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Alzheimer's, Parkinson's, Type II Diabetes Are Similar At The Molecular
Level
Science Daily - Alzheimer's disease, Parkinson's disease, type II diabetes,
the human version of mad cow disease and other degenerative diseases are
more closely related at the molecular level than many scientists realized,
an international team of chemists and molecular biologists reported April 29
in the online version of the journal Nature.
A montage of 100 microcrystals of protein fragments derived from amyloid
fibrils. To provide scale, the image of a U.S. dime is superimposed.
(Credit: UCLA)
Harmful rope-like structures known as amyloid fibrils, which are linked
protein molecules that form in the brains of patients with these diseases,
contain a stack of water-tight "molecular zippers," the scientists report.
"We have shown that the fibrils have a common atomic-level structure," said
David Eisenberg, director of the UCLA-Department of Energy Institute of
Genomics and Proteomics, a Howard Hughes Medical Institute investigator and
a member of the research team. "All of these diseases are similar at the
molecular level; all of them have a dry steric zipper. With each disease, a
different protein transforms into amyloid fibrils, but the proteins are very
similar at the atomic level."
The research, while still preliminary, could help scientists develop tools
for diagnosing these diseases and, potentially, for treating them through
"structure-based drug design," said Eisenberg, a UCLA professor of chemistry
and molecular biology.
The researchers, including scientists with the European Synchrotron
Radiation Facility in Grenoble, France, report 11 new three-dimensional
atomic protein structures, including those for both of the main proteins
that form amyloid fibrils in Alzheimer's disease.
"It has been a joy to see so many new structures," said Michael Sawaya, a
research scientist with UCLA and the Howard Hughes Medical Institute and a
member of the team. "Each one is like a Christmas present. Now that we have
so many of these that we can classify, I am thrilled to see each
three-dimensional arrangement of atoms, what the structural similarities and
differences are, and which of the differences are significant. We see many
similarities, but there are details that are different. As we study more
structures, we expect to determine the common features among them.
"It is clear from the positions of the atoms where the zipper is," Sawaya
added. "Like pieces in a jigsaw puzzle, they have to fit together just
right. We are finding out how they fit together. We don't yet know all the
ways of forming the zippers; we are working to fill in the missing pieces
and are hopeful of doing so. Thanks to our colleagues in Grenoble and
Copenhagen, technology is not limiting us."
In an earlier Nature paper (June 9, 2005), Eisenberg and his colleagues
reported the three-dimensional structure of an amyloid-like protein from
yeast that revealed the surprising molecular zipper.
"In 2005, we were like prospectors who found flakes of gold in a stream,"
Eisenberg said. "Now we see the real nuggets. In this paper, we present
atomic-level structures for crystals related to fibrils from proteins
associated with numerous human diseases."
The research shows that very short segments of proteins are involved in
forming amyloid fibrils; Eisenberg and his colleagues know some of the
segments. Knowing the segments makes it easier to design tests to detect
whether a new drug is effective, Eisenberg noted. Several proteins contain
more than one amyloid fibril-forming segment.
"It's exciting how rapidly this work is progressing," said Rebecca Nelson, a
UCLA senior postdoctoral fellow with the UCLA-DOE Institute of Genomics and
Proteomics and a member of the team. "Once we formed the collaboration with
the scientists in France to use the European Synchrotron Radiation Facility,
everything became easier."
Nelson describes the proteins associated with Alzheimer's and other amyloid
fibril diseases as "transformer" proteins that instead of doing their normal
work start forming pathological fibril structures.
Eisenberg's research team used a sophisticated computer algorithm to analyze
proteins known to be associated with human diseases. Magdalena Ivanova, a
senior research scientist, found that when the computer algorithm says a
protein will form an amyloid fibril, the protein almost always does.
While the molecular zipper is very similar in all cases, there are
differences, which are cataloged in this Nature paper. For example, while
the amyloid fibrils are all characterized by a "cross-beta X-ray diffraction
pattern" in a small section of the protein that the scientists call the
spine, and there are always two sheets, the sheets can be face to face, or
face to back.
If the molecular zipper is universal in amyloid fibrils, as Eisenberg
believes, is it possible to pry open the zipper or prevent its formation?
Melinda Balbirnie, a UCLA postdoctoral scholar and a member of the research
team, is able to produce fibrils and has developed a test, using a wide
variety of chemical compounds, to determine whether the fibrils break up.
She is "hopeful" her strategy will succeed in breaking up the fibrils.
A mystery on which the new Nature paper sheds light is what causes different
strains of prions (infectious proteins) in which the protein sequence is
identical.
"Our research gives a strong hypothesis that the origin of prion strains is
encoded in the packing of the molecules in the fibrils which we are seeing
in the crystals," Ivanova said.
The research unfolded over nearly a decade. A key breakthrough occurred when
the UCLA team began working closely with Christian Riekel, a distinguished
scientist at the European Synchrotron Radiation Facility in Grenoble,
France, who studies the crystal structures of small-scale molecules with an
X-ray microcrystallography instrument, and Anders Madsen, Riekel's former
graduate student, who is now with the University of Copenhagen in Denmark.
Riekel invented ways to get a fine beam of X-rays to bombard microcrystals.
He and Madsen were able to collect valuable diffraction data.
"It has been a great international collaboration," Eisenberg said.
Co-authors on the research, in addition to Riekel and Madsen, are Shilpa
Sambashivan, a recent graduate student in Eisenberg's laboratory who is now
a postdoctoral fellow at Stanford University; UCLA graduate students Stuart
Sievers, Marcin Apostol, Jed Wiltzius and Heather McFarlane, all members of
Eisenberg's laboratory; and Michael J. Thompson, a former postdoctoral
scientist in the laboratory;
"We could not have done this long-term research without substantial funding
and are very grateful to the Howard Hughes Medical Institute, the National
Institutes of Health and the National Science Foundation for supporting our
research," Eisenberg said.
Note: This story has been adapted from a news release issued by UCLA.

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