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Computer Simulation Shows How Fibrils - Proteins That Cluster in
Diseases - Form
SOURCE: Medical News Today, UK
WWWeb: http://tinyurl.com/5f7et

23 Nov 2004

To get a better look at how proteins gather into clusters called
amyloid fibrils - which are associated with important human diseases
such as Alzheimer's, Parkinson's and the so-called prion diseases
like Mad Cow - researchers at North Carolina State University decided
to make movies.

Dr. Carol Hall, Alcoa Professor of chemical engineering at NC State
and Hung D. Nguyen, a graduate student in Hall's lab, used a computer
simulation technique, discontinuous molecular dynamics, to visualize
the meanderings of small proteins called peptides. Movies of the
simulation show that 96 randomly placed peptides spontaneously
aggregate into what Hall calls a “sandwich” of layered protein
sheets, similar to the amyloid fibrils discovered in diseased people
and animals. Hall says that understanding how fibrils form in human
or animal organs may lead to discoveries of how to slow or halt
fibril formation.

The research was published in the Nov. 16 edition of Proceedings of
the National Academy of Sciences.

It is not known whether fibrils cause Alzheimer's, Parkinson's and
the other so-called amyloid diseases, or whether they are just
associated symptoms. In any event, the fibrils form plaques in human
and animal organs, often the brain. Although it's not clear if these
plaques cause memory loss in Alzheimer's patients, for instance,
scientists are interested in finding out the mechanisms behind the
formation of fibrils.

"All of these diseases - Alzheimer's, Parkinson's, ALS, Huntington's -
 have the same unusual phenomena. Proteins - completely different
proteins in each disease - assemble into ordered aggregates, amyloid
fibrils, so that a vital organ, usually the brain, is crisscrossed by
these structures," Hall said. "This tells us that the problem has
something to do with the general nature of proteins rather than with
the specifics of the particular disease-associated proteins."

Besides studying fibrils in the test tube, researchers would like to
make computer models to view fibril formation. This is not possible
using the traditional atomic-level protein folding simulation
techniques - which follow the motions of every atom on every protein -
 because fibril formation takes a long time.

So Hall and Nguyen developed a less-detailed model of protein
geometry and energetics and applied it to a relatively simple
protein, polyalanine, which had been found to form fibrils in test
tubes. With this approach, the NC State researchers were able to
watch spontaneous fibril formation in about 60 hours on a fast
computer. That's much quicker than atomic-level simulations.

In the simulation movie, 12 to 96 peptides were initially scattered
randomly across the computer screen. When set into motion, the
researchers first saw groups of two to five proteins coming together
and falling apart and eventually forming amorphous clumps that twist
around each other, like a rope. These twisted structures began coming
together, like the ingredients in a sandwich, layered above and below
each other. In the end, the simulation showed a fibril-like structure
with only a few outlying peptides refusing to aggregate.

Hall says her method of reducing the level of detail in her protein
model just to the point where the key features that drive fibril
formation remain and other features are neglected allows her to get a
broad molecular-level picture of the fibril formation process.

Hall's work is sponsored by the National Institutes of Health. She
has recently been funded to attempt computer simulations of fibril
formation by beta amyloids, the peptides that aggregate in
Alzheimer's disease.

- kulikowski -

Note to editors: An abstract of the paper follows.

“Molecular Dynamic Simulations of Spontaneous Fibril Formation By
Random-Coil Peptides”

Authors: Hung D. Nguyen and Dr. Carol Hall, North Carolina State
University
Published: Nov. 16, 2004, in Proceedings of the National Academy of
Sciences

Abstract:
Assembly of normally soluble proteins into amyloid fibrils is a cause
or associated symptom of numerous human disorders, including
Alzheimer's and the prion diseases. We report molecular-level
simulation of spontaneous fibril formation. Systems containing 12-96
model polyalanine peptides form fibrils at temperatures greater than
a critical temperature that decreases with peptide concentration and
exceeds the peptide's folding temperature, consistent with
experimental findings. Formation of small amorphous aggregates
precedes ordered nucleus formation and subsequent rapid fibril growth
through addition of beta-sheets laterally and monomeric peptides at
fibril ends. The fibril's structure is similar to that observed
experimentally.

Contact: Dr. Carol Hall
[log in to unmask]
919-515-3571
North Carolina State University

SOURCE: Medical News Today, UK
WWWeb: http://tinyurl.com/5f7et

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