Cytosolic Interactome Protects Against Protein Unfolding in a Single Molecule Experiment

Barbara Scalvini; Laurens W.H.J. Heling; Vahid Sheikhhassani; Vanda Sunderlikova; Sander J. Tans; Alireza Mashaghi

doi:10.1002/adbi.202300105

Cytosolic Interactome Protects Against Protein Unfolding in a Single Molecule Experiment

Barbara Scalvini, Laurens W.H.J. Heling, Vahid Sheikhhassani, Vanda Sunderlikova, Sander J. Tans, Alireza Mashaghi^*

^*Corresponding author for this work

BN/Sander Tans Lab

Research output: Contribution to journal › Article › Scientific › peer-review

1 Citation (Scopus)

Abstract

Single molecule techniques are particularly well suited for investigating the processes of protein folding and chaperone assistance. However, current assays provide only a limited perspective on the various ways in which the cellular environment can influence the folding pathway of a protein. In this study, a single molecule mechanical interrogation assay is developed and used to monitor protein unfolding and refolding within a cytosolic solution. This allows to test the cumulative topological effect of the cytoplasmic interactome on the folding process. The results reveal a stabilization against forced unfolding for partial folds, which are attributed to the protective effect of the cytoplasmic environment against unfolding and aggregation. This research opens the possibility of conducting single molecule molecular folding experiments in quasi-biological environments.

Original language	English
Article number	2300105
Number of pages	10
Journal	Advanced Biology
Volume	7
Issue number	12
DOIs	https://doi.org/10.1002/adbi.202300105
Publication status	Published - 2023

Keywords

chaperone
cytosol
optical tweezers
protein folding
single-molecule assay

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abstract = "Single molecule techniques are particularly well suited for investigating the processes of protein folding and chaperone assistance. However, current assays provide only a limited perspective on the various ways in which the cellular environment can influence the folding pathway of a protein. In this study, a single molecule mechanical interrogation assay is developed and used to monitor protein unfolding and refolding within a cytosolic solution. This allows to test the cumulative topological effect of the cytoplasmic interactome on the folding process. The results reveal a stabilization against forced unfolding for partial folds, which are attributed to the protective effect of the cytoplasmic environment against unfolding and aggregation. This research opens the possibility of conducting single molecule molecular folding experiments in quasi-biological environments.",

keywords = "chaperone, cytosol, optical tweezers, protein folding, single-molecule assay",

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T1 - Cytosolic Interactome Protects Against Protein Unfolding in a Single Molecule Experiment

AU - Scalvini, Barbara

AU - Heling, Laurens W.H.J.

AU - Sheikhhassani, Vahid

AU - Sunderlikova, Vanda

AU - Tans, Sander J.

AU - Mashaghi, Alireza

PY - 2023

Y1 - 2023

N2 - Single molecule techniques are particularly well suited for investigating the processes of protein folding and chaperone assistance. However, current assays provide only a limited perspective on the various ways in which the cellular environment can influence the folding pathway of a protein. In this study, a single molecule mechanical interrogation assay is developed and used to monitor protein unfolding and refolding within a cytosolic solution. This allows to test the cumulative topological effect of the cytoplasmic interactome on the folding process. The results reveal a stabilization against forced unfolding for partial folds, which are attributed to the protective effect of the cytoplasmic environment against unfolding and aggregation. This research opens the possibility of conducting single molecule molecular folding experiments in quasi-biological environments.

AB - Single molecule techniques are particularly well suited for investigating the processes of protein folding and chaperone assistance. However, current assays provide only a limited perspective on the various ways in which the cellular environment can influence the folding pathway of a protein. In this study, a single molecule mechanical interrogation assay is developed and used to monitor protein unfolding and refolding within a cytosolic solution. This allows to test the cumulative topological effect of the cytoplasmic interactome on the folding process. The results reveal a stabilization against forced unfolding for partial folds, which are attributed to the protective effect of the cytoplasmic environment against unfolding and aggregation. This research opens the possibility of conducting single molecule molecular folding experiments in quasi-biological environments.

KW - chaperone

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KW - optical tweezers

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KW - single-molecule assay

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DO - 10.1002/adbi.202300105

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Cytosolic Interactome Protects Against Protein Unfolding in a Single Molecule Experiment

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Keywords

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