Researchers at the University of Melbourne have discovered that a protein
involved in the progression of Alzheimer's disease also has properties that
could be helpful for human health.
The discovery helps researchers better understand the complicated brain
chemistry behind the development of Alzheimer's disease, a condition that
affects hundreds of thousands of Australians.
An international team of researchers, led by Dr Simon Drew at the
University of Melbourne and Prof Wojciech Bal at the Polish Academy of Sciences,
has revealed that a shorter form of a protein called beta amyloid, may act as a
sponge that safely binds a metal that can damage brain tissue when it's in
excess.
Researchers have been intensely interested in the role of beta-amyloid in
the development of Alzheimer's disease. This is because clumps of the protein
are formed in brains of people with the illness.
In the late 1990s, high levels of copper were discovered within these
clumps. Copper is essential to health, but too much can produce harmful free
radicals. Many scientists began to suspect that this copper might be
contributing to the disease. They found that beta-amyloid can bind to copper
indiscriminately and allow it to produce these damaging free radicals.
Closer analysis of beta amyloid protein has revealed different sizes. A
good proportion of beta amyloid is missing the first three links at the start of
the protein's chain-like structure.
"This short form has been overlooked by most researchers since the
composition of beta amyloid was first identified 30 years ago," Dr Simon Drew
explains.
"We know that the shorter form of beta amyloid is present in the diseased
brain, but we now know that it is abundant in healthy brains as well.
"The small change in length makes a huge difference to its copper binding
properties. We found that the short form of the protein is capable of binding
copper at least 1000 times stronger than the longer forms. It also wraps around
the metal in a way that prevents it from producing free radicals.
"Given these properties and its relative abundance, we can speculate this
type of beta amyloid is protective. It's very different from the current view of
how beta amyloid interacts with biological copper."
So far, therapies aimed at lowering the production of beta amyloid have
shown only a modest ability to slow cognitive decline and the number of people
affected by the Alzheimer's disease continues to grow.
Dr Drew and the team from Poland are now working to develop a method for
identifying the copper-bound form of the short beta amyloid in the body.
This will enable them to screen how much copper it holds in the brain,
whether it safely escorts the copper from one place to another, and how this may
change in aging and disease.
"If a beneficial role in copper balance can be established, it's still
possible to have too much of a good thing," Dr Drew said.
"As the amount of beta amyloid in the brain increases during Alzheimer's
disease, the shorter form can also clump together and this may interfere with
its normal function. Higher levels of the short form may further enable it to
soak up copper from other places where it is needed. It could be a Jekyll and
Hyde scenario."
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