Epstein-Barr Virus-Encoded Latent Membrane Protein 1 Upregulates Glucose Transporter 1 Transcription via the mTORC1/NF-κB Signaling Pathways.

Accumulating evidence indicates that oncogenic viral protein plays a crucial role in activating aerobic glycolysis during tumorigenesis, but the underlying mechanisms are largely undefined. Epstein-Barr virus (EBV)-encoded latent membrane protein 1 (LMP1) is a transmembrane protein with potent cell signaling properties and has tumorigenic transformation property. Activation of NF-κB is a major signaling pathway mediating many downstream transformation properties of LMP1. Here we report that activation of mTORC1 by LMP1 is a key modulator for activation of NF-κB signaling to mediate aerobic glycolysis. NF-κB activation is involved in the LMP1-induced upregulation of glucose transporter 1 (Glut-1) transcription and growth of nasopharyngeal carcinoma (NPC) cells. Blocking the activity of mTORC1 signaling effectively suppressed LMP1-induced NF-κB activation and Glut-1 transcription. Interfering NF-κB signaling had no effect on mTORC1 activity but effectively altered Glut-1 transcription. Luciferase promoter assay of Glut-1 also confirmed that the Glut-1 gene is a direct target gene of NF-κB signaling. Furthermore, we demonstrated that C-terminal activating region 2 (CTAR2) of LMP1 is the key domain involved in mTORC1 activation, mainly through IKKß-mediated phosphorylation of TSC2 at Ser939 Depletion of Glut-1 effectively led to suppression of aerobic glycolysis, inhibition of cell proliferation, colony formation, and attenuation of tumorigenic growth property of LMP1-expressing nasopharyngeal epithelial (NPE) cells. These findings suggest that targeting the signaling axis of mTORC1/NF-κB/Glut-1 represents a novel therapeutic target against NPC.IMPORTANCE Aerobic glycolysis is one of the hallmarks of cancer, including NPC. Recent studies suggest a role for LMP1 in mediating aerobic glycolysis. LMP1 expression is common in NPC. The delineation of essential signaling pathways induced by LMP1 in aerobic glycolysis contributes to the understanding of NPC pathogenesis. This study provides evidence that LMP1 upregulates Glut-1 transcription to control aerobic glycolysis and tumorigenic growth of NPC cells through mTORC1/NF-κB signaling. Our results reveal novel therapeutic targets against the mTORC1/NF-κB/Glut-1 signaling axis in the treatment of EBV-infected NPC.

A complementary transposon tool kit for Drosophila melanogaster using P and piggyBac.

With the availability of complete genome sequence for Drosophila melanogaster, one of the next strategic goals for fly researchers is a complete gene knockout collection. The P-element transposon, the workhorse of D. melanogaster molecular genetics, has a pronounced nonrandom insertion spectrum. It has been estimated that 87% saturation of the approximately 13,500-gene complement of D. melanogaster might require generating and analyzing up to 150,000 insertions. We describe specific improvements to the lepidopteran transposon piggyBac and the P element that enabled us to tag and disrupt genes in D. melanogaster more efficiently. We generated over 29,000 inserts resulting in 53% gene saturation and a more diverse collection of phenotypically stronger insertional alleles. We found that piggyBac has distinct global and local gene-tagging behavior from that of P elements. Notably, piggyBac excisions from the germ line are nearly always precise, piggyBac does not share chromosomal hotspots associated with P and piggyBac is more effective at gene disruption because it lacks the P bias for insertion in 5' regulatory sequences.

[Cyclooxygenase-2 expression in esophageal cancer cells and induction by mitomycin C].

OBJECTIVE: To study the relationship between COX-2 expression in esophageal cancer cell (EC/CUHK-1) and mitomycin C (MMC) treatment. METHODS: 2 mg/L of MMC was added to the well-grown EC/CUHK-1 cells cultured in RPMI-1640 including 10% FCS, and the medium was totally changed after 0.5, 1, 2, 4 and 8 h treatment, respectively. Cells were collected after another 24 h culture. Protein expression of COX-2, Bcl-2, Rb, p53 were examined by Western blot, and RT-PCR method was used to confirm the COX-2 expression in mRNA level. Cell cycle analysis for cells collected at 0, 0.5, 2, 4 and 8 h was performed on an EPICS profile analyzer. RESULTS: The cell cycle analysis showed that the percentage of apoptosis cells were (4.12 +/- 0.83)%, (1.00 +/- 0.11)%, (4.32 +/- 0.99)%, (9.46 +/- 2.11)% and (31.10 +/- 3.57)%, respectively. COX-2 mRNA expression were 2.60, 1.70, and 0.08 times, COX-2 protein expression were 2.0, 3.1 and 2.8 times, Bcl-2 protein were 3.6, 14.0 and 12.0 times, p53 protein were 1.8, 0.5 and 0.2 times, hyperphosphorylated form Rb were 8.2, 8.4 and 6.2 times, underphosphorylated form Rb were 1.8, 0.5 and 0.2 times in 0.5, 2 and 4 h after MMC treatment, respectively, as compared with the control group. CONCLUSIONS: The COX-2 expression showed coincidence up-regulation according to the MMC-induced anti-apoptosis function activation in esophageal cancer cells, and the process was at least partly associated with Rb phosphorylation and p53 accumulation. It is implied that COX-2 may be a protecting factor in MMC induced esophageal cancer cell apoptosis, and the use of COX-2 inhibitor as an enhancer for esophageal cancer chemotherapy may be reasonable.