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EAAC1 protein is the main transporter of cysteine into neurons, providing
vital antioxidant protection
 A study conducted at the San Francisco VA Medical Center has identified a
protein found in both mice and humans that appears to play a key role in
protecting neurons from oxidative stress, a toxic process linked to
neurodegenerative illnesses including Alzheimer's and Parkinson's diseases.
The study, led by Raymond Swanson, MD, chief of neurology and rehabilitation
services at SFVAMC, identified the protein - known as EAAC1 in mice and as
EAAT3 in humans - as the main mechanism through which the amino acid cysteine
is transported into neurons. Cysteine is an essential component of
glutathione, which Swanson terms "the most important antioxidant in the
brain."
It had been thought previously that the main function of the protein was to
remove excess glutamate, a neurotransmitter, from brain cells.
"It's known that neurons don't take up cysteine directly, and it's never been
clear exactly how it gets there," says Swanson, who is also professor and
vice chair of neurology at the University of California, San Francisco. "This
study provides the first evidence that EAAC1 is the mechanism by which
cysteine gets into neurons - and that transporting cysteine is probably its
chief function."
Study findings are currently available in the Advance Online Publication
section of Nature Neuroscience.
Antioxidants such as glutathione provide protection from oxidative stress,
which kills cells through the "uncontrolled reaction of lipids in the cells
with oxygen--basically, burning them out," says Swanson. Since the brain uses
a lot of oxygen and is "chock full of lipids," it is particularly vulnerable
to oxidative stress, he notes.
In the first part of the study, Swanson and his co-authors observed a colony
of mice deficient in the gene responsible for the production of EAAC1 and
compared their behavior with that of a colony of normal, or "wild type,"
mice. They noticed that around the age of 11 months - old age for a mouse -
the gene-deficient mice began to act listlessly, not groom themselves
properly, and exhibit other signs of senility. In contrast, the wild type
mice "looked and acted totally normal," according to Swanson.
Then, in postmortem examination, the researchers found that the brains of the
EACC1-deficient mice had abnormally enlarged ventricles - openings within the
brain that provide a path for cerebrospinal fluid - while the ventricles of
the wild type mice were normal. Enlarged ventricles "also occur in
Alzheimer's patients," Swanson notes.
In addition, it was found that the EAAC1-deficient brains had fewer neurons in
the hippocampus, and that all neurons in the hippocampus and cortex showed
evidence of oxidative stress, unlike in the wild type mice.
The researchers then compared brain slices from younger mice in both groups.
They found that it took ten times less hydrogen peroxide - a powerful oxidant
- to kill slices from the EAAC1-deficient mice than it took to kill slices
from the normal mice. This demonstrated that brains of mice unable to produce
EAAC1 were ten times as vulnerable to oxidative stress as mice with the
ability to produce EAAC1.
The researchers also found that the neurons of the EAAC1-deficient mice
contained lower levels of the antioxidant glutathione compared to those of
the normal mice.
Taken together, these results "support the idea that oxidative stress
contributes to aging" in the brain, a well-known concept that Swanson calls
"appealing," but difficult to prove or disprove. "This certainly adds
credence to the idea," he says.
In the final part of the study, Swanson and his team investigated whether
oxidative stress in EAAC1-deficient mice might be reversible.
For several days, a group of gene-deficient mice were fed N-acetylcysteine, an
oral form of cysteine that is readily taken up by neurons. When their neuron
slices were compared with slices from untreated gene-deficient mice, it was
found that N-acetylcysteine "had completely corrected the biochemical defect"
in their neurons, recounts Swanson. "Their glutathione levels were normal,
their ability to withstand hydrogen peroxide toxicity was normal, and the
oxidants we saw in the neurons in response to oxidative challenges were
normal."
Based on the results of the current study, Swanson and his group are working
to determine whether EAAC1 expression is altered in neurodegenerative
illnesses such as Alzheimer's and Parkinson's diseases. Should this prove to
be the case, says Swanson, then manipulation of EAAC1 levels "might provide a
novel approach" to the treatment of these diseases in the future.

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