Your search keyword '"De Vlaminck, I. (author)"' showing total 16 results

1. Annealing helicase HARP closes RPA-stabilized DNA bubbles non-processively

Author

Burnham, D.R. (author), Nijholt, B. (author), de Vlaminck, I. (author), Quan, Jinhua (author), Yusufzai, Timur (author), Dekker, C. (author), Burnham, D.R. (author), Nijholt, B. (author), de Vlaminck, I. (author), Quan, Jinhua (author), Yusufzai, Timur (author), and Dekker, C. (author)

Abstract

We investigate the mechanistic nature of the Snf2 family protein HARP, mutations of which are responsible for Schimke immuno-osseous dysplasia. Using a single-molecule magnetic tweezers assay, we construct RPA-stabilized DNA bubbles within torsionally constrained DNA to investigate the annealing action of HARP on a physiologically relevant substrate. We find that HARP closes RPA-stabilized bubbles in a slow reaction, taking on the order of tens of minutes for ∼600 bp of DNA to be re-annealed. The data indicate that DNA re-anneals through the removal of RPA, which is observed as clear steps in the bubbleclosing traces. The dependence of the closing rate on both ionic strength and HARP concentration indicates that removal of RPA occurs via an association-dissociation mechanism where HARP does not remain associated with the DNA. The enzyme exhibits classical Michaelis-Menten kinetics and acts cooperatively with a Hill coefficient of 3 ± 1. Our work also allows the determination of some important features of RPA-bubble structures at low supercoiling, including the existence of multiple bubbles and that RPA molecules are mis-registered on the two strands., BN/Cees Dekker Lab, QN/Akhmerov Group

Published

2017

2. Annealing helicase HARP closes RPA-stabilized DNA bubbles non-processively

Author

Burnham, D.R. (author), Nijholt, B. (author), de Vlaminck, I. (author), Quan, Jinhua (author), Yusufzai, Timur (author), Dekker, C. (author), Burnham, D.R. (author), Nijholt, B. (author), de Vlaminck, I. (author), Quan, Jinhua (author), Yusufzai, Timur (author), and Dekker, C. (author)

Abstract

We investigate the mechanistic nature of the Snf2 family protein HARP, mutations of which are responsible for Schimke immuno-osseous dysplasia. Using a single-molecule magnetic tweezers assay, we construct RPA-stabilized DNA bubbles within torsionally constrained DNA to investigate the annealing action of HARP on a physiologically relevant substrate. We find that HARP closes RPA-stabilized bubbles in a slow reaction, taking on the order of tens of minutes for ∼600 bp of DNA to be re-annealed. The data indicate that DNA re-anneals through the removal of RPA, which is observed as clear steps in the bubbleclosing traces. The dependence of the closing rate on both ionic strength and HARP concentration indicates that removal of RPA occurs via an association-dissociation mechanism where HARP does not remain associated with the DNA. The enzyme exhibits classical Michaelis-Menten kinetics and acts cooperatively with a Hill coefficient of 3 ± 1. Our work also allows the determination of some important features of RPA-bubble structures at low supercoiling, including the existence of multiple bubbles and that RPA molecules are mis-registered on the two strands., BN/Cees Dekker Lab, QN/Akhmerov Group

Published

2017

3. Skewed brownian fluctuations in single-molecule magnetic tweezers.

Author

Burnham, D.R. (author), De Vlaminck, I. (author), Henighan, T. (author), Dekker, C. (author), Burnham, D.R. (author), De Vlaminck, I. (author), Henighan, T. (author), and Dekker, C. (author)

Abstract

Measurements in magnetic tweezers rely upon precise determination of the position of a magnetic microsphere. Fluctuations in the position due to Brownian motion allows calculation of the applied force, enabling deduction of the force-extension response function for a single DNA molecule that is attached to the microsphere. The standard approach relies upon using the mean of position fluctuations, which is valid when the microsphere axial position fluctuations obey a normal distribution. However, here we demonstrate that nearby surfaces and the non-linear elasticity of DNA can skew the distribution. Through experiment and simulations, we show that such a skewing leads to inaccurate position measurements which significantly affect the extracted DNA extension and mechanical properties, leading to up to two-fold errors in measured DNA persistence length. We develop a simple, robust and easily implemented method to correct for such mismeasurements., BN/Bionanoscience, Applied Sciences

Published

2014

4. Skewed brownian fluctuations in single-molecule magnetic tweezers.

Author

Burnham, D.R. (author), De Vlaminck, I. (author), Henighan, T. (author), Dekker, C. (author), Burnham, D.R. (author), De Vlaminck, I. (author), Henighan, T. (author), and Dekker, C. (author)

Abstract

Measurements in magnetic tweezers rely upon precise determination of the position of a magnetic microsphere. Fluctuations in the position due to Brownian motion allows calculation of the applied force, enabling deduction of the force-extension response function for a single DNA molecule that is attached to the microsphere. The standard approach relies upon using the mean of position fluctuations, which is valid when the microsphere axial position fluctuations obey a normal distribution. However, here we demonstrate that nearby surfaces and the non-linear elasticity of DNA can skew the distribution. Through experiment and simulations, we show that such a skewing leads to inaccurate position measurements which significantly affect the extracted DNA extension and mechanical properties, leading to up to two-fold errors in measured DNA persistence length. We develop a simple, robust and easily implemented method to correct for such mismeasurements., BN/Bionanoscience, Applied Sciences

Published

2014

5. A nanopore sensor and method for selective detection of analytes in a sample

Author

De Vlaminck, I. (author), Plesa, C. (author), Dekker, C. (author), De Vlaminck, I. (author), Plesa, C. (author), and Dekker, C. (author)

Abstract

BN/Bionanoscience, Applied Sciences

Published

2013

6. Scanning a DNA molecule for bound proteins using hybrid magnetic and optical tweezers

Author

Van Loenhout, M.T. (author), De Vlaminck, I. (author), Flebus, B. (author), Den Blanken, J.F. (author), Zweifel, L.P. (author), Hooning, K.M. (author), Kerssemakers, J.W. (author), Dekker, C. (author), Van Loenhout, M.T. (author), De Vlaminck, I. (author), Flebus, B. (author), Den Blanken, J.F. (author), Zweifel, L.P. (author), Hooning, K.M. (author), Kerssemakers, J.W. (author), and Dekker, C. (author)

Abstract

The functional state of the genome is determined by its interactions with proteins that bind, modify, and move along the DNA. To determine the positions and binding strength of proteins localized on DNA we have developed a combined magnetic and optical tweezers apparatus that allows for both sensitive and label-free detection. A DNA loop, that acts as a scanning probe, is created by looping an optically trapped DNA tether around a DNA molecule that is held with magnetic tweezers. Upon scanning the loop along the ?-DNA molecule, EcoRI proteins were detected with ?17 nm spatial resolution. An offset of 33±5 nm for the detected protein positions was found between back and forwards scans, corresponding to the size of the DNA loop and in agreement with theoretical estimates. At higher applied stretching forces, the scanning loop was able to remove bound proteins from the DNA, showing that the method is in principle also capable of measuring the binding strength of proteins to DNA with a force resolution of 0.1 pN/[Formula: see text]. The use of magnetic tweezers in this assay allows the facile preparation of many single-molecule tethers, which can be scanned one after the other, while it also allows for direct control of the supercoiling state of the DNA molecule, making it uniquely suitable to address the effects of torque on protein-DNA interactions., BN/Bionanoscience, Applied Sciences

Published

2013

7. A nanopore sensor and method for selective detection of analytes in a sample

Author

De Vlaminck, I. (author), Plesa, C. (author), Dekker, C. (author), De Vlaminck, I. (author), Plesa, C. (author), and Dekker, C. (author)

Abstract

BN/Bionanoscience, Applied Sciences

Published

2013

8. Scanning a DNA molecule for bound proteins using hybrid magnetic and optical tweezers

Author

Van Loenhout, M.T. (author), De Vlaminck, I. (author), Flebus, B. (author), Den Blanken, J.F. (author), Zweifel, L.P. (author), Hooning, K.M. (author), Kerssemakers, J.W. (author), Dekker, C. (author), Van Loenhout, M.T. (author), De Vlaminck, I. (author), Flebus, B. (author), Den Blanken, J.F. (author), Zweifel, L.P. (author), Hooning, K.M. (author), Kerssemakers, J.W. (author), and Dekker, C. (author)

Abstract

The functional state of the genome is determined by its interactions with proteins that bind, modify, and move along the DNA. To determine the positions and binding strength of proteins localized on DNA we have developed a combined magnetic and optical tweezers apparatus that allows for both sensitive and label-free detection. A DNA loop, that acts as a scanning probe, is created by looping an optically trapped DNA tether around a DNA molecule that is held with magnetic tweezers. Upon scanning the loop along the ?-DNA molecule, EcoRI proteins were detected with ?17 nm spatial resolution. An offset of 33±5 nm for the detected protein positions was found between back and forwards scans, corresponding to the size of the DNA loop and in agreement with theoretical estimates. At higher applied stretching forces, the scanning loop was able to remove bound proteins from the DNA, showing that the method is in principle also capable of measuring the binding strength of proteins to DNA with a force resolution of 0.1 pN/[Formula: see text]. The use of magnetic tweezers in this assay allows the facile preparation of many single-molecule tethers, which can be scanned one after the other, while it also allows for direct control of the supercoiling state of the DNA molecule, making it uniquely suitable to address the effects of torque on protein-DNA interactions., BN/Bionanoscience, Applied Sciences

Published

2013

9. Non-Bias-Limited Tracking of Spherical Particles, Enabling Nanometer Resolution at Low Magnification

Author

Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), Dekker, C. (author), Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), and Dekker, C. (author)

Abstract

We present a three-dimensional tracking routine for nondiffraction-limited particles, which significantly reduces pixel bias. Our technique allows for increased resolution compared to that of previous methods, especially at low magnification or at high signal/noise ratio. This enables tracking with nanometer accuracy in a wide field of view and tracking of many particles. To reduce bias induced by pixelation, the tracking algorithm uses interpolation of the image on a circular grid to determine the x-, y-, and z-positions. We evaluate the proposed algorithm by tracking simulated images and compare it to well-known center-of-mass and cross-correlation methods. The final resolution of the described method improves up to an order of magnitude in three dimensions compared to conventional tracking methods. We show that errors in x,y-tracking can seriously affect z-tracking if interpolation is not used. We validate our results with experimental data obtained for conditions matching those used in the simulations. Finally, we show that the increased performance of the proposed algorithm uniquely enables it to extract accurate data for the persistence length and end-to-end distance of 107 DNA tethers in a single experiment, BN/Bionanoscience, Applied Sciences

Published

2012

10. Magnetic Forces and DNA Mechanics in Multiplexed Magnetic Tweezers

Author

De Vlaminck, I. (author), Henighan, T. (author), Van Loenhout, M.T.J. (author), Burnham, D.R. (author), Dekker, C. (author), De Vlaminck, I. (author), Henighan, T. (author), Van Loenhout, M.T.J. (author), Burnham, D.R. (author), and Dekker, C. (author)

Abstract

Magnetic tweezers (MT) are a powerful tool for the study of DNA-enzyme interactions. Both the magnet-based manipulation and the camera-based detection used in MT are well suited for multiplexed measurements. Here, we systematically address challenges related to scaling of multiplexed magnetic tweezers (MMT) towards high levels of parallelization where large numbers of molecules (say 103) are addressed in the same amount of time required by a single-molecule measurement. We apply offline analysis of recorded images and show that this approach provides a scalable solution for parallel tracking of the xyz-positions of many beads simultaneously. We employ a large field-of-view imaging system to address many DNA-bead tethers in parallel. We model the 3D magnetic field generated by the magnets and derive the magnetic force experienced by DNA-bead tethers across the large field of view from first principles. We furthermore experimentally demonstrate that a DNA-bead tether subject to a rotating magnetic field describes a bicircular, Limaçon rotation pattern and that an analysis of this pattern simultaneously yields information about the force angle and the position of attachment of the DNA on the bead. Finally, we apply MMT in the high-throughput investigation of the distribution of the induced magnetic moment, the position of attachment of DNA on the beads, and DNA flexibility. The methods described herein pave the way to kilo-molecule level magnetic tweezers experiments., BN/Bionanoscience, Applied Sciences

Published

2012

11. Mechanism of Homology Recognition in DNA Recombination from Dual-Molecule Experiments

Author

De Vlaminck, I. (author), Van Loenhout, M.T.J. (author), Zweifel, L. (author), Den Blanken, J. (author), Hooning, K. (author), Hage, S. (author), Kerssemakers, J. (author), Dekker, C. (author), De Vlaminck, I. (author), Van Loenhout, M.T.J. (author), Zweifel, L. (author), Den Blanken, J. (author), Hooning, K. (author), Hage, S. (author), Kerssemakers, J. (author), and Dekker, C. (author)

Abstract

In E. coli homologous recombination, a filament of RecA protein formed on DNA searches and pairs a homologous sequence within a second DNA molecule with remarkable speed and fidelity. Here, we directly probe the strength of the two-molecule interactions involved in homology search and recognition using dual-molecule manipulation, combining magnetic and optical tweezers. We find that the filament's secondary DNA-binding site interacts with a single strand of the incoming double-stranded DNA during homology sampling. Recognition requires opening of the helix and is strongly promoted by unwinding torsional stress. Recognition is achieved upon binding of both strands of the incoming dsDNA to each of two ssDNA-binding sites in the filament. The data indicate a physical picture for homology recognition in which the fidelity of the search process is governed by the distance between the DNA-binding sites., BN/Bionanoscience, Applied Sciences

Published

2012

12. Non-Bias-Limited Tracking of Spherical Particles, Enabling Nanometer Resolution at Low Magnification

Author

Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), Dekker, C. (author), Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), and Dekker, C. (author)

Abstract

We present a three-dimensional tracking routine for nondiffraction-limited particles, which significantly reduces pixel bias. Our technique allows for increased resolution compared to that of previous methods, especially at low magnification or at high signal/noise ratio. This enables tracking with nanometer accuracy in a wide field of view and tracking of many particles. To reduce bias induced by pixelation, the tracking algorithm uses interpolation of the image on a circular grid to determine the x-, y-, and z-positions. We evaluate the proposed algorithm by tracking simulated images and compare it to well-known center-of-mass and cross-correlation methods. The final resolution of the described method improves up to an order of magnitude in three dimensions compared to conventional tracking methods. We show that errors in x,y-tracking can seriously affect z-tracking if interpolation is not used. We validate our results with experimental data obtained for conditions matching those used in the simulations. Finally, we show that the increased performance of the proposed algorithm uniquely enables it to extract accurate data for the persistence length and end-to-end distance of 107 DNA tethers in a single experiment, BN/Bionanoscience, Applied Sciences

Published

2012

13. Magnetic Forces and DNA Mechanics in Multiplexed Magnetic Tweezers

Author

De Vlaminck, I. (author), Henighan, T. (author), Van Loenhout, M.T.J. (author), Burnham, D.R. (author), Dekker, C. (author), De Vlaminck, I. (author), Henighan, T. (author), Van Loenhout, M.T.J. (author), Burnham, D.R. (author), and Dekker, C. (author)

Abstract

Magnetic tweezers (MT) are a powerful tool for the study of DNA-enzyme interactions. Both the magnet-based manipulation and the camera-based detection used in MT are well suited for multiplexed measurements. Here, we systematically address challenges related to scaling of multiplexed magnetic tweezers (MMT) towards high levels of parallelization where large numbers of molecules (say 103) are addressed in the same amount of time required by a single-molecule measurement. We apply offline analysis of recorded images and show that this approach provides a scalable solution for parallel tracking of the xyz-positions of many beads simultaneously. We employ a large field-of-view imaging system to address many DNA-bead tethers in parallel. We model the 3D magnetic field generated by the magnets and derive the magnetic force experienced by DNA-bead tethers across the large field of view from first principles. We furthermore experimentally demonstrate that a DNA-bead tether subject to a rotating magnetic field describes a bicircular, Limaçon rotation pattern and that an analysis of this pattern simultaneously yields information about the force angle and the position of attachment of the DNA on the bead. Finally, we apply MMT in the high-throughput investigation of the distribution of the induced magnetic moment, the position of attachment of DNA on the beads, and DNA flexibility. The methods described herein pave the way to kilo-molecule level magnetic tweezers experiments., BN/Bionanoscience, Applied Sciences

Published

2012

14. Mechanism of Homology Recognition in DNA Recombination from Dual-Molecule Experiments

Author

De Vlaminck, I. (author), Van Loenhout, M.T.J. (author), Zweifel, L. (author), Den Blanken, J. (author), Hooning, K. (author), Hage, S. (author), Kerssemakers, J. (author), Dekker, C. (author), De Vlaminck, I. (author), Van Loenhout, M.T.J. (author), Zweifel, L. (author), Den Blanken, J. (author), Hooning, K. (author), Hage, S. (author), Kerssemakers, J. (author), and Dekker, C. (author)

Abstract

In E. coli homologous recombination, a filament of RecA protein formed on DNA searches and pairs a homologous sequence within a second DNA molecule with remarkable speed and fidelity. Here, we directly probe the strength of the two-molecule interactions involved in homology search and recognition using dual-molecule manipulation, combining magnetic and optical tweezers. We find that the filament's secondary DNA-binding site interacts with a single strand of the incoming double-stranded DNA during homology sampling. Recognition requires opening of the helix and is strongly promoted by unwinding torsional stress. Recognition is achieved upon binding of both strands of the incoming dsDNA to each of two ssDNA-binding sites in the filament. The data indicate a physical picture for homology recognition in which the fidelity of the search process is governed by the distance between the DNA-binding sites., BN/Bionanoscience, Applied Sciences

Published

2012

15. Torsional regulation of hRPA-induced unwinding of double-stranded DNA

Author

De Vlaminck, I. (author), Vidic, I. (author), Van Loenhout, M.T.J. (author), Kanaar, R. (author), Lebbink, J.H.G. (author), Dekker, C. (author), De Vlaminck, I. (author), Vidic, I. (author), Van Loenhout, M.T.J. (author), Kanaar, R. (author), Lebbink, J.H.G. (author), and Dekker, C. (author)

Abstract

All cellular single-stranded (ss) DNA is rapidly bound and stabilized by single stranded DNA-binding proteins (SSBs). Replication protein A, the main eukaryotic SSB, is able to unwind double-stranded (ds) DNA by binding and stabilizing transiently forming bubbles of ssDNA. Here, we study the dynamics of human RPA (hRPA) activity on topologically constrained dsDNA with single-molecule magnetic tweezers. We find that the hRPA unwinding rate is exponentially dependent on torsion present in the DNA. The unwinding reaction is selflimiting, ultimately removing the driving torsional stress. The process can easily be reverted: release of tension or the application of a rewinding torque leads to protein dissociation and helix rewinding. Based on the force and salt dependence of the in vitro kinetics we anticipate that the unwinding reaction occurs frequently in vivo. We propose that the hRPA unwinding reaction serves to protect and stabilize the dsDNA when it is structurally destabilized by mechanical stresses., BN/Bionanoscience, Applied Sciences

Published

2010

16. Torsional regulation of hRPA-induced unwinding of double-stranded DNA

Author

De Vlaminck, I. (author), Vidic, I. (author), Van Loenhout, M.T.J. (author), Kanaar, R. (author), Lebbink, J.H.G. (author), Dekker, C. (author), De Vlaminck, I. (author), Vidic, I. (author), Van Loenhout, M.T.J. (author), Kanaar, R. (author), Lebbink, J.H.G. (author), and Dekker, C. (author)

Abstract

All cellular single-stranded (ss) DNA is rapidly bound and stabilized by single stranded DNA-binding proteins (SSBs). Replication protein A, the main eukaryotic SSB, is able to unwind double-stranded (ds) DNA by binding and stabilizing transiently forming bubbles of ssDNA. Here, we study the dynamics of human RPA (hRPA) activity on topologically constrained dsDNA with single-molecule magnetic tweezers. We find that the hRPA unwinding rate is exponentially dependent on torsion present in the DNA. The unwinding reaction is selflimiting, ultimately removing the driving torsional stress. The process can easily be reverted: release of tension or the application of a rewinding torque leads to protein dissociation and helix rewinding. Based on the force and salt dependence of the in vitro kinetics we anticipate that the unwinding reaction occurs frequently in vivo. We propose that the hRPA unwinding reaction serves to protect and stabilize the dsDNA when it is structurally destabilized by mechanical stresses., BN/Bionanoscience, Applied Sciences

Published

2010