George Papadakis scite author profile

DNA bending plays a significant role in many biological processes, such as gene regulation, DNA replication, and chromosomal packing. Understanding how such processes take place and how they can, in turn, be regulated by artificial agents for individual oriented therapies is of importance to both biology and medicine. In this work, we describe the application of an acoustic wave device for characterizing the conformation of DNA molecules tethered to the device surface via a biotin-neutravidin interaction. The acoustic energy dissipation per unit mass observed upon DNA binding is directly related to DNA intrinsic viscosity, providing quantitative information on the size and shape of the tethered molecules. The validity of the above approach was verified by showing that the predesigned geometries of model double-stranded and triple-helix DNA molecules could be quantitatively distinguished: the resolution of the acoustic measurements is sufficient to allow discrimination between same size DNA carrying a bent at different positions along the chain. Furthermore, the significance of this analysis to the study of biologically relevant systems is shown during the evaluation of DNA conformational change upon protein (histone) binding.

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Shear acoustic wave biosensor for detecting DNA intrinsic viscosity and conformation: A study with QCM-D

Tsortos

Papadakis

Gizeli

2008

Biosensors and Bioelectronics

124

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All-plastic, low-power, disposable, continuous-flow PCR chip with integrated microheaters for rapid DNA amplification

Moschou

Vourdas

Kokkoris

et al. 2014

Sensors and Actuators B: Chemical

120

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Direct Detection of DNA Conformation in Hybridization Processes

et al. 2012

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DNA hybridization studies at surfaces normally rely on the detection of mass changes as a result of the addition of the complementary strand. In this work we propose a mass-independent sensing principle based on the quantitative monitoring of the conformation of the immobilized single-strand probe and of the final hybridized product. This is demonstrated by using a label-free acoustic technique, the quartz crystal microbalance (QCM-D), and oligonucleotides of specific sequences which, upon hybridization, result in DNAs of various shapes and sizes. Measurements of the acoustic ratio ΔD/ΔF in combination with a "discrete molecule binding" approach are used to confirm the formation of straight hybridized DNA molecules of specific lengths (21, 75, and 110 base pairs); acoustic results are also used to distinguish between single- and double-stranded molecules as well as between same-mass hybridized products with different shapes, i.e., straight or "Y-shaped". Issues such as the effect of mono- and divalent cations to hybridization and the mechanism of the process (nucleation, kinetics) when it happens on a surface are carefully considered. Finally, this new sensing principle is applied to single-nucleotide polymorphism detection: a DNA hairpin probe hybridized to the p53 target gene gave products of distinct geometrical features depending on the presence or absence of the SNP, both readily distinguishable. Our results suggest that DNA conformation probing with acoustic wave sensors is a much more improved detection method over the popular mass-related, on/off techniques offering higher flexibility in the design of solid-phase hybridization assays.

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