Kahalalide F, the only member of the family of peptides called kahalalides, isolated from the sacoglossan mollusc Elysia rufescens and the green alga Bryopsis sp., with important bioactivity, is in clinical trials for treatment of prostate cancer. An efficient solid-phase synthetic approach is reported. Kahalalide F presents several synthetic difficulties: (i) an ester bond between two beta-branched and sterically hindered amino acids; (ii) a didehydroamino acid; and (iii) a rather hydrophobic sequence with two fragments containing several beta-branched amino acids in a row, one of them terminated with a saturated aliphatic acid. The cornerstones of our strategy were (i) a quasiorthogonal protecting system with allyl, tert-butyl, fluorenyl, and trityl-based groups, (ii) azabenzotriazole coupling reagents, (iii) formation of the didehydroamino acid residue on the solid phase, and (iv) cyclization and final purification in solution. HPLC, high-field NMR, and biological activity studies showed that the correct stereochemistry of the natural product is that proposed by Rinehart et al. whereas the stereochemistry proposed by Scheuer et al. is that of a biologically less active diastereoisomer.
Kahalalide F (KF) is a natural product currently under phase II clinical trials. Here, we report the solid phase synthesis of 132 novel analogues of kahalalide F and their in vitro activity on a panel of up to 14 cancer cell lines. The structure-activity relationship of these analogues revealed that KF is highly sensitive to backbone stereotopical modification but not to side chain size modification. These observations suggest that this compound has a defined conformational structure and also that it interacts with chiral compounds through its backbone and not through its side chains. The N-terminal aliphatic acid appears to be a hydrophobic buoy in a membrane-like environment. Moreover, significant improvement of the in vitro activity was achieved.
α,β‐Didehydroamino acids are frequently encountered in natural peptides with important biological activity. Herein, we report a mild and convenient method for the preparation of peptides containing α,β‐didehydroamino acids, where solid‐phase techniques are used both for elongation of the peptide chain and formation of the double bond. This bond is formed through a β‐elimination reaction, using a water soluble carbodiimide as the activating reagent of the hydroxyl function, and catalyzed by CuCl.
[reaction: see text] A solid-phase method for the synthesis of tentoxin has been developed. Two key steps-dehydration and N-alkylation-are carried out while the peptide is anchored to the resin. The method, which has been validated by the preparation of a library of tentoxin analogues, should be applicable to the generation of further libraries that have the tentoxin scaffold structure, as well as other structures containing N-alkylated didehydroamino acids.
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