Ibrahim Halimeh scite author profile

Electrophysiological studies of the interaction of polymers with pores formed by bacterial toxins (1) provide a window on single molecule interaction with proteins in real time, (2) report on the behavior of macromolecules in confinement, and (3) enable label-free single molecule sensing. Using pores formed by the staphylococcal toxin α-hemolysin (aHL), a particularly pertinent observation was that, under high salt conditions (3-4 M KCl), the current through the pore is blocked for periods of hundreds of microseconds to milliseconds by poly(ethylene glycol) (PEG) oligomers (degree of polymerization approximately 10-60). Notably, this block showed monomeric sensitivity on the degree of polymerization of individual oligomers, allowing the construction of size or mass spectra from the residual current values. Here, we show that the current through the pore formed by aerolysin (AeL) from Aeromonas hydrophila is also blocked by PEG but with drastic differences in the voltage-dependence of the interaction. In contrast to aHL, AeL strongly binds PEG at high transmembrane voltages. This fact, which is likely related to AeL's highly charged pore wall, allows discrimination of polymer sizes with particularly high resolution. Multiple applications are now conceivable with this pore to screen various nonionic or charged polymers.

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Activity of the Gramicidin A Ion Channel in a Lipid Membrane with Switchable Physical Properties

Reiter

Zaitseva

Baaken³

et al. 2019

Langmuir

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Lipid bilayer membranes formed from the artificial 1,3-diamidophospholipid Pad-PC-Pad have the remarkable property that their hydrophobic thickness can be modified in situ: the particular arrangement of the fatty acid chains in Pad-PC-Pad allows them to fully interdigitate below 37 °C, substantially thinning the membrane with respect to the noninterdigitated state. Two stimuli, traversing the main phase transition temperature of the lipid or addition of cholesterol, have previously been shown to disable the interdigitated state. Both manipulations cause an increase in hydrophobic thickness of about 25 Å due to enhanced conformational entropy of the lipids. Here, we characterize the interdigitated state using electrophysiological recordings from free-standing lipid-membranes formed on micro structured electrode cavity arrays. Compared to standard membranes made from 1,2-diphytanoyl-sn-glycero-3-phosphocholin (DPhPC), pure Pad-PC-Pad membranes at room temperature had lowered electroporation threshold and higher capacitance. Ion channel formation by the peptide Gramicidin A was clearly facilitated in pure Pad-PC-Pad membranes at room temperature, with activity occurring at significantly lower peptide concentrations and channel dwell times increased by 2 orders of magnitude with respect to DPhPC-membranes. Both elevation of temperature beyond the phase transition and addition of cholesterol reduced channel dwell times, as expected if the reduced membrane thickness stabilized channel formation due to decreased hydrophobic mismatch.

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Translocation and Binding in the Recognition of Short Oligonucleotides by a Biological Nanopore

Boukhet

Halimeh

Baaken³

et al. 2017

Biophysical Journal

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heterogeneous polymer through an outer mitochondrial membrane passive transport channel, the voltage-dependent anion channel (VDAC), depends on the electrical and membrane association properties of both the charged and uncharged regions of a-synuclein. We introduce complementary models that describe this motion in two limits: first, a simple Markov model accounts for the simultaneous interaction of multiple a-synuclein molecules with VDAC for high membrane surface a-synuclein coverage. Second, the detailed energy landscape of this motion in the dilute limit can be reconstructed from the entropic, electrostatic, and membrane binding components by optimizing a drift-diffusion framework to the experimental data. The models predict the probability of a-synuclein translocation across VDAC pore, with immediate implications for the (patho-)physiological role of a-synuclein in mitochondrial functioning. Finally, we show that the time-dependent effect of a-synuclein on the electrical properties of VDAC reports on the motion of the junction between the charged and uncharged regions of the polymer through the pore.

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Membrane Arrays for Single-Channel Recordings

Zaitseva¹,

Petersen²,

Martinez

et al. 2018

Biophysical Journal

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Length- and Species-Selective Detection of Short Oligonucleotides using a Microelectrode Cavity Array of Biological Nanopores

Halimeh

Cao

Baaken³

et al. 2016

Biophysical Journal

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Ibrahim Halimeh

High-Resolution Size-Discrimination of Single Nonionic Synthetic Polymers with a Highly Charged Biological Nanopore

Activity of the Gramicidin A Ion Channel in a Lipid Membrane with Switchable Physical Properties

Translocation and Binding in the Recognition of Short Oligonucleotides by a Biological Nanopore

Membrane Arrays for Single-Channel Recordings

Length- and Species-Selective Detection of Short Oligonucleotides using a Microelectrode Cavity Array of Biological Nanopores

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