Your search keyword '"Strick, Terence R"' showing total 17 results

1. Direct observation of helicase-topoisomerase coupling within reverse gyrase.

Author

Yang X, Garnier F, Débat H, Strick TR, and Nadal M

Subjects

Adenosine Triphosphate metabolism, DNA, Bacterial metabolism, DNA-Binding Proteins metabolism, Models, Molecular, Protein Conformation, Protein Domains, Thermus genetics, DNA metabolism, DNA Helicases metabolism, DNA Topoisomerases metabolism, DNA Topoisomerases, Type I metabolism

Abstract

Reverse gyrases (RGs) are the only topoisomerases capable of generating positive supercoils in DNA. Members of the type IA family, they do so by generating a single-strand break in substrate DNA and then manipulating the two single strands to generate positive topology. Here, we use single-molecule experimentation to reveal the obligatory succession of steps that make up the catalytic cycle of RG. In the initial state, RG binds to DNA and unwinds ∼2 turns of the double helix in an ATP-independent fashion. Upon nucleotide binding, RG then rewinds ∼1 turn of DNA. Nucleotide hydrolysis and/or product release leads to an increase of 2 units of DNA writhe and resetting of the enzyme, for a net change of topology of +1 turn per cycle. Final dissociation of RG from DNA results in rewinding of the 2 turns of DNA that were initially disrupted. These results show how tight coupling of the helicase and topoisomerase activities allows for induction of positive supercoiling despite opposing torque., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

2. Molecular scaffolds: when DNA becomes the hardware for single-molecule investigations.

Author

Gosse C, Strick TR, and Kostrz D

Subjects

Base Pairing, Biomechanical Phenomena, DNA End-Joining Repair, DNA chemistry, DNA genetics, Single Molecule Imaging

Abstract

Over the past few decades, single-molecule manipulation has been widely applied to the real-time analysis of biomolecular interactions. It has enabled researchers to decipher structure-function relationships for polymers, enzymes, and larger-scale molecular machines, in particular by harnessing force to probe both chemical and mechanical stabilities. Nucleic acids have played a central role in this effort because, in addition to their biological significance, they exhibit unique polymeric properties which have recast them as key components participating in numerous experimental designs. In this review, we introduce recent developments highlighting this dual nature of nucleic acids in biophysics, as objects of study but also as tools allowing novel approaches. More specifically, we present molecular scaffolds as an emerging concept and describe their use in single-molecule force spectroscopy. Aspects related to folding and noncovalent interactions will be presented in parallel to research in enzymology, with a focus on the acquisition of thermodynamic and kinetic data., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

3. A modular DNA scaffold to study protein-protein interactions at single-molecule resolution.

Author

Kostrz D, Wayment-Steele HK, Wang JL, Follenfant M, Pande VS, Strick TR, and Gosse C

Subjects

Animals, DNA, Single-Stranded chemistry, Humans, Models, Molecular, Nanotechnology methods, Sirolimus metabolism, TOR Serine-Threonine Kinases metabolism, Tacrolimus Binding Protein 1A metabolism, DNA chemistry, Nanostructures chemistry, Protein Interaction Mapping methods

Abstract

The residence time of a drug on its target has been suggested as a more pertinent metric of therapeutic efficacy than the traditionally used affinity constant. Here, we introduce junctured-DNA tweezers as a generic platform that enables real-time observation, at the single-molecule level, of biomolecular interactions. This tool corresponds to a double-strand DNA scaffold that can be nanomanipulated and on which proteins of interest can be engrafted thanks to widely used genetic tagging strategies. Thus, junctured-DNA tweezers allow a straightforward and robust access to single-molecule force spectroscopy in drug discovery, and more generally in biophysics. Proof-of-principle experiments are provided for the rapamycin-mediated association between FKBP12 and FRB, a system relevant in both medicine and chemical biology. Individual interactions were monitored under a range of applied forces and temperatures, yielding after analysis the characteristic features of the energy profile along the dissociation landscape.

Published

2019

4. Simple calibration of TIR field depth using the supercoiling response of DNA.

Author

Duboc C, Graves ET, and Strick TR

Subjects

Calibration, DNA chemistry, Nanotechnology methods, Single Molecule Imaging methods, Spectrometry, Fluorescence methods

Abstract

The combination of single-molecule fluorescence and nanomanipulation techniques into a single experimental platform enables one to carry out correlative analysis of the composition and the activity of complex, multicomponent molecular systems. Here we describe implementation and calibration of such a combined system allowing simultaneous single-molecule force spectroscopy and fluorescence imaging of proteins acting on the DNA using magnetic trapping coupled with fluorescence excitation based on a Total Internal Reflection (TIR), or evanescent, field. We propose a simple and robust in situ method for calibration of the TIR field depth against the mechanical properties of nanomanipulated DNA, and which is made possible by the fact that the magnetic bead used to trap and nanomanipulate DNA and measure its conformation also exhibits autofluorescence in the TIR field. Indeed, the fact that the bead size is on the 1-micron scale does not preclude sensitive probing of an intensity field which decays exponentially on the 0.1micron-scale. We demonstrate the usefulness of this approach by mapping out TIR field depth as a function of the angle of incidence of the illuminating laser at the glass-water interface and showing that one recovers the expected theoretical relationship between field depth and angle of incidence., (Copyright © 2016. Published by Elsevier Inc.)

Published

2016

5. Single-molecule studies using magnetic traps.

Author

Lionnet T, Allemand JF, Revyakin A, Strick TR, Saleh OA, Bensimon D, and Croquette V

Subjects

DNA metabolism, Elasticity, Protein Binding, DNA chemistry, Magnetics, Microspheres

Abstract

In recent years, techniques have been developed to study and manipulate single molecules of DNA and other biopolymers. In one such technique, the magnetic trap, a single DNA molecule is bound at one end to a glass surface and at the other to a magnetic microbead. Small magnets, whose position and rotation can be controlled, pull on and rotate the microbead. This provides a simple method to stretch and twist the molecule. The system allows one to apply and measure forces ranging from 10(-3) to >100 pN. In contrast to other techniques, the force measurement is absolute and does not require calibration of the sensor. In this article, we describe the principle of the magnetic trap, as well as its use in the measurement of the elastic properties of DNA and the study of DNA-protein interactions.

Published

2012

6. Magnetic trap construction.

Author

Lionnet T, Allemand JF, Revyakin A, Strick TR, Saleh OA, Bensimon D, and Croquette V

Subjects

Biotin metabolism, DNA metabolism, Digoxigenin metabolism, Nanotechnology methods, DNA chemistry, Magnetics, Microspheres

Abstract

In recent years, techniques have been developed to study and manipulate single molecules of DNA and other biopolymers. In one such technique, the magnetic trap, a single DNA molecule is bound at one end to a glass surface and at the other to a magnetic microbead. Small magnets, whose position and rotation can be controlled, pull on and rotate the microbead. This provides a simple method to stretch and twist the molecule. The system allows one to apply and measure forces ranging from 10(-3) to >100 picoNewtons (pN). In contrast to other techniques, the force measurement is absolute and does not require calibration of the sensor. This protocol describes a procedure for building and using a magnetic trap. It gives a method for constructing a microchamber suitable for magnetic tweezers studies, including antibody coating and passivation. It also describes a series of simple steps to achieve end-labeling of DNA anchoring fragments. One anchoring fragment is biotin-labeled and the other is labeled with digoxigenin. The anchoring fragments are then digested and ligated to a central DNA region containing the sequence of interest. The biotinylated DNA is adsorbed onto streptavidin-coated magnetic beads, and the DNA-bead mixture attaches specifically to the antidigoxigenin-coated surface of the microchamber.

Published

2012

7. Abortive initiation and productive initiation by RNA polymerase involve DNA scrunching.

Author

Revyakin A, Liu C, Ebright RH, and Strick TR

Subjects

Base Sequence, Biomechanical Phenomena, DNA chemistry, Models, Genetic, Molecular Sequence Data, Nucleic Acid Conformation, RNA biosynthesis, Transcription Initiation Site physiology, DNA metabolism, DNA-Directed RNA Polymerases metabolism, Promoter Regions, Genetic, Transcription, Genetic physiology

Abstract

Using single-molecule DNA nanomanipulation, we show that abortive initiation involves DNA "scrunching"--in which RNA polymerase (RNAP) remains stationary and unwinds and pulls downstream DNA into itself--and that scrunching requires RNA synthesis and depends on RNA length. We show further that promoter escape involves scrunching, and that scrunching occurs in most or all instances of promoter escape. Our results support the existence of an obligatory stressed intermediate, with approximately one turn of additional DNA unwinding, in escape and are consistent with the proposal that stress in this intermediate provides the driving force to break RNAP-promoter and RNAP-initiation-factor interactions in escape.

Published

2006

8. Single-molecule DNA nanomanipulation: improved resolution through use of shorter DNA fragments.

Author

Revyakin A, Ebright RH, and Strick TR

Subjects

DNA Helicases chemistry, DNA, Superhelical chemistry, DNA-Binding Proteins chemistry, Polymerase Chain Reaction, DNA chemistry, Nanotechnology methods

Published

2005

9. Real-time detection of single-molecule DNA compaction by condensin I.

Author

Strick TR, Kawaguchi T, and Hirano T

Subjects

Adenosine Triphosphate metabolism, Animals, Chromatography, Affinity, Multiprotein Complexes, Nanotechnology, Xenopus laevis, Adenosine Triphosphatases metabolism, DNA metabolism, DNA-Binding Proteins metabolism, Nucleic Acid Conformation

Abstract

Background: Condensin is thought to contribute to large-scale DNA compaction during mitotic chromosome assembly. It remains unknown, however, how the complex reconfigures DNA structure at a mechanistic level., Results: We have performed single-molecule DNA nanomanipulation experiments to directly measure in real-time DNA compaction by the Xenopus laevis condensin I complex. Condensin can bind to the nanomanipulated DNA in the absence of ATP, but it compacts the DNA only in the presence of hydrolyzable ATP. Linear compaction is evidenced by a reduction in the end-to-end extension of nanomanipulated DNA. The reaction results in total compaction of the DNA (i.e., zero end-to-end extension). Discrete and reversible DNA compaction events are observed in the presence of competitor DNA when the DNA is subjected to weak stretching forces (F = 0.4 picoNewton [pN]). The distribution of step sizes is broad and displays a peak at approximately 60 nm ( approximately 180 bp) as well as a long tail. This distribution is essentially unaffected by the topological state of the DNA substrate. Increasing the force to F = 10 pN drives the system toward step-wise reversal of compaction. The distribution of step sizes observed upon disruption of condensin-DNA interactions displays a sharp peak at approximately 30 nm ( approximately 90 bp) as well as a long tail stretching out to hundreds of nanometers., Conclusions: The DNA nanomanipulation assay allows us to demonstrate for the first time that condensin physically compacts DNA in an ATP-hydrolysis-dependent manner. Our results suggest that the condensin complex may induce DNA compaction by dynamically and reversibly introducing loops along the DNA.

Published

2004

10. Promoter unwinding and promoter clearance by RNA polymerase: detection by single-molecule DNA nanomanipulation.

Author

Revyakin A, Ebright RH, and Strick TR

Subjects

Nanotechnology, DNA genetics, DNA-Directed RNA Polymerases metabolism, Promoter Regions, Genetic

Abstract

By monitoring the end-to-end extension of a mechanically stretched, supercoiled, single DNA molecule, we have been able directly to observe the change in extension associated with unwinding of approximately one turn of promoter DNA by RNA polymerase (RNAP). By performing parallel experiments with negatively and positively supercoiled DNA, we have been able to deconvolute the change in extension caused by RNAP-dependent DNA unwinding (with approximately 1-bp resolution) and the change in extension caused by RNAP-dependent DNA compaction (with approximately 5-nm resolution). We have used this approach to quantify the extent of unwinding and compaction, the kinetics of unwinding and compaction, and effects of supercoiling, sequence, ppGpp, and nucleotides. We also have used this approach to detect promoter clearance and promoter recycling by successive RNAP molecules. We find that the rate of formation and the stability of the unwound complex depend profoundly on supercoiling and that supercoiling exerts its effects mechanically (through torque), and not structurally (through the number and position of supercoils). The approach should permit analysis of other nucleic-acid-processing factors that cause changes in DNA twist and/or DNA compaction.

Published

2004

11. Dissection of DNA double-strand-break repair using novel single-molecule forceps.

Author

Wang, Jing L, Duboc, Camille, Wu, Qian, Ochi, Takashi, Liang, Shikang, Tsutakawa, Susan E, Lees-Miller, Susan P, Nadal, Marc, Tainer, John A, Blundell, Tom L, and Strick, Terence R

Subjects

Animals, Humans, Spodoptera, DNA Repair Enzymes, DNA Restriction Enzymes, Calcium-Binding Proteins, DNA-Binding Proteins, DNA, Genetic Techniques, Chromosome Pairing, Phosphorylation, DNA Breaks, Double-Stranded, DNA End-Joining Repair, Sf9 Cells, Ku Autoantigen, DNA Ligase ATP, DNA Breaks, Double-Stranded, Chemical Sciences, Biological Sciences, Medical and Health Sciences, Biophysics, Developmental Biology

Abstract

Repairing DNA double-strand breaks (DSBs) by nonhomologous end joining (NHEJ) requires multiple proteins to recognize and bind DNA ends, process them for compatibility, and ligate them together. We constructed novel DNA substrates for single-molecule nanomanipulation, allowing us to mechanically detect, probe, and rupture in real-time DSB synapsis by specific human NHEJ components. DNA-PKcs and Ku allow DNA end synapsis on the 100 ms timescale, and the addition of PAXX extends this lifetime to ~2 s. Further addition of XRCC4, XLF and ligase IV results in minute-scale synapsis and leads to robust repair of both strands of the nanomanipulated DNA. The energetic contribution of the different components to synaptic stability is typically on the scale of a few kilocalories per mole. Our results define assembly rules for NHEJ machinery and unveil the importance of weak interactions, rapidly ruptured even at sub-picoNewton forces, in regulating this multicomponent chemomechanical system for genome integrity.

Published

2018

12. Cotranscriptional R-loop formation by Mfd involves topological partitioning of DNA.

Author

Portman, James R., Brouwer, Gwendolyn M., Bollins, Jack, Savery, Nigel J., and Strick, Terence R.

Subjects

RNA polymerases, BACTERIAL proteins, NUCLEIC acids, DNA, SINGLE molecules

Abstract

R-loops are nucleic acid hybrids which form when an RNA invades duplex DNA to pair with its template sequence. Although they are implicated in a growing number of gene regulatory processes, their mechanistic origins remain unclear. We here report realtime observations of cotranscriptional R-loop formation at singlemolecule resolution and propose a mechanism for their formation. We show that the bacterial Mfd protein can simultaneously interact with both elongating RNA polymerase and upstream DNA, tethering the two together and partitioning the DNA into distinct supercoiled domains. A highly negatively supercoiled domain forms in between Mfd and RNA polymerase, and compensatory positive supercoiling appears in front of the RNA polymerase and behind Mfd. The nascent RNA invades the negatively supercoiled domain and forms a stable R-loop that can drive mutagenesis. This mechanism theoretically enables any protein that simultaneously binds an actively translocating RNA polymerase and upstream DNA to stimulate R-loop formation. [ABSTRACT FROM AUTHOR]

Published

2021

13. Tracking enzymatic steps of DNA topoisomerases using single-molecule micromanipulation

Author

Strick, Terence R., Charvin, Gilles, Dekker, Nynke H., Allemand, Jean-François, Bensimon, David, and Croquette, Vincent

Subjects

*MAGNETIC traps, *ENZYMES, *DNA, *ELASTICITY

Abstract

In this article, we describe single-molecule assays using magnetic traps and we applied these assays to topoisomerase enzymes which unwind and disentangle DNA molecules. First, the elasticity of single DNA molecule is characterized using the magnetic trap. We show that a twisting constraint may be easily applied and that its effect upon DNA may be measured accurately. Then we describe how the topoisomerase activity may be observed at the single-molecule level giving direct access to the important biological parameters of the enzyme such as velocity and processivity. Furthermore, individual cycles of unwinding can be observed in real time. This permits an accurate characterization of the enzyme''s biochemical cycle. The data treatment required to identify and analyze individual topoisomerization cycles will be presented in detail. This analysis is applicable to a wide variety of molecular motors. To cite this article: T.R. Strick et al., C. R. Physique 3 (2002) 595–618. [Copyright &y& Elsevier]

Published

2002

14. Single-molecule analysis of DNA uncoiling by type II topoisomerase.

Author

Strick, Terence R. and Croquette, Vincent

Subjects

*DNA topoisomerase II, *DNA, *ADENOSINE triphosphate

Abstract

Focuses on a single-molecule analysis of DNA uncoiling induced by a type II topoisomerase. Use of a single Drosophila melanogaster topoisomerase II; Monitoring of DNA extension in the presence of adenosine triphosphate; Relaxation of two supercoils during a single catalytic turnover.

Published

2000

15. DNA replication: Unlocking the secrets of fork arrest.

Author

Fan, Jun and Strick, Terence R

Subjects

*DNA replication, *DNA, *CHROMOSOME replication, *PROTEIN-protein interactions, *DNA denaturation

Abstract

The article comments on the study on DNA replication by B. A. Berghuis, et al. within the issue which describes a high-throughput single-molecule approach to probe the nanoscale mechanical properties of the Tus-Ter protein-DNA complex. The authors cites and discuss the results of the study. They remark that the reconstitution of strand separation on a Ter site has allowed the study to reveal the intrinsic strength of the Tus-Ter lock.

Published

2015

16. Eeny meeny miny moe, catch a transcript by the toe, or how to enumerate eukaryotic transcripts.

Author

Strick, Terence R. and Hernandez, Nouria

Subjects

*RNA polymerases, *TRANSCRIPTION factors, *DNA, *EUKARYOTES, *FLUORESCENCE

Abstract

In this issue of Genes & Development, Revyakin and colleagues (pp. 1691-1702) measure the relation between individual RNA polymerase II transcription events and transcription factor assembly by counting RNA transcripts retained on the template DNA using single-molecule fluorescence. [ABSTRACT FROM AUTHOR]

Published

2012

17. Corrigendum: FtsK: A groovy helicase.

Author

Strick, Terence R and Quessada-Vial, Audrey

Subjects

*DNA

Abstract

A correction to the article on a model that explain the low degree of positive deoxyribonucleic acid (DNA) supercoiling that was published in the previous issue is presented.

Published

2007