DNA visualization in single molecule studies carried out with optical tweezers: Covalent versus non-covalent attachment of fluorophores

Abstract As the basic building blocks of chromatin, nucleosomes play a key role in dictating the accessibility of the eukaryotic genome. Consequently, nucleosomes are involved in essential genomic transactions such as DNA transcription, replication and repair. In order to unravel the mechanisms by which nucleosomes can influence, or be altered by, DNA-binding proteins, single-molecule techniques are increasingly employed. To this end, DNA molecules containing a defined series of nucleosome positioning sequences are often used to reconstitute arrays of nucleosomes in vitro. Here, we describe a novel method to prepare DNA molecules containing defined arrays of the ‘601’ nucleosome positioning sequence by exploiting Gibson Assembly cloning. The approaches presented here provide a more accessible and efficient means to generate arrays of nucleosome positioning motifs, and facilitate a high degree of control over the linker sequences between these motifs. Nucleosomes reconstituted on such arrays are ideal for interrogation with single-molecule techniques. To demonstrate this, we use dual-trap optical tweezers, in combination with fluorescence microscopy, to monitor nucleosome unwrapping and histone localisation as a function of tension. We reveal that, although nucleosomes unwrap at ~20 pN, histones (at least histone H3) remain bound to the DNA, even at tensions beyond 60 pN.

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Single-Molecule Studies of Protein Folding with Optical Tweezers

Annual Review of Biochemistry ◽

10.1146/annurev-biochem-013118-111442 ◽

2020 ◽

Vol 89 (1) ◽

pp. 443-470 ◽

Cited By ~ 5

Author(s):

Carlos Bustamante ◽

Lisa Alexander ◽

Kevin Maciuba ◽

Christian M. Kaiser

Keyword(s):

Protein Folding ◽

Optical Tweezers ◽

Single Molecule ◽

Cellular Protein ◽

Folding Energy ◽

Precise Control ◽

Single Molecule Studies ◽

Force Range ◽

And Function

Manipulation of individual molecules with optical tweezers provides a powerful means of interrogating the structure and folding of proteins. Mechanical force is not only a relevant quantity in cellular protein folding and function, but also a convenient parameter for biophysical folding studies. Optical tweezers offer precise control in the force range relevant for protein folding and unfolding, from which single-molecule kinetic and thermodynamic information about these processes can be extracted. In this review, we describe both physical principles and practical aspects of optical tweezers measurements and discuss recent advances in the use of this technique for the study of protein folding. In particular, we describe the characterization of folding energy landscapes at high resolution, studies of structurally complex multidomain proteins, folding in the presence of chaperones, and the ability to investigate real-time cotranslational folding of a polypeptide.

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Rescuing Replication from Barriers: Mechanistic Insights from Single-Molecule Studies

Molecular and Cellular Biology ◽

10.1128/mcb.00576-18 ◽

2019 ◽

Vol 39 (10) ◽

Cited By ~ 1

Author(s):

Bo Sun

Keyword(s):

Real Time ◽

Optical Tweezers ◽

Single Molecule ◽

Replication Fork ◽

Magnetic Tweezers ◽

Origin Of Replication ◽

Replication Fork Progression ◽

Nucleotide Incorporation ◽

Single Molecule Studies ◽

Replication Failure

ABSTRACT To prevent replication failure due to fork barriers, several mechanisms have evolved to restart arrested forks independent of the origin of replication. Our understanding of these mechanisms that underlie replication reactivation has been aided through unique dynamic perspectives offered by single-molecule techniques. These techniques, such as optical tweezers, magnetic tweezers, and fluorescence-based methods, allow researchers to monitor the unwinding of DNA by helicase, nucleotide incorporation during polymerase synthesis, and replication fork progression in real time. In addition, they offer the ability to distinguish DNA intermediates after obstacles to replication at high spatial and temporal resolutions, providing new insights into the replication reactivation mechanisms. These and other highlights of single-molecule techniques and remarkable studies on the recovery of the replication fork from barriers will be discussed in this review.

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A new method for the covalent attachment of DNA to a surface for single-molecule studies

Colloids and Surfaces B Biointerfaces ◽

10.1016/j.colsurfb.2010.11.002 ◽

2011 ◽

Vol 83 (1) ◽

pp. 91-95 ◽

Cited By ~ 16

Author(s):

Daniel J. Schlingman ◽

Andrew H. Mack ◽

Simon G.J. Mochrie ◽

Lynne Regan

Keyword(s):

Single Molecule ◽

New Method ◽

Covalent Attachment ◽

Single Molecule Studies

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7. Following biochemistry within the cell

Biochemistry: A Very Short Introduction ◽

10.1093/actrade/9780198833871.003.0007 ◽

2021 ◽

pp. 93-110

Author(s):

Mark Lorch

Keyword(s):

Green Fluorescent Protein ◽

Optical Tweezers ◽

Single Molecule ◽

Motor Proteins ◽

Fluorescent Protein ◽

Patch Clamping ◽

Signal To Noise ◽

Single Molecule Studies ◽

Technical Challenges ◽

Green Fluorescent

This chapter presents key advances in the study of individual molecules within cells. When one applies this individualistic methodology to biochemicals, one enters the realms of single-molecule biophysics. There are of course formidable technical challenges associated with single-molecule studies, not least of which is the signal-to-noise problem. The chapter discusses patch clamping, nanoscopes, and optical tweezers. Patch clamping provided insights into the protein machinery that controls the flow of ions in and out of cells. The chapter also examines cytokinesis, cytoskeletons, and motor proteins, and the use of Green Fluorescent Protein (GFP).

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Evolution of conventional optical tweezers through addition of secondary laser beam for single-molecule studies

Optical Trapping and Optical Micromanipulation XVII ◽

10.1117/12.2568669 ◽

2020 ◽

Author(s):

Prerna Kabtiyal ◽

Ariel Robbins ◽

Elizabeth Jergens ◽

Joshua Johnson ◽

Carlos Castro ◽

...

Keyword(s):

Laser Beam ◽

Optical Tweezers ◽

Single Molecule ◽

Single Molecule Studies

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Regulation of N-Cadherin Dynamics at Neuronal Contacts by Ligand Binding and Cytoskeletal Coupling

Molecular Biology of the Cell ◽

10.1091/mbc.e05-04-0335 ◽

2006 ◽

Vol 17 (2) ◽

pp. 862-875 ◽

Cited By ~ 59

Author(s):

Olivier Thoumine ◽

Mireille Lambert ◽

René-Marc Mège ◽

Daniel Choquet

Keyword(s):

Optical Tweezers ◽

Single Molecule ◽

Growth Cones ◽

Membrane Diffusion ◽

Turnover Rates ◽

Intact Cells ◽

Intrinsic Mechanism ◽

Active Regulation ◽

Single Molecule Studies ◽

Bond Kinetics

N-cadherin plays a key role in axonal outgrowth and synaptogenesis, but how neurons initiate and remodel N-cadherin-based adhesions remains unclear. We addressed this issue with a semiartificial system consisting of N-cadherin coated microspheres adhering to cultured neurons transfected for N-cadherin-GFP. Using optical tweezers, we show that growth cones are particularly reactive to N-cadherin coated microspheres, which they capture in a few seconds and drag rearward. Such strong coupling requires an intact connection between N-cadherin receptors and catenins. As they move to the basis of growth cones, microspheres slow down while gradually accumulating N-cadherin-GFP, demonstrating a clear delay between bead coupling to the actin flow and receptor recruitment. Using FRAP and photoactivation, N-cadherin receptors at bead-to-cell contacts were found to continuously recycle, consistently with a model of ligand-receptor reaction not limited by membrane diffusion. The use of N-cadherin-GFP receptors truncated or mutated in specific cytoplasmic regions show that N-cadherin turnover is exquisitely regulated by catenin partners. Turnover rates are considerably lower than those obtained previously in single molecule studies, demonstrating an active regulation of cadherin bond kinetics in intact cells. Finally, spontaneous neuronal contacts enriched in N-cadherin exhibited similar turnover rates, suggesting that such dynamics of N-cadherin may represent an intrinsic mechanism underlying the plasticity of neuronal adhesions.

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