Lecture_Week6_Viruses, Viroids, and Prions.pptx

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Viruses, Viroids, and Prions
tiny but deadly.
Learning objectives week 6
Explain to me what the different parts of a virus are and
the functions of these parts.

Explain how viruses replicate and how this is different
from bacterial growth.

Understand how cancer forms and explain how
mutations and viruses are important for this process.
 So why should we care about
viruses?
Influenza virus – the flu 1918-1920
75,000,000 died
HIV – 35,000,000 died last ~30 years
Dengue fever – 50,000,000-100,000,000
infections per year.
Outline:
What are viruses, viroids, and prions
Viral diseases and viral anatomy
Viral replication and release
Viral culturing and study
Viroids and prions
Outline:
What are viruses, viroids, and prions
Viral diseases and viral anatomy
Viral replication and release
Viral culturing and study
Viroids and prions
Viruses, Viroids, and Prions
tiny but deadly.
 So what are viruses, viroids,
and prions?
Acellular--- meaning that compared to even
bacteria, they are very simple
Composed of one or a few different
biomolecules
Cannot reproduce independently
Cannot grow or respond to the
environment.
There are more bacteria than human cells in
a human body and researchers think there
are even more viruses than bacteria.
Half of the human genome is made of DNA
thought to be viral in origin.
Cause many human diseases
 So what are viruses, viroids,
and prions?
Acellular--- meaning that compared to even
bacteria, they are very simple
Composed of one or a few different Chicken Pox
biomolecules
Cannot reproduce independently
Cannot grow or respond to the
environment.
There are more bacteria than human cells in
a human body and researchers think there
are even more viruses than bacteria.
Half of the human genome is made of DNA
thought to be viral in origin.
Cause many human diseases
Outline:
What are viruses, viroids, and prions
Viral diseases and viral anatomy
Viral replication and release
Viral culturing and study
Viroids and prions
 Viruses– cause most of the
diseases that plague the
industrialized world
Cannot carry out any metabolic pathway
Neither grow nor respond to the
environment
Cannot reproduce independently
Recruit the cell’s metabolic pathways to
increase their numbers
No cytoplasmic membrane, cytosol,
organelles (with one exception)
Have extracellular and intracellular state
Some of the diseases caused by
viruses
 Most viruses infect only particular host
cells

May be so specific they
infect only particular kind
of cell in a particular host

Viral surface proteins
have affinity for specific
proteins on host cell

Generalists – infect many
kinds of cells in many
different hosts
Viruses live in both Extracellular and
Intracellular states.
Extracellular State
Called virion
Protein coat (capsid) surrounding
nucleic acid
Nucleic acid and capsid also called
nucleocapsid
Some have phospholipid envelope
Outermost layer provides protection and
recognition sites for host cells
Intracellular State
Capsid removed
Virus exists as nucleic acid
Viruses have 2 main parts a genome
and capsid.
The genome is just like any
other genome, composed of
nucleic acid

Cannot replicate on its own,
needs a host cell’s
replication machinery.

Capsid is the viruses body,
comprised of protein and
arranges in a symmetrical
manner around the virus.
Different viruses can have genomes
made of different types of nucleic
acids. Partial genome Viral
Show more variety in of E. coli genome
nature of their genomes
than do cells
Primary way scientists
categorize and classify
viruses
May be DNA or RNA, but
never both
dsDNA, ssDNA, dsRNA,
ssRNA
Linear and segmented or
single and circular
Much smaller than
Capsids are the outer protein coat
of the virus
Provide protection for
viral nucleic acid
Means of attachment to
host’s cells
Composed of protein
subunits called
capsomeres
Capsomere made of
single or multiple
types of proteins
Viruses come in three
basic shapes Helical,
 The viral envelope covers the capsid and genome
and is acquired from the host during replication or
release.
Composed of
phospholipid bilayer
and proteins
Envelope is portion of
membrane system of
host
Some proteins are
virally coded
glycoproteins
(spikes)
Envelope’s proteins
and glycoproteins
Take home messages
Viruses are small and deadly.
Different types of viruses infect different types of
cells.
Viruses are composed of a capsid which is made
of protein and a nucleic acid genome.
The type of nucleic acid in which makes up the
viral genome is a convenient way to classify
viruses.
Some viruses also have an envelope composed of
fatty acids.
Outline:
What are viruses, viroids, and prions
Viral diseases and viral anatomy
Viral replication and release
Viral culturing and study
Viroids and prions
 Viral replication is dependent
upon the hosts organelles and
Lytic replication enzymes.
Replication cycle usually
results in death and lysis of
host cell
Stages of lytic replication
cycle of bacteriophage
Attachment
Entry
Synthesis
Assembly
Release
 Lysogeny is another type of viral
replication cycle
Infected host cells grow and
reproduce normally for Lambda Phage: one of the most us
generations before they lyse molecular tools ever.

Temperate phages
Prophages – inactive phages

Lysogenic conversion results
when phages carry genes
that alter the phenotype of a
bacterium
 Attachment Prophage
Entry in chromosome
Lambda
phage

Lytic Lysogeny
cycle
Synthesis

Release Replication of
chromosome
Assembly and virus;
cell division
Induction
Further replications and
cell divisions

Figure 13.11 The lysogenic replication cycle in bacteriophages: phage lambda and E. coli
 Viruses are the ultimate replicating
machine
Number of infective virions

is
in medium (log scale)

by lys
Burst size

irions
e of v
Entry Releas

Synthesis and assembly

Time (minutes)
Attachment Burst time

E. coli 20 minutes to replicate
Yeast 2 hours to replicate
Human cells much longer to replicat
Figure 13.9 Pattern of virion abundance in lytic cycle
 Group Questions

Larger viruses typically have a double stranded
genome where as smaller viruses have a single
stranded genome. Why might this be?

If colony of 1 million bacteria was infected by a
single phage and each lytic replication cycle
produced 200 phage how many replication cycles
would it take before all of the bacteria are killed.
Assume each bacteria is only infected by a single
phage.
Replication of animal viruses follows the basic pathway
of bacteriophages with a few key differences.

Differences between
animal and bacteria
viruses
Presence of envelope
around some viruses

Eukaryotic nature of animal
cells may require additional
steps for integration.
Virus must get into the
nucleus
Replication of animal viruses follows the basic pathway
of bacteriophages with a few key differences.
Differences
Presence of envelope
around some viruses

Eukaryotic nature of
animal cells

Lack of cell wall in
animal cells, so entry
into a human cell is
different from
Replication of animal viruses follows the basic pathway
of bacteriophages with a few key differences.
Differences
Presence of envelope
around some viruses

Eukaryotic nature of
animal cells

Lack of cell wall in
animal cells, so entry
into a human cell is
different from
Central Dogma of Biology provides
some guiding principles for viral
replication
Viruses must assemble
(put themselves together)

This means they must

1)Copy their genome
2)Make the proteins that
make the capsid

How this happens depends
upon the type of virus.

Messenger RNA = mRNA
Different viruses have genomes made
of different nucleic acids.
Show more variety in
nature of their genomes
than do cells
Primary way scientists
categorize and classify
viruses
May be DNA or RNA, but
never both
dsDNA, ssDNA, dsRNA,
ssRNA
Linear and segmented or
single and circular
 Some Useful definitions:
ss = single stranded
ds = double stranded
+ is like messenger RNA can be
directly translated into protein
- is the opposite so it cannot be
directly translated into protein
 Synthesis of animal viruses requires
different strategies depending on the type
of nucleic acid it uses for a genome.

DNA viruses can use the RNA viruses often
machinery of the cell as they
are essentially very very small replicate in the cytoplasm.
parts of the mammalian
genome.
This is more complicated
Usually means that they have due to variation of the
to go the nucleus in order to type of RNA genome you
replicate. can potentially have.

DNA replication machinery is
+ssRNA, -ssRNA, dsRNA
located there.
 Synthesis of animal viruses
requires different strategies
depending on the type of
nucleic acid it uses for a
genome.
Remember the virus must make both more
viral genomes and capsids.

+ssRNA can act as messengerRNA = mRNA
so the viral genome can be translated as
any other transcript (capsid)

Viral RNA polymerase makes –ssRNA

From the –ssRNA more + ssRNA can be
transcribed

+ssRNA retroviruses are slightly different
as they require a DNA intermediate
 So what if you are an RNA virus that wants to incorporate into the
genome or make more RNA virus?

reverse
transcriptase is an
Reverse
transcriptase
enzyme used to generate
complementary DNA from
an RNA template

Drugs that inhibit these
enzymes can be potent
antivirals?
 Synthesis of animal viruses
requires different strategies
depending on the type of
nucleic acid it uses for a
genome.
-ssRNA have to overcome the fact
that
–ssRNA can’t be directly used by
ribosomes

Carry a special enzyme to make
+ssRNA
Carries a RNA dependent
RNA transcriptase in its capsid
 Synthesis of animal viruses
requires different strategies
depending on the type of
nucleic acid it uses for a
genome.
dsRNA viruses use a
combination of the strategies
mentioned previously
The mechanisms of assembly and release of
animals viruses depends upon its genetic
material.
Most DNA viruses assemble in nucleus

Most RNA viruses develop solely in cytoplasm

Number of viruses produced depends on type of
virus and size and initial health of host cell
 Three mechanisms of virus
release:
1) Lysis: cells break open Cell Lysis
and die

Naked viruses are
released by exocytosis
or lysis
Exocytosis is when the viruses leave
the cell without breaking open the
cell.

Makes the cells sick but they don’t die
so they can still make more viruses.
 I. Enveloped viruses
Do not usually lyse the host cell and thus cause
persistent infections.

Similar to exocytosis but in addition the virus wraps
itself in the cytoplasmic membrane of the cell.

This hides it from the immune system
and facilitates entry into a new cell.

Figure 13.14 The process of budding in enveloped viruses
 Viral Latency (How many of you
have heard of Shingles?)

More than 3 million US
cases per year
Preventable by vaccine
Short-term: resolves within
days to weeks
 What is latency?
Chicken Pox Latency leads to Shingles later
Latency is when animal viruses
remain dormant in host cells

May be stay there for years with no
viral activity

Some latent viruses do not become
incorporated into host
chromosomes

Incorporation of provirus into host
DNA is permanent
Take home messages
Viruses can replicate very very quickly.
Viruses use much of the host replication
machinery in order to replicate as such finding
drugs that are effective against them is difficult.
Synthesis of animal viruses requires different
strategies depending on the type of nucleic acid
it uses as a genome.
Outline:
What are viruses, viroids, and prions
Viral diseases and viral anatomy
Viral replication and release
Viral culturing and study
Viroids and prions
 Viruses Oncogenes and Cancer
Cancer is a group of diseases
involving abnormal cell
growth with the potential to
invade or spread to other
parts of the body.

Neoplasia
Uncontrolled cell division
in multicellular animal
Mass of neoplastic cells is
tumor

The difference between
benign and malignant tumors
is metastasis.
Viruses Oncogenes and Cancer:
Cancer is a group of diseases
involving abnormal cell
growth with the potential to
invade or spread to other
parts of the body.

Neoplasia
Uncontrolled cell division
in multicellular animal
Mass of neoplastic cells is
tumor
So how does a cell get to be
The difference between
benign and malignant tumors
like this and
is metastasis. what do viruses have to do with
any of this?
 There are many different factors that contribute to the
activation of oncogenes (genes that can cause cancer when
activated)

Ultraviolet light
Radiation
Carcinogens
Viruses

The one things that link all of these factors is that they
damage and thus mutate DNA.
 There are many different factors that contribute
to the activation of oncogenes

Woman who constantly used tanning
Ultraviolet
light beds shares gruesome selfie
Radiation
Carcinogens
Viruses
 There are many different factors that contribute
to the activation of oncogenes

Ultraviolet
light
Radiation
Carcinogens
Viruses
 There are many different factors that contribute
to the activation of oncogenes
Viruses cause 20–25% of human
cancers
Some carry copies of oncogenes as
part of their genomes
Some promote oncogenes already
present in host
Some interfere with tumor
repression
Specific viruses are known to cause
~15% of human cancers
Burkitt’s lymphoma
Hodgkin’s disease
Kaposi’s sarcoma
Cervical cancer
The oncogene theory of cancer induction

Normal
noncancerous
state

Protooncogene= oncogene that is as
Figure 13.16 The oncogene theory of cancer induction
Figure 13.16 The oncogene theory of cancer induction
I want to study viruses, I want to study cancer,
how can I do this?

Viruses cause cancer
Viruses cause many of
the most dangerous
diseases
We should study viruses
 Are Viruses Alive?

Some consider them complex
pathogenic chemicals
Others consider them the least complex
living entities
Use sophisticated methods to invade cells
Have the ability to take control of their host cell
Are able to replicate themselves as long as in a
host

© 2012 Pearson Education Inc.
 Viruses cannot be grown outside of a host, so to
study them scientists must grow them in some other
cell.

Inside a mature
organism bacteria,
plant, or animal
Fertilized eggs
Cell culture Bacterial la
Viral plaqu
n allow the researcher to estimate
the number of viruses
Viruses cannot be grown outside of a host so to
study them scientists must grow them in some
other cell.
Inside a mature
organism bacteria,
plant, or animal
Fertilized eggs
Cell culture

Growing viruses in plants or animals leads to
a whole host of ethical and technical issues.
 A wide variety of sites suitable for viral
inoculation
make eggs especially useful in
Air sac Injection into
culturing viruses chorioallantoic
Injection into membrane
chorioallantois
Injection into
Figure 13.18 embryo
Inoculation
sites for the
culture of
viruses in
embryonated
chicken eggs
Injection into Injection into
amnion yolk sac
 Culturing Viruses in Cell (Tissue) Culture can be
simpler than maintaining animals

Consists of cells isolated
from an organism and grown
on a medium or in a broth

Two types of cell cultures
Diploid cell cultures (100
generations max) these are
just normal cells taken from
our bodies

Continuous cell cultures
derived from tumors so
 Henrietta Lacks (HeLa cells) are
cells from a cervical cancer.
Henrietta died in the 1950’s her cells are still
being used a standard of human cell culture.

Neither Lacks nor her family gave her physician
permission to harvest the cells. At that time,
permission was neither required nor customarily
sought. The cells were later commercialized. In the
1980s, family medical records were published
without family consent.

Genome sequence was published without their
consent.
Group questions
1) List some challenges of studying viruses that infect
humans.

2) Describe how viral infection can cause cancer. Why do
we not get cancer every time we get a virus?

potentially helpful videos on viral
replication
https://
www.youtube.com/watch?v=uIut0oVWC
Eg
https://www.youtube.com/watch?
v=J4BN4dARpio
Take home messages
Viruses can cause cancer by mutating areas of
the genome that in turn allow for unregulated cell
growth.
Many other factors can contribute to oncogene
activation.
Viruses require a host cell to replicate.
In order to study viruses researchers grow them
inside other cells.
Combinations of viral biology and cancer biology
has lead to development of some of the most
powerful tools in biology.
Outline:
What are viruses, viroids, and prions
Viral diseases and viral anatomy
Viral replication and release
Viral culturing and study
Viroids and prions
 Viroids are extremely small
circular infectious pieces of RNA
that infect plants.
Genome of bacteriophage T7 PSTV
Viroids can have grave economic
consequences
They infect many
important crops.
Are thought to be
relics of the RNA
world which is
something we will
discuss in more
detail in the
coming weeks.
 Prions are single proteins that when
undergo a structural change can cause
disease.
Proteinaceous infectious agents

Cellular PrP protein
Made by all mammals
Normal structure with -helices called
cellular PrP

Prion PrP
Disease-causing form with -pleated
sheets called prion PrP

Prion PrP changes shape of cellular
PrP so it becomes prion PrP
 Prions act like bad influences, they take
well behaved proteins and make them
pathogenic.
They only cause disease in
mammals Three different Prion
Diseases
Normally, nearby proteins and
polysaccharides force PrP into
its correct shape (cellular Prp)
PrP mutations result in
formation of prion PrP
Fatal neurological degeneration,
fibril deposits in brain, and loss
of brain matter
Large vacuoles form in brain
Characteristic spongy
Prion diseases are horrible, but they are
relatively rare.
No treatment
Fatal
Are spread through ingestion of infected
material or through membrane protein contact.

Prions only destroyed by incineration or
autoclaving in 1 N NaOH
Take home messages
Viroids are small infectious pieces of RNA that
generally infect plants.
Prions are infectious proteins that have
structurally changed such that they can cause
healthy proteins to change structure as well.
Prions cause neurodegenerative diseases but
luckily they are relatively rare.
Prions are virtually indestructible
Group Questions
1) Why might it be beneficial for a virus not to kill a cell?

2) Describe the main difference between + and – strand
RNA virus replication.

3) Is single stranded DNA normally found in human cells
that have not been infected with a ssDNA virus.
 Tiny holes found in the
thalamus
caused by a prion that is
genetically inherited.

Thalamus is responsible for
allowing
you to fall into deep sleep.
http://www.cnn.com/2017/09/19/health/fatal-insomnia-family-curse-somethings-
Prion Overview video