Abstract |
Duplex DNA can be analyzed by a variety of techniques in order to
characterize DNA-protein interactions; parameters assessed during the
binding interaction include intrinsic properties of the DNA, such as length and
curvature, the sequence specificity of the proteins and charge effects. A
primary goal of this work was to explore the ability to use acoustic biosensors
for monitoring conformational changes of surface-attached biomolecules
during binding interactions; a task that is challenging and of significance to
biotechnology. A second goal was to use experimental data to test the validity
of a novel viscosity-based theoretical model, which uses acoustic data to
provide quantitative information related to DNA conformation and bending
processes.
In a first step, the parameters examined for surface-attached DNA in
solution were the length of the molecules, their shape and their attachment
mode. "Straight" ds-DNA molecules of various lengths, as well as "bent" and
"triangle" DNA molecules were constructed and attached to the device surface;
results clearly showed that the acoustic response could probe variations in the
conformation of those molecules. Furthermore, the excellent agreement found
between theoretical predictions and experimental data verified that the
acoustic signal can be used as a measure of the intrinsic viscosity of the
attached biomolecules at the device surface/liquid interface.
A second set of experiments was performed in order to investigate nonspecific
protein-DNA interactions. Electrostatic binding of a positively charged
histone protein on the negatively charged backbone of the surface immobilized
DNA was examined as a function of surface charge, DNA length, shape and
surface coverage. Acoustic measurements reflected on the viscoelastic
behavior of the adsorbed biomolecules suggesting the formation of a flat,
collapsed DNA film, cross-linked with histone proteins. This explanation was
further validated by AFM imaging of histone-DNA complex; AFM images
verified the interpretation that non-specific charge interactions lead to the
formation of rigid, compact biomolecular layers.
Last but not least, sequence specific DNA bending was investigated as a third
parameter that, in addition to intrinsic shape and charge, affects protein-DNA
interactions. The method employed for that purpose was the oligonucleotidedirected
triple helix formation, a general method for the sequence-specific
recognition of double helical DNA. Using triple helix formation for DNA
recognition in the major groove, a bifunctional oligonucleotide was designed
to mimic a DNA bending protein. Acoustic measurements were again able to
discriminate the various conformations adopted by the DNA molecules and
were correlated to published values. The significance of these results is
demonstrated by the fact that for the first time, acoustic data can be combined
with viscosity theory to provide not just qualitative but quantitative information
on the relatively complex phenomenon of induced DNA bending.
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