Inhibiting JNK Dephosphorylation and Induction of Apoptosis by Novel Anticancer Agent NSC-741909 in Cancer Cells

NSC-741909 is a recently identified novel anticancer agent that suppresses the growth of several NCI-60 cancer cell lines with a unique anticancer spectrum. However, its molecular mechanisms remain unknown. To determine the molecular mechanisms of NSC-741909-induced antitumor activity, we analyzed the changes of 77 protein biomarkers in a sensitive lung cancer cell line after treatment with this compound by using reverse-phase protein microarray. The results showed that phosphorylation of mitogen-activated protein (MAP) kinases (P38 MAPK, ERK, and JNK) were persistently elevated by the treatment with NSC-741909. However, only the JNK-specific inhibitor SP600125 effectively blocked the apoptosis induced by NSC-741909. Moreover, NSC-741909-mediated apoptosis was also blocked by a dominant-negative JNK construct, suggesting that sustained activation of JNK is critical for the apoptosis induction. Further studies revealed that treatment with NSC-741909 suppressed dephosphorylation of JNK and the expression of MAPK phosphatase-1. Thus, NSC-741909-mediated inhibition of JNK dephosphorylation results in sustained JNK activation, which leads to apoptosis in cancer cells.Because of genetic and epigenetic changes in cancer cells, it is possible to identify tumor-selective cytotoxic agents by synthetic lethality screening for compounds that kill isogenic cancer cells but not their normal counterparts (1). The term synthetic lethality was originally used to describe a lethal phenotype caused by mutations of two genes (2), i.e. mutations of the two genes are lethal if they occur together but viable if they occur separately. A synthetically lethal phenotype often indicates that the two genes or two related pathways affect a common essential biologic function. Unfortunately, our current knowledge of molecular networks in normal or cancer cells is not adequate for us to predict what genes are synthetically lethal partners to an oncogene or a mutated tumor suppressor gene. Nevertheless, synthetic lethality screening allows us to identify cytotoxic agents specific for certain cancer cells because a compound targeting to such a partner can be identified by their lethality when administered to cancer cells with elevated activities of a particular oncogene.Using synthetic lethality screening, we recently identified an indole compound (designated oncrasin-1) that kills immortalized and tumorigenic human ovarian epithelial cells expressing mutant K-Ras but not cells expressing wild-type Ras genes (3). Furthermore, this compound effectively induced apoptosis at low micromolar or nanomolar concentrations in a variety of lung cancer cells with K-Ras mutations but did not kill cells with wild-type Ras genes. Molecular characterization revealed that oncrasin-1 can induce abnormal aggregation of protein kinase C-ι in the nucleus of oncrasin-sensitive cells but not in oncrasin-resistant cells and that oncrasin-1-induced apoptosis was blocked by siRNA³ of K-Ras or protein kinase C-ι (3), demonstrating that oncrasin-1 is synthetically lethal for K-Ras and protein kinase C-ι, one of the downstream effectors of Ras signaling pathways (4). Our search for oncrasin-1 analogues identified several active compounds with similar chemical structures. Testing of one of the oncrasin-1 analogues, oncrasin-60 (NSC-741909), on NCI-60 cancer cell lines showed that it is highly active against several cell lines derived from lung, colon, breast, ovary, and kidney cancers and that it lies outside the category of adequately studied classes of antitumor agents, suggesting that those compounds could be novel anticancer agents. However, the mechanisms of apoptosis induction by oncrasin compounds remain to be characterized. Here, we used reverse-phase protein array to determine molecular changes induced by NSC-741909 in a sensitive cell line. Our results indicated that sustained c-Jun N-terminal protein kinase (JNK) activation caused by suppression of JNK dephosphorylation contributes to NSC-741909-induced apoptosis.