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Brain activity, drugs could affect Alzheimer's progression
The activity of connections among brain cells significantly
affects levels of the toxic protein beta-amyloid (Aß) that
is a major cause of Alzheimer's disease (AD), researchers
have found. Aß is produced by the cleavage of amyloid
precursor protein (APP) within brain cells.
Findings suggest that the kind of mental activity people
practice or drugs they might take for depression or anxiety
could affect their AD risk or the disease progression.
In an article in the December 22, 2005, issue of Neuron,
David Holtzman and colleagues detailed studies in which they
determined how neuronal activity affected the level of Aß in
the "interstitial fluid" (ISF) between cells. The brain
damage of AD is caused in considerable part by high levels
of Aß in the ISF, where it aggregates into the
brain-clogging plaque that kills brain cells.
In studies with mice, they found that stimulating brain cells
while sampling ISF revealed a significant increase in Aß
levels. Conversely, when they administered drugs that
blocked neuronal activity, Aß levels dropped.
Their studies also revealed that Aß appeared to be released
from the same kinds of sac-like vesicles in neurons that
transport the chemical signals called neurotransmitters that
one neuron uses to triggers a nerve impulse in its neighbor.
Such vesicles launch their cargoes across the connections
called synapses between neurons.
One important question arising from their findings, noted the
researchers, is the effect of cognitive activity--such as
that produced by an enriched environment--on Aß levels. Both
animal and human studies have suggested that such activity
affects Aß plaque levels.
"One hypothesis is that enrichment may increase overall
synaptic activity in some brain regions and decrease it in
others, depending on the environmental alteration," wrote
Holtzman and his colleagues. "For example, certain memory
tasks in humans simultaneously increase and decrease
activity within different brain areas. Increased activity
might result in increased susceptibility to Aß deposition if
the activated neural circuits contain high levels of human
APP expression, thereby increasing Aß release from those
pathways. Conversely, if synaptic activity decreases in a
brain area that is normally vulnerable to Aß pathology, then
there may be reduced Aß deposition as a consequence of
enrichment," they wrote.
Overall, the researchers concluded that "these findings are
consistent with the possibility that physical and
environmental changes resulting in altered neuronal/synaptic
activity throughout life can modulate the amount of Aß that
accumulates in plaques in a region-dependent manner.
"That synaptic activity and Aß levels are directly linked in
vivo may have important treatment implications," they wrote.
"Drugs used to treat neuropsychiatric disorders, such as
depression or anxiety, among many others, directly influence
neurotransmitters, and their receptors, thereby altering
synaptic activity," they wrote. "Thus, it is likely that
these drugs might influence Aß levels within specified
neuronal networks as well. If so, such drugs could
potentially influence risk or progression of AD.
Understanding the effects of drugs on ISF Aß may enable the
design of ways to decrease soluble Aß levels, including
synaptotoxic Aß oligomers, in specific brain regions.
"Defining the relationship between normal brain function and
the metabolism of a key protein involved in a
neurodegenerative disease may provide new clues into the
factors that regulate the biology of AD as well as other
disorders of the nervous system," they wrote.