Formation and dynamics of endoplasmic reticulum-like lipid nanotube networks
Journal article, 2017

We report on the self-organized formation and dynamics of artificial lipid nanotube networks, which, in terms of morphology and behavior, resemble the endoplasmic reticulum(ER) of biological cells. The networks, initially generated from a solid- supported planar phospholipid membrane, undergo a morphological transformation, triggered by the chelation and removal of Ca2+ from the environment surrounding the membrane. Calcium depletion gradually causes de-pinning, thus de-wetting, at the membrane-substrate interface. We observe dynamic re-arrangements very similar to the ones reported for the cellular ER, such as sliding of tubes and formation of new junctions, and quantify these transformations. We also show occurrences of the dynamic replacement of lipidic particles on nanotubes as indicators for the existence of a tension gradient throughout the network, as well as the spontaneous formation of small vesicles from semi-free floating tubes. We propose that these artificial networks are suitable to serve as a bottom-up-generated structural model for the cellular ER, whose fascinating characteristic morphology is suggested to be tied to its biological function, but with respect to formation, dynamics, and functional details still incompletely understood.

Tubules

Membrane-Proteins

Migration

Bilayer

Author

T. Bilal

Irep Gözen

Chalmers, Chemistry and Chemical Engineering, Chemistry and Biochemistry

Biomaterials Science

2047-4830 (ISSN) 2047-4849 (eISSN)

Vol. 5 7 1256-1264

Subject Categories

Physical Chemistry

DOI

10.1039/c7bm00227k

More information

Created

10/8/2017