Abstract
AbstractThe aggregation of the 11 residue long NACore peptide segment of α-synuclein (68-GAVVTGVTAVA-78) has been investigated using a combination of cryogenic transmission electron microscopy (cryo-TEM), small- and wide-angle X-ray scattering, and spectroscopy techniques. The aqueous peptide solubility is pH dependent, and aggregation was triggered by a pH quench from pH 11.3 to approximately pH 8 or 6, where the average peptide net charge is weakly negative (pH 8), or essentially zero (pH 6). Cryo-TEM shows the presence of long and stiff fibrillar aggregates at both pH, that are built up from β-sheets, as demonstrated by circular dichroism spectroscopy and thioflavin T fluorescence. The fibrils are crystalline, with a wide angle X-ray diffraction pattern that is consistent with a previously determined crystal structure of NACore. Of particular note is the cryo-TEM observation of small globular shaped aggregates, of the order of a few nanometers in size, adsorbed onto the surface of already formed fibrils at pH 6. The fibrillation kinetics is slow, and occurs on the time scale of days. Similarly slow kinetics is observed at both pH, but slightly slower at pH 6, even though the peptide solubility is here expected to be lower. The observation of the small globular shaped aggregates, together with the associated kinetics, could be highly relevant in relation to mechanisms of secondary nucleation and oligomer formation in amyloid systems.
Highlights
Proteins are an essential part of cellular life as they perform a multitude of functions in cells
The morphology of a β-sheet with the lowest free energy is in general a twisted structure, which can be understood on basis of the chiral nature of amino acids (Chothia, 1973; Weatherford and Salemme, 1979)
Many amyloid fibrils have an inherent twist (Chiti and Dobson, 2017; Eisenberg and Sawaya, 2017). This is likely due to that the preferred twist of β-sheets is conserved to some extent even when they assemble into fibrils
Summary
Proteins are an essential part of cellular life as they perform a multitude of functions in cells. Sometimes proteins deviate from the native conformations by misfolding and aggregation, which has been associated with misfunction and diseases. One example of protein aggregation is amyloid formation, which is associated with diseases such as Alzheimer’s disease, Parkinson’s disease, and diabetes mellitus type 2 (Chiti and Dobson, 2017; Eisenberg and Sawaya, 2017). Bacteria and fungi may for example utilize amyloid aggregates in processes such as adhesion to surfaces, cell aggregation, and biofilm formation as well as in lowering of air-water surface tension (Fowler et al, 2007)
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