AGGRESSION-RELATED GENE WEAKENS BRAIN'S IMPULSE CONTROL CIRCUITS

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U.S. Department of Health and Human Services 
NATIONAL INSTITUTES OF HEALTH 
NIH News 
National Institute of Mental Health (NIMH) 
http://www.nimh.nih.gov/ 

EMBARGOED FOR RELEASE: Monday, March 20, 2006; 5:00 p.m. ET 

CONTACT: Jules Asher, NIMH Press Office (NIMHpress@xxxxxxx),
301-443-4536

AGGRESSION-RELATED GENE WEAKENS BRAIN'S IMPULSE CONTROL CIRCUITS

A version of a gene previously linked to impulsive violence appears to
weaken brain circuits that regulate impulses, emotional memory and
thinking in humans, researchers at the National Institutes of Health's
(NIH) National Institute of Mental Health (NIMH) have found. Brain scans
revealed that people with this version -- especially males -- tended to
have relatively smaller emotion-related brain structures, a hyperactive
alarm center and under-active impulse control circuitry. The study
identifies neural mechanisms by which this gene likely contributes to
risk for violent and impulsive behavior through effects on the
developing brain.

NIMH intramural researchers Andreas Meyer-Lindenberg, M.D., Daniel
Weinberger, M.D., Ph.D., and colleagues report on their magnetic
resonance imaging (MRI) study online in the "Proceedings of the National
Academy of Sciences" during the week of March 20, 2006.

"These new findings illustrate the breathtaking power of 'imaging
genomics' to study the brain's workings in a way that helps us to
understand the circuitry underlying diversity in human temperament,"
said NIH Director Elias A. Zerhouni, M.D., who conducted MRI studies
earlier in his career.

"By itself, this gene is likely to contribute only a small amount of
risk in interaction with other genetic and psychosocial influences; it
won't make people violent," explained Meyer-Lindenberg. "But by studying
its effects in a large sample of normal people, we were able to see how
this gene variant biases the brain toward impulsive, aggressive
behavior."

The gene is one of two common versions that code for the enzyme
monoamine oxydase-A (MAO-A), which breaks down key mood-regulating
chemical messengers, most notably serotonin. The previously identified
violence-related, or L, version, contains a different number of
repeating sequences in its genetic code than the other version (H),
likely resulting in lower enzyme activity and hence higher levels of
serotonin. These, in turn, influence how the brain gets wired during
development. The variations may have more impact on males because they
have only one copy of this X-chromosomal gene, while females have two
copies, one of which will be of the H variant in most cases.

Several previous studies had linked increased serotonin during
development with violence and the L version of MAO-A. For example, a
2002 study* by NIMH-funded researchers discovered that the gene's
effects depend on interactions with environmental hard knocks: men with
L were more prone to impulsive violence, but only if they were abused as
children. Meyer-Lindenberg and colleagues set out to discover how this
works at the level of brain circuitry.

Using structural MRI in 97 subjects, they found that those with L showed
reductions in gray matter (neurons and their connections) of about 8
percent in brain structures of a mood-regulating circuit (cingulate
cortex, amygdala) among other areas. Volume of an area important for
motivation and impulse regulation (orbital frontal cortex) was increased
by 14 percent in men only. Although the reasons are unknown, this could
reflect deficient pruning -- the withering of unused neuronal
connections as the brain matures and becomes more efficient, speculates
Meyer-Lindenberg.

The researchers then looked at effects on brain activity using
functional MRI (fMRI) scans. While performing a task matching
emotionally evocative pictures -- angry and fearful faces -- subjects
with L showed higher activity in the fear hub (amygdala). At the same
time, decreased activity was observed in higher brain areas that
regulate the fear hub (cingulate, orbital frontal, and insular cortices)
-- essentially the same circuit that was changed in volume.

While these changes were found in both men and women, two other
experiments revealed gene-related changes in men only. In a task which
required remembering emotionally negative information, men, but not
women, with L had increased reactivity in the fear (amygdala) and memory
(hippocampus) hubs. Men with L were also deficient during a task
requiring them to inhibit a simple motor response; they failed to
activate a part of the brain (cingulate cortex) important for inhibiting
such behavioral impulses. This region was, conspicuously, the cortex
area that was most reduced in volume.

The findings echo those of a 2005 NIMH study** showing how another
serotonin-related gene variant shapes the same mood-regulating circuit.
In this study also, the gene version that boosts serotonin levels
resulted in impaired emotion-related lower brain structures, increased
fear hub activation and a weaker response of its regulatory circuits.
Yet, the effects of the L version of MAO-A were more extensive, perhaps
reflecting the fact that it also impacts another key mood-regulating
neurotransmitter, norepinephrine.

The weakened regulatory circuits in men with L are compounded by
intrinsically weaker connections between the orbital frontal cortex and
amygdala in all men, say the researchers.

"Heightened sensitivity in brain circuits important to cognitive
inhibition and memory for negative emotional information may contribute
to increased vulnerability of men with L exposed to abuse during
childhood," suggested Weinberger. "Since only men showed gene effects in
several of these circuits, this could lead to a situation where multiple
brain control mechanisms are impaired and contribute to manifestly
violent behavior, a kind of genetic double jeopardy."

Also participating in the study were: Joshua Buckholtz, Bhaskar
Kolachana, Ahmad Hariri, Lukas Pezawas, Giuseppe Blasi, Ashley Wabnitz,
Robyn Honea, Beth Verchinski, Joseph Callicott, Michael Egan, and
Venkata Mattay, NIMH Clinical Brain Disorders Branch. 

To view a photo of an MRI scan that shows subjects with the
violence-related version of the MAO-A gene, please visit
http://www.nih.gov/news/pr/mar2006/nimh-20.htm.

NIMH is part of the National Institutes of Health (NIH), the Federal
Government's primary agency for biomedical and behavioral research. NIH
is a component of the U.S. Department of Health and Human Services.

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.
  
-------------------------------------------------
* Caspi A, McClay J, Moffitt TE, Mill J, Martin J, Craig IW, Taylor A,
Poulton R. Role of genotype in the cycle of violence in maltreated
children. "Science". 2002 Aug 2;297(5582):851-4.

** Pezawas L, Meyer-Lindenberg A, Drabant EM, Verchinski BA, Munoz KE,
Kolachana BS, Egan MF, Mattay VS, Hariri AR, Weinberger DR. 5-HTTLPR
polymorphism impacts human cingulate-amygdala interactions: a genetic
susceptibility mechanism for depression. "Nat Neurosci". 2005
Jun;8(6):828-34. Epub 2005 May 8. 
-------------------------------------------------

##
 
This NIH News Release is available online at:
http://www.nih.gov/news/pr/mar2006/nimh-20.htm.

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