Gephyronic acid

Biological Properties

Preliminary studies demonstrated that Gephyronic acid inhibited growth of yeast and molds as well as elicited a cytostatic effect through the inhibition of eukaryotic protein synthesis in mammalian cell cultures. Feeding experiments done with radioactive precursors showed a drastic difference in incorporation of leucine by a human leukemic cell like K-562, but little difference in the incorporation of uridine and thymidine. This suggested that the primary target of gephyronic acid is protein synthesis. As such, it is a potential target for cancer chemotherapy. Gene expression profiling of human breast cancer cell lines is underway in an effort to further define the potential of Gephyronic acid as a chemotherapeutic lead.

Screening of a library of compounds derived from myxobacteria found that Gephyronic acid was the strongest inhibitor of processing bodies (P-bodies) assembly. P-bodies are discrete cytoplasmic mRNP granules that contain non-translating mRNA and protein from the mRNA decay pathway and from miRNA silencing machinery. Within P-bodies, mRNAs can be degraded, but components of P-bodies can rapidly cycle in and out to return to translation. The mechanism of P-body assembly inhibition by Gephyronic acid has not been characterized, but initial studies suggest that the mode of action could be through stalling ribosomes on mRNA or by reflecting early steps of translation initiation, such as binding of ribosomal subunits or initiation factors.

The same study also found that Gephyronic acid inhibits eIF2α-phosphorylation and formation of stress granules under stress conditions. Stress granules contain non-translating mRNAs and translation initiation factors, suggesting that they may form as a result of aggregation of mRNPs stalled during translation initiation. By monitoring immunofluresence of an established stress granules marker, it was found that stress granule formation was inhibited in the presence of Gephyronic acid. Gephyronic acid may have a direct or indirect effect on translation initiation factor eIF2α, which would trap mRNA into nonfunctional initiation complexes, inhibiting both P-body and stress granule formation.

Biosynthesis

Sequencing of the PKS gene cluster in C. violaceus was conducted and confirmed to reveal five type I polyketide synthases and post-PKS tailoring enzymes with O-methyltransferase and cytochrome P450 monooxygenase. The overall structure correlates well with modular arrangement of PKS-encoded proteins, aside from some unexpected elements that are likely caused by inactive domains. Initial loading uses a GCN5-related N-acetyltransferase (GNAT) domain instead of the typical AT domain.

Gephyronic acid contains a methyl ether at C-5 and a C-12/C-13 epoxide. These functional groups are incorporated by post-PKS tailoring enzymes. GphA is likely responsible for installation of the C-5 methyl ether. O-methyltransferases SpiB and SpiK used in spirangien biosynthesis exhibit the same SAM-binding motif as GphA.

GphK is a member of the cytochrome p450 superfamily and is suspected to carry out the epoxidation of the C12-C13 olefin. Such epoxidation in post-PKS modications has been seen in epothilone biosynthesis by EpoK. In EpoK, the consensus mechanism of epoxidation by P450 involves the formation of a pi-complex between an oxoferryl pi-cation radical species (Fe^IV) and the olefin pi bond, followed by electron transfer, formation of the olefin pi-cation radical and finally epoxidation.

However, it is also possible that in addition to cytochrome p450, a FAD-dependant monoxygenase is also required to install the epoxide. This codependent process is seen in tirandamycin biosynthesis by TamL. Experiments to clarify the function of these enzymes in gephyronic acid biosynthesis are underway.