Effect of a novel piperazine compound on cancer cells

Many drugs have been developed for anticancer chemotherapy. However, more anti-cancer drugs should be developed from potential chemicals to circumvent the disadvantages of existing drugs. Most anti-cancer chemicals induce apoptosis in cancer cells. This study tested the efficiency of a new chemical, the piperazine derivative 1-[2-(Allylthio) benzoyl]-4-(4-methoxyphenyl) piperazine (CB01), on glioblastoma (U87) and cervix cancer (HeLa) cells. CB01 was highly cytotoxic to these cells (IC50S < 50 nM) and induced the traditional apoptotic symptoms of DNA fragmentation and nuclear condensation at 40 nM. Western-blot analysis of the cell lysates revealed that the intracellular apoptotic marker proteins, such as cleaved caspase-3, cytochrome c, and Bax, were highly upregulated in the CB01-treated cells. Furthermore, increased activities of caspase-3 and -9, but not caspase-8, were observed. Therefore, these results suggest that CB01 can act as an anticancer chemotherapeutic by stimulating the intrinsic mitochondrial signaling pathway to induce cytotoxicity and apoptosis in cancer cells.

SSTP1, A Host Defense Peptide, Exploits the Immunomodulatory Il6 Pathway to Induce Apoptosis in Cancer Cells

Background: The anticancer activities of host defense peptides (HDPs) are mainly attributed to their cell penetrating activity. Accordingly, several approaches based on machine learning, calculating the membrane pore formation ability, have been proposed for the anti-cancer peptide identification. Since the membranolytic activity can lead to nonspecific effects, like hemolysis, the therapeutic application of such molecules is limited. In this context, we considered the immunomodulatory activity of HDPs, which is regulated by specific membrane targets and immunomodulatory pathways in immune cells. As many immunomodulators are aberrantly expressed in cancer cells, the possibility of the activation of an immunomodulatory pathway was investigated for a novel anticancer HDP, SSTP1.Methods: The fourteen mature peptides identified by shotgun cloning from the frog-skin secretions were screened for cytotoxicity in oral cancer cells. The mechanism of action of the selected peptide, SSTP1 was investigated in comparison to its inactive mutant, SSTP2. An RNA-Seq coupled with pathway enrichment analysis was performed to identify the upstream signaling leading to the mitochondrial pathway of apoptosis. Since the activation of the IL6/IL6R pathway was suggested, we performed in silico docking studies to find the binding of SSTP1 to the IL6/IL6Rα/gp130 complex. The dynamic simulation predicted the conformational changes in the active site residues. The confocal co-localization studies, pull-down assay, FRET analysis, western blot and reporter assays were performed to elucidate the role of the IL6/IL6R pathway in SSTP1-induced apoptosis. Specific small molecule inhibitors and neutralizing antibodies were used to ascertain the role of the IL6/IL6Rα/gp130 complex in the activation of JNK/AP1 pathway-dependent cell death.Results: SSTP1, a novel temporin, modulates the IL6 pathway and induces apoptosis when it binds to IL6Rα on the active IL6/IL6Rα/gp130 complex, rearranging the active site residues. In contrast to the IL6 blockers inhibiting JAK/STAT activity, SSTP1 shifts the proliferative IL6/JAK/STAT signaling to the apoptotic IL6/JNK/AP1 pathway. In IL6Rα-overexpressing cancer cells, apoptosis is preferred over the membranolytic activity, upon SSTP1 treatment.Conclusions: Here, we provide the evidence of an HDP-induced signaling through immunomodulators, leading to apoptosis in cancer cells. Our study also implies the importance of identifying the targets of HDPs for their clinical application

Neutrophils drive endoplasmic reticulum stress-mediated apoptosis in cancer cells through arginase-1 release

Human neutrophils constitutively express high amounts of arginase-1, which depletes arginine from the surrounding medium and downregulates T-cell activation. Here, we have found that neutrophil arginase-1, released from activated human neutrophils or dead cells, induced apoptosis in cancer cells through an endoplasmic reticulum (ER) stress pathway. Silencing of PERK in cancer cells prevented the induction of ER stress and apoptosis. Arginase inhibitor Nω-hydroxy-nor-arginine inhibited apoptosis and ER stress response induced by conditioned medium from activated neutrophils. A number of tumor cell lines, derived from different tissues, were sensitive to neutrophil arginase-1, with pancreatic, breast, ovarian and lung cancer cells showing the highest sensitivity. Neutrophil-released arginase-1 and arginine deprivation potentiated the antitumor action against pancreatic cancer cells of the ER-targeted antitumor alkylphospholipid analog edelfosine. Our study demonstrates the involvement of neutrophil arginase-1 in cancer cell killing and highlights the importance and complex role of neutrophils in tumor surveillance and biology.

Resveratrol Derivative, Trans-3, 5, 4 ′ -Trimethoxystilbene Sensitizes Osteosarcoma Cells to Apoptosis via ROS-Induced Caspases Activation

Numerous studies have shown that resveratrol can induce apoptosis in cancer cells. Trans-3, 5, 4 ′ -trimethoxystilbene (TMS), a novel derivative of resveratrol, is a more potent anticancer compound than resveratrol and can induce apoptosis in cancer cells. Herein, we examined the mechanisms involved in TMS-mediated sensitization of human osteosarcoma (143B) cells to TNF-related apoptosis-inducing ligand- (TRAIL-) induced apoptosis. Our results showed that cotreatment with TSM and TRAIL activated caspases and increased PARP-1 cleavage in 143B cells. Decreasing cellular ROS levels using NAC reversed TSM- and TRAIL-induced apoptosis in 143B cells. NAC abolished the upregulated expression of PUMA and p53 induced by treatment with TRAIL and TSM. Silencing the expression of p53 or PUMA using RNA interference attenuated TSM-mediated sensitization of 143B cells to TRAIL-induced apoptosis. Knockdown of Bax also reversed TSM-induced sensitization of 143B cell to TRAIL-mediated apoptotic cell death. These results indicate that cotreatment with TRAIL and TSM evaluated intracellular ROS level, promoted DNA damage, and activated the Bax/PUMA/p53 pathway, leading to activation of both mitochondrial and caspase-mediated apoptosis in 143B cells. Orthotopic implantation of 143B cells in mice also demonstrated that cotreatment with TRAIL and TSM reversed resistance to apoptosis in cells without obvious adverse effects in normal cells.