James M. Flink scite author profile

Although amyloid fibrillation is generally believed to be a nucleation-dependent process, the nuclei are largely structurally uncharacterized. This is in part due to the inherent experimental challenge associated with structural descriptions of individual components in a dynamic multi-component equilibrium. There are indications that oligomeric aggregated precursors of fibrillation, and not mature fibrils, are the main cause of cytotoxicity in amyloid disease. This further emphasizes the importance of characterizing early fibrillation events. Here we present a kinetic x-ray solution scattering study of insulin fibrillation, revealing three major components: insulin monomers, mature fibrils, and an oligomeric species. Low-resolution three-dimensional structures are determined for the fibril repeating unit and for the oligomer, the latter being a helical unit composed of five to six insulin monomers. This helical oligomer is likely to be a structural nucleus, which accumulates above the supercritical concentration used in our experiments. The growth rate of the fibrils is proportional to the amount of the helical oligomer present in solution, suggesting that these oligomers elongate the fibrils. Hence, the structural nucleus and elongating unit in insulin amyloid fibrillation may be the same structural component above supercritical concentrations. A novel elongation pathway of insulin amyloid fibrils is proposed, based on the shape and size of the fibrillation precursor. The distinct helical oligomer described in this study defines a conceptually new basis of structure-based drug design against amyloid diseases.

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Study on the binding of Thioflavin T to β-sheet-rich and non-β-sheet cavities

Groenning

Olsen

Weert

et al. 2007

Journal of Structural Biology

236

244

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Binding mode of Thioflavin T in insulin amyloid fibrils

Groenning

Norrman

Flink

et al. 2007

Journal of Structural Biology

206

220

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Osmotic Concentration of Fruit Slices Prior to Freeze Dehydration

Hawkes

Flink

1978

J Food Processing Preservation

253

157

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Organoleptic quality of freeze‐dried foods can be improved by increasing the solids content of the food material to levels of 25–35%. This also results in a reduction of the water load to the freeze‐drier, which greatly improves the economics of the process. For solid foods, such as fruit slices, the increase in solids concentration is achievable by an osmosis process. Sucrose has generally been the solute of choice, but economic considerations are indicating that the suitability of new osmosis solutes should be evaluated. Several mixed osmosis solutes were evaluated for their effectiveness in concentrating apple slices prior to freeze‐drying. Kinetics of water loss and solute uptake were determined for solutions of differing composition and concentration. Several of the osmotically preconcentrated freeze‐dried apple slices were evaluated for organoleptic acceptability.

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James M. Flink

The Changing Face of Glucagon Fibrillation: Structural Polymorphism and Conformational Imprinting

A Helical Structural Nucleus Is the Primary Elongating Unit of Insulin Amyloid Fibrils

Study on the binding of Thioflavin T to β-sheet-rich and non-β-sheet cavities

Binding mode of Thioflavin T in insulin amyloid fibrils

Osmotic Concentration of Fruit Slices Prior to Freeze Dehydration

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