Epothilones: novel microtubule-stabilising agents.

The past few years have witnessed the regulatory approvals of the anticancer microtubule stabilising taxane drugs, Taxol and Taxotere, which are rapidly gaining acceptance as important antineoplastic agents with potential against numerous solid tumour malignancies. Despite a basic understanding of the biochemical target of taxanes dating back nearly 20 years, new classes of tubulin-binding microtubule polymerisation enhancers were only reported in the last two years. Epothilones and discodermolide are newly discovered compounds, which are structurally distinct from the taxanes, but which possess similar tubulin polymerising and cell biological effects. In the first studies reported, these compounds displayed similar or greater potencies than taxanes, and the epothilones may represent an advance over the taxanes in retaining toxicity against various taxane-resistant cell lines. This review summarises the data published on epothilones and discodermolide and proposes further steps that could establish these new classes of compounds as potential second generation microtubule polymerisation enhancers.

Epothilones, a new class of microtubule-stabilizing agents with a taxol-like mechanism of action.

Tubulin polymerization into microtubules is a dynamic process, with the equilibrium between growth and shrinkage being essential for many cellular processes. The antineoplastic agent taxol hyperstabilizes polymerized microtubules, leading to mitotic arrest and cytotoxicity in proliferating cells. Using a sensitive filtration-calorimetric assay to detect microtubule nucleating activity, we have identified epothilones A and B as compounds that possess all the biological effects of taxol both in vitro and in cultured cells. The epothilones are equipotent and exhibit kinetics similar to taxol in inducing tubulin polymerization into microtubules in vitro (filtration, light scattering, sedimentation, and electron microscopy) and in producing enhanced microtubule stability and bundling in cultured cells. Furthermore, these 16-membered macrolides are competitive inhibitors of [3H]taxol binding, exhibiting a 50% inhibitory concentration almost identical to that of taxol in displacement competition assays. Epothilones also cause cell cycle arrest at the G2-M transition leading to cytotoxicity, similar to taxol. In contrast to taxol, epothilones retain a much greater toxicity against P-glycoprotein-expressing multiple drug resistant cells. Epothilones, therefore, represent a novel structural class of compounds, the first to be described since the original discovery of taxol, which not only mimic the biological effects of taxol but also appear to bind to the same microtubule-binding site as taxol.

Cytotoxic cyclolignans from Koelreuteria henryi.

Chemical investigation of the cytotoxic fraction of Koelreuteria henryi resulted in the isolation of three cyclolignans. A new cyclolignan, named koelreuterin-1 was elucidated as furo[3',4':6,7]naphtho[2,3-d]-1,3-dioxol-6(8H)-one,5-(7-methoxy-1, 3- benzodioxol-5-yl)[1]. Two known cyclolignans were characterized as austrobailignan-1 [2] and austrobailignan-2 [3]. The structure elucidation of 1 was based on extensive 1H- and 13C-nmr spectral analyses. Further chemical conversion of 2 to 3 and oxidative transformation of 2 to 1 unambiguously confirmed the structure of 1. The cytotoxicity and tubulin polymerization inhibitory activity of 1-3 are discussed.

Preliminary X-ray crystallographic analysis of a modified basic fibroblast growth factor.

Human basic fibroblast growth factor (hbFGF) has been modified, with Ala3 and Ser5 substituted by glutamic acid, and the purified recombinant protein has been crystallized. The crystals are triclinic (space group P1) with unit cell parameters a = 31.0 A, b = 33.6 A, c = 34.7 A, alpha = 88 degrees, beta = 85 degrees, gamma = 76 degrees, and they diffract to at least 2 A.

Overexpression of tubulin in yeast: differences in subunit association.

Microtubules are cytoskeletal organelles composed principally of polymerized alpha beta-tubulin heterodimers. The specific roles and the detailed structures of the individual alpha- and beta-tubulin subunits have not been established, since the conditions necessary for separating the heterodimer result in loss of the subunits' ability to repolymerize. We have overcome this obstacle by constructing plasmids which allow regulated overexpression of individual tubulin subunits in the yeast Saccharomyces cerevisiae under control of the galactose promoter. Overproduction was monitored with alpha- and beta-tubulin-specific antibodies using immunoblotting of cell extracts, and the state of association of the individual subunits in vivo was determined by immunofluorescence microscopy. Cells overproducing only beta-tubulin accumulated fibrous structures associated with the cell membrane, whereas cells overproducing only alpha-tubulin displayed a diffuse signal throughout the cytoplasm. Cells simultaneously overexpressing alpha- and beta-tubulin subunits accumulated membrane-associated, filamentous arrays in which both subunits were incorporated. When cells with the fibrous tubulin-containing structures are treated with zymolyase, a yeast cell wall disrupting enzyme, the fibers appear to splay apart, suggesting that the immunofluorescent rings represent bundles of fibers. Cells overproducing beta-tubulin alone or both alpha- and beta-tubulin were examined at various times after galactose induction, and significant differences were found in the tubulin association state prior to the formation of fibers. For alpha beta-tubulin, fibers form directly from a nuclear structure, whereas beta-tubulin alone first accumulates in the cytoplasm. The differences in patterns of tubulin accumulation and assembly presumably reflect a difference in the intrinsic association properties of the alpha- and beta-subunits.