Physciosporin suppresses the proliferation, motility and tumourigenesis of colorectal cancer cells.

BACKGROUND: Lichens, which represent symbiotic associations of fungi and algae, are potential sources of numerous natural products. Physciosporin (PHY) is a potent secondary metabolite found in lichens and was recently reported to inhibit the motility of lung cancer cells via novel mechanisms. PURPOSE: The present study investigated the anticancer potential of PHY on colorectal cancer (CRC) cells. METHODS: PHY was isolated from lichen extract by preparative TLC. The effect of PHY on cell viability, motility and tumourigenicity was elucidated by MTT assay, hoechst staining, flow cytometric analysis, transwell invasion and migration assay, soft agar colony formation assay, Western blotting, qRT-PCR and PCR array in vitro as well as tumorigenicity study in vivo. RESULTS: PHY decreased the viability of various CRC cell lines (Caco2, CT26, DLD1, HCT116 and SW620). Moreover, PHY elicited cytotoxic effects by inducing apoptosis at toxic concentrations. At non-toxic concentrations, PHY dose-dependently suppressed the invasion, migration and colony formation of CRC cells. PHY inhibited the motility of CRC cells by suppressing epithelial-mesenchymal transition and downregulating actin-based motility markers. In addition, PHY downregulated ß-catenin and its downstream target genes cyclin-D1 and c-Myc. Moreover, PHY modulated KAI1 C-terminal-interacting tetraspanin and KAI1 expression, and downregulated the downstream transcription factors c-jun and c-fos. Finally, PHY administration showed considerable bioavailability and effectively decreased the growth of CRC xenografts in mice without causing toxicity. CONCLUSION: PHY suppresses the growth and motility of CRC cells via novel mechanisms.

Basic and clinical pharmacology contribution to extend anthelmintic molecules lifespan.

The correct use of pharmacology-based information is critical to design successful strategies for the future of parasite control in livestock animals. Integrated pharmaco-parasitological research approaches have greatly contributed to optimize drug activity. In an attempt to manage drug resistance in helminths of ruminants, combinations of two or more anthelmintics are being used or promoted, based on the fact that individual worms may have a lower degree of resistance to a multiple component formulation, when each chemical has a different mode of action compared to that observed when a single compound is used. However, as emphasized in the current review, the occurrence of potential pharmacokinetic and/or pharmacodynamic interactions between drug components highlights the need for deeper and integrated research to identify the advantages or disadvantages associated with the use of combined drug preparations. This review article provides integrated pharmacokinetic/pharmacodynamic and clinical pharmacology information pertinent to preserve the traditional and modern active ingredients as practical tools for parasite control. Novel pharmacological data on derquantel and monepantel, as representatives of modern anthelmintics for use in livestock, is summarized here. The article also summarizes the pharmaco-parasitological knowledge considered critical to secure and/or extend the lifespan of the recently available novel molecules.

Ranking the Binding Energies of p53 Mutant Activators and Their ADMET Properties.

The guardian of the genome, p53, is the most mutated protein found in all cancer cells. Restoration of wild-type activity to mutant p53 offers promise to eradicate cancer cells using novel pharmacological agents. Several molecules have already been found to activate mutant p53. While the exact mechanism of action of these compounds has not been fully understood, a transiently open pocket has been identified in some mutants. In our study, we docked twelve known activators to p53 into the open pocket to further understand their mechanism of action and rank the best binders. In addition, we predicted the absorption, distribution, metabolism, excretion and toxicity properties of these compounds to assess their pharmaceutical usefulness. Our studies showed that alkylating ligands do not all bind at the same position, probably due to their varying sizes. In addition, we found that non-alkylating ligands are capable of binding at the same pocket and directly interacting with Cys124. The comparison of the different ligands demonstrates that stictic acid has a great potential as a p53 activator in terms of less adverse effects although it has poorer pharmacokinetic properties.