Ae Ran Moon

DUSP6 is a novel transcriptional target of p53 and regulates p53-mediated apoptosis by modulating expression levels of Bcl-2 family proteins

p53 regulates various cellular responses through transcriptional regulation of distinct sets of target genes. Dual specificity phosphatase 6 (DUSP6) is a cytosolic phosphatase that inactivates the extracellular‐signal‐regulated kinase 1/2 (ERK1/2). This study demonstrates that p53 transactivates DUSP6 in human colorectal HCT116 cells to regulate ERK1/2 in p53‐mediated cell death. DUSP6 is transactivated by p53 overexpression and genotoxic agents, and chromatin immunoprecipitation revealed two p53‐binding sites in the DUSP6 promoter responsible for DUSP6 induction. Expression of shDUSP6 inhibited 5′‐FU‐induced cell death, whereas overexpression of DUSP6 increased susceptibility to 5′‐FU. 5′‐FU treatment dephosphorylated ERK in a DUSP6‐dependent manner, resulting in destabilization of Bcl‐2 and stabilization of Bad. These results provide insights on the modulatory role of p53 in the survival pathway by up‐regulating DUSP6.

The Cell Death–Inducing Activity of the Peptide Containing Noxa Mitochondrial-Targeting Domain Is Associated with Calcium Release

DNA damage stabilizes the p53 tumor suppressor protein that determines the cell fate by either cell cycle arrest or cell death induction. Noxa, the BH3-only Bcl-2 family protein, was shown to be a key player in p53-induced cell death through the mitochondrial dysfunction; however, the molecular mechanism by which Noxa induces the mitochondrial dysfunction to cause cell death in response to genotoxic agents is largely unknown. Here, we show that the mitochondrial-targeting domain (MTD) of Noxa is a prodeath domain. Peptide containing MTD causes massive necrosis in vitro through cytosolic calcium increase; it is released from the mitochondria by opening the mitochondrial permeability transition pore. MTD peptide-induced cell death can be inhibited by calcium chelator BAPTA-AM. Moreover, MTD peptide shows the potent tumor-killing activities in mice by joining with tumor-homing motifs.

Effects of the BH3‐only protein human Noxa on mitochondrial dynamics

Mitochondria form reticular networks comprised of filamentous tubules and continuously move and change shape. Bcl‐2 family proteins actively participate in the regulation of mitochondria fragmentation. Here, we show that human Noxa, which belongs to the BH3‐only pro‐apoptotic Bcl‐2 family, causes mitochondrial fragmentation. We found that while the Bcl‐2 homology 3 (BH3) domain of Noxa is not associated with mitochondrial fragmentation, the mitochondrial targeting domain (MTD) of Noxa is the region responsible for inducing fragmentation. Two leucine residues in MTD play a key role in the process. Furthermore, the lack of Noxa causes a significant reduction of Velcade‐induced mitochondrial fragmentation. Together, these results provide novel insight into the role of Noxa in mitochondrial dynamics and cell death.

Suppression of IRF4 by IRF1, 3, and 7 in Noxa expression is a necessary event for IFN-γ-mediated tumor elimination.

IFN-γ plays a critical role in tumor immunosurveillance by affecting either immune cells or tumor cells; however, IFN-mediated effects on tumor elimination are largely unknown. In this study, we showed that IFN regulatory factors (IRF) modulated by IFNs up- and downregulated Noxa expression, a prodeath BH3 protein, in various cancer cells. Inhibition of Noxa expression using short hairpin RNA in tumor cells leads to resistance against lipopolysaccharide (LPS)-induced tumor elimination, in which IFN-γ is known as a critical effecter in mice. Chromatin immunoprecipitation analysis in both CT26 cells and SP2/0 cells, sensitive and resistant to LPS-induced tumor elimination, respectively, revealed that the responsiveness of IRF1, 3, 4, and 7 in the Noxa promoter region in response to IFN-γ might be crucial in LPS-induced tumor elimination. IRF1, 3, and 7 were upregulated by IFN-γ and activated Noxa expression, leading to the death of Noxa wild-type baby mouse kidney (BMK) cells but not of Noxa-deficient BMK cells. In contrast, IRF4 acts as a repressor for Noxa expression and inhibits cell death induced by IRF1, 3, or 7. Therefore, although IFN-γ alone are not able to induce cell death in tumor cells in vitro, Noxa induction by IFN-γ, which is regulated by the balance between its activators (IRF1, 3, and 7) and its repressor (IRF4), is crucial to increasing the susceptibility of tumor cells to immune cell-mediated cytotoxicity. Mol Cancer Res; 9(10); 1356–65. ©2011 AACR.

High-sensitivity C-reactive protein and mean platelet volume as predictive values after percutaneous coronary intervention for long-term clinical outcomes: a comparable and additive study.

This study was designed to establish the relationship of high-sensitivity C-reactive protein (hsCRP) and mean platelet volume (MPV) with the development of adverse outcomes after percutaneous coronary intervention (PCI). hsCRP levels and MPV were analysed in 372 patients who underwent PCI, with the primary endpoint as major adverse cardiac and cerebrovascular events (MACCE): a composite of cardiac death, myocardial infarction (MI), target vessel revascularization (TVR), ischemic stroke and stent thrombosis. During the follow-up period (mean, 25.8 months), there were 21 cardiac deaths, 10 MIs including four stent thrombosis events, seven ischemic strokes and 29 TVRs. The hsCRP cut-off level was set at 0.31 mg/dl using the receiver operating characteristic curve to differentiate between the groups with and without MACCE. The MPV cut-off level was set at 8.00 fl by the receiver operating characteristic curve to differentiate between the groups with and without MACCE. A Kaplan–Meier analysis revealed that the high hsCRP group (≥0.31 mg/dl) had a significantly higher cardiac death and MACCE rate than the low hsCRP group (<0.31 mg/dl), and the high MPV group (>8.00 fl) had a significantly higher cardiac death and MACCE rate than the low MPV group (⩽8.00 fl). Furthermore, the high hsCRP and MPV groups were significantly associated with an increased risk of MACCE. These results show that hsCRP and MPV are predictive markers after PCI for MACCE; they are also additively associated with a higher risk of MACCE.

Homer1 regulates the susceptibility to TRAIL

TRAIL is an apoptotic cell death-inducing ligand that belongs to a TNF superfamily. To identify the regulators that govern the susceptibility to TRAIL, TRAIL-resistant HeLa (TR) cells were established by repeatedly treating HeLa cells with TRAIL. Here we showed that scaffolding protein Homer1 plays a decisive role in regulating the apoptotic susceptibility to TRAIL. TR cells showing the normal susceptibility to FasL and chemotherapeutic agent etoposide expressed the lower protein levels of Homer1 than parental HeLa cells. They showed the delayed activation of caspases-8, Bid cleavage and Bax translocation to mitochondria in response to TRAIL. Reconstitution of Homer1 expression in TR cells significantly restored the susceptibility to TRAIL. In addition, knock-down of Homer1 using interfering shRNA in parental HeLa cells lost the susceptibility to TRAIL. Together, our data indicate that Homer1 plays a critical role in determining the apoptotic susceptibility to TRAIL.

A novel protein, MUDENG, induces cell death in cytotoxic T cells.

A screening system comprised of a randomized hybrid-ribozyme library has previously been used to identify pro-death genes in Fas-mediated apoptosis, and short sequence information of candidate genes from this system was previously reported by Kawasaki and Taira [H. Kawasaki, K. Taira, A functional gene discovery in the Fas-mediated pathway to apoptosis by analysis of transiently expressed randomized hybrid-ribozyme libraries, Nucleic Acids Res. 30 (2002) 3609-3614]. In this study, we have cloned the full-length of the candidates open reading frames and found that one of the candidates, referred to as MUDENG (Mu-2 related death-inducing gene), which is composed of 490 amino acids that contain the adaptin domain found in the mu2 subunit of APs related to clathrin-mediated endocytosis, is able to induce cell death by itself. Ectopic expression of MUDENG induced cell death in Jurkat T cells and HeLa cells. In addition, when MUDENG expression was evaluated by immnuohistochemical staining, it was found in most tissues, including the intestine and testis. Furthermore, MUDENG appears to be evolutionary conserved from mammals to amphibians, suggesting that it may have a common role in cell death. Taken together, these results suggest that MUDENG is likely to play an important role in cell death in various tissues.

Necrosis-inducing peptide has the beneficial effect on killing tumor cells through neuropilin (NRP-1) targeting.

The therapeutic efficacy of most anti-cancer drugs depends on their apoptosis-inducing abilities. Previously, we showed that a peptide containing the mitochondrial targeting domain (MTD) found in Noxa, a BH-3 only protein of Bcl-2 family, induces necrosis. Here, a fusion peptide of neuropilin-1 (NRP-1) targeting peptide and MTD peptide, designated tumor homing motif 17:MTD (TU17:MTD), was found to induce necrosis in cancer cells in vitro and to cause the regression of tumors when intravenously injected into mice bearing subcutaneous CT26 colorectal carcinoma tumors. The necrosis within tumor tissues was evident upon administering TU17:MTD. TU17:MTD penetrated into tumor cells by targeting to Neuropilin-1, which could be blocked by anti-NRP-1 antibody. The efficacy of TU17:MTD on tumor regression was higher than that of TU17:D(KLAKLAK)2, a fusion peptide of NRP-1 targeting peptide and a pro-apoptotic peptide. The necrotic cell death within tumor tissues was evident at day 1 after administering TU17:MTD systemically. Transplanted subcutaneous substantially reduced in size within two weeks and 5 days, respectively, with no apparent side effects. Together, these results propose that the pro-necrotic peptide MTD may present an alternative approach for development of targeted anti-cancer agents.

Therapeutic Inhibitors against Mutated BRAF and MEK for the Treatment of Metastatic Melanoma

Melanoma is one of the most aggressive cancers in the world and is responsible for the majority of skin cancer deaths. Recent advances in the field of immunotherapy using active, adoptive, and antigen-specific therapeutic approaches, have generated the expectation that these technologies have the potential to improve the treatment of advanced malignancies, including melanoma. Treatment options for metastatic melanoma patients have been dramatically improved by the FDA approval of new therapeutic agents including vemurafenib, dabrafenib, and sorafenib. These kinase inhibitors have the potential to work in tandem with MEK, PI3K/AKT, and mTOR to inhibit the activity of melanoma inducing BRAF mutations. This review summarizes the effects of the new therapeutic agents against melanoma and the underlying biology of these BRAF inhibitors.

Potentiation of TRAIL killing activity by multimerization through isoleucine zipper hexamerization motif

Tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) is a homo-trimeric cytotoxic ligand. Several studies have demonstrated that incorporation of artificial trimerization motifs into the TRAIL protein leads to the enhancement of biological activity. Here, we show that linkage of the isoleucine zipper hexamerization motif to the N-terminus of TRAIL, referred as ILz(6):TRAIL, leads to multimerization of its trimeric form, which has higher cytotoxic activity compared to its native state. Size exclusion chromatography of ILz(6):TRAIL revealed possible existence of various forms such as trimeric, hexameric, and multimeric (possibly containing one-, two-, and multi-units of trimeric TRAIL, respectively). Increased number of multimerized ILz(6):TRAIL units corresponded with enhanced cytotoxic activity. Further, a high degree of ILz(6):TRAIL multimerization triggered rapid signaling events such as activation of caspases, tBid generation, and chromatin condensation. Taken together, these results indicate that multimerization of TRAIL significantly enhances its cytotoxic activity. [BMB Reports 2016; 49(5): 282-287]