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March
7 - Paradoxical Alzheimer's Finding May Shed New Light on
Memory Loss
Do you
remember the seventh song that played on your radio on the
way to work yesterday? Most of us don’t, thanks to a
normal forgetting process that is constantly “cleaning
house” – culling inconsequential information from
our brains. Researchers at the Buck Institute now believe
that this normal memory loss is hyper-activated in Alzheimer’s
disease (AD) and that this effect is key to the profound memory
loss associated with the incurable neurodegenerative disorder.
Last year, this same group of researchers found that they
could completely prevent Alzheimer’s disease in mice
genetically engineered with a human Alzheimer’s gene—“Mouzheimer’s”—by
blocking a single site of cleavage of one molecule, called
APP for amyloid precursor protein. Normally, this site on
APP is attacked by molecular scissors called caspases, but
blocking that process prevented the disease. Now they have
studied human brain tissue and found that, just as expected,
patients suffering from AD clearly show more of this cleavage
process than people of the same age who do not have the disease.
However, when they extended their studies to much younger
people without Alzheimer’s disease, they were astonished
to find an apparent paradox: these younger people displayed
as much as ten times the amount of the same cleavage event
as the AD patients. The researchers now believe they know
why.
The Buck Institute study implicates a biochemical “switch”
associated with that cleavage of APP, causing AD brains to
become stuck in the process of breaking memories, and points
to AD as a syndrome affecting the plasticity or malleability
of the brain. “Young brains operate like Ferraris –
shifting between forward and reverse, making and breaking
memories with a facility that surpasses that of older brains,
which are less plastic,” said Dale Bredesen, MD, Buck
Institute faculty member and leader of the research group.
“We believe that in aging brains, AD occurs when the
‘molecular shifting switch’ gets stuck in the
reverse position, throwing the balance of making and breaking
memories seriously off kilter.”
In previous research, lead author Veronica Galvan, PhD, prevented
this cleavage in mice genetically engineered to develop the
amyloid plaques and deposits associated with AD. These surprising
mice had normal memories and showed no signs of brain shrinkage
or nerve cell damage, despite the fact that their brains were
loaded with the sticky A-beta plaques that are otherwise associated
with Alzheimer’s disease.
“A-beta is produced throughout the brain throughout
life; we believe that it is a normal regulator of the synapses,
the connections between neurons,” said Galvan, who added
that AD, like cancer, is a disease in which imbalanced cell
signaling plays an important role.
“The fact that many people develop A-beta plaques yet
show no symptoms of AD tells us that the downstream signaling
of A-beta—not just A-beta itself—is critical,”
said Bredesen, “and these pathways can be targeted therapeutically.
Simply put, we can restore the balance.” Continuing
research at the Buck Institute focuses on nerve signaling
and efforts to “disconnect” the molecular mechanism
that throws memory-making in the reverse direction, as well
as understanding mechanisms that support brain cell connections
that are crucial to the process of memory making.
Source: Buck Institute for Age Research
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