Depth-dependent photolabelling of membrane hydrophobic core with 9-diazofluorene-2-butyric acid.

Hydrophobic photoactivable reagents, which readily partition into membranes, have proved very useful for studying membrane hydrophobic core. These reagents have been linked to fatty acids in order to obtain amphipathic photoactivable reagents which label membranes more effectively. By varying the length of these amphipathic reagents, an attempt to label membrane hydrophobic core at different depths can be made. We report here 9-diazofluorene-2-butyric acid as a new photoactivable reagent which labels the single bilayer vesicles prepared from egg phosphatidylcholine. The labelling site on the fatty acyl chains could be traced to be between the carbon atom 4 and 6. The new probe thus labels the membrane at a site which is proximal to what can be predicted from its length and transverse location in membranes.

Design, synthesis, and fluorescence studies of fluorenyl fatty acids as new depth-dependent fluorescent probes for membranes: getting over the looping-back problem.

Fluorescent fatty acids have proved very useful in studying the membrane hydrophobic core. They readily partition into membranes or can be converted to phospholipids, which form integral components of membranes. By attaching the fluorescent chromophore to different positions along the alkyl chain of fatty acids, e.g., an anthroyloxy group attached via an ester linkage to n-hydroxystearic acid, membranes have been probed at different depths. While this is an interesting approach and has been extensively used, relatively little attention has been paid to the molecular design of these probes in order to have minimal membrane perturbation. In the present study we have looked into the general problem of design of such depth-dependent membrane probes. We report here a series of fluorenyl fatty acids with varying fatty acid chain lengths, i.e., (2-fluorenyl)acetic acid, -butyric acid, -hexanoic acid, and -octanoic acid, in order to obtain information at different depths in the membrane hydrophobic core. To see the effect of attachment of a hydrophobic tail on the orientation of such fatty acids in membranes, an n-butyl group was linked to the C-7 position of fluorene in (2-fluorenyl)butyric acid to get 4-(7-n-butylfluoren-2-yl)butyric acid. Further, to assess their ability to act as depth-dependent fluorescent probes, these fatty acids were incorporated in vesicles prepared from egg phosphatidylcholine, and their fluorescence quenching was studied with potassium iodide, Cu(II), 9,10-dibromostearic acid, and 12-bromostearic acid.(ABSTRACT TRUNCATED AT 250 WORDS)