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The
gut reaction to HIV —
The
gut contains 40-60% of the body's immune cells. As a result,
gut tissue is uniquely vulnerable to HIV, and careful investigation
of gut tissue is likely to provide important clues to the
pathology underlying HIV infection.
It
might seem counter-intuitive that by examining the gut one
can learn a great deal about a blood-borne virus that attacks
the immune system. However, the surface of the gut is a mucosal
membrane, and like all mucosal membranes is associated with
specialized immune, or lymphoid, tissue. The gut-associated
lymphoid tissue (GALT), the largest lymphoid organ in the
body, serves as a substantial reservoir of HIV in infected
people, and plays important roles in the pathology of HIV
infection.
Mucosal membranes in the rectum and the urogenital tracts
serve as entry points for sexually transmitted HIV; therefore,
viral dynamics in these tissues are particularly relevant
to the etiology of HIV disease. This holds true even for lymphoid
tissue in mucosal membranes when the initial infection occurs
elsewhere. SIV, a virus related to HIV that infects monkeys,
will become established in GALT within days of infection even
when the virus was inoculated intravenously. This highlights
the special vulnerability of GALT to infection with HIV.
Three
factors contribute to this vulnerability. First, GALT contains
a large population of cells known as activated helper T lymphocytes.
These are the very cells that HIV prefers most to infect.
Second, gut mucosal membrane is specialized in transporting
material into the body for evaluation by immune cells, and
this activity provides a potential mechanism for HIV to enter
even healthy mucosal tissue. Third, recent data now indicate
that chemokine receptors, the cell surface molecules that
HIV uses as attachment points for entering into cells, are
expressed at high levels on cells found in the gut, making
infection that much easier for the virus.
The gut contains large numbers of susceptible cells
The majority of the material that enters the body is breathed
in or swallowed, and the first contact this material has with
the body is at mucosal surfaces along the respiratory or digestive
tracts. In the case of material that is swallowed, much of
it will be essential nutrients that must be absorbed, while
other material will be potentially harmful. GALT must correctly
differentiate between what the body requires, what is inert,
and what must be excluded.
The
lining of the human gut has 200 times more surface area than
the skin. Naturally, this much area requires great numbers
of immune cells for vigilance. The gut is estimated to contain
40-60% of the body's total lymphocyte population.
These
immune cells are normally in a mild state of activation. This
is generally useful, since activated lymphocytes are more
vigilant against harmful material. On the other hand, proteins
from food are not always fully digested by the time they reach
the intestines, and would serve as antigens that induce a
strong inflammatory response�an allergic reaction�if some
mechanism were not available for tolerance as well. As a result,
a balance is normally struck between activation mechanisms
for protection and immune tolerance mechanisms to prevent
aberrant (and potentially harmful) responses to inert materials
or essential nutrients.
This chronic mild activation of GALT immune cells exacerbates
the damage caused by HIV in the gut. HIV will productively
infect several classes of cells, but displays a preference
for infecting the helper T cell type, the subset of lymphocytes
that bears the marker CD4. When helper T cells are activated,
as many that reside in the gut are, they become even more
susceptible to HIV infection.
One
would expect from this that cell loss in HIV infection would
be highest in GALT regions in which helper T cells are concentrated,
and this is what has been observed. The lamina propria is
a region of GALT that is rich in activated helper T cells.
The lamina propria sits right near the mucosal surface, and
is separated from all the material in the gut by a single
layer of epithelial cells. A number of papers have described
cell loss in GALT in patients with HIV, and in monkeys infected
with SIV. In both cases, there is a selective loss of CD4+
helper T cells within the lamina propria, and there are indications
that helper T cells are depleted in the lamina propria before
there is loss detected in the blood.
The
chronic mild activation level of gut T cells renders them
vulnerable to HIV infection. At the same time, the tolerance
mechanisms that provide a brake against aberrant activity
might possibly serve to retard effective anti-HIV responses.
HIV
enters in a Trojan Horse?
HIV and SIV are much more efficient at infecting compromised
mucosal membranes than intact ones, but infection of intact
membranes has been documented. Recent work has raised the
intriguing possibility that HIV can usurp normal mechanisms
for transporting material across these surfaces to gain entry
into the body.
The mucosal surface of the gut is surrounded by a layer one
cell thick, the epithelium. This thin layer is all that stands
between the interior of the body and all the nutrients and
potentially infectious agents within the intestines. The cells
of the gut epithelium are specialized to transport antigens
across this layer to the GALT for analysis (to either launch
an immune response if the antigen is considered harmful or
to tolerate it if is considered benign). Intact viruses can
also be transported across the epithelium by these cells.
"M" cells are the cell type within the epithelium thought
to be responsible for the transport and presentation of antigens
to lymphoid cells within. Lymphocytes migrate towards the
M cells to become educated about the material the gut is being
exposed to. Many of these lymphocytes are the activated helper
T cells that are particularly vulnerable to infection with
HIV. HIV can adhere to the surface of M cells, and it is possible
that T cells inside the gut mucosa become infected when they
migrate out to meet M cells.
It is not yet clear that HIV can infect the intact gut in
this manner, but a related cell type � the dendritic cell
� is known to promote HIV infection of activated helper T
cells within lymph nodes by just this mechanism. The long-lasting
retention of intact virus by dendritic cells is a significant
impediment to eradicating HIV from lymph nodes with antiviral
treatments. Since extensive networks of dendritic cells exist
in the gut as well, it also might impact the clinical course
of treatment.
High chemokine receptor levels add to the gut's vulnerability
HIV infects cells that express particular cell surface molecules
that act as attachment points for the virus. These molecules
are called chemokine receptors, because they normally bind
chemokines, signaling molecules that activate lymphocytes
and macrophages (another kind of white blood cell).
Using the endoscopic rectal biopsy technique, Dr. Peter Anton
and associates at UCLA reported at the XII World AIDS Conference
in Geneva, Switzerland that the chemokine receptor profile
of T lymphocytes in the gastrointestinal tract render them
particularly vulnerable to infection by HIV.
Upon isolating T cells from the rectal biopsies, Dr. Anton's
group measured the level of one particular type of chemokine
receptor, known as CCR5. HIV prefers to attach to this type
of chemokine receptor during transmission. Once an infection
is established, the virus develops an affinity for other kinds
of chemokine receptors. The expression profile of CCR5 in
GALT immune cells is therefore a particularly relevant parameter
in models of HIV infection.
The percentage of helper T cells that bear CCR5 is significantly
greater in the gut T cell population than in the blood T cell
population. This is true in healthy, uninfected individuals
as well as in HIV-infected individuals. The number of CCR5
molecules present on each cell is also significantly higher
in gut CD4+ T cells than in blood CD4+ T cells.
One
can conclude from this that the potential for infection of
CD4+ T cells in the gut is high, but there is another variable
that can affect the degree to which this is true. Activated
lymphocytes secrete the very chemokines that normally occupy
these receptors, thereby preventing HIV from binding. These
chemokines also cause CD4+ T cells to remove the receptors
from their membranes, closing the door to HIV infection. Unfortunately,
although there is a degree of immune activation under normal
conditions in the gut that would tend to favor chemokine secretion,
this activation also recruits additional T cells to the gut
lining from the blood, providing potentially more viral targets.
GALT
is a significant HIV reservoir.
Rectal biopsies of HIV-infected people have established that
GALT is a significant repository of virus, and declines in
select T cell populations within the gut are correlated with
the stage of disease. As discussed in the article, "Whole
Body Viral Burden" (page 21), viral replication occurs at
a faster rate within GALT than in blood or lymph nodes. It
is likely that HIV infection of GALT is a significant contributor
to progression to AIDS.
A
longitudinal study within individual patients has not been
attempted before, to establish the relationship between the
viral dynamics in GALT and the rest of the body. Accordingly,
AIDS RESEARCH Alliance's collaborative effort with Dr. Peter
Anton of UCLA (see page 11 for the study description) aims
to establish a repeatable measure of viral burden within GALT
tissue that can be used for analyzing such relationships.
These studies will be key to elucidating mechanisms of pathology
caused by HIV infection.
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