Viral structure, function and pathogenesis.ppt
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About This Presentation
Detailed description of Viral pathogenesis.
Slide Content
Viral Pathogenesis
Derek Wong
http://virology-online.com
Derek Wong
http://virology-online.com
Viral Pathogenesis
Viral pathogenesis is the process by which a viral infection
leads to disease.
Viral pathogenesis is an abnormal situation of no value to
the virus.
The majority of viral infections are subclinical. It is not in
the interest of the virus to severely harm or kill the host.
The consequences of viral infections depend on the
interplay between a number of viral and host factors.
Viral pathogenesis is the process by which a viral infection
leads to disease.
Viral pathogenesis is an abnormal situation of no value to
the virus.
The majority of viral infections are subclinical. It is not in
the interest of the virus to severely harm or kill the host.
The consequences of viral infections depend on the
interplay between a number of viral and host factors.
Outcome of Viral Infection
Acute Infection
Recovery with no residue effects
Recovery with residue effects e.g. acute viral encephalitis leading to
neurological sequelae.
Death
Proceed to chronic infection
Chronic Infection
Silent subclinical infection for life e.g. CMV, EBV
A long silent period before disease e.g. HIV, SSPE, PML
Reactivation to cause acute disease e.g. herpes and shingles.
Chronic disease with relapses and excerbations e.g. HBV, HCV.
Cancers e.g. EBV, HTLV-1, HPV, HBV, HCV, HHV-8
Acute Infection
Recovery with no residue effects
Recovery with residue effects e.g. acute viral encephalitis leading to
neurological sequelae.
Death
Proceed to chronic infection
Chronic Infection
Silent subclinical infection for life e.g. CMV, EBV
A long silent period before disease e.g. HIV, SSPE, PML
Reactivation to cause acute disease e.g. herpes and shingles.
Chronic disease with relapses and excerbations e.g. HBV, HCV.
Cancers e.g. EBV, HTLV-1, HPV, HBV, HCV, HHV-8
Factors in Viral Pathogenesis
Effects of viral infection on cells (Cellular Pathogenesis)
Entry into the Host
Course of Infection (Primary Replication, Systemic Spread,
Secondary Replication)
Cell/Tissue Tropism
Cell/Tissue Damage
Host Immune Response
Virus Clearance or Persistence
Effects of viral infection on cells (Cellular Pathogenesis)
Entry into the Host
Course of Infection (Primary Replication, Systemic Spread,
Secondary Replication)
Cell/Tissue Tropism
Cell/Tissue Damage
Host Immune Response
Virus Clearance or Persistence
Cellular Pathogenesis
Cells can respond to viral infections in 3 ways: (1) No apparent change,
(2) Death, and (3) Transformation
Direct cell damage and death from viral infection may result from
diversion of the cell's energy
shutoff of cell macromolecular synthesis
competition of viral mRNA for cellular ribosomes
competition of viral promoters and transcriptional enhancers for cellular
transcriptional factors such as RNA polymerases, and inhibition of the
interferon defense mechanisms.
Indirect cell damage can result from
integration of the viral genome
induction of mutations in the host genome
inflammation
host immune response.
Cells can respond to viral infections in 3 ways: (1) No apparent change,
(2) Death, and (3) Transformation
Direct cell damage and death from viral infection may result from
diversion of the cell's energy
shutoff of cell macromolecular synthesis
competition of viral mRNA for cellular ribosomes
competition of viral promoters and transcriptional enhancers for cellular
transcriptional factors such as RNA polymerases, and inhibition of the
interferon defense mechanisms.
Indirect cell damage can result from
integration of the viral genome
induction of mutations in the host genome
inflammation
host immune response.
Viral Entry
Skin - Most viruses which infect via the skin require a breach in the
physical integrity of this effective barrier, e.g. cuts or abrasions. Many
viruses employ vectors, e.g. ticks, mosquitos or vampire bats to breach
the barrier.
Conjunctiva and other mucous membranes - rather exposed site and
relatively unprotected
Respiratory tract - In contrast to skin, the respiratory tract and all other
mucosal surfaces possess sophisticated immune defence mechanisms, as
well as non-specific inhibitory mechanisms (cilliated epithelium, mucus
secretion, lower temperature) which viruses must overcome.
Gastrointestinal tract - a hostile environment; gastric acid, bile salts,
etc. Viruses that spread by the GI tract must be adapted to this hostile
environment.
Genitourinary tract - relatively less hostile than the above, but less
frequently exposed to extraneous viruses (?)
Skin - Most viruses which infect via the skin require a breach in the
physical integrity of this effective barrier, e.g. cuts or abrasions. Many
viruses employ vectors, e.g. ticks, mosquitos or vampire bats to breach
the barrier.
Conjunctiva and other mucous membranes - rather exposed site and
relatively unprotected
Respiratory tract - In contrast to skin, the respiratory tract and all other
mucosal surfaces possess sophisticated immune defence mechanisms, as
well as non-specific inhibitory mechanisms (cilliated epithelium, mucus
secretion, lower temperature) which viruses must overcome.
Gastrointestinal tract - a hostile environment; gastric acid, bile salts,
etc. Viruses that spread by the GI tract must be adapted to this hostile
environment.
Genitourinary tract - relatively less hostile than the above, but less
frequently exposed to extraneous viruses (?)
Course of Viral Infection
Primary Replication
The place of primary replication is where the virus replicates after
gaining initial entry into the host.
This frequently determines whether the infection will be localized at
the site of entry or spread to become a systemic infection.
Systemic Spread
Apart from direct cell-to-cell contact, the virus may spread
via the blood stream and the CNS.
Secondary Replication
Secondary replication takes place at susceptible organs/tissues
following systemic spread.
Primary Replication
The place of primary replication is where the virus replicates after
gaining initial entry into the host.
This frequently determines whether the infection will be localized at
the site of entry or spread to become a systemic infection.
Systemic Spread
Apart from direct cell-to-cell contact, the virus may spread
via the blood stream and the CNS.
Secondary Replication
Secondary replication takes place at susceptible organs/tissues
following systemic spread.
Cell Tropism
Viral affinity for specific body tissues (tropism) is determined by
Cell receptors for virus.
Cell transcription factors that recognize viral promoters and
enhancer sequences.
Ability of the cell to support virus replication.
Physical barriers.
Local temperature, pH, and oxygen tension enzymes and non-
specific factors in body secretions.
Digestive enzymes and bile in the gastrointestinal tract that
may inactivate some viruses.
Viral affinity for specific body tissues (tropism) is determined by
Cell receptors for virus.
Cell transcription factors that recognize viral promoters and
enhancer sequences.
Ability of the cell to support virus replication.
Physical barriers.
Local temperature, pH, and oxygen tension enzymes and non-
specific factors in body secretions.
Digestive enzymes and bile in the gastrointestinal tract that
may inactivate some viruses.
Cell Damage
Viruses may replicate widely throughout the body without any
disease symptoms if they do not cause significant cell damage or
death.
Retroviruses do not generally cause cell death, being released
from the cell by budding rather than by cell lysis, and cause
persistent infections.
Conversely, Picornaviruses cause lysis and death of the cells in
which they replicate, leading to fever and increased mucus
secretion in the case of Rhinoviruses, paralysis or death (usually
due to respiratory failure) for Poliovirus.
Viruses may replicate widely throughout the body without any
disease symptoms if they do not cause significant cell damage or
death.
Retroviruses do not generally cause cell death, being released
from the cell by budding rather than by cell lysis, and cause
persistent infections.
Conversely, Picornaviruses cause lysis and death of the cells in
which they replicate, leading to fever and increased mucus
secretion in the case of Rhinoviruses, paralysis or death (usually
due to respiratory failure) for Poliovirus.
Immune Response
The immune response to the virus probably has the greatest impact
on the outcome of infection.
In the most cases, the virus is cleared completely from the body and
results in complete recovery.
In other infections, the immune response is unable to clear the virus
completely and the virus persists.
In a number of infections, the immune response plays a major
pathological role in the disease.
In general, cellular immunity plays the major role in clearing virus
infection whereas humoral immunity protects against reinfection.
The immune response to the virus probably has the greatest impact
on the outcome of infection.
In the most cases, the virus is cleared completely from the body and
results in complete recovery.
In other infections, the immune response is unable to clear the virus
completely and the virus persists.
In a number of infections, the immune response plays a major
pathological role in the disease.
In general, cellular immunity plays the major role in clearing virus
infection whereas humoral immunity protects against reinfection.
Immune Pathological Response
Enhanced viral injury could be due to one or a mixture of the
following mechanisms;-
Increased secondary response to Tc cells e.g. HBV
Specific ADCC or complement mediated cell lysis
Binding of un-neutralized virus-Ab complexes to cell surface Fc
receptors, and thus increasing the number of cells infected e.g.
Dengue haemorrhagic fever, HIV.
Immune complex deposition in organs such as the skin, brain or
kidney e.g. rash of rubella and measles.
Enhanced viral injury could be due to one or a mixture of the
following mechanisms;-
Increased secondary response to Tc cells e.g. HBV
Specific ADCC or complement mediated cell lysis
Binding of un-neutralized virus-Ab complexes to cell surface Fc
receptors, and thus increasing the number of cells infected e.g.
Dengue haemorrhagic fever, HIV.
Immune complex deposition in organs such as the skin, brain or
kidney e.g. rash of rubella and measles.
Viral Clearance or
Persistence
The majority of viral infections are cleared but certain
viruses may cause persistent infections. There are 2 types of
chronic persistent infections.
True Latency - the virus remains completely latent
following primary infection e.g. HSV, VZV. Its genome
may be integrated into the cellular genome or exists as
episomes.
Persistence - the virus replicates continuously in the body
at a very low level e.g. HIV, HBV, CMV, EBV.
Persistence
The majority of viral infections are cleared but certain
viruses may cause persistent infections. There are 2 types of
chronic persistent infections.
True Latency - the virus remains completely latent
following primary infection e.g. HSV, VZV. Its genome
may be integrated into the cellular genome or exists as
episomes.
Persistence - the virus replicates continuously in the body
at a very low level e.g. HIV, HBV, CMV, EBV.
Mechanisms of Viral Persistence
antigenic variation
immune tolerance, causing a reduced response to an antigen, may be due
to genetic factors, pre-natal infection, molecular mimicry
restricted gene expression
down-regulation of MHC class I expression, resulting in lack of
recognition of infected cells e.g. Adenoviruses
down-regulation of accessory molecules involved in immune recognition
e.g. LFA-3 and ICAM-1 by EBV.
infection of immunopriviliged sites within the body e.g. HSV in sensory
ganglia in the CNS
direct infection of the cells of the immune system itself e.g. Herpes
viruses, Retroviruses (HIV) - often resulting in immunosuppression.
antigenic variation
immune tolerance, causing a reduced response to an antigen, may be due
to genetic factors, pre-natal infection, molecular mimicry
restricted gene expression
down-regulation of MHC class I expression, resulting in lack of
recognition of infected cells e.g. Adenoviruses
down-regulation of accessory molecules involved in immune recognition
e.g. LFA-3 and ICAM-1 by EBV.
infection of immunopriviliged sites within the body e.g. HSV in sensory
ganglia in the CNS
direct infection of the cells of the immune system itself e.g. Herpes
viruses, Retroviruses (HIV) - often resulting in immunosuppression.
Examples of Viral Pathogenesis
Rubella
Transmitted by the respiratory route and replicates upper/lower
respiratory tract and then local lymphoid tissues.
Following an incubation period of 2 weeks, a viraemia occurs and the
virus spreads throughout the body.
Clinical Features:-
maculopapular rash due to immune complex deposition
lymphadenopathy
fever
arthropathy (up to 60% of cases)
Transmitted by the respiratory route and replicates upper/lower
respiratory tract and then local lymphoid tissues.
Following an incubation period of 2 weeks, a viraemia occurs and the
virus spreads throughout the body.
Clinical Features:-
maculopapular rash due to immune complex deposition
lymphadenopathy
fever
arthropathy (up to 60% of cases)
Rubella infection during pregnancy
Rubella virus enters the fetus during the maternal viraemic phase
through the placenta.
The damage to the fetus seems to involve all germ layers and results
from rapid death of some cells and persistent viral infection in others.
Preconception Risks
0-12 weeks 100% risk of fetus being congenitally infected
resulting in major congenital
abnormalities.
Spontaneous abortion occurs in 20% of cases.
13-16 weeks deafness and retinopathy 15%
after 16 weeks normal
development, slight risk of deafness
and retinopathy
Rubella virus enters the fetus during the maternal viraemic phase
through the placenta.
The damage to the fetus seems to involve all germ layers and results
from rapid death of some cells and persistent viral infection in others.
Preconception Risks
0-12 weeks 100% risk of fetus being congenitally infected
resulting in major congenital
abnormalities.
Spontaneous abortion occurs in 20% of cases.
13-16 weeks deafness and retinopathy 15%
after 16 weeks normal
development, slight risk of deafness
and retinopathy
Herpes Simplex Virus
HSV is spread by contact, as the virus is shed in saliva, tears, genital
and other secretions.
Primary infection is usually trivial or subclinical in most individuals.
It is a disease mainly of very young children ie. those below 5 years.
About 10% of the population acquires HSV infection through the
genital route and the risk is concentrated in young adulthood.
Following primary infection, 45% of orally infected individuals and
60% of patients with genital herpes will experience recurrences.
The actual frequency of recurrences varies widely between
individuals. The mean number of episodes per year is about 1.6.
HSV is spread by contact, as the virus is shed in saliva, tears, genital
and other secretions.
Primary infection is usually trivial or subclinical in most individuals.
It is a disease mainly of very young children ie. those below 5 years.
About 10% of the population acquires HSV infection through the
genital route and the risk is concentrated in young adulthood.
Following primary infection, 45% of orally infected individuals and
60% of patients with genital herpes will experience recurrences.
The actual frequency of recurrences varies widely between
individuals. The mean number of episodes per year is about 1.6.
Pathogenesis
During the primary infection, HSV spreads locally and a short-lived
viraemia occurs, whereby the virus is disseminated in the body. Spread to
the to craniospinal ganglia occurs.
The virus then establishes latency in the craniospinal ganglia.
The exact mechanism of latency is not known, it may be true latency
where there is no viral replication or viral persistence where there is a low
level of viral replication.
Reactivation - It is well known that many triggers can provoke a
recurrence. These include physical or psychological stress, infection;
especially pneumococcal and meningococcal, fever, irradiation; including
sunlight, and menstruation.
During the primary infection, HSV spreads locally and a short-lived
viraemia occurs, whereby the virus is disseminated in the body. Spread to
the to craniospinal ganglia occurs.
The virus then establishes latency in the craniospinal ganglia.
The exact mechanism of latency is not known, it may be true latency
where there is no viral replication or viral persistence where there is a low
level of viral replication.
Reactivation - It is well known that many triggers can provoke a
recurrence. These include physical or psychological stress, infection;
especially pneumococcal and meningococcal, fever, irradiation; including
sunlight, and menstruation.
Clinical Manifestations
HSV is involved in a variety of clinical manifestations
which includes ;-
1. Acute gingivostomatitis
2. Herpes Labialis (cold sore)
3. Ocular Herpes
4. Herpes Genitalis
5. Other forms of cutaneous herpes
7. Meningitis
8. Encephalitis
9. Neonatal herpes
HSV is involved in a variety of clinical manifestations
which includes ;-
1. Acute gingivostomatitis
2. Herpes Labialis (cold sore)
3. Ocular Herpes
4. Herpes Genitalis
5. Other forms of cutaneous herpes
7. Meningitis
8. Encephalitis
9. Neonatal herpes
Dengue (1)
Dengue
is the biggest arbovirus problem in the world today
with over 2 million cases per year. Dengue is found in SE Asia,
Africa and the Caribbean and S America.
Flavivirus, 4 serotypes, transmitted by Aedes mosquitoes which
reside in water-filled containers.
Human infections arise from a human-mosquitoe-human cycle
Classically, dengue presents with a high fever,
lymphadenopathy, myalgia, bone and joint pains, headache, and
a maculopapular rash.
Dengue
is the biggest arbovirus problem in the world today
with over 2 million cases per year. Dengue is found in SE Asia,
Africa and the Caribbean and S America.
Flavivirus, 4 serotypes, transmitted by Aedes mosquitoes which
reside in water-filled containers.
Human infections arise from a human-mosquitoe-human cycle
Classically, dengue presents with a high fever,
lymphadenopathy, myalgia, bone and joint pains, headache, and
a maculopapular rash.
Distribution of Dengue
Man-Arthropod-Man Cycle
Dengue (2)
Severe cases may present with haemorrhagic fever and shock
with a mortality of 5-10%. (Dengue haemorrhagic fever or
Dengue shock syndrome.)
Dengue haemorrhagic fever and shock syndrome appear most
often (90%) in patients previously infected by a different
serotype of dengue, thus suggesting an immunopathological
mechanism.
Antibody-dependent enhancement - Binding of heterotypic
antibodies to the virus, and subsequent infection of
macrophages with Fc receptors.
Severe cases may present with haemorrhagic fever and shock
with a mortality of 5-10%. (Dengue haemorrhagic fever or
Dengue shock syndrome.)
Dengue haemorrhagic fever and shock syndrome appear most
often (90%) in patients previously infected by a different
serotype of dengue, thus suggesting an immunopathological
mechanism.
Antibody-dependent enhancement - Binding of heterotypic
antibodies to the virus, and subsequent infection of
macrophages with Fc receptors.
Hepatitis B Virus
Incubation period: Average 60-90 days
Range 45-180 days
Clinical illness (jaundice):<5 yrs, <10%
5 yrs, 30%-50%
Acute case-fatality rate:0.5%-1%
Chronic infection: <5 yrs, 30%-90%
5 yrs, 2%-10%
Premature mortality from
chronic liver disease: 15%-25%
Hepatitis B - Clinical
Features
Range 45-180 days
Clinical illness (jaundice):<5 yrs, <10%
5 yrs, 30%-50%
Acute case-fatality rate:0.5%-1%
Chronic infection: <5 yrs, 30%-90%
5 yrs, 2%-10%
Premature mortality from
chronic liver disease: 15%-25%
Hepatitis B - Clinical
Features
Symptomatic Infection
Chronic Infection
Age at Infection
Chronic Infection (%)
S
y
m
p
t
o
m
a
t
i
c
I
n
f
e
c
t
i
o
n
(
%
)
Birth 1-6 months 7-12 months 1-4 yearsOlder Children
and Adults
0
20
40
60
80
100100
80
60
40
20
0
Outcome of Hepatitis B Virus
Infection
by Age at Infection
C
h
r
o
n
i
c
I
n
f
e
c
t
i
o
n
(
%
)
Chronic Infection
Age at Infection
Chronic Infection (%)
S
y
m
p
t
o
m
a
t
i
c
I
n
f
e
c
t
i
o
n
(
%
)
Birth 1-6 months 7-12 months 1-4 yearsOlder Children
and Adults
0
20
40
60
80
100100
80
60
40
20
0
Outcome of Hepatitis B Virus
Infection
by Age at Infection
C
h
r
o
n
i
c
I
n
f
e
c
t
i
o
n
(
%
)
Spectrum of Chronic Hepatitis B Diseases
1. Chronic Persistent Hepatitis - asymptomatic
2.Chronic Active Hepatitis - symptomatic
exacerbations of hepatitis
3. Cirrhosis of Liver
4. Hepatocellular Carcinoma
1. Chronic Persistent Hepatitis - asymptomatic
2.Chronic Active Hepatitis - symptomatic
exacerbations of hepatitis
3. Cirrhosis of Liver
4. Hepatocellular Carcinoma
HIV Pathogenesis
The profound immunosuppression seen in AIDS is due to the
depletion of T4 helper lymphocytes.
In the immediate period following exposure, HIV is present at a high
level in the blood (as detected by HIV Antigen and HIV-RNA assays).
It then settles down to a certain low level (set-point) during the
incubation period. During the incubation period, there is a massive
turnover of CD4 cells, whereby CD4 cells killed by HIV are replaced
efficiently.
Eventually, the immune system succumbs and AIDS develop when
killed CD4 cells can no longer be replaced (witnessed by high HIV-
RNA, HIV-antigen, and low CD4 counts).
The profound immunosuppression seen in AIDS is due to the
depletion of T4 helper lymphocytes.
In the immediate period following exposure, HIV is present at a high
level in the blood (as detected by HIV Antigen and HIV-RNA assays).
It then settles down to a certain low level (set-point) during the
incubation period. During the incubation period, there is a massive
turnover of CD4 cells, whereby CD4 cells killed by HIV are replaced
efficiently.
Eventually, the immune system succumbs and AIDS develop when
killed CD4 cells can no longer be replaced (witnessed by high HIV-
RNA, HIV-antigen, and low CD4 counts).
HIV half-lives
Activated cells that become infected with HIV produce virus
immediately and die within one to two days.
Production of virus by short-lived, activated cells accounts for the vast
majority of virus present in the plasma.
The time required to complete a single HIV life-cycle is approximately
1.5 days.
Resting cells that become infected produce virus only after immune
stimulation; these cells have a half-life of at least 5-6 months.
Some cells are infected with defective virus that cannot complete the
virus life-cycle. Such cells are very long lived, and have an estimated
half-life of approximately three to six months.
Such long-lived cell populations present a major challenge for anti-
retroviral therapy.
Activated cells that become infected with HIV produce virus
immediately and die within one to two days.
Production of virus by short-lived, activated cells accounts for the vast
majority of virus present in the plasma.
The time required to complete a single HIV life-cycle is approximately
1.5 days.
Resting cells that become infected produce virus only after immune
stimulation; these cells have a half-life of at least 5-6 months.
Some cells are infected with defective virus that cannot complete the
virus life-cycle. Such cells are very long lived, and have an estimated
half-life of approximately three to six months.
Such long-lived cell populations present a major challenge for anti-
retroviral therapy.
Summary
Viral Pathogenesis depends on the complex interplay of a
large number of viral and host factors.
Viral factors include cell tropism and cellular
pathogenesis.
The immune response is the most important host factor, as
it determines whether the virus is cleared or not.
Sometimes, the immune response itself is responsible for
the damage.
Viral Pathogenesis depends on the complex interplay of a
large number of viral and host factors.
Viral factors include cell tropism and cellular
pathogenesis.
The immune response is the most important host factor, as
it determines whether the virus is cleared or not.
Sometimes, the immune response itself is responsible for
the damage.
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