4.5 Article

Experimental Investigations on the Conductance of Lipid Membranes under Differential Hydrostatic Pressure

Journal

MEMBRANES
Volume 12, Issue 5, Pages -

Publisher

MDPI
DOI: 10.3390/membranes12050479

Keywords

bilayer lipid membrane; conductance; curvature; pressure; electrophysiology

Funding

  1. National Science Foundation [1554166]
  2. National Institute of Health [P20GM103408, P20GM109095]
  3. Division Of Materials Research
  4. Direct For Mathematical & Physical Scien [1554166] Funding Source: National Science Foundation

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Studies have shown that the curvature of lipid membranes influences permeability, with most experiments using flat membranes ignoring this physiological relevance. By adapting an experimental system with differential hydrostatic pressure on a lipid membrane and measuring capacitance and conductance, a strong correlation between membrane geometry changes and conductance was observed. This system may help understand the intricate relationship between membrane mechanics, cellular functionalities, and mechanical stimulation effects.
The unassisted transport of inorganic ions through lipid membranes has become increasingly relevant to an expansive range of biological phenomena. Recent simulations indicate a strong influence of a lipid membrane's curvature on its permeability, which may be part of the overall cell sensitivity to mechanical stimulation. However, most ionic permeability experiments employ a flat, uncurved lipid membrane, which disregards the physiological relevance of curvature on such investigations. To fill this gap in our knowledge, we adapted a traditional experimental system consisting of a planar lipid membrane, which we exposed to a controlled, differential hydrostatic pressure. Our electrophysiology experiments indicate a strong correlation between the changes in membrane geometry elicited by the application of pressure, as inferred from capacitance measurements, and the resulting conductance. Our experiments also confirmed the well-established influence of cholesterol addition to lipid membranes in adjusting their mechanical properties and overall permeability. Therefore, the proposed experimental system may prove useful for a better understanding of the intricate connections between membrane mechanics and adjustments of cellular functionalities upon mechanical stimulation, as well as for confirmation of predictions made by simulations and theoretical modeling.

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