Diastereoselective Synthesis of Biologically Active Cyclopenta[b]indoles.

The cyclopenta[b]indole motif is present in several natural and synthetic biologically active compounds, being directly responsible for the biological effects some of them present. We described herein a three step sequence for the synthesis of cyclopenta[b]indoles with a great structural diversity. The method is based on an oxidative Michael addition of suitable indoles on the double bond of Morita-Baylis-Hillman adducts mediated by a hypervalent iodine reagent (IBX) to form ß-ketoesters, which were chemoselectively reduced with NaBH4 in THF to give the corresponding ß-hydroxy-esters. The diastereoisomeric mixture was then treated with a catalytic amount of triflic acid (20 mol %) to give cyclopenta[b]indoles with overall yields ranging from 8 to 73% (for 2 steps). The acid-catalyzed cyclization step gave the required heterocycles, via an intramolecular Friedel-Crafts reaction, with high diastereoselectivity, where only the trans product was observed. A mechanistic study monitored by ESI-(+)-MS was also conducted to collect evidence about the mechanism of this reaction. The new molecules herein synthesized were also evaluated against a panel of human cancer cells demonstrating a promising antitumoral profile.

Synthetic Spirocyclohexadienones as New Anti-Migratory Compounds in Triple- Negative Breast Cancer Cell Migration.

BACKGROUND: Triple-negative BC is the most aggressive type of breast cancer and its lack of responsiveness to conventional therapies requires screening of new chemical entities. Anti-migratory compounds are promising to treat metastatic cancer since they inhibit one of the main steps of the metastatic cascade. Spirocyclic compounds are non-conventional structures used as building blocks for the synthesis of biologically active molecules and considered interesting structures in the search for new targets in cancer research. OBJECTIVE: Here, we evaluated the potential of eight synthetic spirocyclohexadienones as cell migration inhibitors. METHODS: The anti-migratory ability of compounds was tested by wound healing and Boyden chamber approaches. Experiments in tubulin were performed by fluorescence and tubulin polymerization techniques. Finally, compounds were submitted to cell proliferation inhibition and flow cytometry assays to explore the mechanism by which they inhibit cell migration. RESULTS: Four compounds inhibited cell migration significantly. Analogs containing the 3,4,5-trimethoxyphenil ring at R1 position were the most potent and, thus, selected for additional experiments. Tubulin polymerization and fluorescence assays highlighted a possible binding of spirocyclohexadienones in the colchicine binding site; however, these compounds did not affect the cell cycle to the same extent as colchicine. Cell proliferation was affected and, notably, the most potent analogs induced apoptosis of tumor cells, suggesting a different mechanism by which they inhibit cell migration. CONCLUSION: We presented, for the first time, a series of eight synthetic spirocyclohexadienones with the ability to inhibit TNBC cell migration. These compounds represent a new category to be explored as anticancer agents.