TY - JOUR
T1 - Protein-Sphingolipid Interactions within Cellular Membranes
AU - Haberkant, P.
AU - Schmitt, O.
AU - Contreras, F.-X.
AU - Thiele, C.
AU - Hanada, K.
AU - Sprong, H.
AU - Reinhard, C.
AU - Wieland, F.T.
AU - Brügger, B.
PY - 2007
Y1 - 2007
N2 - Each intracellular organelle critically depends on maintaining its specific lipid composition that in turn contributes to the biophysical properties of the membrane. With our knowledge increasing about the organization of membranes with defined microdomains of different lipid compositions, questions arise as to the molecular mechanisms that underly targeting to/segregation from microdomains of a given protein. In addition to specific lipid-transmembrane segment interactions as a basis for partitioning, presence in a given microdomain may alter the conformation of proteins, and, thus, the activity and availability for regulatory modifications. However, for most proteins the specific lipid environment of transmembrane segments as well as its relevance to protein function and overall membrane organization is largely unknown. In order to help filling this gap, we have synthezised a novel photoactive sphingolipid precursor that, together with a precursor for phosphoglycerolipids and with photo-cholesterol, was investigated in vivo with regard to specific protein transmembrane span-lipid interactions. As proof of principle we show specific labeling of the ceramide transporter with the sphingolipid probe, and describe specific in vivo interactions of lipids with caveolin-1, PI-TPß, and the mature form of nicastrin.
This novel photolabile sphingolipid probe allows detection of protein-sphingolipid interactions within the membrane bilayer of living cells.
AB - Each intracellular organelle critically depends on maintaining its specific lipid composition that in turn contributes to the biophysical properties of the membrane. With our knowledge increasing about the organization of membranes with defined microdomains of different lipid compositions, questions arise as to the molecular mechanisms that underly targeting to/segregation from microdomains of a given protein. In addition to specific lipid-transmembrane segment interactions as a basis for partitioning, presence in a given microdomain may alter the conformation of proteins, and, thus, the activity and availability for regulatory modifications. However, for most proteins the specific lipid environment of transmembrane segments as well as its relevance to protein function and overall membrane organization is largely unknown. In order to help filling this gap, we have synthezised a novel photoactive sphingolipid precursor that, together with a precursor for phosphoglycerolipids and with photo-cholesterol, was investigated in vivo with regard to specific protein transmembrane span-lipid interactions. As proof of principle we show specific labeling of the ceramide transporter with the sphingolipid probe, and describe specific in vivo interactions of lipids with caveolin-1, PI-TPß, and the mature form of nicastrin.
This novel photolabile sphingolipid probe allows detection of protein-sphingolipid interactions within the membrane bilayer of living cells.
M3 - Article
SN - 0022-2275
JO - Journal of Lipid Research
JF - Journal of Lipid Research
ER -