Chengye Yuan

Identification of RIP1 kinase as a specific cellular target of necrostatins.

Necroptosis is a cellular mechanism of necrotic cell death induced by apoptotic stimuli in the form of death domain receptor engagement by their respective ligands under conditions where apoptotic execution is prevented. Although it occurs under regulated conditions, necroptotic cell death is characterized by the same morphological features as unregulated necrotic death. Here we report that necrostatin-1, a previously identified small-molecule inhibitor of necroptosis, is a selective allosteric inhibitor of the death domain receptor-associated adaptor kinase RIP1 in vitro. We show that RIP1 is the primary cellular target responsible for the antinecroptosis activity of necrostatin-1. In addition, we show that two other necrostatins, necrostatin-3 and necrostatin-5, also target the RIP1 kinase step in the necroptosis pathway, but through mechanisms distinct from that of necrostatin-1. Overall, our data establish necrostatins as the first-in-class inhibitors of RIP1 kinase, the key upstream kinase involved in the activation of necroptosis.

Structure–activity relationship study of a novel necroptosis inhibitor, necrostatin-7

Necroptosis is a regulated caspase-independent cell death mechanism characterized by morphological features resembling non-regulated necrosis. Necrotatin-7 (Nec-7), a novel potent small-molecule inhibitor of necroptosis, is structurally distinct from previously described necrostatins (Nec-1, Nec-3, Nec-4 and Nec-5). Here, we describe a series of structural modifications and the structure-activity relationship (SAR) of the Nec-7 series for inhibiting necroptosis.

A novel necroptosis inhibitor—necrostatin-21 and its SAR study

An initial structure-activity relationship study of the novel necroptosis inhibitor Nec-21 was described. Any changes of the tetracyclic scaffold were detrimental for the activity. Introduction of a substituent to 7 or 8 position (e.g., cyano or methoxy group, respectively), would increase the activity. The 7 and 8-position disubstituted compound 17 b was 35-fold as potent as the lead, while EC50 reached 14 nM.

Synthesis and SAR study of diphenylbutylpiperidines as cell autophagy inducers

A novel series of diphenylbutylpiperidines as autophagy inducers was described and extensive SAR studies resulted in derivatives (15d-e, 15i-j) with 10-fold greater activity than the lead compounds 1 and 2. Meanwhile, a new synthetic route to diphenylbutyl bromide (6) from bromobenzene and γ-butyrolactone was also reported here.

Diphenylbutylpiperidine-based cell autophagy inducers: Design, synthesis and SAR studies

A novel series of diphenylbutylpiperidine derivatives in which a benzo-five or six membered heterocycle was linked at the 4-position of the piperidine moiety were designed and synthesized. Structure–activity relationship (SAR) studies of these compounds indicated that some molecules show promising autophagy inducing activity. Replacement of the fluorine atom by a CF3 group on the diphenyl part resulted in significant enhancement of the autophagy inducing effect. In the addition, a group of diphenylpentyl nitriles also showed similar bioactivities.

Structure-activity relationship study of E6 as a novel necroptosis inducer.

Necroptosis inducers represent a promising potential treatment for drug-resistant cancer. We herein describe the structure modification of E6, which was identified recently as a potent and selective necroptosis inducer. The studies described herein demonstrate for the first time that functionalized biphenyl derivatives possess necroptosis inducer activity. Furthermore, these studies have led to the identification of two promising compounds (5h and 5j) that can be used for further optimization studies as well as mechanism of action investigations.