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Literature DB >> 27844436

Single-Molecule Protein Folding Experiments Using High-Precision Optical Tweezers.

Junyi Jiao¹, Aleksander A Rebane¹, Lu Ma², Yongli Zhang³.

Abstract

How proteins fold from linear chains of amino acids to delicate three-dimensional structures remains a fundamental biological problem. Single-molecule manipulation based on high-resolution optical tweezers (OT) provides a powerful approach to study protein folding with unprecedented spatiotemporal resolution. In this method, a single protein or protein complex is tethered between two beads confined in optical traps and pulled. Protein unfolding induced by the mechanical force is counteracted by the spontaneous folding of the protein, reaching a dynamic equilibrium at a characteristic force and rate. The transition is monitored by the accompanying extension change of the protein and used to derive conformations and energies of folding intermediates and their associated transition kinetics. Here, we provide general strategies and detailed protocols to study folding of proteins and protein complexes using optical tweezers, including sample preparation, DNA-protein conjugation and methods of data analysis to extract folding energies and rates from the single-molecule measurements.

Entities: Chemical Disease Gene Species

Keywords: Energy landscape; Hidden Markov modeling; Optical tweezers; Protein folding; SNARE assembly; SNARE proteins; Single-molecule manipulation; gp41

Mesh：

Substances：

Year: 2017 PMID： 27844436 PMCID： PMC5508109 DOI： 10.1007/978-1-4939-6421-5_14

Source DB: PubMed Journal: Methods Mol Biol ISSN： 1064-3745

58 in total

Single-Molecule Protein Folding Experiments Using High-Precision Optical Tweezers.

1. SNARE assembly and disassembly exhibit a pronounced hysteresis.

2. Structure-Based Derivation of Protein Folding Intermediates and Energies from Optical Tweezers.

3. Force unfolding kinetics of RNA using optical tweezers. I. Effects of experimental variables on measured results.

4. Preventing Alzheimer's disease.

5. Core structure of gp41 from the HIV envelope glycoprotein.

6. Highly anisotropic stability and folding kinetics of a single coiled coil protein under mechanical tension.

7. Reshaping of the conformational search of a protein by the chaperone trigger factor.

8. ClpX(P) generates mechanical force to unfold and translocate its protein substrates.

9. SNAP receptors implicated in vesicle targeting and fusion.

10. Munc18-1-regulated stage-wise SNARE assembly underlying synaptic exocytosis.

Review 1. Energetics, kinetics, and pathway of SNARE folding and assembly revealed by optical tweezers.

2. Munc13 binds and recruits SNAP25 to chaperone SNARE complex assembly.

3. Single-Molecule Optical Tweezers Study of Regulated SNARE Assembly.

4. Probing Intermolecular Interactions within the Amyloid β Trimer Using a Tethered Polymer Nanoarray.

5. Single-molecule manipulation of macromolecules on GUV or SUV membranes using optical tweezers.

6. POTATO: Automated pipeline for batch analysis of optical tweezers data.

7. The force required to remove tubulin from the microtubule lattice by pulling on its α-tubulin C-terminal tail.

8. Stepwise membrane binding of extended synaptotagmins revealed by optical tweezers.

9. Two Disease-Causing SNAP-25B Mutations Selectively Impair SNARE C-terminal Assembly.

10. Munc13-1 MUN domain and Munc18-1 cooperatively chaperone SNARE assembly through a tetrameric complex.