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Bile acids modulate signaling by functional perturbation of plasma membrane domains.

The Journal of biological chemistry (2013-10-30)
Yong Zhou, Kelsey N Maxwell, Erdinc Sezgin, Maryia Lu, Hong Liang, John F Hancock, Elizabeth J Dial, Lenard M Lichtenberger, Ilya Levental
ZUSAMMENFASSUNG

Eukaryotic cell membranes are organized into functional lipid and protein domains, the most widely studied being membrane rafts. Although rafts have been associated with numerous plasma membrane functions, the mechanisms by which these domains themselves are regulated remain undefined. Bile acids (BAs), whose primary function is the solubilization of dietary lipids for digestion and absorption, can affect cells by interacting directly with membranes. To investigate whether these interactions affected domain organization in biological membranes, we assayed the effects of BAs on biomimetic synthetic liposomes, isolated plasma membranes, and live cells. At cytotoxic concentrations, BAs dissolved synthetic and cell-derived membranes and disrupted live cell plasma membranes, implicating plasma membrane damage as the mechanism for BA cellular toxicity. At subtoxic concentrations, BAs dramatically stabilized domain separation in Giant Plasma Membrane Vesicles without affecting protein partitioning between coexisting domains. Domain stabilization was the result of BA binding to and disordering the nonraft domain, thus promoting separation by enhancing domain immiscibility. Consistent with the physical changes observed in synthetic and isolated biological membranes, BAs reorganized intact cell membranes, as evaluated by the spatial distribution of membrane-anchored Ras isoforms. Nanoclustering of K-Ras, related to nonraft membrane domains, was enhanced in intact plasma membranes, whereas the organization of H-Ras was unaffected. BA-induced changes in Ras lateral segregation potentiated EGF-induced signaling through MAPK, confirming the ability of BAs to influence cell signal transduction by altering the physical properties of the plasma membrane. These observations suggest general, membrane-mediated mechanisms by which biological amphiphiles can produce their cellular effects.

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Deoxycholsäure Natriumsalz, BioXtra, ≥98.0% (dry matter, NT)
Sigma-Aldrich
Deoxycholsäure, ≥98% (HPLC)
Sigma-Aldrich
Deoxycholsäure Natriumsalz, ≥97% (titration)
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Deoxycholsäure, ≥99.0% (T)