EHV2 Chapter 11 Slide Presentation PDF

Summary

This document provides learning objectives, a lecture outline, and detailed information about the history, taxonomy, epidemiology, and clinical progression of human immunodeficiency virus (HIV) infection. It also discusses the molecular virology of HIV-1, including the viral structure and enzymes within the core.

Full Transcript

CHAPTER 11
HUMAN IMMUNODEFICIENCY
VIRUS

Essential Human Virology, 2nd Editi
 Learning Objectives

Following completion of this chapter, students should be
able to:

1. Recall important events in the early years of HIV/AIDS,
including how each was discovered and the importance of
medical advances against the virus;

2. Relay the taxonomy, groups, and subtypes of HIV viruses;

3. Explain the origin of HIV-1 and HIV-2;

4. Worldwide and in the United States, examine the prevalence
of HIV/AIDS in different regions, age groups, sexes, and
demographic groups;

5. Describe the transmission of HIV and the clinical course of
infection;

6. Identify the function of each HIV protein that was discussed
 Lecture Outline

History of HIV infection

Taxonomy and origins of HIV

Epidemiology of HIV/AIDS

Clinical progression of HIV/AIDS
Molecular virology and replication of
HIV-1
 History of HIV Infection
June 5, 1981: Morbidity and Mortality Weekly Report
(MMWR) publishes a case study that documents five
uncommon cases of pneumonia caused by the fungus
Pneumocystis carinii (now known as Pneumocystis
jirovecii) in young, previously healthy gay men
Within days, additional cases were being reported to the
CDC

Also in 1981, cases of Kaposi’s sarcoma -- a rare skin
cancer generally only seen in older men -- were being
reported in previously healthy, young gay men in New York
and California

270 cases of this severe immunodeficiency had been
reported by the end of the year

Later determined to be AIDS
 History of HIV Infection
1982: CDC establishes the name “acquired immune
deficiency syndrome” (AIDS) to replace what had
been referred to as “gay-related immune deficiency”
(GRID) in an effort not to misclassify the disease
Had also received reports of AIDS in:

people who had received blood transfusions

heterosexual partners of individuals with AIDS

hemophiliacs: people who lack clotting factor VII as a
result of a gene deficiency and must receive it through
intravenous injections of clotting factor concentrates
derived from human plasma
About half of all people with hemophilia and 90% of
those with severe hemophilia became infected with
HIV through contaminated factor VIII
 History of HIV Infection
1983: CDC had identified all major routes of Figure 11.1 CDC

transmission

Blood and blood products
Sexual intercourse
Congenital transmission

Not from:
respiratory secretions
food/water
air
personal contact
Despite this, fears of
contracting this deadly
disease lead to
discrimination, violence,
and stigma for those
infected
 History of HIV Infection
1983: First major breakthrough against the disease

Pasteur Institute researchers Françoise Barré-Sinoussi and
Luc Montagnier isolated a retrovirus, which they name
lymphadenopathy-associated virus (LAV), from the lymph
node of an individual with AIDS
They shared the 2008 Nobel Prize in Physiology or
Medicine for this discovery

In the same issue of the scientific journal Science, National
Cancer Institute researcher Robert Gallo described a
retrovirus that he named the third of the human T-
lymphotropic viruses, HTLV-III

The following year, Montagnier and Gallo held a joint
press conference to announce the two viruses were in
fact the same virus and likely the cause of AIDS

International Committee on the Taxonomy of Viruses
officially named the retrovirus “human
 History of HIV Infection
Slow but steady progress -- Figure 11.1
both scientifically and
socially -- occurred over the
following 10+ years

1985: Blood test for HIV
developed
1987: First antiretroviral drug,
zidovudine (AZT), approved
1987: AIDS quilt went on
display with 1920 panels
1994: Highly-active
antiretroviral therapy
(HAART), a cocktail of several
antiviral drugs together, began
being used as the standard
treatment
Also known as Cindy Smith
combination
 History of HIV Infection
2022 – nearly 40 years after the discovery of HIV:

1.5 million people still infected each year globally

No HIV/AIDS vaccine yet exists
 Lecture Outline

History of HIV infection

Taxonomy and origins of HIV

Epidemiology of HIV/AIDS

Clinical progression of HIV/AIDS
Molecular virology and replication of
HIV-1
 Taxonomy and Origins of HIV

Two types (species) of HIV
HIV-1
HIV-2

Family: Retroviridae
Subfamily: Orthoretrovirinae
Genera: Lentivirus
Species: Human immunodeficiency
virus 1
Human immunodeficiency virus 2

The two types cause clinically indistinguishable
conditions
Viral loads tend to be lower during HIV-2 infection,
HIV-2 is less easily transmitted, and progression to
 Taxonomy and Origins of HIV
HIV-1 and HIV-2 are further subdivided into genetically
distinct groups
HIV-1:
Group M (main/major)
Group O (outlier)
Group N (non-M, non-O)
Group P (newest group)

Figure 11.2
 Taxonomy and Origins of HIV
HIV-1 Group M is further divided into nine distinct
subtypes/clades

Map image reprinted with permission of Wolters Kluwer Health, Inc., from Figure 11.3
Hemelaar et al., Global trends in molecular epidemiology of HIV-1 during
2000-2007. AIDS 2011: 25(5), 679-689.

HIV-1 group M viruses are the cause of the worldwide
pandemic
Subtype C is responsible for ∼50% of infections
worldwide
 Taxonomy and Origins of HIV
HIV-1 and HIV-2 are further subdivided into genetically
distinct groups
HIV-1:
Group M (main/major)
Worldwide pandemic
Group O (outlier)
50% of HIV-
infected individuals develop severe flu-like
symptoms:
Fever
Swollen lymph nodes
Sore throat
Arthralgia (joint pain)
Myalgia (muscle pain)
Headache
Fatigue
Weight loss
Sometimes a rash

Viral loads reach very high levels
Person seroconverts (produces antibodies against
the virus) as symptoms resolve
 Clinical Progression of HIV/AIDS
2. Asymptomatic Phase (Clinical Latency Stage)
Symptoms are absent or limited
HIV slowly replicates, causing the gradual depletion of CD4 T
cells

Lasts an average of 10 years without antiretroviral therapy
(ART)

Rapid progressors take 2-3 years to progress through this
stage (10-15%)
Long-term nonprogressors (LTNPs) maintain normal CD4 T
cell counts and low HIV titers without ART (5%)
A subset known as elite controllers even maintain
undetectable viral loads
Reasons may include genetic factors, the type of immune
response that is elicited, and differences in the HIV-1
strains
Activation of cytotoxic T lymphocytes, rather than
antibody production, correlates with protection
 Clinical Progression of HIV/AIDS
2. Asymptomatic Phase (Clinical Latency Stage)
CD4 T cells are progressively depleted as the virus causes
direct and indirect damage to the cells

Uninfected person: 500-1500 CD4 T cells/µL of blood

When the CD4 T cell level falls below 500 cells/µL of
blood, opportunistic infections occur: infections
caused by pathogens that are normally cleared by the
immune system but cause disease when an
individual’s immune system becomes impaired
 Clinical Progression of HIV/AIDS
3. Acquired Immune Deficiency Syndrome (AIDS)

A person is classified as progressed to AIDS when
he/she develops one or more opportunistic
infections or has a CD4 T cell count below 200
cells/µL of blood
At serious risk of developing a life-threatening
opportunistic disease
Person diagnosed with AIDS lives around 3 years or
1 year if an opportunistic infection is acquired

Fungi
Bacteria
Viruses
Parasites
 Clinical Progression of HIV/AIDS
Figure 11.7
Candida albicans Kaposi’s sarcoma

Kaposi’s sarcoma with Cysts of Pneumocystis jiroveci,
Candida albicans formerly known as
Pneumocystis carinii

courtesy of the CDC and (B and C) Sol Silverman, Jr., D.D.S.; (D) Dr. Edwin P. Ewing, Jr.
 Clinical Progression of HIV/AIDS
3. Acquired Immune Deficiency Syndrome (AIDS)

Other disease complications

Kidney disease, due to:
the infection of kidney cells by HIV
immune complexes, antigen-antibody
complexes that become lodged in the kidneys
a side effect of antiretroviral drugs

Neurological manifestations (>50% of HIV+
individuals)
Cognitive issues
HIV-associated dementia
Encephalitis: inflammation of the brain
Meningitis: inflammation of the meninges
 Clinical Progression of HIV/AIDS
Ultimately, why does the immune system fail to fight off
HIV?

End-stage progression is characterized by a reduction in the
number of HIV-specific cytotoxic T lymphocytes

With the increased diversity of the HIV population due to
mutation, and the reduction of CD4 T cell help in activating B cells
and cytotoxic T lymphocytes, the immune system becomes
overwhelmed
Progression of HIV-1
infection to AIDS can
be predicted based
upon the viral load
and the CD4 T cell
counts in an
individual

Currently, ART is the
only way to reduced
HIV replication and
slow T cell decline
Pre-exposure
prophylaxis (PrEP)
prevents infection in
high-risk HIV-negative
people
Antiretroviral drugs
target several stages
of replication
 Clinical Progression of HIV/AIDS
Progression of HIV-1 infection to AIDS can be predicted
based upon the viral load and the CD4 T cell counts in an
individual

Currently, ART is the only way to reduced HIV replication and slow
T cell decline
40% of the 37 million people living with HIV/AIDS are accessing
HAART/cART
Antiretroviral drugs target several stages of replication

The use of HAART has led to significant increases in the life
expectancy of an HIV+ individual:

In 2000-2002, a 20-year-old with HIV on HAART was expected
to live until
age 56

In 2016, a 20-year-old with HIV on HAART was expected to live
until
age 78.4 (6.8 years less than HIV-infected individuals)
 Lecture Outline

History of HIV infection

Taxonomy and origins of HIV

Epidemiology of HIV/AIDS

Clinical progression of HIV/AIDS
Molecular virology and replication of
HIV-1
 Molecular Virology
HIV is an enveloped retrovirus possessing a cone- or
bullet-shaped capsid

CDC / Maureen Metcalfe and Tom Hodge
Figure 11.8
 Molecular Virology
Capsid built from a single
protein, the capsid
protein (CA)

Two complete copies of
the +ssRNA genome
Considered pseudodiploid
because only 1 of the 2
copies is used for reverse
transcription
+ssRNA genome possesses
a 5’ cap and 3’ poly(A) tail,
but it is not infectious

Figure 11.8
 Molecular Virology
Within the core:

Nucleocapsid protein
(NC) that coats the
viral RNA

Three enzymes:
Reverse
transcriptase (RT)
Integrase (RT)
Protease (PR)

Vpr, an accessory
Figure 11.8
protein that is involved
in the transport of
cDNA into the nucleus
 Molecular Virology
The envelope surrounds the
core to create a virion 100-
120 nm in diameter

Matrix protein (MA)
attaches to the inner
surface of the envelope

Trimers of the envelope
glycoproteins (Env) are
found on the surface
Consist of gp120
(surface subunit, SU)
Figure 11.8
and gp41
(transmembrane
subunit, TM)
gp120 and gp41 are cleaved
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
The Env glycoprotein trimer mediates adsorption of the
virion to the cell surface receptor, CD4, found on helper
T cells (below) and a population of macrophages and
dendritic cells

Figure 11.9
Seth Pincus, Elizabeth Fischer, and Austin Athman, National Institute of Allergy and Infectious Diseases
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
Before contacting CD4 T cells, the virus gains entry into
the body through the bloodstream or by exposure of the
virus to genital or intestinal mucosal epithelial surfaces

HIV crosses through the tight junctions that attach cells
of the epithelium together or penetrates through small
tears in the epithelium that occur during sexual activity
or as a result of other pathogens

In the tissue, HIV comes into contact with macrophages
and dendritic cells
Macrophages with CD4 can be infected by CCR5-
tropic strains
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
On dendritic cells, HIV is able to bind a receptor known
as DC-SIGN
Triggers endocytosis of HIV into vesicles
Dendritic cell travels to lymph node

Figure 11.10
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
When the dendritic cell makes contact with a CD4 T cell
in the lymph node, a virological synapse is formed
where exocytosed HIV virions come into contact with
HIV uses the dendritic cells as
CD4 T cells
“Trojan horses” for transport
of virions from the lymph
node to the tissue

Figure 11.10
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
HIV gp120 binds CD4 and one of
two co-receptors, either CCR5 or
CXCR4
Variations in the gp120 molecule
determine the tropism for CCR5 or
CXCR4
CCR5 is the primary co-receptor
used during initial infection, and
CCR5 strains display tropism for
macrophages and a subset of
mucosal-associated memory CD4
T cells
Known as R5 or M-tropic isolates
CXCR4 strains (X4 or T-tropic
isolates) arise later during
Figure 11.11
infection and preferentially infect
IN-DEPTH LOOK: INDIVIDUALS WITH CCR5 MUTATIONS

Within the Caucasian population, some individuals
have a 32-base-pair deletion in CCR5 (termed
CCR532)
Causes a frameshift mutation in CCR5 that leads
to a shortened, nonfunctional receptor that
cannot be used for HIV for entry
10-15% of Caucasians are heterozygous; only
1% are homozygous

Homozygotes are more resistant to infection
with R5 strains of HIV-1 (although still
susceptible to R4 strains)
Heterozygotes display delayed progression to
AIDS

32 allele has not been found in people of
IN-DEPTH LOOK: INDIVIDUALS WITH CCR5 MUTATIONS

In 2005, an HIV-infected man with leukemia (a
cancer of white blood cells) underwent
myeloablative therapy for his cancer
Uses radiation or chemotherapy to eliminate the
leukemia cells but kills off all immune system
cells in the process
Followed by hematopoietic stem cell
transplantation (HSCT), the transfer of bone
marrow stem cells to reconstitute the immune
system cells
Received bone marrow from a CCR532
homozygote
Result:
HIV loads became undetectable
The “Berlin patient” was able to discontinue HAART
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription

1. Binding of gp120 to CD4 causes a conformation change in the
molecule that reveals the binding site for the co-receptor
2. Binding of gp120 to the co-receptor modifies the heterodimer,
revealing a fusion peptide within gp41 that is inserted into the
plasma membrane
3. gp41 refolds to create a fusion pore (likely after internalization of
the virion into an endosome through clathrin-mediated
endocytosis) Fig. 11.11
4. The core (nucleocapsid) is released through the pore into the
cytoplasm
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription

Much remains to be learned about HIV uncoating

The viral capsid influences reverse transcription
Reverse transcription occurs within the capsid
The capsid must dissociate at least partially to allow
access to cellular factors (e.g. nucleotides)
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
Reverse Transcriptase
Heterodimer of two polypeptide Subunit 2 (p66)
chains, p51 and p66 in green, blue, and gray

Performs several enzymatic
functions:
1. RNA-dependent DNA
polymerase

2. DNA-dependent DNA
polymerase

3. RNase H (able to degrade the
RNA portion of an RNA-DNA Subunit 1 (p51) in
duplex) orange
Figure 4.14
Does not have proofreading ability
Beilhartz et al., Viruses 2010, 2: 900-926.
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
The retrovirus genome has several different domains that are of
importance during viral replication
Only 1 of the 2 +ssRNA genome strands serves as a template for
reverse transcription
A tRNA obtained from the previous cell -- usually specific for lysine
or proline -- acts astRNA
a primer to start reverse transcription
primer

R R
Redundant Redundant
sequence sequence

Unique 5’ Unique 3’
domain domain
Reverse Transcription
occurs in cytoplasm
carried out by reverse
transcriptase

(Follow along with handout)

Figure 4.12
Image used with permission from Elsevier/Academic
Press: Alan J. Cann, Principles of Molecular Virology 4 th
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription

Result of reverse transcription: complementary DNA (cDNA)

Long terminal Long terminal
repeat repeat

Resulting LTRs in cDNA are important for integration
 Replication of HIV-1
Attachment, Penetration, Uncoating, and Reverse
Transcription
Core protects reverse transcribed cDNA until it enters the nucleus

Most retroviruses must wait until the nuclear envelope dissolves
during mitosis in order to gain entry into the nucleus
As a lentivirus, HIV cDNA is able to cross nuclear pores
The pre-integration complex (PIC) is the term for the HIV
cDNA and proteins -- both of viral and cellular origin -- that
facilitate entry of the cDNA into the nucleus
HIV proteins involved: CA, NC, MA, RT, IN, Vpr
Interact with nucleoporin proteins that constitute the
nuclear pore complex

Figure 11.11
 Replication of HIV-1
Integration and Replication
Carried out by integrase
enzyme

Integrated cDNA is known as
proviral DNA; in its
integrated state, HIV is
known as a provirus

Integration is not directed to
any site, although it usually
occurs in an area of active
transcription

Figure 4.13
Image used with permission from Elsevier/Academic Press: Alan J. Cann, Principles of Molecular
 Replication of HIV-1
Integration and Replication
All retroviruses possess the
three major gag, pol, and
env genes

HIV also encodes several
essential and accessory
regulatory proteins
 Replication of HIV-1
Integration and Replication
HIV proviral DNA contains at least 9 open reading
frames that encode 15 individual proteins, in total
HIV relies upon extensive splicing of viral mRNAs to
generate its mature transcripts
As with all retroviruses, the LTR contains a viral
promoter

Figure 11.12
 Replication of HIV-1
Integration and Replication
Full-length, capped and polyadenylated viral mRNAs
are created
The mRNAs for Gag and Gag-Pol precursors are
unspliced
The mRNAs for vif, vpr, vpu, and env are spliced
once
The mRNAs for tat, rev, and nef are multiply-
spliced

Figure 11.12
 Replication of HIV-1
Integration and Replication
Host transcription factors bind to the U3 portion of the
LTR and recruit RNA pol II to the proviral DNA

Tat (transactivator of transcription) and Rev
(regulator of expression of viral proteins) are
expressed first

Tat binds to the viral mRNAs as they are being
transcribed, stabilizing RNA pol II to ensure full-
length transcription

Rev shuttles unspliced transcripts from the nucleus
to the cytoplasm (i.e. gag, gag-pol)
Normally any mRNAs with splice sites are retained in the
nucleus for splicing
 Replication of HIV-1
Integration and Replication
Translation of the 3 polyproteins occurs
1. The Gag precursor is cleaved by the viral protease into the
MA, CA, NC, and p6 proteins only after the virion is released
from the cell
2. During translation of the Gag polyprotein, about 5% of the time
the ribosome undergoes a frame shifting event that leads to
continued translation, forming the Gag-Pol precursor
Autocatalysis cleaves off the Pol portion, which is further
cleaved into PR, IN, and the two RT subunits

Figure 11.12
 Replication of HIV-1
Integration and Replication
Translation of the 3 polyproteins occurs
3. The Env precursor p160 is highly glycosylated in the rough ER
and a cellular enzyme in the Golgi complex cleaves it into gp120
and gp41

The remaining six HIV proteins are the product of spliced full-
length mRNAs and are translated individually
Accessory proteins Vif, Vpr, Vpu, and Nef are not essential
but increase replication of HIV virions and infectivity

Figure 11.12
 Replication of HIV-1
Integration and Replication
Replication of the genome occurs
The viral +ssRNA genome is transcribed by RNA pol II as a
full-length, unspliced, capped, and polyadenylated mRNA
Transcription starts within the LTR, transcribing the 5’ R and
U5 regions, coding sequences, and 3’ U3 and R regions to
reconstitute the HIV genome

proviral
DNA

RNA pol II
 Replication of HIV-1
Assembly
Gag precursor is targeted to the plasma membrane,
where the MA portion interacts with the inner side of
the plasma membrane
The other end of the Gag precursor associates with
the viral genome
The Env subunits gp120 and gp41 (non-covalently
associated) are targeted to the site of assembly
gp41 provides the transmembrane domain
gp120 associates with gp41 external to the virion
envelope Dr. Matthew Gonda / National Cancer Institute

Fig 11.13
 Replication of HIV-1
Release
Assembled virion buds from the surface of the cell,
obtaining its envelope in the process

Dr. Matthew Gonda / National Cancer Institute

Fig 11.13
 Replication of HIV-1
Maturation
Maturation occurs after budding
The viral protease cleaves several sites within Gag
and Pol precursors
The release of the individual proteins dramatically
alters the architecture of the capsid, creating a fully-
infectious virion

Dr. Matthew Gonda / National Cancer Institute

Fig 11.13
Replication of HIV-1
DEPTH LOOK: WHY DOESN’T AN HIV VACCINE EXIST YE
Vaccine efforts began almost immediately following
the discovery of HIV in 1983
First clinical trial of an HIV vaccine occurred in 1986
No vaccine has yet shown statistical significance of its
efficacy

Why haven’t any candidate HIV vaccines been
successful?
1. Traditional methods (live attenuated or inactivated virus
vaccines) have not been effective in providing protective
immunity
2. HIV is a human virus that does not infect typical animal models --
testing for safety and efficacy is a challenge
3. HIV mutates quickly due to the low fidelity of the RT
4. The number of HIV subtypes make it unreasonable to create a
“universal vaccine” against them all
5. gp120 is highly glycosylated, preventing antibodies from easily
interacting with it
6. How should the immune system be stimulated for protective
DEPTH LOOK: WHY DOESN’T AN HIV VACCINE EXIST YE
Candidate vaccines that generated neutralizing
antibodies against gp120 were not protective
 Vaccine efforts shifted to the cell-mediated
response

A vaccine using adenovirus to express HIV Gag, Pol,
and Nef proteins was highly immunogenic in monkeys
but did not prevent infection of humans

Most promising so far: a “prime-boost” strategy
“Prime” vaccine -- recombinant vector vaccine
using canarypox to deliver and express HIV Gag,
Pol, and Env peptides
Administered SIX times
Last two injections included the “boost” vaccine,
containing the gp120 protein
Vaccine was 31.2% effective in preventing HIV
DEPTH LOOK: WHY DOESN’T AN HIV VACCINE EXIST YE
Broadly neutralizing antibodies (bNAbs) that
neutralize a range of HIV isolates have been observed
in rare HIV+ individuals
Requires someone to have been infected for years
Antibodies have mutations that allow the antibody
to pass through glycans to interact with conserved
regions of gp120
Numerous bNAbs have been identified
New vaccine trials are attempting to elicit bNAbs in
vaccinated HIV
CONCLUSION: individuals
VACCINE DEVELOPMENT IS ONE
OF THE GREATEST CHALLENGES THAT SCIENTISTS
HAVE ENCOUNTERED