteria have defenses against phages.

Natural selection favors bacterial mutants with receptors sites that
are no longer recognized by a particular type of phage.

Bacteria produce restriction nucleases that recognize and cut up
foreign DNA, including certain phage DNA.

Modifications to the bacteria’s own DNA prevent its destruction by
restriction nucleases.

But, natural selection favors resistant phage mutants.

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In the lysogenic cycle, the phage genome replicates without
destroying the host cell.

Temperate phages, like phage lambda, use both lytic and
lysogenic cycles.

Within the host, the virus’ circular DNA engages in either the
lytic or lysogenic cycle.

During a lytic cycle, the viral genes immediately turn the host cell
into a virus­producing factory, and the cell soon lyses and releases
its viral products.

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The viral DNA molecule, during the lysogenic cycle, is incorporated
by genetic recombination into a specific site on the host cell’s
chromosome.

In this prophage stage, one of its genes codes for a protein that
represses most other prophage genes.

Every time the host divides, it also copies the viral DNA and passes
the copies to daughter cells.

Occasionally, the viral genome exits the bacterial chromosome and
initiates a lytic cycle.

This switch from lysogenic to lytic may be initiated by an
environmental trigger.

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http://www.youtube.com/watch?v=Rpj0emEGShQ

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5. Animal viruses are diverse in
their modes of infection and
replication
Many variations on the basic scheme of viral infection and
reproductions are represented among animal viruses.

One key variable is the type of nucleic acid that serves as a virus’
genetic material.

Another variable is the presence or absence of a membranous
envelope.

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Viruses equipped with an outer envelope use the envelope to enter
the host cell.

Glycoproteins on the envelope bind to specific receptors on the
host’s membrane.

The envelope fuses with the host’s membrane, transporting the
capsid and viral genome inside.

The viral genome duplicates and directs the host’s protein synthesis
machinery to synthesize capsomeres with free ribosomes and
glycoproteins with bound ribosomes.

After the capsid and viral genome self­assemble, they bud from the
host cell covered with an envelope derived from the host’s plasma
membrane, including viral glycoproteins.

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These enveloped viruses
do not necessarily kill the
host cell.

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Some viruses have envelopes that are not derived from plasma
membrane.

The envelope of the herpesvirus is derived from the nuclear envelope
of the host.

These double­stranded DNA viruses reproduce within the cell nucleus
using viral and cellular enzymes to replicate and transcribe their DNA.

Herpesvirus DNA may become integrated into the cell’s genome as a
provirus.

The provirus remains latent within the nucleus until triggered by
physical or emotional stress to leave the genome and initiate active viral
production.

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The viruses that use RNA as the genetic material are quite diverse,
especially those that infect animals.

In some with single­stranded RNA (class IV), the genome acts as
mRNA and is translated directly.

In others (class V), the RNA genome serves as a template for
mRNA and for a complementary RNA.

This complementary strand is the template for the synthesis of
additional copies of genome RNA.

All viruses that require RNA ­> RNA synthesis to make mRNA
use a viral enzyme that is packaged with the genome inside the
capsid.

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Retroviruses (class VI) have the most complicated life cycles.

These carry an enzyme, reverse transcriptase, which transcribes
DNA from an RNA template.

The newly made DNA is inserted as a provirus into a
chromosome in the animal cell.

The host’s RNA polymerase transcribes the viral DNA into more
RNA molecules.

These can function both as mRNA for the synthesis of viral
proteins and as genomes for new virus particles released from the
cell.

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Human immunodeficiency virus (HIV), the virus that causes AIDS
(acquired immunodeficiency syndrome) is a retrovirus.

The viral particle includes
an envelope with glyco­
proteins for binding to
specific types of red blood
cells, a capsid containing
two identical RNA strands
as its genome and two
copies of reverse
transcriptase.

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The reproductive cycle of
HIV illustrates the pattern
of infection and replication
in a retrovirus.

After HIV enters the host
cell, reverse transcriptase
synthesizes double stranded
DNA from the viral RNA.

Transcription produces
more copies of the viral
RNA that are translated into
viral proteins, which self­
assemble into a virus
particle and leave the host.

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The link between viral infection and the symptoms it produces is
often obscure.

Some viruses damage or kill cells by triggering the release of
hydrolytic enzymes from lysosomes.

Some viruses cause the infected cell to produce toxins that lead
to disease symptoms.

Other have molecular components, such as envelope proteins,
that are toxic.

In some cases, viral damage is easily repaired (respiratory
epithelium after a cold), but in others, infection causes permanent
damage (nerve cells after polio).

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Many of the temporary symptoms associated with a viral
infection results from the body’s own efforts at defending itself
against infection.

The immune system is a complex and critical part of the body’s
natural defense mechanism against viral and other infections.

Modern medicine has developed vaccines, harmless variants or
derivatives of pathogenic microbes, that stimulate the immune
system to mount defenses against the actual pathogen.

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The first vaccine was developed in the late 1700s by Edward
Jenner to fight smallpox.

Jenner learned from his patients that milkmaids who had
contracted cowpox, a milder disease that usually infects cows, were
resistant to smallpox.

In his famous experiment in 1796, Jenner infected a farmboy with
cowpox, acquired from the sore of a milkmaid with the disease.

When exposed to smallpox, the boy resisted the disease.

Because of their similarities, vaccination with the cowpox virus
sensitizes the immune system to react vigorously if exposed to
actual smallpox virus.

Effective vaccines against many other viruses exist.

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Vaccines can help prevent viral infections, but they can do little to
cure most viral infection once they occur.

Antibiotics which can kill bacteria by inhibiting enzyme or
processes specific to bacteria are powerless again viruses, which have
few or no enzymes of their own.

Some recently­developed drugs do combat some viruses, mostly
by interfering with viral nucleic acid synthesis.

AZT interferes with reverse transcriptase of HIV.

Acyclovir inhibits herpes virus DNA synthesis.

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In recent years, several very dangerous “emergent viruses” have risen
to prominence.

HIV, the AIDS virus, seemed to appear suddenly in the early 1980s.

Each year new strains of influenza virus cause millions to miss work
or class, and deaths are not uncommon.

The deadly Ebola
virus has caused
hemorrhagic fevers
in central Africa
periodically since
1976.

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The emergence of these new viral diseases is due to
three processes: mutation, spread of existing viruses from
one species to another, and dissemination of a viral
disease from a small, isolated population.

Mutation of existing viruses is a major source of new
viral diseases.

RNA viruses tend to have high mutation rates because
replication of their nucleic acid lacks proofreading.

Some mutations create new viral strains with sufficient
genetic differences from earlier strains that they can
infect individuals who had acquired immunity to these
earlier strains.

This is the case in flu epidemics.

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Another source of new viral diseases is the spread of
existing viruses from one host species to another.

It is estimated that about three­quarters of new human
diseases have originated in other animals.

For example, hantavirus, which killed dozens of people in
1993, normally infects rodents, especially deer mice.

That year unusually wet weather in the southwestern U.S.
increased the mice’s food,
exploding its populations.

Humans acquired hantavirus
when they inhaled dust
containing traces of urine
and feces from infected mice.

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Finally, a viral disease can spread from a small, isolated
population to a widespread epidemic.

For example, AIDS went unnamed and virtually
unnoticed for decades before spreading around the world.

Technological and social factors, including affordable
international travel, blood transfusion technology, sexual
promiscuity, and the abuse of intravenous drugs, allowed
a previously rare disease to become a global scourge.

These emerging viruses are generally not new but are
existing viruses that expand their host territory.

Environmental change can increase the viral traffic
responsible for emerging disease.

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All tumor viruses transform cells into cancer cells after
integration of viral nucleic acid into host DNA.

Viruses may carry oncogenes that trigger cancerous
characteristics in cells.

These oncogenes are often versions of proto­oncogenes
that influence the cell cycle in normal cells.

Proto­oncogenes generally code for growth factors or
proteins involved in growth factor function.

In other cases, a tumor virus transforms a cell by turning
on or increasing the expression of proto­oncogenes.

It is likely that most tumor viruses cause cancer only in
combination with other mutagenic events.

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6. Plant viruses are
serious agricultural pests
Plant viruses can stunt plant growth and diminish
crop yields.

Most are RNA viruses with rod­shaped capsids
produced by a spiral of capsomeres.

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Plant viral diseases spread by two major routes.

In horizontal transmission, a plant is infected with the
virus by an external source.

Plants are more susceptible if their protective epidermis is
damaged, perhaps by wind, chilling, injury, or insects.

Insects are often carriers of viruses, transmitting disease
from plant to plant.

In vertical transmission, a plant inherits a viral infection
from a parent.

This may occurs by asexual propagation or in sexual
reproduction via infected seeds.

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Once it starts reproducing inside a plant cell, virus
particles can spread throughout the plant by passing
through plasmodermata.

These cytoplasmic connections penetrate the walls
between adjacent cells.

Agricultural scientists have
focused their efforts largely
on reducing the incidence
and transmission of viral
disease and in breeding
resistant plant varieties.

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7. Viroids and prions are infectious
agents even simpler than viruses

Viroids , smaller and simpler than even viruses, consist
of tiny molecules of naked circular RNA that infect plants.

Their several hundred nucleotides do not encode for
proteins but can be replicated by the host’s cellular
enzymes.

These RNA molecules can disrupt plant metabolism and
stunt plant growth, perhaps by causing errors in the
regulatory systems that control plant growth.

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Prions are infectious proteins that spread a disease.

They appear to cause several degenerative brain
diseases including scrapie in sheep, “mad cow
disease”, and Creutzfeldt­Jacob disease in humans.

According to the leading hypothesis, a prion is a
misfolded form of a normal brain protein.

It can then convert a normal protein into the prion
version, creating a chain reaction that increases their
numbers.

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8. Viruses may have evolved
from other mobile genetic
elements
Viruses are in the semantic fog between life and
nonlife.

An isolated virus is biologically inert and yet it has a
genetic program written in the universal language of
life.

Although viruses are obligate intracellular parasites
that cannot reproduce independently, it is hard to deny
their evolutionary connection to the living world.

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Because viruses depend on cells for their own propagation, it
is reasonable to assume that they evolved after the first cells
appeared.

Most molecular biologists favor the hypothesis that viruses
originated from fragments of cellular nucleic acids that could
move from one cell to another.

A viral genome usually has more in common with the
genome of its host than with those of viruses infecting other
hosts.

Perhaps the earliest viruses were naked bits of nucleic acids
that passed between cells via injured cell surfaces.

The evolution of capsid genes may have facilitated the
infection of undamaged cells.

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Candidates for the original sources of viral genomes
include plasmids and transposons.

Plasmids are small, circular DNA molecules that are
separate from chromosomes.

Plasmids, found in bacteria and in the eukaryote yeast,
can replicate independently of the rest of the cell and are
occasionally be transferred between cells.

Transposons are DNA segments that can move from one
location to another within a cell’s genome.

Both plasmids and transposons are mobile genetic
elements.

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