Synthesis and biological activity of sphingosines with integrated azobenzene switches.

A flexible synthetic approach towards biologically active sphingoid base-like compounds with an integrated azobenzene framework was achieved via installing a chiral amino-alcohol fragment into the azobenzene system by utilizing the Wittig olefination of substituted (E)-triphenyl[4-(phenyldiazenyl)benzyl]phosphonium salts and d-isoascorbic acid derived aldehydes. All the prepared derivatives underwent a series of experiments to probe their photochromic properties, including the reversible E/Z isomerisation, material fatigue and thermal relaxation rate. The targeted E- and Z-isomeric sphingoid analogues were screened in vitro for anticancer activity on a panel of seven human malignant cell lines. Cell viability experiments revealed outstanding antiproliferative/cytotoxic activities of all the tested compounds with IC50 values in the low micromolar range for the most active derivatives. The biological activity of E- and Z-isomeric forms is different. Their entirely accurate differentiation is prevented by the rapid thermal relaxation of the corresponding Z-isomers.

A 'Chiron' approach to novel phytosphingosine mimetics based on a cascade [3,3]-sigmatropic rearrangement.

Straightforward access to enantiomerically pure 3,4-diamino-3,4-dideoxyphytosphingosines, as novel analogues of natural d-ribo-phytosphingosine was accomplished, starting from two available chirons: dimethyl l-tartrate and d-isoascorbic acid. A sequential Overman rearrangement followed by late-stage introduction of the alkyl side chain moiety via olefin cross-metathesis is the cornerstone of this approach. The preliminary evaluation study of the synthesised sphingomimetics, based on their ability to inhibit a proliferation of human cancer cells, showed promising cytotoxicity against Jurkat and HeLa cells for (2R,3R,4S)-2,3,4-triaminooctadecan-1-ol trihydrochloride.