AIDS (Acquired
ImmunoDeficiency Syndrome) is one of the worst pandemics the
world has ever known. HIV (Human Immunodeficiency Virus), the virus
that causes AIDS, was first discovered in 1981 in a remote area of
central Africa. It has since swept across the globe, infecting
millions in a relatively short period of time. AIDS has killed 21.8
million people that we know of, with 3 million people dying in the
year 2000 alone
The thought of contracting HIV is frightening. And there is good
reason for that fear -- the disease is presently incurable, it has a
high mortality rate, it spreads quickly and there is no vaccine to
protect against it. In today's world, that combination is rare. For
example, small pox is often fatal, but the disease has been
completely contained through vaccinations. Tuberculosis is often
fatal but can usually be cured with antibiotics if caught early.
AIDS has been able to
infect and kill so many people because of its unique makeup. Let's
look at some of the features that make this disease so unusual:
HIV spreads by
intimate contact with an infected person. Forms of intimate
contact that can transmit AIDS include sexual activity and any
sort of situation that allows blood from one person to enter
another. Especially when you compare it with the many viruses
that spread through the air, it would seem like the intimacy
involved in the transmission of AIDS would be a limiting factor.
However…
..
A person can
carry and transmit the HIV virus for many years before any
symptoms show themselves. A person can be contagious for a
decade or more before any visible signs of disease become
apparent. In a decade, a promiscuous HIV carrier can potentially
infect dozens of people, who each can infect dozens of people,
and so on.
..
HIV invades the
cells of our immune system and reprograms the cells to become
HIV-producing factories. Slowly, the number of immune cells in
the body dwindles and AIDS develops. Once AIDS manifests, a
person is susceptible to many different infections, because the
immune system has been weakened so much by the HIV it can no
longer fight back effectively. HIV has also shown the ability to
mutate, which makes treating the virus nearly impossible.
The last feature in
this list is the one that is truly unique. HIV invades and destroys
the immune system -- the system that would normally protect the body
from a virus. HIV corrupts and disables the system that should be
guarding against HIV.
In the United States, given the current distribution of HIV in the
population, there is better than a one in 1,000 chance of
contracting HIV during an unprotected heterosexual encounter,
according to the Centers for Disease Control and Prevention (CDC).
In some locations, the chances are even higher. Unprotected sex is
the most common way of transmitting HIV. Your chances for infection
increase with each new partner. Here is a list of ways in which HIV
can be transmitted:
Sexual contact
Sharing
contaminated intravenous needles
Breastfeeding
(mother to baby)
Infected mother
to fetus during pregnancy or birth
Blood
transfusions (Rare in countries where blood is screened for HIV
antibodies.)
There is also a
slight chance of transmission through kissing and biting. However,
there have been very few cases of HIV being transmitted through
either method. In fact, the CDC has investigated only one case in
which HIV infection was attributed to open-mouth kissing.
HIV does not transmit
through the air or surface contact like cold and flu viruses do. HIV
is a fragile virus and doesn't survive well outside the human body.
This fragility makes the possibility of environmental transmission
very remote. Outside of a host cell, HIV doesn't survive for very
long. In laboratory studies, the CDC has shown that once the fluid
(blood, sweat, tears, etc..) containing the HIV virus dries, the
risk of environmental transmission is nearly zero.
There is a lot of
misinformation about how HIV can be transmitted. So, here is a list
of ways in which HIV is not transmitted:
Saliva, tears and
sweat -
Saliva and tears contain only small amounts of HIV, and
scientists haven't detected any HIV in the sweat of an infected
person.
Insects - Studies
show no evidence of HIV transmission through bloodsucking
insects. This is true even in areas where there are many cases
of AIDS and large populations of mosquitoes.
Like all viruses, HIV treads the fine line that separates living
things from nonliving things. Viruses lack the chemical machinery
that human cells utilize to support life. So, HIV requires a host
cell to stay alive and replicate. To replicate, the virus creates
new virus particles inside a host cell and those particles carry the
virus to new cells. Fortunately the virus particles are fragile.
Viruses, like HIV,
don't have cell walls or a nucleus. Basically, viruses are made up
of genetic instructions wrapped inside a protective shell. An HIV
virus particle, called a virion, is spherical in shape and has a
diameter of about one 10,000th of a millimeter.
HIV infects one
particular type of immune system cell. This cell is called the CD4+T
cell, also know as a T-helper cell (see How
the Immune System Works for details on T cells). Once infected,
the T-helper cell turns into a HIV-replicating cell. T-helper cells
play a vital role in the body's immune response. There are typically
1 million T-cells per one milliliter of blood. HIV will slowly
reduce the number of T-cells until the person develops AIDS.
To understand how HIV
infects the body, let's first look at the virus's basic structure.
Here are the basic parts of the HIV virus:
Viral envelope -
This is the outer coat of the virus. It is composed of two
layers of fatty molecules, called lipids. Embedded in the viral
envelope are proteins from the host cell. There are also about
72 copies of Env protein, which protrudes from the envelope
surface. Env consists of a cap made of three or four molecules
called glycoprotein (gp) 120, and a stem consisting of three to
four gp41 molecules.
p17 protein - The
HIV matrix protein that lies between the envelope and core
Viral core -
Inside the envelope is the core, which contains 2,000 copies of
the viral protein, p24. These proteins surround two single
strands of HIV RNA, each containing a copy of the virus's nine
genes. Three of these genes -- gag, pol and env -- contain
information needed to make structural proteins for new virions.
HIV is a retrovirus,
which means it has genes composed of ribonucleic acid (RNA)
molecules. Like all viruses, HIV replicates inside host cells. It's
considered a retrovirus because it uses an enzyme, reverse
transcriptase, to convert RNA into DNA.
Once the HIV virus
enters the body, it heads for the lymphoid tissues, where it finds
T-helper cells. Let's look at how the HIV virus infects immune
system cells and replicates:
Binding - The
HIV attaches to the immune cell when the gp120 protein of the
HIV virus binds with the CD4 protein of the T-helper cell. The
viral core enters the T-helper cell and the virion's protein
membrane fuses with the cell wall.
Reverse
transcription - The viral enzyme, reverse transcriptase,
copies the virus's RNA into DNA.
Integration - The
newly created DNA is carried into the cell's nucleus by the
enzyme, viral integrase, and it binds with cell's DNA. HIV DNA
is called a provirus.
Transcription
- The viral DNA in the nucleus separates and creates
messenger RNA (mRNA), using the cell's own enzymes. The mRNA
contains the instructions for making new viral proteins.
Translation - The
mRNA is carried back out of the nucleus by the cell's enzymes.
The virus then uses the cell's natural protein-making mechanisms
to make long chains of viral proteins and enzymes.
Assembly - RNA
and viral enzymes gather at the edge of the cell. An enzyme,
called protease, cuts the polypeptides into viral proteins.
Budding - New
HIV virus particles pinch out from the cell membrane and break
away with a piece of the cell membrane surrounding them. This is
how enveloped viruses leave the cell. In this way, the host cell
is not destroyed.
The newly replicated
virions will infect other T-helper cells and cause the person's
T-helper cell count to slowly dwindle. The lack of T-helper cells
compromises the immune system. When a person's T-helper cell count
drops below 200,000 cells per one milliliter of blood, he or she is
considered to have AIDS. The development of AIDS takes about two to
15 years, but about half of all people with HIV will develop AIDS
within 10 years after becoming infected, according to the CDC.
No one dies from AIDS
or HIV specifically. Instead, an AIDS-infected person dies from
infections, because his or her immune system has been dissipated. An
AIDS patient could die from the common cold as easily as he or she
could from cancer. The person's body cannot fight off the infection,
and he or she eventually dies.
To understand the devastation of AIDS, you have to understand the
high mortality rate of people who develop the disease. If you
counted every person in the city of Chicago, which is about 3
million, you would get the idea of how many people died worldwide
from AIDS in 2000. Basically, that means that each year AIDS kills
the same number of people that populate the third largest city in
the United States.
More then 36 million people are
infected with the HIV virus worldwide, with 25.3 million of those
cases in sub-Saharan Africa. Additionally, anther 5.3 million new
HIV infections occurred in 2000, which represents about 16,000 new
cases per day. The regions with the greatest number of people living
HIV/AIDS, according to the World Health Organization, include:
Sub-Saharan Africa - 25.3
million
South and Southeast Asia - 5.8
million
Latin America - 1.4 million
North America - 920,000
Eastern Europe/Central Asia - 700,000
In the United States, 753,907 cases
had been reported to the CDC through June 2000. However, the CDC
estimates that as many as 900,000 Americans are living with HIV or
AIDS.
There is also a
slight chance of transmission through kissing and biting. However,
there have been very few cases of HIV being transmitted through
either method. In fact, the CDC has investigated only one case in
which HIV infection was attributed to open-mouth kissing.
HIV does not transmit
through the air or surface contact like cold and flu viruses do. HIV
is a fragile virus and doesn't survive well outside the human body.
This fragility makes the possibility of environmental transmission
very remote. Outside of a host cell, HIV doesn't survive for very
long. In laboratory studies, the CDC has shown that once the fluid
(blood, sweat, tears, etc..) containing the HIV virus dries, the
risk of environmental transmission is nearly zero.
There is a lot of
misinformation about how HIV can be transmitted. So, here is a list
of ways in which HIV is not transmitted:
Saliva, tears and
sweat -
Saliva and tears contain only small amounts of HIV, and
scientists haven't detected any HIV in the sweat of an infected
person.
Insects - Studies
show no evidence of HIV transmission through bloodsucking
insects. This is true even in areas where there are many cases
of AIDS and large populations of mosquitoes.
Like all viruses, HIV treads the fine line that separates living
things from nonliving things. Viruses lack the chemical machinery
that human cells utilize to support life. So, HIV requires a host
cell to stay alive and replicate. To replicate, the virus creates
new virus particles inside a host cell and those particles carry the
virus to new cells. Fortunately the virus particles are fragile.
Viruses, like HIV,
don't have cell walls or a nucleus. Basically, viruses are made up
of genetic instructions wrapped inside a protective shell. An HIV
virus particle, called a virion, is spherical in shape and has a
diameter of about one 10,000th of a millimeter.
HIV infects one
particular type of immune system cell. This cell is called the CD4+T
cell, also know as a T-helper cell (see How
the Immune System Works for details on T cells). Once infected,
the T-helper cell turns into a HIV-replicating cell. T-helper cells
play a vital role in the body's immune response. There are typically
1 million T-cells per one milliliter of blood. HIV will slowly
reduce the number of T-cells until the person develops AIDS.
To understand how HIV
infects the body, let's first look at the virus's basic structure.
Here are the basic parts of the HIV virus:
Viral envelope -
This is the outer coat of the virus. It is composed of two
layers of fatty molecules, called lipids. Embedded in the viral
envelope are proteins from the host cell. There are also about
72 copies of Env protein, which protrudes from the envelope
surface. Env consists of a cap made of three or four molecules
called glycoprotein (gp) 120, and a stem consisting of three to
