Autophagy induced by cathepsin S inhibition induces early ROS production, oxidative DNA damage, and cell death via xanthine oxidase.

Cathepsin S plays multiple roles in MHC class II antigen presentation, extracellular matrix degradation, angiogenesis, and tumorogenesis. Our previous study revealed that targeting cathepsin S could induce cellular cytotoxicity and reduce cell viability. For the current study, we further investigated the molecular mechanism responsible for targeting cathepsin S-induced cell death and its association with autophagy. Distinct from regulation of the classic autophagy pathway by reactive oxygen species (ROS), we demonstrated that autophagy is the genuine regulator of early ROS production. The molecular silencing of autophagy-dependent ATG genes (ATG5, ATG7, and LC3) and the pharmacologic inhibition of autophagy with 3-MA and wortmannin reduced ROS production significantly. In addition, xanthine oxidase (XO), which is upregulated by autophagy, is required for early ROS production, oxidative DNA damage, and consequent cell death. Autophagy inhibition suppresses the upregulation of XO, which is induced by cathepsin S inhibition, resulting in reduced ROS generation, DNA damage, and cell death. Collectively, our study reveals a noncanonical molecular pathway in which, after the inhibition of cathepsin S, autophagy induces early ROS production for oxidative DNA damage and cell death through XO.

Targeting cathepsin S induces tumor cell autophagy via the EGFR-ERK signaling pathway.

Cathepsin S is a cellular cysteine protease, which is frequently over-expressed in human cancer cells and plays important role in tumor metastasis. However, the role of cathepsin S in regulating cancer cell survival and death remains undefined. The aim of this study was to determine whether targeting cathepsin S could induce autophagy/apoptosis in cancer cells. In this study, we demonstrated that targeting cathepsin S by either specific small molecular inhibitors or cathepsin S siRNA induced autophagy and subsequent apoptosis in human cancer cells, and the induction of autophagy was dependent on the phosphorylation of EGFR and activation of the EGFR-related ERK/MAPK-signaling pathway. In conclusion, the current study reveals that cathepsin S plays an important role in the regulation of cell autophagy through interference with the EGFR-ERK/MAPK-signaling pathway.

Combination of arsenic trioxide and BCNU synergistically triggers redox-mediated autophagic cell death in human solid tumors.

Arsenic trioxide (As(2)O(3)) is an effective treatment for relapsed or refractory acute promyelocytic leukemia (APL). After the discovery of As(2)O(3) as a promising treatment for APL, several studies investigated the use of As(2)O(3) as a single agent in the treatment of solid tumors; however, its therapeutic efficacy is limited. Thus, the systematic study of the combination of As(2)O(3) with other clinically used chemotherapeutic drugs to improve its therapeutic efficacy in treating human solid tumors is merited. In this study, we demonstrate for the first time, using isobologram analysis, that As(2)O(3) exhibits a synergistic interaction with N,N'-bis(2-chloroethyl)-N-nitrosourea (BCNU). The synergistic augmentation of the cytotoxicity of As(2)O(3) with BCNU is in part through the autophagic cell death machinery in human solid tumor cells. As(2)O(3) and BCNU in combination produce enhanced cytotoxicity via the depletion of reduced glutathione (GSH) and augmentation of reaction oxygen species (ROS) production. Further analysis indicated that the extension of GSH depletion by this combined regimen occurs through the inhibition of the catalytic activity of glutathione reductase. Blocking ROS production with antioxidants or ROS scavengers effectively inhibits cell death and autophagy formation, indicating that redox-mediated autophagic cell death involves the synergism of As(2)O(3) with BCNU. Taken together, this is the first evidence that BCNU could help to extend the therapeutic spectrum of As(2)O(3). These findings will be useful in designing future clinical trials of combination chemotherapy with As(2)O(3) and BCNU, with the potential for broad use against a variety of solid tumors.

Characterization of novel transforming growth factor-beta type I receptors found in malignant pleural effusion tumor cells.

BACKGROUND: Tumors expressing a transforming growth factor-beta type I receptor (T beta RI) mutant with sequence deletions in a nine-alanine (9A) stretch of the signal peptide are reported to be highly associated with disease progression. Expression of this mutant could interfere with endogenous TGFbeta signaling in the cell. However, little is known about the importance of the remaining part of the signal peptide on the cellular function of T beta RI. RESULTS: We cloned and identified four new in-frame deletion variants of T beta RI, designated DM1 to DM4, in pleural effusion-derived tumor cells. Intriguingly, DM1 and DM2, with a small region truncated in the putative signal peptide of T beta RI, had a serious defect in their protein expression compared with that of the wild-type receptor. Using serial deletion mutagenesis, we characterized a region encoded by nucleotides 16-51 as a key element controlling T beta RI protein expression. Consistently, both DM1 and DM2 have this peptide deleted. Experiments using cycloheximde and MG132 further confirmed its indispensable role for the protein stability of T beta RI. In contrast, truncation of the 9A-stretch itself or a region downstream to the stretch barely affected T beta RI expression. However, variants lacking a region C-terminal to the stretch completely lost their capability to conduct TGFbeta-induced transcriptional activation. Intriguingly, expression of DM3 in a cell sensitive to TGFbeta made it significantly refractory to TGFbeta-mediated growth inhibition. The effect of DM3 was to ablate the apoptotic event induced by TGFbeta. CONCLUSION: We identified four new transcript variants of T beta RI in malignant effusion tumor cells and characterized two key elements controlling its protein stability and transcriptional activation. Expression of one of variants bestowed cancer cells with a growth advantage in the presence of TGFbeta. These results highlight the potential roles of some naturally occurring T beta RI variants on the promotion of tumor malignancy.