Abstract
Water permeability through single-file channels is affected by intrinsic factors such as their size and polarity and by external determinants like their lipid environment in the membrane. Previous computational studies revealed that the obstruction of the channel by lipid headgroups can be long-lived, in the range of nanoseconds, and that pore-length-matching membrane mimetics could speed up water permeability. To test the hypothesis of lipid-channel interactions modulating channel permeability, we designed different gramicidin A derivatives with attached acyl chains. By combining extensive molecular-dynamics simulations and single-channel water permeation measurements, we show that by tuning lipid-channel interactions, these modifications reduce the presence of lipid headgroups in the pore, which leads to a clear and selective increase in their water permeability.
| Original language | English |
|---|---|
| Pages (from-to) | 1698-1705 |
| Number of pages | 8 |
| Journal | Biophysical Journal |
| Volume | 103 |
| Issue number | 8 |
| DOIs | |
| Publication status | Published - 17 Oct 2012 |
Fields of science
- 103036 Theoretical physics
- 211904 Biomechanics
- 103020 Surface physics
- 210 Nanotechnology
- 104010 Macromolecular chemistry
- 106006 Biophysics
- 106022 Microbiology
- 106048 Animal physiology
- 209 Industrial Biotechnology
- 304 Medical Biotechnology
- 404 Agricultural Biotechnology, Food Biotechnology
- 106049 Ultrastructure research
- 103021 Optics
- 106002 Biochemistry
- 104017 Physical chemistry
- 208 Environmental Biotechnology
- 104014 Surface chemistry
- 106023 Molecular biology
- 107 Other Natural Sciences
- 301110 Physiology
- 301206 Pharmacology
- 206 Medical Engineering
- 301306 Medical molecular biology
- 302044 Medical physics
- 301902 Immunology
- 305910 Traffic medicine
JKU Focus areas
- Engineering and Natural Sciences (in general)