Docking simulation study and kinase selectivity of f152A1 and its analogs.

f152A1 is a potent inhibitor of MAP kinases and TNFα-transcription. When f152A1 and its analogs are assayed against ERK2, MEK1, and MEKK1, these compounds show different inhibition profiles. It is considered that the highly reactive cis-enone moiety and modifications of the 14-membered resorcylic lactone ring may determine their kinase selectivity and potency. In order to clarify the different potencies of these compounds toward MAP kinases, conformational analysis, molecular orbital studies, and docking simulation studies using model structures of ERK2, MEK1, and MEKK1 have been performed. These studies have revealed that (i) ligand binding does not depend on chemical bonding but on molecular interaction (molecular orbital analysis), (ii) the cis-enone moiety of inhibitors is in the range of Michael addition reaction with the Cys166 residue in ERK2 (docking simulation study), and (iii) molecular shape of M1(8) conformations is the best fit for the ATP binding site of kinases. Considering the molecular docking analysis of these inhibitors in these kinases, molecular shape will be most important to their corresponding kinases activities.

Conformational analyses and MO studies of f152A1 and its analogues as potent protein kinase inhibitors.

f152A1 was isolated from a fermentation broth of Curvularia verruculosa and characterized as a potent inhibitor of TNFalpha transcription, with anti-inflammatory activity. f152A1 and several analogues displayed inhibitory activity against the MAP kinases ERK2 and MEK1 in in vitro kinase assays. Through SAR studies on f152A1 and analogues prepared via total synthesis, we have identified structural features that contribute to inhibitory activity. To rationalize these results and to aid in the discovery process, a combination of high temperature molecular dynamics and MOPAC AM1 semiempirical molecular orbital method studies was used in studies that yielded a postulated active conformation, M1(8). This active conformation M1(8) reflects a high degree of conformational similarity among f152A1 and its more potent analogues. In view of the highly reactive cis-enone moiety in the flexible 14-membered resorcylic acid lactone ring of f152A1, the chemical reactivities of the enone moieties in various analogues were assessed by molecular orbital calculations. The enone reactivity analyses suggested that these inhibitors were prone to Michael addition at the alpha,beta-unsaturated ketone moiety and might chemically react with cysteine residues in the ATP-binding site of MAP kinases. Reactivity of the cis-enone moiety and the M1(8) conformation make important contributions to the inhibitory activity of MAP kinases.