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Fluorescent fusion proteins as probes to characterize tau fibril polymorphismLindberg, Max January 2019 (has links)
Alzheimer's disease (AD) is a large and growing problem and while we today lack a full understanding of this disease, we know that the protein tau and the amyloid fibrils it forms play a central role in its development. We also know that these fibrils can have different morphologies in different diseases and that fibrils produced in vitro not necessarily adopt any of the morphologies found in patients. This means there is a need for more pathologically relevant fibrils in vitro to be able to understand this disease better. One approach to satisfy this need is to use fibrils found in patients as seeds and thus transfer their morphology to recombinantly purified protein. To facilitate this process this study has attempted to develop a way to differentiate between different fibril morphologies using a FRET based system. This involves fluorescent fusion proteins (tau-EXFPs) and fluorescent amyloid probes as well as seeding experiments with pseudo wild type tau (PWT) and tau with the P301L mutation. Greater differences in terms of fibrillation rates and ThT fluorescence between PWT and P301L was shown than previously reported between WT and P301L. They were also shown to differ in fibril morphology in TEM. The ThT fluorescence intensity was to a certain degree transferable from PWT to P301L by seeding. Furthermore, this study confirms that the tau-EXFP fusion protein can be incorporated into amyloid fibrils and strongly suggests that a FRET effect between EXFP and BTD14 (as well as X34 and ThT) can be achieved. It also demonstrates differences in FRET efficiency between PWT and P301L fibrils using FLIM. These results indicate that a FRET based approach could be a useful method to discern different fibril morphologies from each other, but further measurements and optimization are needed before this method could be reliably applied. The fusion proteins could also be used to investigate tau spreading in vivo, e.g. in D. melanogaster. To find suitable FRET partners to the fusion proteins, a ligand screen was conducted. This could be used as an alternative to the FRET method. With the right selection of fluorescent amyloid probes, a unique fingerprint for each fibril morphology could maybe be generated and fulfill the same intended function as the FRET method.
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