In most neurodegenerative diseases, misfolded proteins aggregate to form an insoluble clump called amyloid.
Many amyloid-forming proteins, including tau in Alzheimer's disease and alpha-synuclein in Parkinson's disease, contain the amino acid proline, whose unique structure induces a bend in the amino acid chain.
Those bends contribute to stacking of adjacent regions of the protein, thus promoting amyloid formation.
During normal protein folding, CyP40 latches on to prolines, orienting them into their characteristic chain- bending conformation, but like most enzymes, it can also operate in reverse, helping to unbend the chain.
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In a mouse model of an Alzheimer's-like disease, experimental expression of CyP40 preserved brain neurons and rescued cognitive deficits.
The same enzyme also disaggregated alpha-synuclein, an aggregate associated with Parkinson's disease. This is the first time that CyP40 has been shown to disaggregate an amyloid responsible for a neurodegenerative disease.
Exactly how CyP40 reduces aggregation is not yet clear, and researchers provide two possibilities.
The enzyme may bind to aggregated protein and, by reversing the proline bend, help unstack and separate the amino acid chain.
Alternatively, the enzyme may bind to the protein before it forms aggregates, sequestering it and thus preventing it from clumping.
Understanding more about the exact mechanism of the enzyme may help point toward a therapeutic strategy centered on proline's role in amyloid formation.
"The finding that Cyp40 can untangle clumps of tau and alpha-synuclein suggests that it, or one of the more than 40 other human proteins with similar activity, may have a role to play in treating neurodegenerative disease," said Laura Blair, from University of South Florida.