Taylor Haynes scite author profile

The accurate sequencing of DNA using nanopores requires control over the speed of DNA translocation through the pores and also of the DNA conformation. Our studies show that ssDNA translocates through hourglass-shaped pores with hydrophobic constriction regions when an electric field is applied. The constriction provides a barrier to translocation and thereby slows down DNA movement through the pore compared with pores without the constriction. We show that ssDNA moves through these hydrophobic pores in an extended conformation and therefore does not form undesirable secondary structures that may affect the accuracy of partial current blockages for DNA sequencing.

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Translocation of flexible and tensioned ssDNA through in silico designed hydrophobic nanopores with two constrictions

Rattu

Belzunces

Haynes

et al. 2021

Nanoscale

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Translocation of flexible and tensioned ssDNA throughin silicodesigned hydrophobic nanopores with two constrictions

Rattu

Haynes

Wallace

et al. 2020

Preprint

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Protein-inspired nanopores with hydrophobic constriction regions have previously been shown to offer some promise for DNA sequencing.Here we explore a series of pores with two hydrophobic constrictions. The impact of nanopore radius, the nature of residues that define the constriction region and the flexibility of the ssDNA is explored. Our results show that aromatic residues slow down DNA translocation, and in the case of short DNA strands, they cause deviations from a linear DNA conformation. When DNA is under tension, translocation is once again slower when aromatic residues are present in the constriction. However, the lack of flexibility in the DNA backbone provides a narrower window of opportunity for the DNA bases to be retained inside the pore via interaction with the aromatic residues, compared to more flexible strands. Consequently, there is more variability in translocation rates for strands under tension. DNA entry into the pores is correlated to pore width, but no such correlation between width and translocation rate is observed.

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Taylor Haynes

Bilateral Testicular Torsion in a Pre-Term Neonate

Electric-Field-Driven Translocation of ssDNA through Hydrophobic Nanopores

Translocation of flexible and tensioned ssDNA through in silico designed hydrophobic nanopores with two constrictions

Translocation of flexible and tensioned ssDNA throughin silicodesigned hydrophobic nanopores with two constrictions

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