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A Single-Molecule Technology for Resolving Chaperone Action in Neurodegenerative Diseases

Projektbeschreibung

Die Rolle von Chaperonen bei neurodegenerativen Erkrankungen

Molekulare Chaperone sind Proteine, die an der Faltung und Entfaltung von Molekülen, einschließlich von Proteinen, beteiligt sind. Diese Chaperone können der Bildung von Proteinaggregaten, die zum Beispiel bei Erkrankungen wie Alzheimer und Parkinson vorkommen, entgegenwirken. Doch wie das genau geschieht, ist bisher weitgehend ungeklärt. Hauptziel des EU-finanzierten Projektes MicroSPARK ist es daher, den Mechanismus zu entschlüsseln, durch den Chaperone amyloidogene Proteinspezies aufspüren und zerlegen können. Mittels Einzelmolekülfluoreszenzspektroskopie wird das Projektteam einzelne Chaperon-Aggregat-Komplexe analysieren, um die genaue Wirkweise der Chaperone zu erforschen. Die Ergebnisse werden den Weg zur Entwicklung von neuen niedermolekularen Modulatoren der Chaperonaktivität bei neurodegenerativen Erkrankungen ebnen.

Ziel

A range of debilitating neurodegenerative disorders, including Alzheimer’s and Parkinson’s diseases, arise from the formation of amyloidogenic protein aggregates. Molecular chaperones can counteract aggregate formation, but their molecular action mechanisms remain poorly understood. This is chiefly due to the fundamental challenge of resolving heterogeneous and dynamic aggregating protein species in the presence of chaperones. In order to address this challenge and to advance our knowledge of chaperone action, I propose establishing µSPARK, a novel technology that will allow, for the first time, the unravelling of the detailed microscopic mechanisms by which chaperones target and disassemble amyloidogenic protein species in heterogeneous mixtures at the single-molecule level. These new insights will become possible through the first-time combination and seamless integration of two advanced technologies: (i) Miniaturized fluidic sorting devices and (ii) single-molecule fluorescence spectroscopy combined with three-colour coincidence detection. This will enable high-throughput single-particle interrogation of individual chaperone–aggregate complexes providing fundamentally new means for understanding key aspects of chaperone function. To demonstrate the new possibilities, µSPARK will be exploited to unravel the action mechanisms of heat-shock proteins in curtailing amyloid-β peptide and α-synuclein aggregation. This will provide new insights into proteostatic regulatory mechanisms in Alzheimer’s and Parkinson’s disease. The µSPARK technology will then be exploited to dissect—with high throughput and single-particle resolution—the molecular action mechanisms of small-molecule modulators that promote the inhibitory function of chaperones on protein aggregation. This will allow identifying new strategies to ameliorate aggregate toxicity and will pave the way for µSPARK to become a novel screening tool for drug development.

Koordinator

THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE
Netto-EU-Beitrag
€ 212 933,76
Adresse
TRINITY LANE THE OLD SCHOOLS
CB2 1TN Cambridge
Vereinigtes Königreich

Auf der Karte ansehen

Region
East of England East Anglia Cambridgeshire CC
Aktivitätstyp
Higher or Secondary Education Establishments
Links
Gesamtkosten
€ 212 933,76