The Role of Buffers in Wild-Type HEWL Amyloid Fibril Formation Mechanism

Brudar, Sandi; Hribar-Lee, Barbara

doi:10.3390/biom9020065

Cited by 38 publications

(27 citation statements)

References 62 publications

(88 reference statements)

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“…[8,11,33,38] As recently reported by Brudar et al, buffer specific effects can dramatically affect amyloid self-assembly by stabilizing or disrupting the protein native structure, so that comparison of our results to previously described sequences is difficult. [39] Our fluorescence data are in accordance to conclusions of theoretical studies and show a correlation between hydrophobicity and amyloid formation rate. [9a,32] Figure 3e) at a concentration of 3 mM was found, which we explain based on its pronounced hydrophobicity, which is the strongest amount of all here studied phenylalanine derivatives (Figure 4a-b).…”

Section: Thioflavin T Fluorescence Assay For the Detection Of Nfgailsupporting

confidence: 89%

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The Impact of Halogenated Phenylalanine Derivatives on NFGAIL Amyloid Formation

et al. 2020

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The hexapeptide hIAPP 22-27 (NFGAIL) is known as a crucial amyloid core sequence of the human islet amyloid polypeptide (hIAPP) whose aggregates can be used to better understand the wild-type hIAPP's toxicity to β-cell death. In amyloid research, the role of hydrophobic and aromatic-aromatic interactions as potential driving forces during the aggregation process is controversially discussed not only in case of NFGAIL, but also for amyloidogenic peptides in general. We have used halogenation of the aromatic residue as a strategy to modulate hydrophobic and aromatic-aromatic interactions and prepared a library of NFGAIL variants containing fluorinated and iodinated phenylalanine analogues. We used thioflavin T staining, transmission electron microscopy (TEM) and smallangle X-ray scattering (SAXS) to study the impact of side-chain halogenation on NFGAIL amyloid formation kinetics. Our data revealed a synergy between aggregation behavior and hydrophobicity of the phenylalanine residue. This study introduces systematic fluorination as a toolbox to further investigate the nature of the amyloid self-assembly process.

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Section: Thioflavin T Fluorescence Assay For the Detection Of Nfgailsupporting

confidence: 89%

“…]: 10 mM ammonium acetate, pH 7.0) [8,11,33,38] . As recently reported by Brudar et al., buffer specific effects can dramatically affect amyloid self‐assembly by stabilizing or disrupting the protein native structure, so that comparison of our results to previously described sequences is difficult [39] …”

Section: Resultsmentioning

confidence: 82%

The Impact of Halogenated Phenylalanine Derivatives on NFGAIL Amyloid Formation

et al. 2020

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“…The fibrils of this protein also present a high pH dependence with respect to stability [ 155 ]. Proteins such as the Hen-egg lysozyme [ 156 ], the regulatory ATPase variant A (RavA) from E.coli [ 157 ], TTR [ 158 ], serum amyloid A [ 159 ], insulin [ 160 ], and glucagon [ 161 ], among others, have been shown to aggregate at acidic conditions (pH = 2–5), where the transition to a β-sheet structure upon oligomerization and amyloid aggregation was observed. However, other peptides and proteins, such as the designed EASZ model peptide [ 162 ], Ac-Phe-Phe-Cys-NH 2 (Ac-FFC-NH 2 ) [ 61 ] amyloid peptide model, and some peptides from human Pbx-regulating protein-1, have been shown to aggregate to β-sheet structure at basic pHs [ 163 ].…”

Section: Circular Dichroism Makes It Possible To Follow Secondarymentioning

confidence: 99%

Evaluation of Peptide/Protein Self-Assembly and Aggregation by Spectroscopic Methods

2020

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The self-assembly of proteins is an essential process for a variety of cellular functions including cell respiration, mobility and division. On the other hand, protein or peptide misfolding and aggregation is related to the development of Parkinson’s disease and Alzheimer’s disease, among other aggregopathies. As a consequence, significant research efforts are directed towards the understanding of this process. In this review, we are focused on the use of UV-Visible Absorption Spectroscopy, Fluorescence Spectroscopy and Circular Dichroism to evaluate the self-organization of proteins and peptides in solution. These spectroscopic techniques are commonly available in most chemistry and biochemistry research laboratories, and together they are a powerful approach for initial as well as routine evaluation of protein and peptide self-assembly and aggregation under different environmental stimulus. Furthermore, these spectroscopic techniques are even suitable for studying complex systems like those in the food industry or pharmaceutical formulations, providing an overall idea of the folding, self-assembly, and aggregation processes, which is challenging to obtain with high-resolution methods. Here, we compiled and discussed selected examples, together with our results and those that helped us better to understand the process of protein and peptide aggregation. We put particular emphasis on the basic description of the methods as well as on the experimental considerations needed to obtain meaningful information, to help those who are just getting into this exciting area of research. Moreover, this review is particularly useful to those out of the field who would like to improve reproducibility in their cellular and biomedical experiments, especially while working with peptide and protein systems as an external stimulus. Our final aim is to show the power of these low-resolution techniques to improve our understanding of the self-assembly of peptides and proteins and translate this fundamental knowledge in biomedical research or food applications.

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“…[8] The latter comprises not only the peptide and the surface but also the solvent, which often contains a buffer to stabilize the pH of the system. The fact that buffer ions can compete with the peptide/ protein in binding to the surface is well known and investigated, [9][10][11][12][13][14][15][16][17][18][19][20] but to the best of our knowledge this has never been done for single amino acids especially for silica. A rational understanding of peptide or protein interactions with surfaces would benefit greatly from data on the interactions of individual amino acids.…”

Section: Introductionmentioning

confidence: 99%

Buffer Influence on the Amino Acid Silica Interaction

et al. 2020

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Protein-surface interactions are exploited in various processes in life sciences and biotechnology. Many of such processes are performed in presence of a buffer system, which is generally believed to have an influence on the protein-surface interaction but is rarely investigated systematically. Combining experimental and theoretical methodologies, we herein demonstrate the strong influence of the buffer type on protein-surface interactions. Using state of the art chromatographic experiments, we measure the interaction between individual amino acids and silica, as a reference to understand protein-surface interactions. Among all the 20 proteinogenic amino acids studied, we found that arginine (R) and lysine (K) bind most strongly to silica, a finding validated by free energy calculations. We further measured the binding of R and K at different pH in presence of two different buffers, MOPS (3-(N-morpholino)propanesulfonic acid) and TRIS (tris(hydroxymethyl)aminomethane), and find dramatically different behavior. In presence of TRIS, the binding affinity of R/K increases with pH, whereas we observe an opposite trend for MOPS. These results can be understood using a multiscale modelling framework combining molecular dynamics simulation and Langmuir adsorption model. The modelling approach helps to optimize buffer conditions in various fields like biosensors, drug delivery or bio separation engineering prior to the experiment.

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The Role of Buffers in Wild-Type HEWL Amyloid Fibril Formation Mechanism

Cited by 38 publications

References 62 publications

The Impact of Halogenated Phenylalanine Derivatives on NFGAIL Amyloid Formation

The Impact of Halogenated Phenylalanine Derivatives on NFGAIL Amyloid Formation

Evaluation of Peptide/Protein Self-Assembly and Aggregation by Spectroscopic Methods

Buffer Influence on the Amino Acid Silica Interaction

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