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. 2019 Jan 1;79(1):125-132.
doi: 10.1158/0008-5472.CAN-18-1938. Epub 2018 Nov 6.

Inhibition of Thioredoxin/Thioredoxin Reductase Induces Synthetic Lethality in Lung Cancers with Compromised Glutathione Homeostasis

Xiang Yan #  1   2 Xiaoshan Zhang #  1 Li Wang  1 Ran Zhang  1 Xingxiang Pu  1 Shuhong Wu  1 Lei Li  3 Pan Tong  4 Jing Wang  4 Qing H Meng  5 Vanessa B Jensen  6 Luc Girard  7 John D Minna  7 Jack A Roth  1 Stephen G Swisher  1 John V Heymach  8 Bingliang Fang  9
Affiliations

Inhibition of Thioredoxin/Thioredoxin Reductase Induces Synthetic Lethality in Lung Cancers with Compromised Glutathione Homeostasis

Xiang Yan et al. Cancer Res. .

Abstract

Glutathione (GSH)/GSH reductase (GSR) and thioredoxin/thioredoxin reductase (TXNRD) are two major compensating thiol-dependent antioxidant pathways that maintain protein dithiol/disulfide balance. We hypothesized that functional deficiency in one of these systems would render cells dependent on compensation by the other system for survival, providing a mechanism-based synthetic lethality approach for treatment of cancers. The human GSR gene is located on chromosome 8p12, a region frequently lost in human cancers. GSR deletion was detected in about 6% of lung adenocarcinomas in The Cancer Genome Atlas database. To test whether loss of GSR sensitizes cancer cells to TXNRD inhibition, we knocked out or knocked down the GSR gene in human lung cancer cells and evaluated their response to the TXNRD inhibitor auranofin. GSR deficiency sensitized lung cancer cells to this agent. Analysis of a panel of 129 non-small cell lung cancer (NSCLC) cell lines revealed that auranofin sensitivity correlated with the expression levels of the GSR, glutamate-cysteine ligase catalytic subunit (GCLC), and NAD(P)H quinone dehydrogenase 1 (NQO1) genes. In NSCLC patient-derived xenografts with reduced expression of GSR and/or GCLC, growth was significantly suppressed by treatment with auranofin. Together, these results provide a proof of concept that cancers with compromised expression of enzymes required for GSH homeostasis or with chromosome 8p deletions that include the GSR gene may be targeted by a synthetic lethality strategy with inhibitors of TXNRD. SIGNIFICANCE: These findings demonstrate that lung cancers with compromised expression of enzymes required for glutathione homeostasis, including reduced GSR gene expression, may be targeted by thioredoxin/thioredoxin reductase inhibitors.

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Conflict of interest statement

Conflicts of Interest

The authors declare that they have no competing interests.

Figures

Figure 1.
Figure 1.
GSR gene deletions in human cancers from TCGA database. (A) GSH/GSR and TXN/TXNRD pathways in regulating protein dithiol/disulfide balance. Both GSH and TXN catalyze the reduction of disulfide bonds in proteins to dithiols, which is critical for maintaining protein functions. (B) Alterations in GSR and other selected genes in lung adenocarcinomas. The mutation frequencies are shown on the left side of the graph. Deletions of the GRS gene overlap mostly with the deletion of TUSC3, a gene located in chromosome 8p22, indicating co-occurrence of GSR deletion and chromosome 8p loss. (C) Frequencies of GSR gene deletions in different types of cancers. The data were obtained by using the cBioPortal for Cancer Genomics.
Figure 2.
Figure 2.
Effect of GSR knockout on auranofin activity in lung cancer cells. (A) Schema of CRISPR/Cas9-mediated knockout of the GSR gene. (B) Western blot verification of GSR-knockout clones 1-5. Wt, controls. (C) Dose responses of A549 and A549/GSR−/− cells to auranofin treatment. (D-E) Apoptosis in response to treatment with auranofin in A549 and A549/GSR−/− cells. * indicates P< 0.05 between two cell lines. (F) PARP cleavage detected by Western blot analysis. β-actin is used as loading control.
Figure 3.
Figure 3.
Auranofin sensitivity in lung cancer cells after knockdown of GSR and/or GCLC genes with shRNA (A-D) or siRNA (E-H). Western blot (A, C, E, G) analysis confirmed knockdown of GSR and/or GCLC in DFC1024 and H2023 lung cancer cell lines. (B, D, F, H) Auranofin sensitivity of the knockdown cells and of the parental and control cells (shControl and siControl) was determined by a quadruplicate assay. The values represent mean ± SD.
Figure 4.
Figure 4.
Auranofin sensitivity and GSR and GCLC gene expression in NSCLC cell lines. (A) The IC50 of auranofin in 129 NSCLC cell lines. (B) The IC50 of auranofin in 12 auranofin-sensitive NSCLC cell lines and 10 auranofin-resistant NSCLC cell lines. (C) Western blot analysis of GSR, GCLC, GCLM, NQO1, and TXNRD1 expression in auranofin-sensitive and -resistant NSCLC cells. Note: the expression of GSR, GCLC, and NQO1 was highly associated with auranofin sensitivity.
Figure 5.
Figure 5.
In vivo activity of auranofin in NSCLC PDX models. (A) Western blot analysis of GSR and GCLC expression in 19 NSCLC PDX specimens. Mice bearing a PDX-12 (B), PDX-2 (C), and PDX-1 (D) were given auranofin (10 mg/kg) or a solvent (control) for the time periods shown. Upper panels show tumor growth after treatment started. The values are presented as the means ± SD (n = 3/group for PDX-1, and n=5/group for PDX-2 and -12). The mean tumor volume in the auranofin group was not significantly different from that in solvent group in PDX-1 model, but was significantly lower than that in the solvent group in both PDX-2 and -12 models (P <0.01) according to analysis of variance with a repeated measurement module. Lower panels show that auranofin caused no significant weight loss in the mice.
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