Principles of organelle membrane bridging established using cytosolic tether mimics

The interactions between different intra-cellular organelles, including the endoplasmic reticulum, have recently been in focus thanks to the tremendous progress in imaging them using cryogenic transmission electron microscopy. However, they are still difficult to study in cellulo, and reconstituting these systems has been a standing challenge. Here we achieve this task using a giant unilamellar vesicle (GUV) and supported lipid bilayer (SLB) system. The tethers, which may reside in the cytosol when unbound, are mimicked by single (or double) stranded DNA sequences of two different lengths with ends that are self-sticky, and with terminal cholesterol moieties which insert into GUV or SLB membranes. The DNA-tethers, bound by their sticky-end, can exist in two possible states - either with both cholesterols in the same membrane or each cholesterol in a different membrane, the latter conformation leading to adhesion. Exchange of tether-molecules between the membranes occurs through the aqueous phase. By developing theoretical arguments that are supported in our experiments, we show that this possibility of exchange and the relative difference in the projected area between the two states drives the adhesion due to collective entropic considerations, rather than the usually considered enthalpy of binding. The establishment of this fundamentally different interaction between two membranes suggests that in physiological conditions, the regulation of contact formation inside cells may be very different from the case of the much studied ligand-receptor pairing on the external cell membrane.