Chapter 5 Lecture Notes on Viruses and Prions PDF

Summary

This document is a chapter on viruses and prions, providing detailed information on the properties, classifications, and mechanisms of viruses. It discusses various aspects, including their roles in evolution, structure, life cycle, and impact on host cells. The chapter covers different types of viruses, their replication methods, and potential effects such as causing damage or transforming cells.

Full Transcript

CHAPTER 5 LECTURE NOTES

Chapter 5 Lecture Notes
Viruses and Prions
1. Discovery of viruses: scientists discovered that a disease in tobacco plant was caused by a virus,
an animal virus causes foot-and-mouth disease in cattle, and bodily fluids that were filtered to
remove bacteria remained infectious indicating there were infectious agents smaller than bacteria
2. Role of viruses in evolution: infect cells and influence their genetic makeup, 8% of the human
and 10-20% of bacterial genome contains viral sequences
3. Properties of viruses
a. Obligate intracellular parasites: cannot multiply unless they invade a host cell and instruct
its machinery to make and release new viruses since they lack enzymes for most
metabolic processes and machinery for protein synthesis
b. Infect: bacteria, algae, fungi, protozoa, plants, and animals, ubiquitous in nature and have
had a major impact on development of biological life
c. Classification and naming: based on hosts and diseases they cause, their structure and
chemical composition, and similarities in genetic makeup, the Internal Committee of the
Taxonomy of Viruses classifies and categorizes viruses
d. Size: 20nm to 1,000nm diameter, almost all require an electron microscope to visualize
e. Describing viruses: active/inactive instead of alive/dead since they are non-living and
unable to multiply independent from a host
f. Attachment to host cells: molecules on virus surfaces provides high specificity for host
cell attachment
g. Viral structure: capsid, nucleic acids, may have one or two enzymes, may have an
envelope, not a cell and do not independently fulfill the characteristics of life
i. Capsid: protein shell that surrounds nucleic acid
1. Nucleocapsid: capsid together with nucleic acids
2. Capsomeres: identical protein subunits that
spontaneously self-assemble into the finished capsid
3. Three types: helical (hollow cylinders), icosahedral
(3D, vary in number of capsomeres), and complex
(never enveloped)
ii. Envelope: covering external to the capsid that is usually a
modified piece of the host's cell membrane from budding
1. Naked viruses consist only of a nucleocapsid
2. Enveloped viruses can bud from the cell membrane,
nuclear envelope, or the endoplasmic reticulum, and
are pleomorphic due to the flexibility the envelope
confers
iii. Spikes: project from the nucleocapsid or the envelope and allow viruses to dock
onto host cells
iv. Virion: fully formed virus that is able to establish an infection in a host cell
v. Nucleic acids: DNA or RNA, not both
1. Only possess genes needed to invade host cells and redirect their activity
2. DNA: double- or single-stranded
3. RNA: double- or more often single-stranded
a. Positive-sense RNA: ready for immediate translation

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b. Negative-sense RNA: used as a template to make mRNA before
translation
c. Segmented: individual genes exist on separate pieces of RNA
d. Retroviruses: possess enzymes to create DNA from their RNA
4. Baltimore Classification System: describes how each type of virus makes
mRNA

TYPES OF VIRAL STRATEGY EXAMPLE
GENOMES
Class I dsDNA dsDNA → mRNA Herpes simplex
(herpes)
Class II ssDNA ssDNA → dsDNA → mRNA Parvovirus B19 (skin
rash)
Class III dsRNA dsRNA → mRNA Rotavirus
(gastroenteritis)
Class IV (+) (+) ssRNA → (-) ssRNA → mRNA Poliovirus (polio)
ssRNA
Class V (-) (-) ssRNA → mRNA Influenza virus
ssRNA (influenza)
Class VI ssRNA- ssRNA-RT → DNA/RNA → HIV (AIDS)
RT dsDNA → mRNA
Class VII dsDNA-RT → mRNA Hepatitis B virus
dsDNA-RT (Hepatitis B)

vi. Other components
1. Enzymes
a. Polymerases: synthesize DNA and RNA
b. Replicases: copy RNA
c. Reverse transcriptase: synthesizes DNA from RNA
d. Most viruses lack the genes for synthesis of metabolic enzymes
2. Taking components from host cell
a. Arenaviruses: take host ribosomes
b. Retroviruses: use host tRNA molecules
h. Multiplication cycles of animal viruses: dictate the way the virus is transmitted, what it
does to the host, immune responses, human measures to control viral infections, vary in
length
i. Adsorption
1. Virus encounters susceptible host cell
and adsorbs specifically to receptors on
the cell membrane that are usually
proteins the cell requires for normal
function
2. Glycoprotein spikes on the envelope or
on the capsid of a naked virus binds to
the receptors on the membrane
3. Host range: range of cells that a virus can infect

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a. Restricted: Hepatitis B, only infects liver cells of humans
b. Moderate: Poliovirus, infects intestinal and nerve cells of primates
c. Broad: rabies, infects various cells of mammals
d. Cells that lack compatible virus receptors are resistant to adsorption and
invasion by that virus
e. Tropisms: specificities of viruses for certain tissues
ii. Penetration and uncoating
1. Virus or its nucleic acid penetrates the host cell membrane
a. Endocytosis: entire virus is engulfed by the cell and enclosed in a
vacuole or vesicle, enzymes in the vacuole may break down the capsid,
freeing the nucleic acid
b. Fusion: viral envelope fuses with cell membrane, nucleocapsid enters
cell, nucleic acids uncoated

iii. Synthesis
1. Replication and protein production
a. DNA viruses: enter nucleus for replication and assembly
b. RNA viruses: enter cytoplasm for replication and assembly
c. Retroviruses: copies its RNA into DNA, complex life cycle
2. Example 1: +ssRNA viruses
a. +ssRNA serves as mRNA and is translated into viral proteins, especially
those useful for further viral replication
b. +ssRNA is replicated into -ssRNA, becoming the template for the
creation of many new +ssRNAs that are used as the viral genomes of
new viruses, additional +ssRNAs are synthesized and used for late-stage
mRNAs
c. Some viruses are equipped with the necessary enzymes for synthesis of
viral components, others utilize those of the host

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d. Proteins for the capsid, spikes, and viral enzymes are synthesized on the
host's ribosomes using its amino acids
3. Example 2: DNA viruses
a. Early phase
i. Viral DNA enters nucleus and genes are transcribed into mRNA
ii. mRNA moves into cytoplasm to be translated into viral
protein/enzymes needed to replicate the viral DNA
iii. Host cell's DNA polymerase is involved
b. Late phase
i. Parts of viral genome are transcribed and translated into proteins
required to form the capsid and other structures
ii. New viral genomes and capsids are assembled
iii. Mature viruses are released by budding or cell disintegration
iv. Assembly
1. Mature viruses are constructed from the growing pool of parts
2. Capsid is first laid down as an empty shell that will serve as the receptable
for the nucleic acid
3. Viral spikes are inserted into the host's cell membrane so they can be picked
up as the virus buds off with its envelope
v. Release
1. Nonenveloped and complex viruses: reach maturation in nucleus or
cytoplasm and are released when the cell lyses or ruptures
2. Enveloped viruses: liberated by budding from the membranes of the
cytoplasm, nucleus, endoplasmic reticulum, or vesicles
a. Nucleocapsid binds to the membrane, which will curve completely
around it and form a small pouch
b. The pouch will pinch off and release the virus with its envelope
3. The number of viruses released by infected cells varies and is controlled by:
the size of the virus and the health of the host cell
a. Poxvirus-infected cell: may release 3,000-4,000 virions
b. Poliovirus-infected cell: may release up to 100,000 virions
c. With large numbers of virions released by some infected cells, there is
potential for rapid viral proliferation as the released viruses encounter
susceptible cells

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4. Damage to host cell
a. Cytopathic effects (CPEs): virus-induced damage to the cell that alters the cell's
microscopic appearance
i. Types of CPEs
1. Gross changes in shape and size
2. Development of intracellular changes
3. Inclusion bodies: compacted masses of viruses or damaged cell organelles
in the nucleus and cytoplasm
4. Syncytia: fusion of multiple damaged host cells into single large cells
containing multiple nuclei
b. Accumulated damage from a viral infection kills most host cells
5. Persistent infections
a. Carrier relationship: some cells harbor the virus and are not immediately lysed, this can
last from a few weeks to the remainder of the host's life, and can remain latent in the
cytoplasm
b. Provirus: viral DNA becomes incorporated into the DNA of the host, measles virus in
brain cells occasionally causing progressive damage
c. Chronic latent state: latent viruses periodically become activated under the influence of
various stimuli, herpes simplex and herpes zoster viruses (chickenpox and shingles)
6. Viruses and cancer
a. Estimation that 20% of cancers are caused by oncoviruses
b. Transformation: effect of oncogenic (cancer-causing) viruses on host cells
c. Some viruses carry genes that directly cause cancers, other viruses produce proteins that
induce a loss of growth regulation, leading to cancer
d. Some retroviruses viral oncogenes incorporate into host cell DNA and produce proteins
that lead to uncontrolled cell growth, other retroviruses viral genes affect expression of
host oncogene leading to uncontrolled cell growth
e. DNA tumor viruses viral genes directly produce proteins that lead to uncontrolled cell
growth

f. Transformed cells demonstrate
i. Increased rate of growth
ii. Changes in their chromosomes
iii. Changes in cell surface molecules
iv. Capacity to divide indefinitely
g. Examples of mammalian oncoviruses capable of initiating tumors
i. Papillomaviruses: cervical cancer
ii. Herpesviruses: Burkitt's lymphoma

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iii. Hepatitis B virus: liver cancer
iv. HTLV-1: leukemia/lymphoma
7. Viruses infecting bacteria
a. Bacteriophage: virus that infects bacteria
i. Most contain double-stranded DNA, some contain RNA
ii. Each bacterial species is parasitized by various specific bacteriophages
iii. May cause the bacteria they infect to become more pathogenic to humans
iv. Virophage: recently discovered, virus that parasitizes other larger viruses that are
also within a host cell
v. T-Even Bacteriophage
1. Infect Escherichia coli
2. Structure: icosahedral capsid containing
DNA, central tube surrounded by a sheath,
collar, base plate, tail pins, and fibers
b. Temperate phage: undergo adsorption and penetration, the
viral genome will either continue with the lytic cycle or
become a prophage in the lysogenic cycle, do not undergo
replication or release immediately
i. Lytic cycle: adsorption → penetration/genetic material injected into cell →
duplication of phage components and replication of virus genetic material →
assembly of new virus → maturation → lysis of weakened cell → release of
viruses
ii. Lysogenic cycle: Viral DNA enters an inactive prophage state that is inserted into
the bacterial chromosome and copied during bacterial cell division
1. Lysogeny: a condition in which the host chromosome carries bacteriophage
DNA
2. Induction: prophage in a lysogenic cell becomes activated and progresses
directly into lytic cycle/viral replication
3. Lysogenic conversion: when a bacterium acquires new genes/traits from its
temperate phage, causing toxin and enzyme production the bacterium would
not otherwise be able to carry out
a. Corynebacterium diphtheriae: diphtheria toxin
b. Vibrio cholerae: cholera toxin
c. Clostridium botulinum: botulinum toxin

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8. Detection of viral growth in cell/tissue culture (in vitro)
a. Cells/tissue cultures are cultivated in sterile chambers with special media that contains
nutrients for the cells to survive, cells form a monolayer that supports viral
multiplication, allows for close inspection of culture for signs of infection
b. Viral growth can be detected by observing degeneration and lysis of infected cells
i. Plaques: where virus-infected cells have been destroyed, clear well-defined patches
in the cell sheet of tissue culture, visible manifestation of CPEs
9. Detection/counting of bacteriophages
a. Plaques: where virus-infected cells have been destroyed and released viruses radiate to
adjacent host cells, clear macroscopic space that corresponds to area of dead cells
10. Prions
a. Misfolded proteins, no nucleic acid
b. Deposited as long protein fibrils in the brain tissue of humans and animals
c. Creutzfeldt-Jakob disease (CJD): affects CNS, causes degeneration and death
i. Genetic mutation
ii. Sporadic CJD
iii. Acquired CJD (medical instruments, organ transplants, consuming infected meat)
d. Bovine spongiform encephalopathy (BSE): "mad cow disease," these prions can be
transmitted to humans
11. Satellite viruses: dependent on other viruses for replication
a. Adeno-associated virus (AAV): originally thought it could only replicate in cells infected
with adenovirus, but can also infect cells that are infected with other viruses
b. Delta agent: naked circle of RNA, expressed only in presence of hepatitis B virus,
worsens the severity of liver damage
12. Viroids: virus-like agents that parasitize plants
a. Smaller size than average virus
b. Naked strands of RNA, lack a capsid or other coating
c. Significant pathogens in economically important plants such as tomatoes, cucumbers and
potatoes
13. Treatment of animal viral infections
a. Antibiotics designed to treat bacterial infections have no effect on viruses
b. Difficult to find drugs that will affect viruses without damaging host cells
c. Almost all licensed antiviral drugs target a step of the viral life cycle
i. Integrase inhibitor class of HIV drugs: interrupts the ability of HIV genetic
information to incorporate into the host cell DNA
ii. Paxlovid for COVID-19: inhibits a packaging enzyme
d. Easier to develop vaccines to prevent viral diseases

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