It
is one of the big scientific mysteries of Alzheimer’s disease: Why do
some people whose brains accumulate the plaques and tangles so strongly
associated with Alzheimer’s not develop the disease?
Now,
a series of studies by Harvard scientists suggests a possible answer,
one that could lead to new treatments if confirmed by other research.
The
memory and thinking problems of Alzheimer’s disease and other dementias
may be related to a failure in the brain’s stress response system, the
new research suggests. If this system is working well, it can protect
the brain from abnormal Alzheimer’s proteins; if it gets derailed, key
areas of the brain start degenerating.
“This
is an extremely important study,” said Li-Huei Tsai, director of the
Picower institute for Learning and Memory at the Massachusetts Institute
of Technology, who was not involved in the research but wrote a
commentary accompanying the study. “This is the first study that is
really starting to provide a plausible pathway to explain why some
people are more vulnerable to Alzheimer’s than other people.”
The research, published on Wednesday
in the journal Nature, focuses on a protein previously thought to act
mostly in the brains of developing fetuses. The scientists found that
the protein also appears to protect neurons in healthy older people from
aging-related stresses. But in people with Alzheimer’s and other
dementias, the protein is sharply depleted in key brain regions.
Experts
said if other scientists can replicate and expand upon the findings,
the role of the protein, called REST, could spur development of new
drugs for dementia, which has so far been virtually impossible to treat.
But they cautioned that much more needs to be determined, including
whether the decline of REST is a cause, or an effect, of brain
deterioration, and whether it is specific enough to neurological
diseases that it could lead to effective therapies.
“You’re
going to see a lot of papers now following up on it,” said Dr. Eric M.
Reiman, executive director of the Banner Alzheimer’s Institute in
Phoenix, who was not involved in the study. “While it’s a preliminary
finding, it raises an avenue that hasn’t been considered before. And if
this provides a handle on which to understand normal brain aging, that
will be great too.”
REST,
a gene regulator that switches off certain genes, is primarily known to
keep fetal neurons in an immature state until they develop to perform
brain functions, said Dr. Bruce A. Yankner, a professor of genetics at
Harvard Medical School and the new study’s lead author. By the time
babies are born, REST becomes inactive, he said, except in some areas
outside the brain like the colon, where it seems to suppress cancer.
While
investigating how different genes in the brain change as people age,
Dr. Yankner’s team was startled to find that REST was the most active
gene regulator in older brains.
“Why
should a fetal gene be coming on in an aging brain?” he wondered. He
hypothesized that it was because in aging, as in birth, brains encounter
great stress, threatening neurons that cannot regenerate if harmed.
His
team discovered that REST appears to switch off genes that promote cell
death, protecting neurons from normal aging processes like energy
decrease, inflammation and oxidative stress.
Analyzing
brains from brain banks and dementia studies, the researchers found
that brains of young adults aged 20 to 35 contained little REST, while
healthy adults between the ages of 73 and 106 had a lot. REST levels
grew the older people got, so long as they did not develop dementia,
suggesting REST is related to longevity.
But
in people with Alzheimer’s, mild cognitive impairment, frontotemporal
dementia and Lewy body dementia, the brain areas affected by these
diseases contained much less REST than healthy brains.
This
was true only in people who actually had memory and thinking problems.
People who remained cognitively healthy, but whose brains had the same
accumulation of amyloid plaques and tau tangles as people with
Alzheimer’s, had three times more REST than dementia sufferers.
REST
levels dropped as symptoms worsened, so people with mild cognitive
impairment had more REST than Alzheimer’s patients. And only key brain
regions were affected. In Alzheimer’s, REST steeply declined in the
prefrontal cortex and hippocampus, areas critical to learning, memory
and planning. Other areas of the brain not involved in Alzheimer’s
showed no REST drop-off.
It
is not yet possible to analyze REST levels in the brains of living
people, and several Alzheimer’s experts said that fact limited what the
new research could prove.
John
Hardy, an Alzheimer’s researcher at University College London,
cautioned in an email that information from post-mortem brains cannot
prove a decline in REST causes dementia because death may produce
unrelated damage to brain cells.
To
probe further, the team conducted what both Dr. Tsai and Dr. Reiman
called a “tour de force” of research, examining REST in mice, roundworms
and cells in the lab.
“We wanted to make sure the story was right,” Dr. Yankner said. “It was difficult to believe at first, to be honest with you.”
Especially
persuasive was that mice genetically engineered to lack REST lost
neurons as they aged in brain areas afflicted in Alzheimer’s.
Dr.
Yankner said REST appears to work by traveling to a neuron’s nucleus
when the brain is stressed. In dementia, though, REST somehow gets
diverted, traveling with toxic dementia-related proteins to another part
of the neuron where it is eventually destroyed.
Experts
said the research, while intriguing, leaves many unanswered questions.
Bradley Wise of the National Institute on Aging’s neuroscience division,
which helped finance the studies, said REST’s role needs further
clarification. “I don’t think you can really say if it’s a cause of
Alzheimer’s or a consequence of Alzheimer’s” yet, he said.
Dr.
Samuel Gandy, an Alzheimer’s researcher at Mount Sinai Medical Center,
wondered if REST figured only in neurodegenerative diseases or in other
diseases too, which could make it difficult to use REST to develop
specific treatments or diagnostic tests for dementia.
“My
ambivalence is, is this really a way that advances our understanding of
the disease or does this just this just tell us this is even more
complicated than we thought?” he said.
Dr.
Yankner’s team is looking at REST in other neurological diseases, like
Parkinson’s. He also has thoughts about a potential treatment, lithium,
which he said appears to stimulate REST function, and is considered
relatively safe.
But
he and other experts said it was too early. “I would hesitate to start
rushing into lithium treatment” unless rigorous studies show it can
forestall dementia, said Dr. John Morris, an Alzheimer’s researcher at
Washington University in St. Louis.
Still,
Dr. Morris said, the REST research the team conducted so far is “very
well done, and certainly helps support this idea that we’ve all tried to
understand about why Alzheimer’s is age-associated and why, while
amyloid is necessary for the development of Alzheimer’s disease, it
certainly is not sufficient.” He added, “There have to be some other
processes and triggers that result in Alzheimer’s.”
Correction: March 19, 2014
Because of an editing error, an earlier version of this article misstated the gender of Dr. Li-Huei Tsai. She is a woman.
Because of an editing error, an earlier version of this article misstated the gender of Dr. Li-Huei Tsai. She is a woman.
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