For over a decade, much research has focused on determining which form of protein aggregate is the most important in mediating cell degeneration (‘small oligomers’ or ‘mature amyloid fibrils’) in these debilitating diseases.
The team of interdisciplinary scientists encompassing the biomedical, neuro, and nanosciences, all of whom are based at Trinity College Dublin, adopted a “neutral territory” approach by comparing the effects of these two forms of a non-disease-related protein.
They made their comparisons in cells and animal models, and via experiments that studied electrical ‘brainwave’ responses in these cells.
They showed that both forms killed cells and impacted on potential memory processes in a similar way to specific proteins such as beta amyloid (Alzheimer’s), alpha-synuclein (Parkinson’s), huntingtin (Huntington’s) and prions (Creutzfeld Jakob) – despite the protein aggregates coming from a non-harmful hen egg protein called lysozyme.
Associate Professor in Biochemistry at Trinity, Dr Kenneth Hun Mok, led the study that will be published in print in the Journal of Biological Chemistry on Friday November 20. An early-version (paper in press) can be viewed here.
Dr Mok said: “It is really surprising that both forms of the protein aggregates operated in a similar way to the neurodegenerative-disease-related proteins. Their toxic effects, which included cell death, came about via different mechanisms, but the big news here is that the mere presence of these protein aggregates seems to endow them with the properties that are so damaging to brain cells – it is a surprise that a non-harmful protein like lysozyme can have such an effect.”
“In addition, we have shown that – rather than one or the other – both the oligomeric and mature fibril forms are clearly toxic, providing an answer to a topic that had been debated for many years.”
“Scientists all across the world, including many here at Trinity, are tirelessly working to develop drug candidates that will prevent such protein aggregation from occurring. It is hoped that preventing or reversing this process will turn the tide in the fight against these debilitating neurodegenerative diseases.”
Along with several young researchers including Níal Harte and Igor Klyubin, Dr Mok collaborated with Professor of Neuropharmacology, Michael J Rowan, Professor in Chemistry, Principal Investigator in CRANN and Dean of Research, John Boland, and Associate Professor in Neuroscience, Gavin Davey, to complete the research.
An early version of the paper in press can be viewed here.
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