Impacts of autophagy-inducing ingredient of areca nut on tumor cells.

Areca nut (AN) is a popular carcinogen used by about 0.6-1.2 billion people worldwide. Although AN contains apoptosis-inducing ingredients, we previously demonstrated that both AN extract (ANE) and its 30-100 kDa fraction (ANE 30-100K) predominantly induce autophagic cell death in both normal and malignant cells. In this study, we further explored the action mechanism of ANE 30-100K-induced autophagy (AIA) in Jurkat T lymphocytes and carcinoma cell lines including OECM-1 (mouth), CE81T/VGH (esophagus), SCC25 (tongue), and SCC-15 (tongue). The results showed that chemical- and small hairpin RNA (shRNA)-mediated inhibition of AMP-activated protein kinase (AMPK) resulted in the attenuation of AIA in Jurkat T but not in OECM-1 cells. Knockdown of Atg5 and Beclin 1 expressions ameliorated AIA in OECM-1/CE81T/VGH/Jurkat T and OECM-1/SCC25/SCC-15, respectively. Furthermore, ANE 30-100K could activate caspase-3 after inhibition of Beclin 1 expression in OECM-1/SCC25/SCC15 cells. Meanwhile, AMPK was demonstrated to be the upstream activator of the extracellular-regulated kinase (ERK) in Jurkat T cells, and inhibition of MEK attenuated AIA in Jurkat T/OECM-1/CE81T/VGH cells. Finally, we also found that multiple myeloma RPMI8226, lymphoma U937, and SCC15 cells survived from long-term non-cytotoxic ANE 30-100K treatment exhibited stronger resistance against serum deprivation through upregulated autophagy. Collectively, our studies indicate that Beclin-1 and Atg5 but not AMPK are commonly required for AIA, and MEK/ERK pathway is involved in AIA. Meanwhile, it is also suggested that long-term AN usage might increase the resistance of survived tumor cells against serum-limited conditions.

Autophagy induction by the 30-100kDa fraction of areca nut in both normal and malignant cells through reactive oxygen species.

Areca nut (AN) is an addictive carcinogen used by about 200-600 million people worldwide. Some AN components are shown to induce apoptosis; however, we previously demonstrated that AN extract (ANE) and the 30-100kDa fraction of ANE (ANE 30-100K) induced autophagy-like responses, such as swollen cell morphology, empty cytoplasm, acidic vesicles, and LC3-II accumulation, in an oral cancer cell line, OECM-1. To further assess the responses of other cell types to ANE 30-100K, we used both normal and malignant cells as the targets of ANE 30-100K and found that normal oral fibroblasts (CMT415), peripheral blood lymphocytes (PBLs), Jurkat leukemia T cells, and esophageal carcinoma cells (CE81T/VGH) exhibited similar responses after ANE 30-100K challenge. ANE 30-100K drastically increased acidic vesicle-containing PBLs isolated from two independent donors (from 0.1% to 92.1% and 2.9% to 64.2%). Furthermore, both ANE- and ANE 30-100K-induced LC3-II accumulation in CMT415 and CE81T/VGH was further increased in the presence of the lysosomal protease inhibitors (pepstatin A, E64d, and leupeptin). On the other hand, ANE 30-100K also increased the level of intracellular reactive oxygen species (ROS), and the ROS scavengers, N-acetylcysteine (NAC) and Tiron, inhibited ANE 30-100K-induced cell death and LC3-II accumulation. Collectively, these results suggest the existence of an autophagy-inducing AN ingredient (AIAI) in ANE 30-100K, which renders ANE as an autophagic flux inducer through ROS in both normal and malignant cells.