Bruno Voigt scite author profile

Within the complex aggregation process of amyloidogenic peptides into fibrils, early stages of aggregation play a central role and reveal fundamental properties of the underlying mechanism of aggregation. In particular, low-molecularweight aggregates of the Alzheimer amyloid-b peptide (Ab) have attracted increasing interest because of their role in cytotoxicity and neuronal apoptosis, typical of aggregation-related diseases. One of the main techniques used to characterize oligomeric stages is fluorescence spectroscopy. To this end, Ab peptide chains are functionalized with fluorescent tags, often covalently bound to the disordered N-terminus region of the peptide, with the assumption that functionalization and presence of the fluorophore will not modify the process of self-assembly nor the final fibrillar structure. In this investigation, we systematically study the effects of four of the most commonly used fluorophores on the aggregation of Ab (1-40). Time-resolved and single-molecule fluorescence spectroscopy have been chosen to monitor the oligomer populations at different fibrillation times, and transmission electron microscopy, atomic force microscopy and x-ray diffraction to investigate the structure of mature fibrils. Although the structures of the fibrils were only slightly affected by the fluorescent tags, the sizes of the detected oligomeric species varied significantly depending on the chosen fluorophore. In particular, we relate the presence of high-molecular-weight oligomers of Ab (1-40) (as found for the fluorophores HiLyte 647 and Atto 655) to net-attractive, hydrophobic fluorophore-peptide interactions, which are weak in the case of HiLyte 488 and Atto 488. The latter leads for Ab (1-40) to low-molecular-weight oligomers only, which is in contrast to Ab (1-42). The disease-relevant peptide Ab (1-42) displays high-molecular-weight oligomers even in the absence of significant attractive fluorophore-peptide interactions. Hence, our findings reveal the potentially high impact of the properties of fluorophores on transient aggregates, which needs to be included in the interpretation of experimental data of oligomers of fluorescently labeled peptides.

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Probing Polymer Chain Conformation and Fibril Formation of Peptide Conjugates

Evgrafova

Voigt

Baumann

et al. 2018

ChemPhysChem

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Covalent conjugates between a synthetic polymer and a peptide hormone were used to probe the molecular extension of these macromolecules and how the polymer modifies the fibril formation of the hormone. NMR spectroscopy of N labeled parathyroid hormone (PTH) was employed to visualize the conformation of the conjugated synthetic polymer, triggered by small temperature changes via its lower critical solution temperature. A shroud-like polymer conformation dominated the molecular architecture of the conjugated chimeras. PTH readily forms amyloid fibrils, which is probably the physiological storage form of the hormone. The polyacrylate based polymers stimulated the nucleation processes of the peptide.

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β-Turn mimetic synthetic peptides as amyloid-β aggregation inhibitors

Deike

Rothemund²,

Voigt

et al. 2020

Bioorganic Chemistry

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Modulation of amyloid β peptide aggregation by hydrophilic polymers

Evgrafova

Voigt

Roos

et al. 2019

Phys. Chem. Chem. Phys.

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A Detailed Analysis of the Morphology of Fibrils of Selectively Mutated Amyloid β (1–40)

et al. 2016

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A small library of rationally designed amyloid β [Aβ(1-40)] peptide variants is generated, and the morphology of their fibrils is studied. In these molecules, the structurally important hydrophobic contact between phenylalanine 19 (F19) and leucine 34 (L34) is systematically mutated to introduce defined physical forces to act as specific internal constraints on amyloid formation. This Aβ(1-40) peptide library is used to study the fibril morphology of these variants by employing a comprehensive set of biophysical techniques including solution and solid-state NMR spectroscopy, AFM, fluorescence correlation spectroscopy, and XRD. Overall, the findings demonstrate that the introduction of significant local physical perturbations of a crucial early folding contact of Aβ(1-40) only results in minor alterations of the fibrillar morphology. The thermodynamically stable structure of mature Aβ fibrils proves to be relatively robust against the introduction of significantly altered molecular interaction patterns due to point mutations. This underlines that amyloid fibril formation is a highly generic process in protein misfolding that results in the formation of the thermodynamically most stable cross-β structure.

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Bruno Voigt

How Fluorescent Tags Modify Oligomer Size Distributions of the Alzheimer Peptide

Probing Polymer Chain Conformation and Fibril Formation of Peptide Conjugates

β-Turn mimetic synthetic peptides as amyloid-β aggregation inhibitors

Modulation of amyloid β peptide aggregation by hydrophilic polymers

A Detailed Analysis of the Morphology of Fibrils of Selectively Mutated Amyloid β (1–40)

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