Introduction to Virology PDF

Summary

This document provides an introduction to virology, covering viral components, viral life cycles, classification, laboratory detection methods, and immune responses to viruses. The material appears to be course notes or lecture materials.

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Introduction to
Virology

Course Instructional Objectives
MCRO 2.1 The student will identify and explain the components of a typically virus,
including the five basic types of viral symmetry and symmetry are seen in ‘classic’ virus
particles.
MCRO 2.2. The student will describe the receptors and VAP found on a naked and
enveloped virus & virus family, including their function.
MCRO 2.3. The student will explain the viral life cycle including the role of T-cell
activation and phagocytosis of the human immune system.
MCRO 2.4 The student will identify the classification of DNA vs RNA viruses, include
their common name and family name.
MCRO 2.5. The student will understand the basics of serology, viral culture, cytology and
the molecular techniques used to identify virus in the lab.

Khan Academy: Viral structure & classification
MCRO 2.1

Components of a Virus
Viral
Component

Role in Viral Life Cycle

Example

Encodes all the information necessary to
produce new progeny virions

DNA or RNA

Protein “shell” that contains/packages viral
nucleic acid, protecting it between infections;
may contain VAP

Icosahedral, helical, or (rarely)
complex

Structural
proteins

Proteins which form the capsid, package the
genome, and/or are attachment proteins

Matrix, nucleocapsid, VP1-VP4
(reovirus), hexon and fiber
(adenovirus), gp41/120 (HIV),
HA (influenza), F (measles)

Non-structural
proteins

Proteins which are required for replication, for Polymerase, helicase, protease
assembly, or which facilitate disease
(flu N), transcription factors,
progression
immunomodulatory factors

Envelope

Lipid bilayer which is an anchoring surface
for viral attachment proteins, facilitates
penetration of the host cell membrane

Nucleic acid
Capsid

Red strings
Small inner green and
blue spheres
Capsid + outer green
stalks and large blue
spheres

Black beads

Orange coat

MCRO 2.1

Viral Capsids and Symmetry
• Most viruses have either
icosahedral or helical capsid
structure with or without an
envelope
• The others have:
– Complex symmetry
– No symmetry
• Capsid or nucleocapsid =
procapsid AND viral genome

http://pathmicro.med.sc.edu/mhunt/intro-vir.htm

MCRO 2.1

“Classic” Viral Particles
Adenovirus

Coronavirus
Figure 47-1 – Medical Microbiology, 9th ed. 2021

Rhabdovirus (rabies)

Figure 42-1 – Medical Microbiology, 9th ed. 2021

Poxvirus

Murray, Rosenthal, and Pfaller – Medical
Microbiology, Figure 50-1, 9th ed. 2021

Filovirus (Ebolavirus)
Figure 50-4 – Medical Microbiology, 9th ed. 2021

Figure 44-1 – Medical Microbiology, 9th ed. 2021

MCRO 2.1

More Images of Icosahedral Capsids

The construction of a spherically (icosahedral) shaped virus
similarly involves the packing together of many identical
subunits, but, in this case, the subunits are placed on the
surface of a geometric solid called an icosahedron. Because
the icosahedron belongs to the symmetry group that
crystallographers refer to as cubic (not the cube shape),
spherically shaped viruses are said to have cubic symmetry,
generally known as icosahedral capsid.

Read: Sherris & Ryan Chapter 6
Citation: Chapter 6 Viruses—Basic Concepts, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922934 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.1

Overview: Chapter 6
§ Viruses are the smallest form of replicating intracellular microorganisms that are comprised of sets
of genes either DNA (DNA viruses) or RNA (RNA viruses) packaged in a protein coat, capsid (naked
capsid viruses) or in a nucleocapsid/capsid, and an outer lipid bilayer envelope (enveloped viruses).
§ Viruses have spikes on their outer surface that bind to the receptors on host cells and antibodies
generated against the spikes neutralize the virus.
§ Viruses are dependent upon host structural components and metabolic functions.
§ DNA viruses replicate in the nucleus by using host RNA polymerase for transcription and either host
or viral DNA polymerase for replication (exception are poxviruses that replicate in the cytoplasm).
§ RNA viruses replicate in the cytoplasm using its own viral RNA-dependent RNA polymerase for both
transcription and replication (exception are influenza viruses and retroviruses that replicate in the
nucleus).
§ Naked capsid viruses are assembled inside the cell and released upon cell death, whereas
enveloped viruses acquire lipid bilayer membrane mainly from plasma membrane and in some
cases from nuclear or cytoplasmic membranes.

Overview: Chapter 6
§ Viral-infected cells may result in cell death and tissue damage (pathology) generally
seen in acute infections
§ A viral infection can persist in hosts (humans) causing a chronic or latent infection with
little or no pathologic changes in target cells or tissues.
§ Since most viruses use their own enzymes (RNA or DNA polymerases) which could be a
target for antivirals, they are prone to genetic changes due to lack of proofreading ability
of these enzymes.
§ The major genetic changes that viruses undergo are mutation and recombination that
allow viruses to escape the immune response and cause damage or persist in the host.
§ During viral latency, viral genome persists in host and may not be eliminated by antiviral
drugs.
§ It is difficult to develop strategies to eliminate latent viral infections by antiviral drugs.

Naked vs Enveloped Viruses

• The basic structure of all viruses places the nucleic acid genome (DNA or RNA) on the inside of a protein
shell called a capsid; these viruses have a defined external capsid and are referred to as naked capsid
viruses.
• The genomes of enveloped viruses form a protein complex and a structure called a nucleocapsid, which is
often surrounded by a matrix protein that serves as a bridge between the nucleocapsid and the inside of
the viral membrane or envelope
Read : Sherris & Ryan Chapter 6
Citation: Chapter 6 Viruses—Basic Concepts, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922934 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.2

Enveloped Viruses

The viral envelope lipid layer membrane contains
virus-encoded glycoproteins
called “spikes” or “peplomers” or “viral envelope
proteins.”
§ Some enveloped viruses also have capsids
between nucleocapsid and matrix protein.
§ Protein or glycoprotein structures
called spikes, which often protrude from the surface
of virus particles, are involved in the initial contact
with receptor on host cells
Read : Sherris & Ryan Chapter 6
Citation: Chapter 6 Viruses—Basic Concepts, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922934 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.2

Viruses and Receptors
• Entry of virus mediated by binding of viral attachment
protein or VAP to specific receptor on host cell
– VAP generally a protein
– Host receptor can be protein or carbohydrate

• Location of VAP
– Naked viruses – VAP is part of capsid structure
– Enveloped viruses – VAP is inserted into viral envelope

• Entry may require interactions between a 2nd set of
viral and host molecules. Provides:
– Increased affinity
– Increased specificity

• Second host molecule = co-receptor
Herpes simplex virus and parvovirus B19 –
see notes section for relevant virology characteristics

MCRO 2.2

Viruses and Receptors
FIGURE LEGEND – Herpes simplex virus (HSV)
contains on its surface five glycoproteins that
are used for its entry into host cells, gB, gC, gD,
gH and gL. gB and gC mediate the initial
attachment of virus particles to heparansulphate moieties on host cell-surface
proteoglycans. gB binding to paired
immunoglobulin-like type 2 receptor- (PILR)
and gD binding to herpesvirus entry mediator
(HVEM), nectin-1, nectin-2 or 3-Osulphotransferase-modified heparan sulphate
trigger membrane fusion, which is mediated
by gB and the gH–gL heterodimer, and release
of the viral nucleocapsid into the host-cell
cytoplasm. Viral-gene transcription occurs
following the release of viral DNA into the cell
nucleus.
http://www.nature.com/nri/journal/v8/n11/full/nri2434.html

MCRO 2.2

Viruses and Receptors

FIGURE LEGEND – A model for parvovirus B19 binding and entry into primary human erythroid cells. Mature
human RBCs, which express high levels of P antigen receptor, allow virus binding but not viral entry because
they lack the α5β1 integrin coreceptor (A), whereas erythroid progenitor cells, which express both P antigen
receptor and α5β1 integrin coreceptor, are permissive for parvovirus B19 entry (B).

MCRO 2.2

http://www.bloodjournal.org/content/102/12/3927?sso-checked=true

Classification Basics

The International Committee for Taxonomy of Viruses (ICTV) considered
various properties, including virions, genome, proteins, envelope, replication,
and physical and biologic properties.
§ Virus families are designated with the suffix, -viridae (as in Herpesviridae)
§ Virus subfamilies with suffix -virinae (Herpesvirinae)
§ Virus genera with suffix -virus (Herpesvirus)
§ Virus species designated by a virus type (herpes simplex virus 1).

MCRO 2.2

VAP and Cell Receptor Pairs
Virus

Family

Structural Characteristics

VAP

Receptor

Cell tropism

HIV-1

Retroviridae

ssRNA, positive sense,
enveloped

gp120

CD4

T cells, macs

EBV

Herpesviridae

dsDNA, icosahedral, enveloped

gp350,
gp220

CD21 (CR2)

B cells

Rabies

Rhabdoviridae

ssRNA, negative sense,
enveloped

G protein

Acetylcholine
receptor

Neurons and
muscle

Influenza

Orthomyxoviridae

ssRNA, negative sense,
segmented, enveloped

HA

Sialic acid

Respiratory
epithelial cells

Rhinovirus

Picornaviridae

ssRNA, positive sense,
icosahedral, non-enveloped

VP1,2,3
complex

ICAM-1

Epithelial cells

SARS-CoV-1 and
SARS-CoV-2

Coronaviridae

ssRNA, positive sense,
enveloped

Spike (E2)
protein

ACE2 (and other
proteins)

Many different cell
types

Adenovirus

Adenoviridae

dsDNA, icosahedral, nonenveloped

Fiber protein

CAR

Many different cell
types

Parvovirus B19

Parvoviridae

ssDNA, icosahedral, nonenveloped

VP1,2

Erythrocyte P Ag
(globoside)

Erythroid precursor
cells

MCRO 2.2 & 2.4

Viral Life Cycle

Khan Academy: Viral Replication
MCRO 2.3

Reminder: Transcription vs Translation

MCRO 2.3

Reminder:
Transcription vs
Translation

MCRO 2.3

Entry by Direct Fusion
Entry by direct fusion:
§ Some enveloped viruses enter cells by direct fusion
mechanism.
§ Viral envelope proteins (spikes) bind to the
receptors on the host cell followed by fusion of the
viral envelope with the plasma membrane of the
host cells, which is promoted by one of the viral
envelope spikes (F protein of RSV and Gp41 of
HIV).
§ After fusion, the nucleocapsid complex is released
in the cytoplasm.
§ This mode of virus entry is seen in enveloped
viruses such as paramyxoviruses, herpesviruses,
and some retroviruses (HIV).
Read : Sherris & Ryan Chapter 6
Citation: Chapter 6 Viruses—Basic Concepts, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922934 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.3

Viral Life Cycle/Replication

Read : Sherris & Ryan Chapter 6
Citation: Chapter 6 Viruses—Basic Concepts, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922934 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.3

Viral Life Cycle/Replication
Viral Life Cell includes:
§ Attachment
§ Penetration
§ Uncoating
§ Synthetic phase (transcription, translation, replication
§ Assembly
§ Release

Read : Sherris & Ryan Chapter 6

MCRO 2.3

Viral Life Cycle:
Viral
Release/Budding

Viral release by budding.
§ Human enveloped viruses acquire lipid bilayer membrane by budding generally from the plasma membrane.
§ Viral spikes are expressed on the cell surface followed by synthesis of matrix protein that associates near the
plasma membrane where viral spikes are present.
§ The matrix protein attracts the assembled nucleocapsid (genome + nucleoprotein) near the plasma membrane
expressing viral spikes followed by envelope membrane wrapping and release of the virus particle
Read : Sherris & Ryan Chapter 6
Citation: Chapter 6 Viruses—Basic Concepts, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922934 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.3

Classification of DNA Viruses
STUDY AID!
DNA viruses are HHAPPPPY!
• H = Hepadnaviridae
• H = Herpesviridae
• A = Adenoviridae
• P = Parvoviridae
• P = Poxviridae
• P = Papillomaviridae
• Py = Polyomaviridae

STUDY AID!
All DNA viruses have
double-stranded genomes
EXCEPT Parvoviridae.

http://pathmicro.med.sc.edu/mhunt/intro-vir.htm

MCRO 2.4

Classification of RNA Viruses
• Multiple combinations of genome
and capsid structure
• Some patterns:
– All RNA viruses are singlestranded except for Reoviridae.
– All negative sense viruses are
enveloped and have helical capsid
structure.
– All non-enveloped viruses have
icosahedral capsid structure.
In “genome-speak”, ds = double-stranded and ss = single-stranded.
MCRO 2.4

Viral Infection and the Immune System: Overview
Viral pathogenesis involves complex interactions between viruses and hosts comprising of transmission, replication,
dissemination, immune response, and pathology to produce disease in humans.
§ Viruses have found several routes to enter and spread in the host and find a target cell/tissue where they can
replicate efficiently and cause cytopathic effects to damage the tissue.
§ In some cases, the immune system is successful in eliminating the virus, whereas in other cases, viruses avoid
elimination by the immune system and persist in the host.
§ While in several cases, the disease is caused by direct viral lysis of the infected cells, in other cases, the disease
is immune-mediated such as immune complexes, cytotoxic CD8 T cells, and cytokines.
• cytokines: any of a number of substances, such as interferon, interleukin, and growth factors, which are
secreted by certain cells of the immune system and have an effect on other cells.
§ Many DNA viruses and some RNA viruses transform cells causing oncogenesis.
§ Host factors and defenses play important roles in viral pathogenesis: note that the same virus may cause a mild
disease in some hosts and a severe disease in other hosts.
§ Innate and adaptive immune responses are critical to eliminate or control viral infections in hosts.
§ Several viral infections cause immune suppression, including a risk of opportunistic and superinfections.
§ Immunocompromised hosts are vulnerable to many viral diseases. Vaccination is the key to provide protection in
the population.
Read: Sherris & Ryan Chapter 7
MCRO 2.3

Immunity: Review Week 1 pptx
Innate Defenses = non-specific defenses
§ Ability to resist damaging organisms and toxins
§ Barriers (skin/gastric acid)
§ Cells (neutrophils & macrophages)
§ Chemicals (lysozyme, complement)
§ Processes (fever, phagocytosis, inflammation)
Acquired Immunity = specific defenses
§ Humoral (antibody-mediated) ----> circulating antibodies
§ Cellular (cell-mediated) ----> activated T cells
MCRO 1.4

Viral Infection and the Immune System

Read: Sherris & Ryan Chapter 7
MCRO 2.3

Viral Infection and the Immune System
§ Viruses cause disease when they breach the host’s primary physical and natural protective
barriers; evade local, tissue, and immune defenses; spread in the body; and destroy cells either
directly or via bystander immune and inflammatory responses.
§ Viral pathogenesis comprises of several stages:
(1) Transmission and entry of the virus into the host: including food and water, aerosol,
respiratory, gastrointestinal, break in the skin, via mucosal or blood, insect or animal bite,
and urogenital, anal or sexual routes
(2) Spread in the host: Viruses generally multiply at the site of entry to establish infection in
the host and can also spread through the host by infecting neighboring cells and/or reach
the blood stream (systemic infection)
(3) Tropism: capability of viruses to infect a discrete population of cells within an organ.
• Cellular or tissue tropism is most often determined by the specific interaction of viral
surface proteins (spikes) and cellular receptors on the host cells
• Viruses such as HIV use a receptor (CD4) and coreceptor (CCR5 or CXCR4)
• Different viruses may use the same receptor on host cells
Read: Sherris & Ryan Chapter 7
MCRO 2.3

Viral Infection and the Immune System
(4) Virulence and cytopathogenicity: the relative ability of a virus to cause disease.
Viral virulence is, basically, the degree of pathogenicity of a virus.
• A virus may be of high or low virulence for a particular host.
• Different strains of the same virus may differ in the degree of pathogenicity
(5) Patterns of viral infection and disease: Not every viral infection results in a
disease. Infection involves multiplication of the virus in the host,
whereas disease represents a clinically apparent response.
• Infections are much more common than disease; unapparent infections are
termed subclinical, and the individual is referred to as a carrier
(6) Host factors: including immune status, genetic background, age, and nutrition, play
important roles in determining the outcome of viral infection. Several innate immune
responses (interferons α and β, natural killer (NK) cells, mucociliary responses, and
others) and adaptive immune responses (antibody and T-cell responses) influence the
outcome of viral infections.
• Individuals with weak immune systems or those who are immunocompromised or
immunosuppressed often have more severe outcomes. Details of immune responses
to infection are described in Chapter 2.
Read: Sherris & Ryan Chapter 7

MCRO 2.3

Viral Infection and the Immune System
(7) Host defense: The two major types of host defenses are nonspecific (innate) and specific
(adaptive) immune responses.
• The innate immune response includes interferons, natural killer (NK) cells, macrophages
(phagocytosis), mucociliary clearance, and fever.
o Interferons are host-encoded proteins that provide the first line of defense against viral
infections
• The adaptive immune response involves humoral immunity (B cells) and cell-mediated
immunity (T cells)
o cytotoxic T lymphocytes (CTL) destroy virus-infected cells
o after viral infection, the first specific immune response is T-cell mediated in which CD8 T
cells recognize viral antigen presented by class I MHC and kill virus-infected cells by
secreting perforins and granzymes causing apoptosis of the viral-infected host cell
(8) Virus-induced immunopathology: even when the host’s working immune system cannot stop a
viral infection leading to disease
• This could be true in viral infections in which a large number of cells are infected in an
individual
• Recent emerging SASR-CoV-2 (COVID-19) pandemic causing multiorgan diseases
involves viral load and excessive cytokine release induced damage.
Read: Sherris & Ryan Chapter 7

MCRO 2.3

Laboratory Detection of Viral Infection
u

Serology: identification of antibodies from a peripheral blood sample

u

Viral culture: use of cell culture to grow viruses in-vitro

u

Cytology/Histology: Study of cell morphology – identification of nuclear changes in a stained cell preparation,
for example

u

Molecular techniques: A variety of molecular biological techniques can be employed to detect viral genome,
for example
u

Variations of PCR, polymerase chain reaction

MCRO 2.5

Growth & Assays of Viruses
The growth of human viruses requires that the host cells be cultivated in the laboratory.
§ To prepare cells for growth in vitro, a tissue is removed from an animal, and the cells are
disaggregated using the proteolytic enzyme trypsin.
§ The cell suspension is seeded into a plastic Petri dish in a medium containing a complex mixture of
amino acids, vitamins, minerals, and sugars.
§ In addition to these nutritional factors, the growth of animal cells requires components present in
animal serum.
§ This method of growing cells is referred to as tissue culture, and the initial cell population is called
a primary culture.
§ The cells attach to the bottom of the plastic dish and remain attached as they divide and eventually
cover the surface of the dish.
§ When the culture becomes crowded, the cells generally cease dividing and enter a resting state.
§ Propagation can be continued by removing the cells from the primary culture plate using trypsin and
reseeding a new plate.
§ Cells taken from a normal (as opposed to cancerous) tissue cannot usually be propagated in this
manner indefinitely.
§ Permanent cell lines are useful for growing viruses
Read : Sherris & Ryan Chapter 6
Citation: Chapter 4 Principles of Laboratory Diagnosis of Infectious Diseases, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922674 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.5

Growth & Assays of Viruses

Viruses are quantitated by a method called the plaque assay.
§ Briefly, viruses are mixed with cells on a Petri plate so that each infectious
particle gives rise to a zone of lysed or dead cells called a plaque. From the
number of plaques on the plate, the titer of infectious particles in the lysate is
calculated. Virus titers are expressed as the number of plaque-forming units
per milliliter (pfu/mL).

Read: Sherris & Ryan Chapter 6
Citation: Chapter 4 Principles of Laboratory Diagnosis of Infectious Diseases, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922674 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.5

PCR
Diagnostic applications of the polymerase chain reaction (PCR). A. A clinical specimen
(eg, pus, tissue) contains DNA from many sources as well as the chromosome of the
organism of interest. If the DNA strands are separated (denatured), the PCR primers
can bind to their target sequences in the specimen itself. B. Amplification of the target
sequence by PCR. (1) The target sequence is shown in its native state. (2) The DNA is
denatured, allowing the primers to bind where they find the homologous sequence. (3)
In the presence of the special DNA polymerase, new DNA is synthesized from both
strands in the region between the primers. (4-6) Additional cycles are added by
temperature control of the polymerase with each new sequence acting as the template
for another. The DNA doubles with each cycle. After 25 to 30 cycles, enough DNA is
present to analyze diagnostically. C. Internal probe. The amplified target sequence is
shown. A probe can be designed to bind to a sequence located between (internal to) the
primers. D. Analysis of PCR amplified DNA. (1) The amplified sequence can be cloned
into a plasmid vector. In this form, a variety of molecular manipulations or sequencing
may be carried out. (2) Direct hybridizations usually make use of an internal probe. The
example shows three specimens, each of which went through steps A and B. After
amplification, each was bound to a separate spot on a filter (dot blot). The filter is then
reacted with the internal probe to detect the PCR-amplified DNA. The result shows that
only the middle specimen contained the target sequence. (3) The amplified DNA may be
detected directly by agarose gel electrophoresis. The example shows detection of
amplified fragments in two of three lanes on the gel. (4) The sensitivity of detection may
be increased by use of the internal probe after Southern transfer. The example shows
detection of a third fragment of the same size that was not seen on the original gel
because the amount of DNA was too small.

Read: Sherris & Ryan Chapter 4, Figure 4-9
Citation: Chapter 4 Principles of Laboratory Diagnosis of Infectious Diseases, Ryan KJ. Sherris & Ryan's Medical Microbiology, 8th Edition; 2022. Available at:
https://accessmedicine.mhmedical.com/content.aspx?bookid=3107&sectionid=260922674 Accessed: January 15, 2024
Copyright © 2024 McGraw-Hill Education. All rights reserved

MCRO 2.5