Aged beta-amyloid is more harmful than normal version!

Scientists have known for years that amyloid fibrils -- harmful, elongated, water-tight rope-like structures -- form in the brains of people with Alzheimer's, and likely hold important clues to the disease. Researchers reported in the journal Nature in 2005 that amyloid fibrils contain proteins that interlock like the teeth of a zipper. The researchers also reported their hypothesis that this dry molecular zipper is in the fibrils that form in Alzheimer's disease, as well as in Parkinson's disease and two dozen other degenerative diseases. Their hypothesis has been supported by recent studies.

Alzheimer's disease, the most common cause of dementia among older adults, is an irreversible, progressive brain disorder that kills brain cells, gradually destroys memory and eventually affects thinking, behavior and the ability to carry out the daily tasks of life. More than 5.5 million Americans, most of whom are over 65, are thought to have dementia caused by Alzheimer's.

The team reports in the journal Nature Communications that the small protein beta amyloid, also known as a peptide, that plays an important role in Alzheimer's has a normal version that may be less harmful than previously thought and an age-damaged version that is more harmful.

The lead author discovered that a specific version of age-modified beta amyloid contains a second molecular zipper not previously known to exist. Proteins live in water, but all the water gets pushed out as the fibril is sealed and zipped up.

What goes wrong with beta amyloid, whose most common forms have 40 or 42 amino acids that are connected like a string of beads on a necklace? The researchers report that with age, the 23rd amino acid can spontaneously form a kink, similar to one in a garden hose. This kinked form is known as isoAsp23. The normal version does not create the stronger second molecular zipper, but the kinked form does.

"Now we know a second water-free zipper can form, and is extremely difficult to pry apart," the author said. "We don't know how to break the zipper."

The normal form of beta amyloid has six water molecules that prevent the formation of a tight zipper, but the kink ejects these water molecules, allowing the zipper to form.

Both wild-type and L-isoAsp23 protofilaments adopt β-helix-like folds with tightly packed cores, resembling the cores of full-length fibrillar Aβ structures, and both self-associate through two distinct interfaces. One of these is a unique Aβ interface strengthened by the isoaspartyl modification.

Powder diffraction patterns suggest a similar structure may be adopted by protofilaments of an analogous segment containing the heritable Iowa mutation, Asp23Asn. Consistent with its early onset phenotype in patients, Asp23Asn accelerates aggregation of Aβ 20–34, as does the L-isoAsp23 modification.

These structures suggest that the enhanced amyloidogenicity of the modified Aβ segments may also reduce the concentration required to achieve nucleation and therefore help spur the pathogenesis of AD.
Why does beta amyloid's 23rd amino acid sometimes form this dangerous kink?

The author thinks the kinks in this amino acid form throughout our lives, but we have a protein repair enzyme that fixes them.

"As we get older, maybe the repair enzyme misses the repair once or twice," the author said. "The repair enzyme might be 99.9% effective, but over 60 years or more, the kinks eventually build up. If not repaired or if degraded in time, the kink can spread to virtually every neuron and can do tremendous damage."

"The good news is that knowing what the problem is, we can think about ways to solve it," the author added. "This kinked amino acid is where we want to look."

The research offers clues to pharmaceutical companies, which could develop ways to prevent formation of the kink or get the repair enzyme to work better; or by designing a cap that would prevent fibrils from growing.

The author said beta amyloid and a much larger protein tau -- with more than 750 amino acids -- make a devastating one-two punch that forms fibrils and spreads them to many neurons throughout the brain. All humans have both beta amyloid and tau. Researchers say it appears that beta amyloid produces fibrils that can lead to tau aggregates, which can spread the toxicity to other brain cells. However, exactly how beta amyloid and tau work together to kill neurons is not yet known.

In this study, the authors produced crystals, both the normal and kinked types, in 15 of beta amyloid's amino acids. They used a modified type of cryo-electron microscopy to analyze the crystals. Cryo-electron microscopy, enables scientists to see large biomolecules in extraordinary detail.

http://newsroom.ucla.edu/releases/alzheimers-brains-beta-amyloids