Design, synthesis, and biological evaluation of new B-RafV600E kinase inhibitors.

The association of deregulated signal pathways with various diseases has long been a research hotspot. One of the most important signal pathways, the MAPK (mitogen-activated protein kinase) signal pathway, plays a vital role in transducing extracellular signals into vital intracellular mechanisms. While mutations on its key component Raf kinase lead to sever diseases, targeted inhibition has thereby become an attractive therapeutic strategy. Several drugs have been approved for the treatment of Raf relevant diseases, yet more candidates are ever needed as the known drugs have confronted resistance and side effects. In the present study, we primarily investigated the binding modes of type I/II and type II inhibitors with B-Raf kinase. Based on the current knowledge, these ligands were fragmented and recombined to provide new interesting insights. Afterwards, a series of derivatives has been synthesized after the validation of hit compound. In addition, in vitro assays were carried out to profile the pharmacological properties of all the entities. Of all the compounds, compound 5h showed the best profile and may be used in the future study.

Identification of novel B-RafV600E inhibitors employing FBDD strategy.

B-Raf kinase is the key point in a main branch of mitogen-activated protein kinase pathways and some of its mutations, such as the V600E mutation, lead to the persistent activation of ERK signaling and the trigger of severe diseases, including melanoma and other somatic cancers. Several potent drugs have been approved to treat B-Raf-related tumors, however, cases of resistance and relapse have been reported universally. Hence, differential scaffolds are in need to alleviate the scarcity of drugs and benefit the therapy of B-Raf-mutant cancers. Herein we report our recent work on the construction of novel B-RafV600E inhibitors employing fragment-based drug design strategy. In this research, we decomposed known inhibitors to fragments and rebuilt new candidates using these blocks according to the evaluation of their potential. Lead compounds were synthesized after selection by means of virtual screening and molecular dynamics validation. Afterwards, we tested the pharmacological efficiency of these entities both in vitro and in vivo utilizing A375 xenograft model. The results favored our rational design intention and hinted this new kind of inhibitors might be helpful in the further explorations of potent agents.