The 3-hydroxy group and 4,5-trans double bond of sphingomyelin are essential for modulation of galactosylceramide transmembrane asymmetry

A1 Journal article (refereed)


Internal Authors/Editors


Publication Details

List of Authors: Malewicz B, Valiyaveettil JT, Jacob K, Byun HS, Mattjus P, Baumann WJ, Bittman R, Brown RE
Publisher: BIOPHYSICAL SOCIETY
Publication year: 2005
Journal: Biophysical Journal
Journal acronym: BIOPHYS J
Volume number: 88
Issue number: 4
Start page: 2670
End page: 2680
Number of pages: 11
ISSN: 0006-3495
eISSN: 1542-0086


Abstract

The structural features of SPM that control the transbilayer distribution of beta- GalCer in POPC vesicles were investigated by C-13- and P-31- NMR spectroscopy using lipid analogs that share physical similarities with GalCer or SPM. The SPM analogs included N- palmitoyl- 4,5- dihydro- SPM, 3- deoxy- SPM, 1- alkyl- 2- amidophosphatidylcholine, and dipalmitoylphosphatidylcholine, a popular model "raft lipid''. The transbilayer distributions of the SPM analogs and SPM in POPC vesicles were similar by P-31- NMR. To observe the dramatic change in GalCer transbilayer distribution that occurs when SPM is included in POPC vesicles, the 3- OH group, 4,5- trans double bond, and amide linkage all were required in SPM. However, inclusion of 2 and 10 mol % dihydroSPM in SPM/ POPC ( 1: 1) vesicles mitigated and completely abrogated the effect of SPM on the transbilayer distribution of GalCer. Despite sharing some structural features with GalCer and localizing preferentially to the inner leaflet of POPC vesicles, dimyristoylphosphatidylethanolamine did not undergo a change in transbilayer distribution when SPM was incorporated into the vesicles. The results support the hypothesis that specific interactions may be favored among select sphingolipids in curvature- stressed membranes and emphasize the potential importance of the SPM- dihydroSPM ratio in membrane fission and fusion processes associated with vesicle biogenesis and trafficking.

Last updated on 2019-17-10 at 02:58