Aureobasidins: structure-activity relationships for the inhibition of the human MDR1 P-glycoprotein ABC-transporter.

Cyclic depsipeptide cyclo-[D-Hmp(1)-L-MeVal(2)-L-Phe(3)-L-MePhe(4)-L-Pro(5)-L-aIle+ ++(6)-L-MeVal(7)-L-Leu(8)-L-betaHOMeVal(9)], the antifungal antibiotic aureobasidin A (AbA), was reported to interfere with ATP-binding cassette (ABC) transporters in yeast and mammalian cells, particularly the MDR1 P-glycoprotein (Pgp), a transmembrane phospholipid flippase or "hydrophobic vacuum cleaner" that mediates multidrug resistance (MDR) of cancer cells. In a standardized assay that measures Pgp function by the Pgp-mediated efflux of the calcein-AM Pgp substrate and uses human lymphoblastoid MDR-CEM (VBL(100)) cells as highly resistant Pgp-expressing cells and the cyclic undecapeptide cyclosporin A (CsA) as a reference MDR-reversing agent (IC(50) of 3.4 microM), AbA was found to be a more active Pgp inhibitor (IC(50) of 2.3 microM). Out of seven natural analogues and 18 chemical derivatives of AbA, several were shown to display even more potent Pgp-inhibitory activity. The Pgp-inhibitory activity was increased about 2-fold by some minor modifications such as those found in the naturally occurring aureobasidins AbB ([D-Hiv(1)]-AbA), AbC ([Val(6)]-AbA), and AbD [gammaHOMeVal(9)]-AbA). The replacement of the [Phe(3)-MePhe(4)-Pro(5)] tripeptide by an 8-aminocaprylic acid or the N(7)()-desmethylation of MeVal(7) led to only a 3.3-fold decreased capacity to inhibit Pgp function, suggesting that the Pgp inhibitory potential of aureobasidins, though favored by the establishment of an antiparallel beta-sheet between the [D-Hmp(1)-L-MeVal(2)-L-Phe(3)] and [L-aIle(6)-L-MeVal(7)-L-Leu(8)-] tripeptides, does not critically depend on the occurrence of the [L-Phe(3)-L-MePhe(4)-L-Pro(5)-L-aIle(6)] type II' beta-turn secondary structure. In contrast, the most potent Pgp inhibitors were found among AbA analogues with [betaHO-MeVal(9)] residue alterations, with some data suggesting a negative impact of the [L-Leu(8)-L-betaHOMeVal(9)-D-Hmp(1)] gamma-turn secondary structure on Pgp inhibitory potential. The [2,3-dehydro-MeVal(9)]-AbA was the most potent Pgp inhibitory aureobasidin, being 13-fold more potent than AbA and 19-fold more potent (on a molar basis) than CsA. Finally, there was no correlation between the SAR for the human MDR1 Pgp inhibition and the SAR for Saccharomyces cerevisiae antifungal activity, which is mediated by an inositol phosphoceramide synthase activity.

The potent immunosuppressive cyclosporin FR901459 inhibits the human P-glycoprotein and formyl peptide receptor functions.

By sequestering cytosolic calcineurin into a molecular complex with cyclophilin and its consequent T-cell dysfunction, some cyclosporins, such as CsA and FR901459 ([Thr2-Leu5-Leu10]-CsA), display potent immunosuppressive activity. Independently on this property, cyclosporins may display one or more other biological activities mediated by interaction with cell surface glycoproteins. Several cyclosporins inhibit the function of human MDRI-encoded P-glycoprotein (Pgp), a flippase known to cause cancer multidrug resistance, but also expressed by some normal immunocompetent cells and by normal epithelial cells which control drug bioavailability in vivo. CsA is known to be a potent Pgp inhibitor with a 3.2 microM IC50 in an assay where the most potent derivative SDZ PSC 833 gives a 0.49 microM IC50. FR901459 is now shown to be a good Pgp inhibitor, being 2-fold weaker only (IC50 of 6 microM) than CsA. Some cyclosporins may also inhibit the function of the human FPR1-encoded formyl peptide receptor (FPR), a chemotactic receptor whose absence is known to impair antibacterial immunity. Yet this inhibition is very weak for all, but one of them, CsH, whose 0.15 micro/M IC50 makes it a much more potent FPR inhibitor than CsA (IC50 >10 microM in the same assay). FR901459 is now shown to be a very potent inhibitor of FPR function (IC50 of 0.6 microM). Since CsH shows little Pgp-inhibitory activity and has no known immunosuppressive activity, FR901459 displays a unique pharmacological profile: like CsA, it inhibits T-cell function; less than CsA, it can inhibit Pgp function on selected leukocyte subsets and on epithelial barriers known to control drug bioavailability; however, much more efficiently than CsA, it can inhibit the FPR function, a receptor involved in some leukocytic inflammatory responses to chemotactic peptides.