Green asymmetric synthesis of epoxypeptidomimetics and evaluation as human cathepsin K inhibitors

Recent Advances in Greener Asymmetric Organocatalysis Using Bio-Based Solvents

Efficient synthetic methods that avoid the extensive use of hazardous reagents and solvents, as well as harsh reaction conditions, have become paramount in the field of organic synthesis. Organocatalysis is notably one of the best tools in building chemical bonds between carbons and carbon-heteroatoms; however, most examples still employ toxic volatile organic solvents. Although a portfolio of greener solvents is now commercially available, only ethyl alcohol, ethyl acetate, 2-methyltetrahydrofuran, supercritical carbon dioxide, ethyl lactate, and diethyl carbonate have been explored with chiral organocatalysts. In this review, the application of these bio-based solvents in asymmetric organocatalytic methods reported in the last decade is discussed, highlighting the proposed mechanism pathway for the transformations.

Discovery of a novel and selective cathepsin L inhibitor with anti-metastatic ability in vitro and in vivo against breast cancer cells

Asperphenamate is a natural product that has attracted considerable interest from researchers worldwide. In the last decade, aiming to increase the biological activity and improve druggability, modifications of the A-ring moiety in asperphenamate have been performed. Our laboratory has also recently reported functional derivatizations of the A ring and studied its effect on the inhibition of cysteine cathepsin L. However, the functional significance of the B-ring fragment toward cathepsin L has not been evaluated thus far. In this paper, forty-four derivatives of the B-ring substituted with different N-phenylsulfonyl groups were designed and synthesized. Among them, the paratrifluromethyl analog B-2a and the 2, 4-difluoro-5-chloro derivative B-11b showed more potent inhibitory activity against cathepsin L than the control compound, ABR, which displayed the strongest inhibitory effect on cathepsin L and S among all reported asperphenamate derivatives. In particular, compound B-2a showed more pronounced selectivity against cathepsin L than the other derivatives. Molecular docking revealed that the N-phenylsulfonylamide moiety was vital for the interactions between B-2a and cathepsin L. Moreover, B-2a displayed no toxicity against normal cells. Therefore, compound B-2a was selected for further studies. Wound-healing assays, Transwell chamber assays and breast cancer lung metastasis mouse models demonstrated that B-2a exhibited antimetastatic ability in vitro and in vivo.

Synthesis and kinetic characterization of hyperbolic inhibitors of human cathepsins K and S based on a succinimide scaffold

Cathepsins K and S are closely related papain-like cysteine peptidases and potential therapeutic targets for metabolic and inflammatory diseases such as osteoporosis and arthritis. Here we describe the reduction of a previously characterized succinimide (2,5-dioxopyrrolidine)-containing hyperbolic inhibitor of cathepsin K (methyl (RS)-N-[1-(4-methoxyphenyl)-2,5-dioxopyrrolidin-3-yl]glycinate), to obtain a better and more selective compound (compound 4a - methyl (2,5-dioxopyrrolidin-3-yl)glycinate), which acted as a hyperbolic mixed inhibitor/activator similar to already known allosteric effectors of cathepsin K. We then investigated the potential of the succinimide scaffold as inhibitors of cathepsins K and/or S and synthesized a library of such compounds by 1,4-addition of α-amino acid esters and related compounds to N-substituted maleimides. From the generated library, we identified the first small molecule hyperbolic inhibitors of cathepsin S (methyl ((R)-2,5-dioxopyrrolidin-3-yl)-l-threoninate (compound R-4c) and 3-{[(1S,2R,3'S)-2-hydroxycyclohexyl]amino}pyrrolidine-2,5-dione (compound (1S,2R,3'S-10)). The former acted via a similar mechanism to compound 4a, while the latter was a hyperbolic specific inhibitor of cathepsin S. Given the versatility of the scaffold, the identified compounds will be used as the basis for the development of high-affinity hyperbolic inhibitors of the individual peptidases and to explore the potential of hyperbolic inhibitors for the inhibition of cysteine cathepsins in in vitro models.