Multi-<i>e</i>GO: an<i>in-silico</i>lens to look into protein aggregation kinetics at atomic resolution

Scalone, Emanuele; Broggini, Luca; Visentin, Cristina; Erba, Davide; Toplek, Fran Bačić; Peqini, Kaliroi; Pellegrino, Sara; Ricagno, Stéfano; Paissoni, Cristina; Camilloni, Carlo

doi:10.1101/2022.02.18.481033

Cited by 2 publications

(1 citation statement)

References 83 publications

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“…The number of residues adopting β-Sheet indicates that the β-Sheet length is related to the number of peptides. In short, the probability and the length of β-Sheet increase with the number of peptides (Scalone et al, 2022), and the probability of other secondary structures decreases accordingly.…”

Section: Systemmentioning

confidence: 99%

Exploring the misfolding and self-assembly mechanism of TTR (105–115) peptides by all-atom molecular dynamics simulation

Zhang

Zhu

Yue³

et al. 2022

Front. Mol. Biosci.

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Pathological aggregation of essentially dissociative Transthyretin (TTR) monomers protein, driven by misfolded and self-interaction, is connected with Amyloid Transthyretin amyloidosis (ATTR) disease. The TTR monomers protein contains several fragments that tend to self-aggregate, such as residue 105–115 sequence [TTR (105–115)]. However, the misfolding and aggregation mechanisms of TTR are still unknown. In this study, we explored the misfolding and self-assembly of TTR (105–115) peptides by all-atom molecular dynamics simulation. Our results indicated that the conformation of the two-peptides appears unstable. In the tetramerization and hexamerization simulations, the results are reversed. When the number of peptides increases, the probability and the length of β-Sheet contents increase. Our results show that that the four- and six-peptides both can form β-Barrel intermediates and then aggregate into fibers. The critical nucleation for the formation of fibril should be larger than four-peptides. The interactions between hydrophobic residues I107-L111 play an important role in the formation of stable fibrils at an early stage. Our results on the structural ensembles and early aggregation dynamics of TTR (105–115) will be useful to comprehend the nucleation and fibrillization of TTR (105–115).

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Section: Systemmentioning

confidence: 99%

Exploring the misfolding and self-assembly mechanism of TTR (105–115) peptides by all-atom molecular dynamics simulation

Zhang

Zhu

Yue³

et al. 2022

Front. Mol. Biosci.

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Multi- e GO: An in silico lens to look into protein aggregation kinetics at atomic resolution

Scalone

Broggini

Visentin

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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Protein aggregation into amyloid fibrils is the archetype of aberrant biomolecular self-assembly processes, with more than 50 associated diseases that are mostly uncurable. Understanding aggregation mechanisms is thus of fundamental importance and goes in parallel with the structural characterization of the transient oligomers formed during the process. Oligomers have been proven elusive to high-resolution structural techniques, while the large sizes and long time scales, typical of aggregation processes, have limited the use of computational methods to date. To surmount these limitations, we here present multi- e GO, an atomistic, hybrid structure-based model which, leveraging the knowledge of monomers conformational dynamics and of fibril structures, efficiently captures the essential structural and kinetics aspects of protein aggregation. Multi- e GO molecular dynamics simulations can describe the aggregation kinetics of thousands of monomers. The concentration dependence of the simulated kinetics, as well as the structural features of the resulting fibrils, are in qualitative agreement with in vitro experiments carried out on an amyloidogenic peptide from Transthyretin, a protein responsible for one of the most common cardiac amyloidoses. Multi- e GO simulations allow the formation of primary nuclei in a sea of transient lower-order oligomers to be observed over time and at atomic resolution, following their growth and the subsequent secondary nucleation events, until the maturation of multiple fibrils is achieved. Multi- e GO, combined with the many experimental techniques deployed to study protein aggregation, can provide the structural basis needed to advance the design of molecules targeting amyloidogenic diseases.

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Multi-eGO: anin-silicolens to look into protein aggregation kinetics at atomic resolution

Cited by 2 publications

References 83 publications

Exploring the misfolding and self-assembly mechanism of TTR (105–115) peptides by all-atom molecular dynamics simulation

Exploring the misfolding and self-assembly mechanism of TTR (105–115) peptides by all-atom molecular dynamics simulation

Multi- e GO: An in silico lens to look into protein aggregation kinetics at atomic resolution

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