Your search keyword '"Nir, G. (author)"' showing total 6 results

1. Dynamic analysis of a diffusing particle in a trapping potential

Author

Lindner, M. (author), Nir, G. (author), Vivante, A. (author), Young, I.T. (author), Garini, Y. (author), Lindner, M. (author), Nir, G. (author), Vivante, A. (author), Young, I.T. (author), and Garini, Y. (author)

Abstract

The dynamics of a diffusing particle in a potential field is ubiquitous in physics, and it plays a pivotal role in single-molecule studies. We present a formalism for analyzing the dynamics of diffusing particles in harmonic potentials at low Reynolds numbers using the time evolution of the particle probability distribution function. We demonstrate the power of the formalism by simulation and by measuring and analyzing a nanobead tethered to a single DNA molecule. It allows one to simultaneously extract all the parameters that describe the system, namely, the diffusion coefficient and the restoring-force constant., IST/Imaging Science and Technology, Applied Sciences

Published

2013

2. Dynamic analysis of a diffusing particle in a trapping potential

Author

Lindner, M. (author), Nir, G. (author), Vivante, A. (author), Young, I.T. (author), Garini, Y. (author), Lindner, M. (author), Nir, G. (author), Vivante, A. (author), Young, I.T. (author), and Garini, Y. (author)

Abstract

The dynamics of a diffusing particle in a potential field is ubiquitous in physics, and it plays a pivotal role in single-molecule studies. We present a formalism for analyzing the dynamics of diffusing particles in harmonic potentials at low Reynolds numbers using the time evolution of the particle probability distribution function. We demonstrate the power of the formalism by simulation and by measuring and analyzing a nanobead tethered to a single DNA molecule. It allows one to simultaneously extract all the parameters that describe the system, namely, the diffusion coefficient and the restoring-force constant., IST/Imaging Science and Technology, Applied Sciences

Published

2013

3. Force-free measurements of the conformations of DNA molecules tethered to a wall

Author

Lindner, M. (author), Nir, G. (author), Medalion, S. (author), Dietrich, H.R.C. (author), Rabin, Y. (author), Garini, Y. (author), Lindner, M. (author), Nir, G. (author), Medalion, S. (author), Dietrich, H.R.C. (author), Rabin, Y. (author), and Garini, Y. (author)

Abstract

Using an optimized combination of tethered particle motion method, total internal reflection, and a gold nanobead, we measured the three-dimensional distribution of the free end of a tethered DNA molecule. The distribution along the axial z direction (perpendicular to the surface) is found to be Rayleigh-like, in agreement with wormlike chain and freely jointed chain simulations. Using these simulations, we show that the presence of the wall increases the correlations between the orientations of neighboring chain segments compared to free DNA. While the measured and the simulated planar (xy) distributions always agree with that of a Gaussian-random-walk (GRW) model, for short DNA lengths (1 ?m) studied in our experiment, the corresponding axial (z) distributions deviate from those predicted for a GRW confined to half-space., BT/Biotechnology, Applied Sciences

Published

2011

4. HU Protein Induces Incoherent DNA Persistence Length

Author

Nir, G. (author), Lindner, M. (author), Dietrich, H.R.C. (author), Girshevitz, O. (author), Vorgias, C.E. (author), Garini, Y. (author), Nir, G. (author), Lindner, M. (author), Dietrich, H.R.C. (author), Girshevitz, O. (author), Vorgias, C.E. (author), and Garini, Y. (author)

Abstract

HU is a highly conserved protein that is believed to play an important role in the architecture and dynamic compaction of bacterial DNA. Its ability to control DNA bending is crucial for functions such as transcription and replication. The effects of HU on the DNA structure have been studied so far mainly by single molecule methods that require us to apply stretching forces on the DNA and therefore may perturb the DNA-protein interaction. To overcome this hurdle, we study the effect of HU on the DNA structure without applying external forces by using an improved tethered particle motion method. By combining the results with DNA curvature analysis from atomic force microscopy measurements we find that the DNA consists of two different curvature distributions and the measured persistence length is determined by their interplay. As a result, the effective persistence length adopts a bimodal property that depends primarily on the HU concentration. The results can be explained according to a recently suggested model that distinguishes single protein binding from cooperative protein binding., Imaging Science and Technology, Applied Sciences

Published

2011

5. Force-free measurements of the conformations of DNA molecules tethered to a wall

Author

Lindner, M. (author), Nir, G. (author), Medalion, S. (author), Dietrich, H.R.C. (author), Rabin, Y. (author), Garini, Y. (author), Lindner, M. (author), Nir, G. (author), Medalion, S. (author), Dietrich, H.R.C. (author), Rabin, Y. (author), and Garini, Y. (author)

Abstract

Using an optimized combination of tethered particle motion method, total internal reflection, and a gold nanobead, we measured the three-dimensional distribution of the free end of a tethered DNA molecule. The distribution along the axial z direction (perpendicular to the surface) is found to be Rayleigh-like, in agreement with wormlike chain and freely jointed chain simulations. Using these simulations, we show that the presence of the wall increases the correlations between the orientations of neighboring chain segments compared to free DNA. While the measured and the simulated planar (xy) distributions always agree with that of a Gaussian-random-walk (GRW) model, for short DNA lengths (1 ?m) studied in our experiment, the corresponding axial (z) distributions deviate from those predicted for a GRW confined to half-space., BT/Biotechnology, Applied Sciences

Published

2011

6. HU Protein Induces Incoherent DNA Persistence Length

Author

Nir, G. (author), Lindner, M. (author), Dietrich, H.R.C. (author), Girshevitz, O. (author), Vorgias, C.E. (author), Garini, Y. (author), Nir, G. (author), Lindner, M. (author), Dietrich, H.R.C. (author), Girshevitz, O. (author), Vorgias, C.E. (author), and Garini, Y. (author)

Abstract

HU is a highly conserved protein that is believed to play an important role in the architecture and dynamic compaction of bacterial DNA. Its ability to control DNA bending is crucial for functions such as transcription and replication. The effects of HU on the DNA structure have been studied so far mainly by single molecule methods that require us to apply stretching forces on the DNA and therefore may perturb the DNA-protein interaction. To overcome this hurdle, we study the effect of HU on the DNA structure without applying external forces by using an improved tethered particle motion method. By combining the results with DNA curvature analysis from atomic force microscopy measurements we find that the DNA consists of two different curvature distributions and the measured persistence length is determined by their interplay. As a result, the effective persistence length adopts a bimodal property that depends primarily on the HU concentration. The results can be explained according to a recently suggested model that distinguishes single protein binding from cooperative protein binding., Imaging Science and Technology, Applied Sciences

Published

2011