AI Article Synopsis
- ABCA1 is a transporter that helps regulate cholesterol levels in cells by facilitating its release, but the exact mechanism of how it works remains unclear.
- Research using living HeLa cells revealed that ABCA1 alters the lipid environment at the plasma membrane, leading to changes in membrane properties and disrupting the organization of lipids.
- These findings indicate that ABCA1's main role is to manage the distribution of lipids in the cell membrane, which is crucial for the effective transfer of cholesterol from cells.
Article Abstract
The ABCA1 transporter orchestrates cellular lipid homeostasis by promoting the release of cholesterol to plasmatic acceptors. The molecular mechanism is, however, unknown. We report here on the biophysical analysis in living HeLa cells of the ABCA1 lipid microenvironment at the plasma membrane. The modifications of membrane attributes induced by ABCA1 were assessed at both the outer and inner leaflet by monitoring either the lifetime of membrane inserted fluorescent lipid analogues by fluorescence lifetime imaging microscopy (FLIM) or, respectively, the membrane translocation of cationic sensors. Analysis of the partitioning of dedicated probes in plasma membrane blebs vesiculated from these cells allowed visualization of ABCA1 partitioning into the liquid disordered-like phase and corroborated the idea that ABCA1 destabilizes the lipid arrangement at the membrane. Specificity was demonstrated by comparison with cells expressing an inactive transporter. The physiological relevance of these modifications was finally demonstrated by the reduced membrane mobility and function of transferrin receptors under the influence of an active ABCA1. Collectively, these data assess that the control of both transversal and lateral lipid distribution at the membrane is the primary function of ABCA1 and positions the effluxes of cholesterol from cell membranes downstream to the redistribution of the sterol into readily extractable membrane pools.
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| http://dx.doi.org/10.1096/fj.08-122192 | DOI Listing |
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