Advanced computational approaches to understand protein aggregation

Ghosh, Deepshikha; Biswas, Anushka; Radhakrishna, Mithun

doi:10.1063/5.0180691

Cited by 2 publications

(1 citation statement)

References 452 publications

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“…They mostly consist of the same polypeptide (so are sometimes considered a useful means of recombinant protein purification) but can certainly entrap other proteins via non-covalent interactions [245,248] This contrasts with the type of ordered self-organisation seen in amyloid fibrils where multiple copies of the same protein also come together but into much more regular or structured shapes (e.g. [61,76,77,[249][250][251][252][253][254]). The hallmark is one of various parallel or antiparallel cross-β sheet motifs [46, [255][256][257][258] that run perpendicular to the fibril axis.…”

Section: Inclusion Bodies Compared With the Growth And Aggregation Of...mentioning

confidence: 99%

Proteomic evidence for amyloidogenic cross-seeding in fibrinaloid microclots

Kell,

Pretorius

2024

Preprint

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In classical amyloidoses, amyloid fibres form through the nucleation and accretion of protein monomers, with protofibrils and fibrils exhibiting a cross-β motif of parallel or antiparallel β-sheets oriented perpendicular to the fibre direction. These protofibrils and fibrils can intertwine to form mature amyloid fibres. Similar phenomena occur in blood from individuals with circulating inflammatory molecules (also those originating from viruses and bacteria). In the presence of inflammagens, pathological clotting can occur, that results in an anomalous amyloid form termed fibrinaloid microclots. Previous proteomic analyses of these microclots have shown the presence of non-fibrin(ogen) proteins, suggesting a more complex mechanism than simple entrapment. We provide evidence against a simple entrapment model, noting that clot pores are too large and centrifugation would have removed weakly bound proteins. Instead, we explore whether co-aggregation into amyloid fibres may involve axial (multiple proteins within the same fibril), lateral (single-protein fibrils contributing to a fibre), or both types of integration. Our analysis of proteomic data from fibrinaloid microclots in different diseases shows no significant overlap with the normal plasma proteome and no correlation between plasma protein abundance and presence in microclots. Notably, abundant plasma proteins like α-2-macroglobulin, fibronectin, and transthyretin are absent from microclots, while less abundant proteins such as adiponectin, periostin, and von Willebrand Factor are well represented. Using bioinformatic tools including AmyloGram and AnuPP, we found that proteins entrapped in fibrinaloid microclots exhibit high amyloidogenic tendencies, suggesting their integration as cross-β elements into amyloid structures. This integration likely contributes to the microclots’ resistance to proteolysis. Our findings underscore the role of cross-seeding in fibrinaloid microclot formation and highlight the need for further investigation into their structural properties and implications in thrombotic and amyloid diseases. These insights provide a foundation for developing novel diagnostic and therapeutic strategies targeting amyloidogenic cross-seeding in blood clotting disorders.

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Section: Inclusion Bodies Compared With the Growth And Aggregation Of...mentioning

confidence: 99%

Proteomic evidence for amyloidogenic cross-seeding in fibrinaloid microclots

Kell,

Pretorius

2024

Preprint

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Utilizing Molecular Dynamics Simulations, Machine Learning, Cryo-EM, and NMR Spectroscopy to Predict and Validate Protein Dynamics

Son,

Kim,

Park

et al. 2024

IJMS

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Protein dynamics play a crucial role in biological function, encompassing motions ranging from atomic vibrations to large-scale conformational changes. Recent advancements in experimental techniques, computational methods, and artificial intelligence have revolutionized our understanding of protein dynamics. Nuclear magnetic resonance spectroscopy provides atomic-resolution insights, while molecular dynamics simulations offer detailed trajectories of protein motions. Computational methods applied to X-ray crystallography and cryo-electron microscopy (cryo-EM) have enabled the exploration of protein dynamics, capturing conformational ensembles that were previously unattainable. The integration of machine learning, exemplified by AlphaFold2, has accelerated structure prediction and dynamics analysis. These approaches have revealed the importance of protein dynamics in allosteric regulation, enzyme catalysis, and intrinsically disordered proteins. The shift towards ensemble representations of protein structures and the application of single-molecule techniques have further enhanced our ability to capture the dynamic nature of proteins. Understanding protein dynamics is essential for elucidating biological mechanisms, designing drugs, and developing novel biocatalysts, marking a significant paradigm shift in structural biology and drug discovery.

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Advanced computational approaches to understand protein aggregation

Cited by 2 publications

References 452 publications

Proteomic evidence for amyloidogenic cross-seeding in fibrinaloid microclots

Proteomic evidence for amyloidogenic cross-seeding in fibrinaloid microclots

Utilizing Molecular Dynamics Simulations, Machine Learning, Cryo-EM, and NMR Spectroscopy to Predict and Validate Protein Dynamics

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