Medicinal chemistry and chemical biology of diketopiperazine-type antimicrotubule and vascular-disrupting agents.

Certain antimicrotubule agents displaying colchicine-like tubulin-depolymerizing activity can act as both cytotoxic and vascular-disrupting agents (VDAs). VDAs constitute a new class of anticancer drugs and are currently in clinical trials. We have developed a VDA clinical candidate (phase II) diketopiperazine (DKP)-type antimicrotubule agent called plinabulin (7) derived from the natural DKP phenylahistin (5), which displays colchicine-like tubulin-depolymerizing activity. To develop more potent antimicrotubule DKP derivatives, we performed an intensive structure-activity relationship study examining the phenyl group of compound 7. This study identified more potent DKP derivatives (2,5-difluoro derivatives [29] and benzophenone derivatives [36]) with vascular-disrupting activities. The benzophenone moiety of compound 36 was further modified to yield the most potent cytotoxic derivative yet discovered, the 4-fluorobenzophenone derivative 38 m, which inhibited the growth of HT-29 cells in vitro at subnanomolar levels. As both VDAs and cytotoxic agents, these potent DKP derivatives are valuable second-generation drug candidates. The chemical biology of plinabulin was examined by designing and synthesizing biotin-tagged photoaffinity probes 40-42 that could be used to indicate the binding mode of compound 7 with tubulin. A tubulin photoaffinity labeling study suggested that compound 7 binds at the interface between the α- and β-tubulins near the colchicine-binding site and not inside the colchicine-binding cavity. A water-soluble prodrug of the poorly water-soluble 7 was next designed in an effort to improve the pharmacokinetics and chemotherapeutic indices. The lead compound 56 revealed high water solubility and a half-life profile appropriate for an injected drug.