History, rare, and multiple events of mechanical unfolding of repeat proteins

Mechanical unfolding of proteins consisting of repeat domains is an excellent tool to obtain large statistics. Force spectroscopy experiments using atomic force microscopy on proteins presenting multiple domains have revealed that unfolding forces depend on the number of folded domains (history) and...

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Bibliographic Details
Published in:The Journal of chemical physics 2018-03, Vol.148 (12), p.123335-123335
Main Authors: Sumbul, Fidan, Marchesi, Arin, Rico, Felix
Format: Article
Language:English
Subjects:
Biochemistry, Molecular Biology
Cell Cycle Proteins - chemistry
Chromosomal Proteins, Non-Histone - chemistry
Cohesins
Life Sciences
Mechanical Phenomena
Protein Conformation
Protein Denaturation
Protein Folding
Proteins - chemistry
Reproducibility of Results
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Summary:Mechanical unfolding of proteins consisting of repeat domains is an excellent tool to obtain large statistics. Force spectroscopy experiments using atomic force microscopy on proteins presenting multiple domains have revealed that unfolding forces depend on the number of folded domains (history) and have reported intermediate states and rare events. However, the common use of unspecific attachment approaches to pull the protein of interest holds important limitations to study unfolding history and may lead to discarding rare and multiple probing events due to the presence of unspecific adhesion and uncertainty on the pulling site. Site-specific methods that have recently emerged minimize this uncertainty and would be excellent tools to probe unfolding history and rare events. However, detailed characterization of these approaches is required to identify their advantages and limitations. Here, we characterize a site-specific binding approach based on the ultrastable complex dockerin/cohesin III revealing its advantages and limitations to assess the unfolding history and to investigate rare and multiple events during the unfolding of repeated domains. We show that this approach is more robust, reproducible, and provides larger statistics than conventional unspecific methods. We show that the method is optimal to reveal the history of unfolding from the very first domain and to detect rare events, while being more limited to assess intermediate states. Finally, we quantify the forces required to unfold two molecules pulled in parallel, difficult when using unspecific approaches. The proposed method represents a step forward toward more reproducible measurements to probe protein unfolding history and opens the door to systematic probing of rare and multiple molecule unfolding mechanisms.
ISSN:0021-9606
1089-7690
DOI:10.1063/1.5013259