|![[Search]](https://talks.cam.ac.uk/images/search.gif?1209136071)
|![[A-Z Index]](https://talks.cam.ac.uk/images/az.gif?1209136071)
|![[Contact]](https://talks.cam.ac.uk/images/contact.gif?1209136071)
||![[University of Cambridge]](https://talks.cam.ac.uk/images/identifier2.gif?1209136071){kind=small} |
COOKIES: By using this website you agree that we can place Google Analytics Cookies on your device for performance monitoring. | ![[Talks.cam]](https://talks.cam.ac.uk/images/talkslogosmall.gif?1209136071) |
University of Cambridge > Talks.cam > Cambridge Neuroscience Seminars > Copper 2+ binding to Aβ accelerates fiber growth and enhances neurotoxicity.
Copper 2+ binding to Aβ accelerates fiber growth and enhances neurotoxicity.Add to your list(s) Download to your calendar using vCal
If you have a question about this talk, please contact Damian Crowther. Although Cu2+ ions are found concentrated within senile plaques of Alzheimer’s disease patients directly bound to A and in vivo studies have shown that impaired copper homeostasis enhances the toxic effects of A. A role for Cu2+ ions in Alzheimer’s disease (AD) is often disputed, as it is believed that Cu2+ ions have a relatively low affinity for A and promote non-toxic amorphous aggregates of amyloid- (A. In contrast with currently held opinion, we show that Cu2+ ions in fact doubles the rate of production of amyloid fibres, accelerating both the nucleation and elongation of fibre formation. We further show that Cu2+ ions bound to A are consistently more toxic to neuronal cells than A in the absence of Cu2+ ions. The affinity of Cu2+ for A is highly disputed. Our competition studies indicate a dissociation constant of 10-11 M, at pH 7.4, for both fibrillar and monomeric forms. Electron paramagnetic resonance studies (EPR) suggest a dynamic view of the tetragonal Cu2+ complex creating an ensemble of coordination geometries in exchange between each other. An active role for Cu2+ ions in accelerating fibre formation and promoting cell death coupled with the high affinity of Cu2+ for A, suggests impaired copper homeostasis could be a risk factor in Alzheimer’s disease. [1] Substoichiometric Levels of Cu2+ Ions Accelerate the Kinetics of Fiber Formation and Promote Cell Toxicity of Amyloid-β from Alzheimer Disease. Claire J. Sarell, Shane R. Wilkinson and John H. Viles (2010) J Biol Chem 285, 41533-41540. [2] Cu(II) binding to amyloid-beta fibrils of Alzheimer’s Disease reveals a pico-molar affinity. CJ Sarell, CD Syme, SEJ Rigby and Viles JH (2009) Biochemistry 48, 4388-402 [3] Copper binding to the amyloid-beta (Aβ) peptide associated with Alzheimer’s disease. CD Syme, RC Nadal, SEJ Rigby and Viles JH (2004) J Biol Chem. 279, 18169-18177 This talk is part of the Cambridge Neuroscience Seminars series. This talk is included in these lists:
Note that ex-directory lists are not shown. |
Other listsSet Theory Seminar Booking Required - Computing/IT Courses at the CMS Maths Knowledge TransferOther talksAtiyah Floer conjecture Loss and damage: Insights from the front lines in Bangladesh Modelling discontinuities in simulator output using Voronoi tessellations Bringing Personality Theory Back to Life: On Persons-in-Context, Idiographic Strategies, and Lazarus The interpretation of black hole solutions in general relativity “It’s like they’re speaking a different language!” Investigating an accidental resistance to school mathematics reform mTORC1 signaling coordinates different POMC neurons subpopulations to regulate feeding Symplectic topology of K3 surfaces via mirror symmetry Knot Floer homology and algebraic methods Single Cell Seminars (September) Unbiased Estimation of the Eigenvalues of Large Implicit Matrices Panel Discussion: Climate Change Is Now |
John H Viles, Queen Mary, University of London
Thursday 20 October 2011, 14:00-15:00