FFP1L3 Introduction to Viruses and Viral Infections 2023 (PDF)

Summary

This document is an introduction to viruses and viral infections, specifically addressing viral morphology, replication, classification, common infections, and diagnosis. It covers various aspects of viral structure and function It also details how viral infections progress and are identified using laboratory and clinical methods.

Full Transcript

Leading the world
to better health
 RCSI Royal College of Surgeons in Ireland Coláiste Ríoga na Máinleá in
Éirinn

Session ID: FFP1ML3

Introduction to viruses and viral infections

Class Year 1

Course Undergraduate Medicine

Lecturer Dr. Muaaz Ather
Prof Manaf Al Qahtani

Date 9th October 2023
 LEARNING OUTCOMES

1. Discuss the basics of viral morphology
2. Explain the basics of viral replication
3. Classify viruses and give some examples
4. Name some common viral infections
5. Briefly discuss what happens when a healthy host
acquires a viral infection
6. Summarise how viral infections are diagnosed in
the laboratory and clinically
 LEARNING OUTCOME

1. Discuss the basics of viral morphology
BASICS - WHAT ARE VIRUSES?

Infectious agents of small size

Contain only one type of nucleic acid:
DNA or RNA, but never both

Are totally dependent on a host cell for
replication

– Rely on the cellular processes of their
hosts to reproduce themselves

Note: Strict intracellular parasites
 BACTERIA VS. VIRUSES
WHAT’S THE DIFFERENCE?
 HOW CAN SOMETHING SO SMALL CAUSE
SO MUCH TROUBLE?

Source: ebug.eu
 VIRUSES: DEAD OR ALIVE?

A. Alive
B. Dead
C. Not sure
 VIRUSES: DEAD OR ALIVE?

https://microbiologysociety.org/publication/past-issues/what-is-life/article/are-vir
uses-alive-what-is-life.html
VIRUSES ARE A BIT LIKE PRESENTS

NUCLEIC ACID IN GIFT WRAPPING
 VIRION COMPONENTS

Capsid: proteinaceous
coat made of
Nucleic Acid capsomers

Nucleic acid: DNA or
RNA (never both)
O
R
Nucleic acid + Capsid =
Nucleocapsid

Envelope: not always
present
 CAPSID OVERVIEW

Protein shell composed of CAPSOMERS
surrounding the genome.

Protective shield

Viruses can have capsids with different shapes and
symmetries
 CAPSID: MORPHOLOGY

Icosahedral
20 faces each an equilateral triangle

Helical

Complex
 BIOLOGICAL ROLE OF THE CAPSID

Introduces viral genome into host cells
– Capsid proteins interact with host cell receptors

Contains antigens
– Stimulate the host immune system

Resistant to
– Drying / Heat / Detergents / Acids / Proteases
 LEARNING OUTCOME

3. Classify viruses and give some examples

4. Name some common viral infections
 VIRAL CLASSIFICATION

Technically not living entities, therefore common rules
that apply to living cellular organisms do not apply

Classified according to

- Phenotypic characteristics e.g. morphology ?enveloped
or not
- Genotypic characteristics e.g. nucleic acid type
- Mechanism of replication
- The hosts they infect
- Lastly... the diseases they cause!
 THE ENVELOPE

Lipid bilayer that surrounds the capsid composed of
phospholipids and glycoprotein

Viruses without an envelope are called ‘non
enveloped’ viruses!
 Derived from host cell
membranes
‘budding’.

Also contains viral
proteins = attach the
virus to receptors on
susceptible host cells
 PROPERTIES OF ENVELOPED VIRUSES

Confers a distinctive serological characteristic by which some
viruses can be diagnosed (antigen)
Surface polypeptides can bind specific receptor sites on the host
cell
Viral antigens stimulate host immune responses

Envelope is sensitive to
Drying / Heat / Detergents / Acid

Consequences
Must stay wet during transmission / Cannot survive in the
gastrointestinal tract / Do not need to kill cells in order to spread
Adapted from Murray, P.R. Rosenthal K.S., Pfaller, M.A. (2005) Medical Microbiology, 5th edition
 GENETICS

Circular or linear nucleic acid
 GENETIC – BROAD CLASSIFICATION

DNA or RNA
(never both)

Single-stranded
or double-
stranded

Sense
 VIRAL ACQUISITION

Vectors – animal or insect
Rabies, dengue
Inhalation
Influenza, coronaviruses, rhinovirus
Faecal oral
Rotavirus, norovirus, hepatitis A&E
Blood borne
Hepatitis B & C, HIV
Sexual
Hepatitis B & C, HIV
Congenital
Rubella, CMV, Hepatitis B & C, HIV
SOME EXAMPLES OF COMMON VIRUSES

Nucleic acid Family Virus Disease

Herpes Herpes simplex Cold sores
Varicella zoster Chickenpox
DNA Shingles
Epstein-Barr Infectious
mononucleosis

Hepadna Hepatitis B Hepatitis

Orthomyxo Influenza Flu

RNA Picorna Polio
Hepatitis A
Polio
Hepatitis
Retro HIV AIDS
 LEARNING OUTCOME

2. Explain the basics of viral replication
 VIRAL REPLICATION

Viruses only reproduce within an appropriate cell

Do not possess the necessary machinery
themselves to replicate

Must invade cell (plant, animal, human) & utilise
cell’s reproduction system to make copies of itself
 VIRAL REPLICATION

1. Attachment/Fusion
2. Penetration/Entry
3. Uncoating
4. Synthesis/Replication
5. Assembly
6. Release

https://courses.lumenlearning.com/microbiology/chapter/the-viral-life-cycle/
 ATTACHMENT AND PENETRATION

Viral attachment
– Capsid
protein/glycoprotein to
host cell receptor

Virus internalised
into cell
– Endocytosis
– Envelope fusion with
the plasma membrane
 UNCOATING

Need to make the genome available
Viral nucleic acid into cytoplasm/ nucleus
 SYNTHESIS & ASSEMBLY

Many strategies for
synthesis of viral
nucleic acid & protein
– Nucleic acid can be
made in nucleus or
cytoplasm
– Protein synthesis
always in cytoplasm
ASSEMBLY & RELEASE OF NEW VIRUS FROM CELL

Viral components must assemble into complete viruses to go
from one host cell to another

Non-enveloped:
lysis or exocytosis
Enveloped: budding
 LEARNING OUTCOME

5. Briefly discuss what happens when a healthy
host acquires a viral infection
 VIRAL PATHOGENESIS

Interaction with target tissue
– Can organism establish a local infection/a systemic infection i.e.
a viraemia

Cytopathological activity
– What effect does it have on host tissue?

Immune response
– Can virus escape immune responses?

Immunopathology
– What type of immune response does the virus initiate?
 Effects of
Viruses on Cells
LATENT
DEAT TRANSFORMA
INFECTI
H TION
ON
Cell becomes
malignant or May
Cytopathog subsequent
enic effect pre-
malignant ly
(CPE) seen reactivate
on cell e.g.
papillomavir e.g. herpes
us viruses
 VIRAL SPREAD

1. Intracellular (cell to cell)
Intercellular bridges e.g. HSV
2. Extracellular
Virus is released from infected cells and spreads to other cells
locally and distally (haematogenous / lymphatic cells) e.g. Influenza
3. Neural
Peripheral nerves to CNS e.g. Rabies, HSV
4. Nuclear
Viral genome incorporated into host genome – passed onto
succeeding cell generations e.g. HIV
 OUTCOME OF VIRAL INFECTIONS

Many viral infections are mild & self limiting
– e.g. Coronaviruses causing common cold
May be severe in vulnerable patients
– e.g. Cytomegalovirus in transplant patients
May be silent
– e.g. Hepatitis C
May reoccur intermittently
– e.g. Herpes simplex virus (cold sores)
May be fatal
– e.g. Rabies

N.B. Infections may be acute or chronic
 LEARNING OUTCOME

6. Summarise how viral infections are diagnosed in
the laboratory and clinically
 CLINICAL DIAGNOSIS

‘It’s probably “just” viral…’ – What I imagine the doctor
said to the first person who presented with COVID-19
symptoms
Often very difficult to distinguish from bacterial infection
But sometimes pretty obvious …

Images from: www.dermnetnz.org
 LABORATORY DIAGNOSIS OF VIRAL INFECTION

Qualitative:

- Detect and identify.
- Is it there
- What is it?
- Is it viable?

Quantitative:
- How much of it is there?
 Detect and/or Identify
the Virus

Molecular Serological Microscopy

Visualize
Detect Virus Detect virus (EM)
Detect Viral
Specific Antibody to or effects of
Antigen
DNA/RNA the Virus
(LM)

EM – Electron
Microscopy
LM – Light Microscopy
 MOLECULAR E.G. PCR & RT-PCR

Fast - (Relatively – many serological tests are faster)
Usually very sensitive
Quantification
Used for
– rapid diagnosis of viral infection
– guide treatment e.g. HIV viral load
– detection of resistance to antiviral drugs
 MICROSCOPY

ImmunoFluorescence (Microscope)
– Rapid detection of viral antigens in specimen
using commercially produced antibodies 🔬
Light Microscope - Inclusion Bodies
– Virus-induced masses within cytoplasm of
cells
– Can be pathognomonic without need for
culture (negri bodies in hippocampal cells in
rabies)

Electron Microscope (EM)
– Specialized
– Can give quick answers to clinical questions
 VIRAL CULTURE

Viruses only replicate within living cells so LIVING
cells needed for culture
Living human or animal cells are grown in artificial
culture
Examine the cells for the effect of viral growth
– ‘Cytopathological effect’
– Haemadsorption (cells acquire the ability to stick to
mammalian red blood cells)
Confirm the ID of the virus by immunofluorescence /
neutralization / haemadsorption inhibition
 DISADVANTAGES OF VIRAL CULTURE

 Slow - up to 4 weeks required for result

🗓😴
 Often very poor sensitivity, sensitivity
depends to a large extent on the
condition of the specimen
 Susceptible to bacterial contamination
 Susceptible to toxic substances which
may be present in the specimen.
 Many viruses will not grow in cell
culture e.g. Hepatitis B, diarrhoeal
viruses, parvovirus, papillomavirus.
 MAJOR ADVANTAGE OF CELL CULTURE

Can determine viability!

If cytopathological effect (CPE) is observed - virus is viable
 SEROLOGY

Testing for viral antigen
e.g. HBsAg (Hepatitis B surface antigen)

AND/OR

Testing for the presence of specific antibodies
produced against viral antigens
– Ideally wo samples required (paired sera): one at the onset of
illness & a second after 7-14 days
– Rise in antibodies confirms infection
 SUMMARY

Viruses are composed of nucleic acid, a protein coat
(capsid) and occasionally an envelope
Totally dependent on host cell for replication
Are classified according to shape, nucleic acid, disease,
host and mechanism of replication
Cause a diverse range of infections
Diagnosis can be made clinically
Laboratory diagnosis may be qualitative or quantitative
and incorporates a number of techniques including
molecular, serological, microscopy and culture
Thank you