Application of Electrochemical Devices to Characterize the Dynamic Actions of Helicases on DNA.

Much remains to be understood about the kinetics and thermodynamics of DNA helicase binding and activity. Here, we utilize probe-modified DNA monolayers on multiplexed gold electrodes as a sensitive recognition element and morphologically responsive transducer of helicase-DNA interactions. The electrochemical signals from these devices are highly sensitive to structural distortion of the DNA produced by the helicases. We used this DNA electrochemistry to distinguish the details of the DNA interactions of three distinct XPB helicases, which belong to the superfamily-2 of helicases. Clear changes in DNA melting temperature and duplex stability were observed upon helicase binding, shifts that could not be observed with conventional UV-visible absorption measurements. Binding dissociation constants were estimated in the range from 10 to 50 nM and correlated with observations of activity. ATP-stimulated DNA unwinding activity was also followed, revealing exponential time scales and distinct time constants associated with conventional and molecular wrench modes of operation further confirmed by crystal structures. These devices thus provide a sensitive measure of the structural thermodynamics and kinetics of helicase-DNA interactions.

DNA as a molecular wire: distance and sequence dependence.

Functional nanowires and nanoelectronics are sought for their use in next generation integrated circuits, but several challenges limit the use of most nanoscale devices on large scales. DNA has great potential for use as a molecular wire due to high yield synthesis, near-unity purification, and nanoscale self-organization. Nonetheless, a thorough understanding of ground state DNA charge transport (CT) in electronic configurations under biologically relevant conditions, where the fully base-paired, double-helical structure is preserved, is lacking. Here, we explore the fundamentals of CT through double-stranded DNA monolayers on gold by assessing 17 base pair bridges at discrete points with a redox active probe conjugated to a modified thymine. This assessment is performed under temperature-controlled and biologically relevant conditions with cyclic and square wave voltammetry, and redox peaks are analyzed to assess transfer rate and yield. We demonstrate that the yield of transport is strongly tied to the stability of the duplex, linearly correlating with the melting temperature. Transfer rate is found to be temperature-activated and to follow an inverse distance dependence, consistent with a hopping mechanism of transport. These results establish the governing factors of charge transfer speed and throughput in DNA molecular wires for device configurations, guiding subsequent application for nanoscale electronics.

Temperature dependence of electrochemical DNA charge transport: influence of a mismatch.

Charge transfer through DNA is of interest as DNA is both the quintessential biomolecule of all living organisms and a self-organizing element in bioelectronic circuits and sensing applications. Here, we report the temperature-dependent properties of DNA charge transport in an electronically relevant arrangement of DNA monolayers on gold under biologically relevant conditions, and we track the effects of incorporating a CA single base pair mismatch. Charge transfer (CT) through double stranded, 17mer monolayers was monitored by following the yield of electrochemical reduction of a Nile blue redox probe conjugated to a modified thymine. Analysis with cyclic voltammetry and square wave voltammetry shows that DNA CT increases significantly with temperature, indicative of more DNA bridges becoming active for transport. The mismatch was found to attenuate DNA CT at lower temperatures, but the effect of the mismatch diminished as temperature was increased. Voltammograms were analyzed to extract the electron transfer rate k(0), the electron transfer coefficient α, and the redox-active surface coverage Γ*. Arrhenius behavior was observed, with activation energies of 100 meV for electron transfer through well-matched DNA. Single CA mismatches increased the activation energy by 60 meV. These results have clear implications for sensing applications and are evaluated with respect to the prominent models of DNA CT.