Abstract
Being capable of characterizing DNA local bending is essential to understand thoroughly many biological processes because they involve a local bending of the double helix axis, either intrinsic to the sequence or induced by the binding of proteins. Developing a method to measure DNA bend angles that does not perturb the conformation of the DNA itself or the DNA-protein complex is a challenging task. Here, we propose a joint theory-experiment high throughput approach to rigorously measure such bend angles using the Tethered Particle Motion (TPM) technique. By carefully modeling the TPM geometry, we propose a simple formula based on a kinked Worm-Like Chain model to extract the bend angle from TPM measurements. Using constructs made of 575 base-pair DNAs with in-phase assemblies of 1 to 7 6A-tracts, we find that the sequence CA6CGG induces a bend angle of 19 [4] {\deg}. Our method is successfully compared to more theoretically complex or experimentally invasive ones such as cyclization, NMR, FRET or AFM. We further apply our procedure to TPM measurements from the literature and demonstrate that the angles of bends induced by proteins, such as Integration Host Factor (IHF) can be reliably evaluated as well.
Highlights
920-Plat Dynamics of Human Telomeric G-Quadruplex Probed by Single Molecule Fluorescence-Force Spectroscopy Jaba Mitra[1], Thuy T.M
Central to the debate has been the argument as to whether overstretched DNA is characterized by strand separation or a deformed, but still base-paired, form called S-DNA
Nanogold and quantum dot conjugates have been used extensively as biomolecular markers, while DNA base pairing has directed the self-assembly of discrete groupings and arrays of organic and inorganic nanocrystals in formation of a network solid for electronic devices and memory components
Summary
920-Plat Dynamics of Human Telomeric G-Quadruplex Probed by Single Molecule Fluorescence-Force Spectroscopy Jaba Mitra[1], Thuy T.M. Central to the debate has been the argument as to whether overstretched DNA is characterized by strand separation (i.e. melted DNA, M-DNA) or a deformed, but still base-paired, form called S-DNA. Recent consensus has emerged that both forms co-exist and that base-pair interactions (A-T vs G-C) likely dictate the structural motif.
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