MIRRAGGE – Minimum Information Required for Reproducible AGGregation Experiments

Reports on phase separation and amyloid formation for multiple proteins and aggregation-prone peptides are recurrently used to explore the molecular mechanisms associated with several human diseases. The information conveyed by these reports can be used directly in translational investigation, e.g., for the design of better drug screening strategies, or be compiled in databases for benchmarking novel aggregation-predicting algorithms. Given that minute protocol variations determine different outcomes of protein aggregation assays, there is a strong urge for standardized descriptions of the different types of aggregates and the detailed methods used in their production. In an attempt to address this need, we assembled the Minimum Information Required for Reproducible Aggregation Experiments (MIRRAGGE) guidelines, considering first-principles and the established literature on protein self-assembly and aggregation. This consensus information aims to cover the major and subtle determinants of experimental reproducibility while avoiding excessive technical details that are of limited practical interest for non-specialized users. The MIRRAGGE table (template available in Supplementary Information) is useful as a guide for the design of new studies and as a checklist during submission of experimental reports for publication. Full disclosure of relevant information also enables other researchers to reproduce results correctly and facilitates systematic data deposition into curated databases.This work was supported by (i) the European Regional Development Fund (ERDF) through the COMPETE 2020—Operacional Programme for Competitiveness and Internationalisation (POCI), Portugal 2020, and by Portuguese funds through FCT—Fundação para a Ciência e a Tecnologia (FCT/MCTES) in the framework of grants POCI-01-0145-FEDER-031173, POCI-01-0145-FEDER-007274, POCI-01-0145-FEDER-031323 (“Institute for Research and Innovation in Health Sciences”), UID/Multi/04046/2013 (BioISI) and PTDC/NEUNMC/2138/2014 (to CMG). SV was funded by the Spanish Ministry of Economy and Competitiveness (BIO2016-78310-R) and by ICREA (ICREA-Academia 2015). ZG and ZB were funded by Slovak research agentures VEGA 02/0145/17, 02/0030/18 and APVV-18-0284. RS was funded by VEGA 02/0163/19. DEO was funded by the Lundbeck Foundation (grant no. R276-2018-671) and the Independent Research Foundation Denmark | Natural Sciences (grant no. 8021-00208B). AP research was supported by UK Dementia Research Institute (RE1 3556) and by ARUK (ARUK-PG2019B-020)

Presence of Magnetic Fluids Leads to the Inhibition of Insulin Amyloid Aggregation

Insulin amyloid aggregation caused serious problems in the treatment of diabetes by insulin injection or by insulin pumps. In vitro formation of insulin amyloid fibrils was investigated in presence of several types of magnetic fluids. Interaction of magnetic fluids with insulin amyloid aggregates led to decrease of insulin fibrillization. The inhibiting activities are affected by coating layer of studied magnetic fluids as well as by their physical properties (diameter, concentration of magnetic particles). The highest inhibiting efficiencies were detected for sterically stabilized magnetic fluids in saline solution (75%) and for magnetic fluids modified by dextran (80%)

Structure-activity relationship of acridine derivatives to amyloid aggregation of lysozyme

Background: Amyloid-related diseases (such as Alzheimer's disease or diabetes type II) are associated with self-assembly of protein into amyloid aggregates. Methods: Spectroscopic and atomic force microscopy were used to determine the ability of acridines to affect amyloid aggregation of lysozyme. Results: We have studied the effect of acridine derivatives on the amyloid aggregation of lysozyme to investigate the acridine structure-activity relationship. The activity of the effective planar acridines was characterized by the half-maximum depolymerization concentration DC(50) and half-maximal inhibition concentration IC(50). For the most effective acridine derivatives we examined their interaction with DNA and their effect on cell viability in order to investigate their eventual influence on cells. We thus identified planar acridine derivatives with intensive anti-amyloid activity (IC(50) and DC(50) values in micromolar range), low cytotoxicity and weak ability to interfere with the processes in the cell. Conclusions: Our findings indicate that both the planarity and the tautomerism of the 9-aminoacridine core together with the reactive nucleophilic thiosemicarbazide substitution play an important role in the anti-amyloid activities of studied derivatives. General significance: The present findings favor the application of the selected active planar acridines in the treatment of amyloid-related diseases