Replication Dynamics

Fast dynamics of supercoiled DNA revealed by single-molecule experiments.

Proceedings of the National Academy of Sciences of the United States of America 104:29 (2007) 11957-11962

Authors:

Aurélien Crut, Daniel A Koster, Ralf Seidel, Chris H Wiggins, Nynke H Dekker

Abstract:

The dynamics of supercoiled DNA play an important role in various cellular processes such as transcription and replication that involve DNA supercoiling. We present experiments that enhance our understanding of these dynamics by measuring the intrinsic response of single DNA molecules to sudden changes in tension or torsion. The observed dynamics can be accurately described by quasistatic models, independent of the degree of supercoiling initially present in the molecules. In particular, the dynamics are not affected by the continuous removal of the plectonemes. These results set an upper bound on the hydrodynamic drag opposing plectoneme removal, and thus provide a quantitative baseline for the dynamics of bare DNA.

Role of tension and twist in single-molecule DNA condensation.

Physical review letters 98:5 (2007) 058103

Authors:

K Besteman, S Hage, NH Dekker, SG Lemay

Abstract:

Using magnetic tweezers, we study in real time the condensation of single DNA molecules under tension. We find that DNA condensation occurs via discrete nucleated events. By measuring the influence of an imposed twist, we show that condensation is initiated by the formation of a plectonemic supercoil. This demonstrates a strong interplay between the condensation transition and externally imposed mechanical constraints.

An RNA toolbox for single-molecule force spectroscopy studies.

Nucleic acids research 35:19 (2007) 6625-6639

Authors:

Igor D Vilfan, Wiecher Kamping, Michiel van den Hout, Andrea Candelli, Susanne Hage, Nynke H Dekker

Abstract:

Precise, controllable single-molecule force spectroscopy studies of RNA and RNA-dependent processes have recently shed new light on the dynamics and pathways of RNA folding and RNA-enzyme interactions. A crucial component of this research is the design and assembly of an appropriate RNA construct. Such a construct is typically subject to several criteria. First, single-molecule force spectroscopy techniques often require an RNA construct that is longer than the RNA molecules used for bulk biochemical studies. Next, the incorporation of modified nucleotides into the RNA construct is required for its surface immobilization. In addition, RNA constructs for single-molecule studies are commonly assembled from different single-stranded RNA molecules, demanding good control of hybridization or ligation. Finally, precautions to prevent RNase- and divalent cation-dependent RNA digestion must be taken. The rather limited selection of molecular biology tools adapted to the manipulation of RNA molecules, as well as the sensitivity of RNA to degradation, make RNA construct preparation a challenging task. We briefly illustrate the types of single-molecule force spectroscopy experiments that can be performed on RNA, and then present an overview of the toolkit of molecular biology techniques at one's disposal for the assembly of such RNA constructs. Within this context, we evaluate the molecular biology protocols in terms of their effectiveness in producing long and stable RNA constructs.

Optical tweezers for force measurements on DNA in nanopores

Review of Scientific Instruments AIP Publishing 77:10 (2006) 105105

Authors:

UF Keyser, J van der Does, C Dekker, NH Dekker

Nanobubbles in solid-state nanopores.

Physical review letters 97:8 (2006) 088101

Authors:

RMM Smeets, UF Keyser, MY Wu, NH Dekker, C Dekker

Abstract:

From conductance and noise studies, we infer that nanometer-sized gaseous bubbles (nanobubbles) are the dominant noise source in solid-state nanopores. We study the ionic conductance through solid-state nanopores as they are moved through the focus of an infrared laser beam. The resulting conductance profiles show strong variations in both the magnitude of the conductance and in the low-frequency noise when a single nanopore is measured multiple times. Differences up to 5 orders of magnitude are found in the current power spectral density. In addition, we measure an unexpected double-peak ionic conductance profile. A simple model of a cylindrical nanopore that contains a nanobubble explains the measured profile and accounts for the observed variations in the magnitude of the conductance.