http://www.eurekalert.org/pub_releases/2001-12/jhmi-sei121801.php
18-Dec-2001
Suppressing the immune system is
one way to treat autoimmune diseases, frustrating conditions in which the
body's tissues are attacked by "friendly fire." But a new study shows that
such blanket defenses are probably not the best way, say scientists from
The Johns Hopkins University School of Medicine.
One of the immune system's soldiers,
interferon-gamma, actually helps prevent tissue damage in mice given a
condition similar to a heart-damaging autoimmune disease in humans, the
scientists report in the Dec. 18 issue of the journal Circulation.
"In treating autoimmune disease,"
says Noel Rose, M.D., Ph.D., a professor of pathology at Hopkins, "it's
possible that treatments that alter the immune system's overall function
could make one autoimmune disease better but make a second one worse."
The scientists discovered interferon-gamma's
protective role as they were trying to figure out how an immune soldier
called interleukin-12 causes heart damage in this disease, known as myocarditis.
Because interleukin-12 "recruits" interferon-gamma, increasing its presence
in cells, the scientists suspected interferon-gamma might be involved in
damaging tissue.
Unexpectedly, mice without normal
interferon-gamma function had more heart damage, and mice treated with
extra interferon-gamma had less damage than normal mice. Extra interferon-gamma
prevented heart damage completely in seven of the 11 mice studied, says
Rose, whose studies were funded by the National Institutes of Health.
"Scientists generally thought that
interferon-gamma was responsible for many actions of interleukin-12, so
it was surprising that the two proteins really have opposite effects in
these mice," explains Marina Afanasyeva, M.D., M.P.H., a Ph.D. candidate
in molecular microbiology and immunology at Johns Hopkins University's
Bloomberg School of Public Health. "Interleukin-12 probably depends on
interferon-gamma for its effects in some circumstances but not others."
Many autoimmune diseases are poorly
understood, says Rose, but some are linked to viral infections. Treating
these diseases can be frustrating, as opportunistic autoimmune diseases
-- those that rise from the ashes of another -- are frequently seen, he
adds.
Critical to the scientists' discovery
was their mouse model of autoimmune myocarditis, which in humans stems
from infection with the Coxackievirus. While most people shake off the
infection's flu-like symptoms, for reasons still unknown at least 50,000
people per year subsequently develop an errant, long-lasting autoimmune
reaction that damages the heart muscle.
The Hopkins team had already identified
the target of this immune attack as a protein called cardiac myosin. By
injecting mice with excess cardiac myosin, they created the autoimmune
response and heart damage without using the virus.
Because interleukin-12 was already
a primary suspect in this autoimmune process and it stimulates production
of interferon-gamma, the scientists thought interferon-gamma might be responsible
for its damaging effects.
However, mice whose gene for interferon-gamma
was knocked out and mice whose interferon-gamma protein was blocked with
an antibody both had larger hearts and more physical evidence of heart
tissue inflammation than mice with normally functioning interferon-gamma,
says Afanasyeva. They're still evaluating the effects on heart function,
she adds, and they don't yet know whether interferon-gamma actively protects
the heart or its absence allows another as-yet-unknown damaging activity
to emerge.
Despite its apparent protective role
in myocarditis, interferon-gamma is unlikely to be useful as a treatment,
notes Rose. "Interferon-gamma is a very potent agent but it can also be
toxic," adds Afanasyeva. "If we study more how interferon-gamma acts, perhaps
we can design safer agents that mimic it."
The scientists emphasize that different
auto-immune diseases likely have different "good" and "bad" soldiers. Even
though it is protective in myocarditis, for example, interferon-gamma is
known to make multiple sclerosis worse.
Co-authors are Yan Wang, Ziya Kaya
(supported by a fellowship from the Deutsche Herzstiftung e.V.), Elizabeth
Stafford and Malte Dohmen, of the department of pathology at the Johns
Hopkins School of Medicine; and Amir Sadighi Akha, now in the pathology
department at the University of Michigan Medical School.
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