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Ed. Note: The following is a press
release from the National Institutes of Health.
October 22, 2006 --
A new NIH-funded study shows that
a specific gene variant in humans affects both sensitivity to short-term
(acute) pain in healthy volunteers and the risk of developing chronic pain
after one kind of back surgery. Blocking increased activity of this gene
after nerve injury or inflammation in animals prevented development of
chronic pain.
The gene in this study, GCH1,
codes for an enzyme called GTP cyclohydrolase. The study suggests that
inhibiting GTP cyclohydrolase activity might help to prevent or treat
chronic pain, which affects as many as 50 million people in the United
States. Doctors also may be able to screen people for the gene variant to
predict their risk of chronic post-surgical pain before they undergo
surgery. The results appear in the October 22, 2006, advance online
publication of Nature Medicine.*
"This is a completely new pathway
that contributes to the development of pain," says Clifford J. Woolf, M.D.,
of Massachusetts General Hospital and Harvard Medical School in Boston, who
led the research. "The study shows that we inherit the extent to which we
feel pain, both under normal conditions and after damage to the nervous
system."
Dr. Woolf carried out the study
in collaboration with Mitchell B. Max, M.D., of the National Institute of
Dental and Craniofacial Research (NIDCR) in Bethesda, Maryland, and
colleagues at the National Institute on Alcoholism Abuse and Alcoholism (NIAAA)
and elsewhere. Dr. Woolf's work was funded by the National Institute of
Neurological Disorders and Stroke (NINDS). The research team also received
funding from NIDCR, NIAAA, and other organizations.
The researchers originally
identified GCH1 by preclinical screening for genes that undergo significant
changes in expression after sciatic nerve injury. GCH1 is one of several
genes that code for enzymes needed to produce a chemical called
tetrahydrobiopterin (BH4). Previous studies have shown that BH4 is an
essential ingredient in the process that produces dopamine and several other
nerve-signaling chemicals (neurotransmitters). It also plays other important
roles in the body. However, this study is the first to show that GCH1 and
BH4 play a role in pain.
The investigators tested the
effects of GTP cyclohydrolase and BH4 in several animal models of pain. They
found that rats with neuropathic pain (pain caused by nerve damage) had
greatly increased levels of GCH1 gene activity and BH4, and that injecting a
GTP cyclohydrolase inhibitor called 2,4-diamino-6-hydroxypyrimidine (DAHP)
alleviated hypersensitivity to pain in animal models of both neuropathic
pain and inflammatory pain. In contrast, injecting BH4 greatly increased
pain sensitivity.
Next, the researchers looked for
GCH1 gene variations in people. They found that a specific variant of the
gene, identified by combinations of one-base-pair changes in the DNA called
single nucleotide polymorphisms or SNPs, protected against development of
chronic post-surgical pain in people who had participated in a study of
surgical diskectomy for back pain. About 28 percent of the people in the
surgical study had at least one copy of the pain-protective variant of the
gene (people have two copies of every gene). The researchers found that
people with two copies of the protective version of GCH1 had the lowest risk
of developing chronic pain, while those with just one copy had an
intermediate risk and those with no copies of the variant had the highest
risk.
The researchers then found that
the gene variant also appeared to reduce sensations of acute pain in normal
volunteers, who had been tested by NIH-supported scientists Dr. William
Maixner at the University of North Carolina and Dr. Roger Fillingim at the
University of Florida. Normal volunteers with two copies of the protective
gene variant were less sensitive to temporary pain induced by pressure and
other stimuli than those with one or no copies.
Analysis of blood cells from the
people who had undergone back surgery showed that, under normal conditions,
the amounts of GTP cyclohydrolase and BH4 were not significantly different
in people with and without the gene variant. When the cells were subjected
to a chemical that increases GCH1 gene activity, however, the amount of gene
activity increased much less in people with the pain-protective variant of
the gene than it did in other people.
The variation that affects pain
sensitivity is in a region of the gene that may control when the gene is
switched on. This, coupled with the results of the blood study, makes the
researchers suspect that the protective version of the gene is less likely
to be switched on during stressful conditions such as nerve damage and
inflammation. "We often hear about gene mutations that are harmful, but here
is a mutation that's actually protective," says Dr. Woolf.
The GTP cyclohydrolase inhibitor
used in this study, DAHP, is not very strong and is unlikely to be useful as
a human drug, Dr. Woolf says. Researchers are now looking for other
substances that might work as GTP cyclohydrolase inhibitor drugs in humans.
Screening people for the
pain-protective gene variant could allow doctors to identify people at high
risk of developing chronic pain before they undergo surgery, Dr. Woolf says.
Doctors might then be able to reduce the risk of chronic pain by providing
more aggressive pain relief or choosing less invasive surgical procedures
for people at high risk of chronic pain. Several studies have suggested that
specific pain drugs or combinations of drugs can reduce the risk of chronic
pain after surgery.
Dr. Woolf and his colleagues are
now planning studies to define exactly how GCH1 is switched on by nerve
injury and inflammation and how it regulates pain. They also hope to
identify other gene variants that affect pain sensitivity and the risk of
chronic pain. "We think this gene accounts for some of the inherited
differences in pain, but other genes may also play a role," Dr. Woolf says.
The NINDS, NIDCR, and NIAAA are
components of the National Institutes of Health (NIH) within the Department
of Health and Human Services. The NINDS (http://www.ninds.nih.gov/)
is the nation's primary supporter of biomedical research on the brain and
nervous system. The NIDCR (http://www.nidcr.nih.gov/)
is the nation's leading funder of research on oral, dental, and craniofacial
health. The NIAAA (http://www.niaaa.nih.gov/)
is the primary U.S. agency for conducting and supporting research on the
causes, consequences, prevention, and treatment of alcohol abuse,
alcoholism, and alcohol problems.
The National Institutes of Health
(NIH) -- The Nation's Medical Research Agency -- includes 27 Institutes and
Centers and is a component of the U.S. Department of Health and Human
Services. It is the primary federal agency for conducting and supporting
basic, clinical and translational medical research, and it investigates the
causes, treatments, and cures for both common and rare diseases. For more
information about NIH and its programs, visit
http://www.nih.gov/.
Disclosure: Dr. Woolf has an
equity holding in a company, Solace Pharmaceuticals, which has licensed
technology from the Massachusetts General Hospital related to this research.
*Tegeder I, Costigan M, Griffin
RS, Abele A, Belfer I, Schmidt H, Ehnert C, Nejim J, Marian C, Scholz J, Wu
T, Allchorne A, Diatchenko L, Binshtok AM, Goldman D, Adolph J, Sama S,
Atlas SJ, Carlezon WA, Parsegian A, Lotsch J, Fillingim RB, Maixner W,
Geisslinger G, Max MB, Woolf CJ. "GTP cyclohydrolase and tetrahydrobiopterin
regulate pain sensitivity and persistence." Nature Medicine, Advance Online
Publication, October 22, 2006, doi: 10.1038/nm1490.
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