General Properties of Viruses Lecture 6 PDF

Summary

These lecture notes provide an overview of the general properties of viruses, including their unique structure, composition, and methods of infection, as well as their response to medical or environmental factors. Key characteristics, mode of transmission, and diseases are covered.

Full Transcript

GENERAL PROPERTIES OF VIRUSES
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 General Characteristics of viruses
✓ They are unique, smallest heterogeneous infectious agents with
sizes ranging from 20-300nm in general

✓ They are non-cellular structures that have a nucleic acid core
containing DNA or RNA

✓ Viruses contain a protein coat called the capsid (for protection,
attachment, and entry)

✓ Viruses are obligate intracellular parasites; grow only in
living cells

✓ They lack ribosomes and enzymes needed for metabolism

✓ They use the raw materials and enzymes of the host cell to be
able to reproduce through processes of complex biosynthesis 2
General characteristics

✓ They are not susceptible to antibiotics (antibiotics target
cellular structures eg., cell wall which viruses lack, viruses do not
replicate on their own and do not perform any metabolic activities
on their own)

✓ Viruses are susceptible to antimicrobial chemical agents e.g.
chlorine, alcohol, formalin, etc

✓ Viruses can infect unicellular organisms such as
mycoplasmas, bacteria, and algae

✓ They can also infect higher plants and animals including insects.
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General characteristics

✓ Major viral groups are
- Plant viruses
- Insect viruses
- Viruses of bacteria (bacteriophage)
- Viruses of vertebrates (animal viruses)

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Virus structure

✓ A virion which is an infectious particle has at least two
components:
- Molecules of either DNA or RNA ( ie. the genome)
- An outer symmetrical protein shell known as the capsid

✓ The nucleic acid and the capsid is referred to as the
nucleocapsid

✓ Some viruses apart from the nucleocapsid may have an extra
membrane called the envelope

✓ Viruses made up of nucleocapsid alone are referred to as naked
viruses ( eg., Human Papillomavirus, Poliovirus)

✓ Viruses with the envelope are called enveloped viruses (eg.,
SARS-COV-2, Ebola, HIV, Hepatitis C) 5
 Virus Structure

Virus strcuture Bacterial structure

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Chemical composition of viruses
✓ Viral nucleic acid
✓ Viral protein
- Capsid
- Enzymes
✓ Viral lipids
✓ Viral glycoproteins

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Nucleic Acid
✓ The viral nucleic acid constitutes the genome (complete set of
genetic material) which carries the genetic information
necessary for replication

✓ The viral nucleic acid may be
- Single or double-stranded
- Circular or linear
- Segmented or non-segmented
- Positive or negative polarity

✓ Each family of viruses possesses a nucleic acid characteristic of
that group

✓ We can analyze the sequence or composition of nucleotides by
using restriction nucleases
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Nucleic acid

✓ All the animal RNA viruses are single-stranded (eg., poliovirus,
rhinovirus, SARS-CoV, MERS-CoV, and SARS-CoV-2 (COVID-19)
except the REO (rotavirus) viruses.

✓ All the animal DNA viruses are double-stranded (Eg. Human
papillomavirus, herpes simplex virus, Poxviridae (variola virus))
except the PARVOVIRUSES ( eg., hepatitis B virus (HBV)

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Viral Protein - Capsid

✓ The capsid is composed of individual polypeptides – coded by the
virus

✓ The number and appearance of capsomers (protein subunits of
the capsid) are characteristic of a virus and important in its
identification

The capsid performs four functions
✓ It protects the nucleic acid from damage in the external
environment
✓ It facilitates attachment to susceptible cells
✓ It confers structural symmetry on the virion
✓ It confers antigenicity (the ability of the virus/antigen to
specifically bind to components of the immune system))
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✓ Viral capsids (coats) are
made of individual protein
subunits

✓ Individual subunits are
called capsomeres

CAPSOMERES

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Viral protein-Enzymes
✓ Polymerase
✓ Integrase
✓ Reverse transcriptase

Viral Lipids-Envelope
✓ The lipids are part of the envelope and are coded for by the host
cell

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Viral Glycoprotein
✓ Viral envelope contains glycoproteins in the form of projections on
the envelope
- Neuraminidase (cleaves sialic acid from glycoproteins to release
new viral particles) and haemagglutinin (facilitate initial
attachment of virus to host cells by binding to sialic acid)
- They are virus coded

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Viral Envelope
✓ The viral envelope is acquired
by the virus during the final
stages of replication

✓ The envelope consists of a
bilayer membrane containing
glycoprotein and lipid

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Viral Envelope

✓ Functions are similar to capsid in naked virions:
- It protects nucleic acid from damage
- It facilitates attachment
- It confers structural symmetry
- It confers antigenicity

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General Morphology of the Virion

✓ Compared to most micro-organisms the virus particle is the
smallest
- Measured in nanometers (10-9 meters = nm)

✓ Viruses range in size from about 20 to 25nm for parvoviruses and
picornaviruses to 200-300nm for poxviruses

✓ Most plant viruses are rod-shaped whilst bacterial viruses show a
more elaborate, tailed structure

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Virion Morphology
✓ The shapes of most animal viruses are frequently referred to in
colloquial terms e.g. spheres, rods, bullet or brick-shaped.

✓ In reality they are complex structures of precise geometric
symmetry

✓ The shape of the virus particle is determined by the
arrangements of the repeating subunit that form the capsid

✓ Precise geometric symmetries are
- Icosahedron
- Helix (worm-like or coiled configuration)
- Complex (irregular configuration)

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Icosahedron
✓ The shape of a regular
icosahedron has 20 faces each
of which is an equilateral
triangle.

✓ The viruses have their nucleic
acid packaged inside the
capsid
- Capsid can be naked or
enveloped

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Helical Viruses

✓ In many RNA viruses, the viral
nucleic acid is closely
associated with the capsid
forming a coil-shaped, helical
structure

✓ A viral envelope always
surrounds helical animal
viruses

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causes influenza 22
Complex viruses

✓ Viruses that do not fit into any
of the two symmetries due to
the complexity of the virion are
described as complex. Eg.,
HIV, Poxvirus

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Virion Morphology

✓ The virus can be grouped into five categories based on their
morphology and nucleocapsid symmetry
- Naked icosahedral viruses
- Enveloped icosahedral viruses
- Naked helical viruses
- Enveloped helical viruses
- Complex viruses

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Reaction to chemical and physical agents

Heat and cold

✓ Different viruses show variable stability to heat and cold

✓ Icosahedral naked viruses tend to be stable at 37°C losing little
infectivity after several hours

✓ Enveloped viruses are much more heat-labile; rapidly dropping in
titre at 37°C

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Effect of heat and cold on viruses

✓ Viral infectivity is generally destroyed by heating at 50°-
60°C for 30min

✓ Viruses can be preserved by storage at sub-zero temperatures
- Some may withstand lyophilization and can be preserved in the
dry state at 4°C or even at RT

✓ Enveloped viruses tend to lose infectivity after prolonged
storage even at -90°C and are very sensitive to freezing
and thawing

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Stabilization of viruses by salts

✓ Many viruses can be stabilized by salts in concentration of mol/L
- Some viruses are not inactivated in the presence of these salts
- Mechanisms of this protection are unknown

Eg., MgCl2 stabilizes Picornaviruses
- MgSO4 stabilizes Myxoviruses
- Na2SO4 stabilizes herpes viruses

✓ The stability of viruses is important in the preparation of vaccines
✓ Salts are added to vaccines to stabilize the preparation

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Stabilization of viruses by salts-pH
✓ Viruses are usually stable between pH values of 5 and 9.

✓ Some viruses are resistant to acidic conditions e.g.
enteroviruses

✓ Extreme alkaline conditions destroy all viruses

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Photodynamic inactivation and reaction

✓ Viruses can be penetrated to varying degrees by vital dyes e.g.
neutral red, toluidine blue, and proflavine

✓ Dyes bind to nucleic acid making it susceptible to inactivation by
visible light

✓ Ultraviolet, x-ray, and high-energy particles inactivate viruses
- They are used in sterilization of plastics, benches
- Dose varies for different viruses

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Ether and Detergents

✓ Ether, like other lipid solvents acts on the lipid in the viral envelope

✓ Non-ionic detergents solubilize lipid constituents of viral membrane

✓ Anionic detergents solubilize viral envelopes and disrupt capsids
into separate polypeptides

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Formaldehyde

✓ Formaldehyde destroys viral infectivity by reacting with nucleic
acid

✓ Single-stranded genome is much more readily inactivated than
double-stranded genome.

✓ Frequently used in the production of inactivated viral vaccines

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Antibiotics & antimicrobial agents

✓ Antibiotics and sulphonamides have no effect on viruses

✓ Antimicrobial agents e.g. chlorine at high concentrations are
required to kill viruses

✓ Alcohols such as isopropanol and ethanol in their pure forms are
relatively ineffective against certain viruses e.g. picornaviruses

NB: 50-70% ethanol more effective

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Mode of transmission
✓ The route of transmission depends on the source and the body
route to the target tissue.

✓ Naked viruses can withstand drying, the effects of detergents, and
extreme pH and temperature.
- The respiratory and fecal-oral routes generally transmit them.
- They can also be acquired from contaminated objects

✓ Enveloped viruses are comparatively fragile
- They require an intact envelope for infectivity
NB: They must remain wet and are spread through:
- respiratory droplets, blood, mucus, saliva, or semen
- injection
- Organ transplantation

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Susceptibility to transmission

✓ Infants, children, and elderly are susceptible to different viruses

✓ The competence of a person’s immune response and his/her
immune history determine how quickly and effectively the
infection is resolved and can also determine the severity of
symptoms

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 Some viruses of medical importance

Flaviviruses (yellow fever virus)
Ebola
Measles
Rubella
Polio
Mumps
SARS COV-2
MERS COV
Varicella Zoster Virus

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Varicella Zoster Virus (VZV)
Virus Characteristics
It belongs to the family of
Herpesvirus (human herpesvirus
3)
It is a double-stranded DNA with
an approximate size of 150-200 nm
in diameter
It has a lipid envelope derived from
the host cell membrane

Structure
It has an Icosahedral capsid
enclosing the viral DNA
The Tegument contains viral
proteins
The Envelope Contains
glycoproteins essential for virus
entry into the host cell

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Diseases Caused
Primary Infection: Varicella (chickenpox), characterized by a
vesicular rash, fever, and malaise

Reactivation
Herpes zoster (shingles), characterized by a painful, unilateral
vesicular rash along a dermatome (an area of skin that is mainly
supplied by a single spinal nerve)

Mode of Attachment
Glycoproteins on the viral envelope interact with host cell surface
receptors, facilitating viral entry

Fusion with host cell membrane allows entry of the viral capsid
into the host cell cytoplasm

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Diagnosis
Clinical Presentation
✓ Characteristic rash and symptoms

Laboratory Tests
PCR-Detection of VZV DNA in lesions, blood, or cerebrospinal fluid
DFA (Direct Fluorescent Antibody)-Detection of VZV antigens in
skin lesions
Serology-Detection of VZV-specific IgM and IgG antibodies

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Control and Treatment

Vaccination
Varicella Vaccine
✓ Live attenuated vaccine for prevention of chickenpox
✓ Zoster Vaccine-Recombinant vaccine for prevention of shingles in
older adults
Antiviral Medications
Acyclovir, Valacyclovir, Famciclovir: Used to treat and reduce the
severity of both chickenpox and shingles

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Influenza virus

✓ Causes acute respiratory infection

Transmission
-Spreads easily through coughs or sneezes

Symptoms
✓ Fever, cough, sore throat, body aches, fatigue, headache, muscle
and joint pain, severe malaise, runny nose

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High-Risk Groups
✓ Pregnant women
✓ Children under 5 years
✓ Older adults
✓ Individuals with chronic conditions or immunosuppression
✓ Health and care workers

Transmission
✓ Droplets from coughs/sneezes
✓ contaminated hands

Diagnosis
✓ Clinical diagnosis is based on symptoms

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✓ Laboratory Tests
- PCR (high sensitivity)
- Rapid diagnostic tests (lower sensitivity)

- Treatment
- Rest, take enough fluids, and symptom relief.
- Antivirals-For high-risk individuals or severe cases.

Prevention
✓ Cover mouth/nose when coughing
✓ wash hands regularly

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 SARS-COV-2
Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is
the causative agent of COVID-19

SARS-CoV-2 is an enveloped, positive-sense, single-stranded RNA
virus of the genus Betacoronavirus

Other members of the genus include MERS-COV, SARS-COV, and
human coronavirus (HCoV)-OC43, HCoV-HKU1.

The coronavirus virion is made up of the nucleocapsid (N),
membrane (M), envelope (E) and spike (S) proteins, which are
structural proteins.

The SARS-COV-2 attaches itself to the host and enters the host by
the help of the S glycoprotein

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Mode of Transmission

Direct Transmission
✓ Respiratory droplets from coughs, sneezes, and talking

Indirect Transmission
✓ Contact with contaminated surfaces followed by touching the face

Aerosol Transmission
✓ Small particles that remain airborne for longer periods

Mode of Attachment
✓ Receptor Binding- S protein binds to the ACE2 receptor on host
cells
✓ Fusion-Viral membrane fuses with the host cell membrane,
allowing entry

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Target Tissue

✓ Primary Target
-Respiratory tract, particularly the alveolar epithelial cells

-Other Targets-Gastrointestinal tract, endothelial cells

Mechanism of Infection
✓ Entry-binding of S protein to ACE2 and fusion with the host cell
membrane
✓ Replication-Viral RNA is released, translated, and replicated in
the host cell cytoplasm
✓ Assembly-New viral particles are assembled in the host cell
✓ Release-Virions are released from the host cell, often causing cell
damage and inflammation
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Prevention Vaccination

✓ mRNA vaccines (e.g., Pfizer-BioNTech, Moderna)
✓ viral vector vaccines (e.g., AstraZeneca, Johnson & Johnson)
✓ inactivated virus vaccines (e.g., Sinopharm, Sinovac)

Non-Pharmaceutical Interventions
✓ Wearing nose mask, hand hygiene, physical distancing, ventilation
of indoor spaces

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 HOMEWORK TWO
Discuss the key characteristics, mode of transmission, diseases they
cause, pathogenesis, and prevention of the following:
Polio virus
HIV

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