Early stages of insulin fibrillogenesis examined with ion mobility mass spectrometry and molecular modelling

H Cole; M Porrini; R Morris; T Smith; J Kalapothakis; S Weidt; C L Mackay; C E MacPhee; P E Barran

doi:10.1039/c5an01253h

Early stages of insulin fibrillogenesis examined with ion mobility mass spectrometry and molecular modelling

H Cole, M Porrini, R Morris, T Smith, J Kalapothakis, S Weidt, C L Mackay, C E MacPhee, P E Barran

Research output: Contribution to journal › Article › peer-review

Abstract

A prevalent type of protein misfolding causes the formation of beta-sheet-rich structures known as amyloid fibrils. Research into the mechanisms of fibril formation has implications for both disease prevention and nanoscale templating technologies. This investigation into the aggregation of insulin utilises ion mobility mass spectrometry coupled with molecular modelling to identify and characterise oligomers formed during the 'lag' phase that precedes fibril growth. High resolution mass spectrometry and collision induced dissociation is used to unequivocally assign species as m/z coincident multimers or confomers, providing a robust analytical approach that supports the use of molecular dynamics to atomistically resolve the observed oligomers. We show that insulin oligomerises to form species In where 2

Original language	English
Pages (from-to)	7000-11
Number of pages	6988
Journal	Analyst
Volume	140
Issue number	20
DOIs	https://doi.org/10.1039/c5an01253h
Publication status	Published - 2015

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10.1039/c5an01253h

http://www.ncbi.nlm.nih.gov/pubmed/26369607

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title = "Early stages of insulin fibrillogenesis examined with ion mobility mass spectrometry and molecular modelling",

abstract = "A prevalent type of protein misfolding causes the formation of beta-sheet-rich structures known as amyloid fibrils. Research into the mechanisms of fibril formation has implications for both disease prevention and nanoscale templating technologies. This investigation into the aggregation of insulin utilises ion mobility mass spectrometry coupled with molecular modelling to identify and characterise oligomers formed during the 'lag' phase that precedes fibril growth. High resolution mass spectrometry and collision induced dissociation is used to unequivocally assign species as m/z coincident multimers or confomers, providing a robust analytical approach that supports the use of molecular dynamics to atomistically resolve the observed oligomers. We show that insulin oligomerises to form species In where 2",

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AU - Cole, H

AU - Porrini, M

AU - Morris, R

AU - Smith, T

AU - Kalapothakis, J

AU - Weidt, S

AU - Mackay, C L

AU - MacPhee, C E

AU - Barran, P E

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AB - A prevalent type of protein misfolding causes the formation of beta-sheet-rich structures known as amyloid fibrils. Research into the mechanisms of fibril formation has implications for both disease prevention and nanoscale templating technologies. This investigation into the aggregation of insulin utilises ion mobility mass spectrometry coupled with molecular modelling to identify and characterise oligomers formed during the 'lag' phase that precedes fibril growth. High resolution mass spectrometry and collision induced dissociation is used to unequivocally assign species as m/z coincident multimers or confomers, providing a robust analytical approach that supports the use of molecular dynamics to atomistically resolve the observed oligomers. We show that insulin oligomerises to form species In where 2

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Early stages of insulin fibrillogenesis examined with ion mobility mass spectrometry and molecular modelling

Abstract

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