Abstract
Helicobacter pylori infection induces chronic inflammation that contributes to gastric tumorigenesis. Tumor necrosis factor (TNF-α) is a proinflammatory cytokine, and polymorphism in the TNF-α gene increases the risk of gastric cancer. We herein investigated the role of TNF-α in gastric tumorigenesis using Gan mouse model, which recapitulates human gastric cancer development. We crossed Gan mice with TNF-α (Tnf) or TNF-α receptor TNFR1 (Tnfrsf1a) knockout mice to generate Tnf−/− Gan and Tnfrsf1a−/− Gan mice, respectively, and examined their tumor phenotypes. Notably, both Tnf−/− Gan mice and Tnfrsf1a−/− Gan mice showed similar, significant suppression of gastric tumor growth compared with control Tnf+/+ or Tnfrsf1a+/+ Gan mice. These results indicate that TNF-α signaling through TNFR1 is important for gastric tumor development. Bone marrow (BM) transplantation experiments showed that TNF-α expressed by BM-derived cells (BMDCs) stimulates the TNFR1 on BMDCs by an autocrine or paracrine manner, which is important for gastric tumor promotion. Moreover, the microarray analysis and colony formation assay indicated that NADPH oxidase organizer 1 (Noxo1) and Gna14 are induced in tumor epithelial cells in a TNF-α-dependent manner, and have an important role in tumorigenicity and tumor-initiating cell property of gastric cancer cells. Accordingly, it is possible that the activation of TNF-α/TNFR1 signaling in the tumor microenvironment promotes gastric tumor development through induction of Noxo1 and Gna14, which contribute to maintaining the tumor cells in an undifferentiated state. The present results indicate that targeting the TNF-α/TNFR1 pathway may be an effective preventive or therapeutic strategy for gastric cancer.
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Introduction
Gastric cancer is the fourth most common cancer and second leading cause of death from malignancy worldwide.1 Helicobacter pylori infection induces chronic gastritis, which is related to gastric cancer development.2, 3 It has been established that inflammation has an important role in cancer development through a variety of mechanisms.4, 5 Genetic polymorphisms in proinflammatory cytokine genes, interleukin (IL)-1β and tumor necrosis factor (TNF)-α are associated with an increased risk of gastric cancer.6, 7, 8 Moreover, a combination of specific polymorphisms in IL-1β, IL-1RN, TNF-α and IL-10 increases the odds ratio for gastric cancer by 27-fold, indicating an important role for these inflammatory cytokines in gastric tumorigenesis.7, 9 It has been demonstrated that transgenic expression of IL-1β in the stomach causes development of gastritis-associated gastric cancer, with the recruitment of myeloid-derived suppressor cells.10 Moreover, mutation in the IL-6 and IL-11 coreceptor, gp130, results in gastric tumor development through activation of Stat3.11, 12 On the other hand, the role of TNF-α in gastric tumorigenesis has not yet been investigated using a genetic mouse model.
Accumulating evidence has indicated that TNF-α is an important cytokine involved in cancer development in a variety of organs. TNF-α production is associated with advanced cancers and a poor prognosis.13, 14 Mouse genetic studies indicated that disruption of the TNF-α or TNFR1 receptor genes resulted in significant suppression of chemically induced tumorigenesis in the mouse skin and colon.15, 16, 17 These results indicate that TNF-α/TNFR1 signaling has a key role in cancer development. Thus, in the present study, we examined the role of TNF-α signaling through its receptor TNFR1 in gastric tumorigenesis.
We have previously generated a gastric tumor mouse model, Gan mice, which develop intestinal-type gastric tumors by the transgenic expression of Wnt1, Ptgs2 and Ptges, encoding Wnt1, COX-2 and mPGES-1, respectively.18, 19 Simultaneous expression of these three genes in the glandular stomach activates both canonical Wnt signaling and the COX-2/PGE2 pathway. Wnt signaling activation is one of the major causes of human gastric cancer.18, 20 On the other hand, the COX-2/PGE2 pathway is induced in a variety of cancers, including gastric cancer, and is important for promoting tumor development.21 Accordingly, Gan mice recapitulate human gastric cancer development at the molecular level and host responses. Notably, the gene expression profiles of Gan mouse tumors are similar to those of human intestinal-type gastric cancer.22 Therefore, it is rational to use Gan mice for studies of the role of microenvironment and host responses, such as inflammation, in gastric tumorigenesis.
In the present study, we crossed Gan mice with Tnf−/− and Tnfrsf1a−/− mice, and found that gastric tumorigenesis was significantly suppressed by disruption of the TNF-α/TNFR1 signaling. Bone marrow (BM) chimera experiments indicated that activation of TNF-α/TNFR1 signaling in BM-derived cells (BMDCs) is important for gastric tumor promotion. Moreover, we found that NADPH oxidase organizer 1 (Noxo1) and Gna14 are induced in gastric tumors by a TNF-α-dependent mechanism, and that these molecules are important for the tumorigenicity and stemness of gastric cancer cells. Accordingly, the present results suggest that activation of TNF-α/TNFR1 signaling promotes gastric tumorigenesis through induction of these tumor-promoting factors in tumor epithelial cells.
Results
Suppression of gastric tumorigenesis in Tnf−/− Gan mice
To examine the role of TNF-α in gastric tumorigenesis, we crossed Gan mice with Tnf knockout mice and examined the tumor phenotype. Notably, the gastric tumor development was significantly suppressed in Tnf−/− Gan mice (Figures 1a and b), and the mean tumor size decreased to 18.0% of that observed in the littermate Tnf+/+ Gan mice (Figure 1c). These results indicate that TNF-α has an important role in gastric tumorigenesis. In Tnf+/+ Gan mice, 5-bromo-2′-deoxyuridine (BrdU)-labeled proliferating cells were found in the entire tumor tissue, whereas the BrdU-incorporated cells were mostly limited to the proliferating zone at the neck area in Tnf−/− Gan mouse tumors (Figure 1d). Therefore, it is possible that cell differentiation was induced outside of the proliferating area in Tnf−/− Gan mouse tumors.
K19-Wnt1 mice did not develop gastric tumors, but they developed small preneoplastic lesions consisting of dysplastic and Ki-67-positive epithelial cells in the glandular stomach (Supplementary Figure 1), which was consistent with previous results.18, 19 Notably, Tnf−/− K19-Wnt1 mice developed a similar number of preneoplastic lesions to the Tnf+/+ K19-Wnt1 mice (Figure 1e). Taken together, these results indicate that TNF-α signaling is not required for the early initiation stage, but has an important role in the promotion stage of gastric tumorigenesis.
Role of TNF-α expressed by BMDCs in tumorigenesis
In Gan mouse gastric tumors, macrophages are infiltrated and activated,23 suggesting that macrophage-derived TNF-α is important for tumor promotion. To assess this possibility, we examined the expression of TNF-α and its receptors, TNFR1 and TNFR2, in tumor epithelial cells and stromal cells that were separately obtained by using laser microdissection (Supplementary Figure 2). Expression levels of TNF-α, TNFR1 and TNFR2 were significantly higher in stromal cells compared with epithelial cells, although their expression was also detected in the tumor epithelial cells (Figure 2a).
To examine the role of TNF-α expressed by BMDCs, we performed BM transplantation from Tnf+/+ green fluorescent protein (GFP) transgenic mice or Tnf−/− mice into Tnf−/− Gan mice. Notably, gastric tumor phenotype was rescued significantly in the Tnf+/+ GFP BM-transplanted Tnf−/− Gan mice (Figure 2b), and the mean tumor size increased about fivefold compared with the control Tnf−/− BM-transplanted Tnf−/− Gan mice (Figure 2c). Strong GFP expression was detected in the gastric tumors of the Tnf+/+ GFP BM-transplanted Tnf−/− Gan mice, indicating extensive infiltration of BMDCs into the tumor tissues. The accumulation of GFP-positive BMDCs, as well as F4/80 positive macrophages, was found in the tumor stroma of BM chimeric mice (Figure 2d). Double fluorescent immunostaining indicated that 78% of GFP-expressing BMDCs were macrophages, whereas GFP expression was not detected in the E-cadherin-positive epithelial cells. These results indicate that TNF-α expressed by BMDCs, including macrophages, is important for gastric tumorigenesis.
Suppression of gastric tumorigenesis in Tnfrsf1a−/− Gan mice
It has been shown that TNF-α signaling through TNFR1, encoded by Tnfrsf1a, is important for skin and colon cancer development.16, 17 To examine the role of TNFR1 signaling in gastric tumorigenesis, we crossed Gan mice with Tnfrsf1a knockout mice and examined the tumor phenotype by X-ray computed tomography (CT) analyses. Notably, the gastric tumor development was significantly suppressed in Tnfrsf1a−/− Gan mice (Figure 3a), and the mean tumor area on CT images was decreased to 40.6% of that of the littermate Tnfrsf1a+/+ Gan mice (Figure 3b). Accordingly, it is possible that TNFR1 is the major receptor for TNF-α involved in the gastric cancer promotion.
Because the expression level of TNFR1 in tumor tissues was higher in stromal cells compared with epithelial cells (Figure 2a), we next examined the role of TNFR1 signaling in BMDCs for gastric tumorigenesis by BM transplantation from Tnfrsf1a−/− mice into Gan mice. By X-ray CT analyses, all control Gan mice that were transplanted with wild-type mouse BM showed a significant increase in tumor size during the 8 weeks of the study (Figures 3c and e). In contrast, Gan mice that received BM from Tnfrsf1a−/− mice showed suppression of gastric tumor growth (Figures 3d and e), indicating that TNF-α signaling through TNFR1 in BMDCs has a role in gastric tumor growth.
Inflammatory responses in Tnf−/− Gan mouse tumor tissues
TNF-α signaling leads to the activation of NF-κB through phosphorylation of IκBα. As expected, the level of phosphorylated IκBα was increased in Gan mouse tumors compared with the wild-type mouse stomach (Figure 4a). In contrast, the IκBα phosphorylation level was significantly decreased in Tnf−/− Gan mouse tumors, indicating that NF-κB activation in tumors was suppressed by the disruption of TNF-α gene. On the other hand, the levels of phosphorylated Stat3 were increased significantly in both the Tnf+/+ and Tnf−/− Gan mouse tumors to similar levels compared with the wild-type mouse level, suggesting that the cytokine pathways other than the TNF-α/NF-κB signaling were not suppressed in the Tnf−/− Gan mouse tumors.
Consistently, infiltration of T cells and macrophages were found in the Tnf−/− Gan mouse gastric tumors, similar to what they had in the Tnf+/+ Gan mouse tumors (Figure 4b). The expression levels of IL-1β, IL-6, CXCL1 and CXCL2 in the gastric tumors were increased in the Tnf+/+ Gan mouse tumors (Figure 4c). Notably, in the Tnf−/− Gan mouse tumors, the expression levels of these cytokines and chemokines significantly increased compared with those in wild-type mouse stomach, thus indicating that inflammation was not suppressed by Tnf gene disruption. It is therefore possible that the activation of TNF-α signaling is required for gastric tumor promotion, even if other tumor-promoting cytokines, such as IL-1β and IL-6, are induced in the tumor tissues.
Differentiation of tumor cells by TNF-α gene disruption
To identify the tumor-promoting factors that are induced by a TNF-α, we performed a microarray analysis using Tnf−/− Gan and Tnf+/+ Gan mouse tumors and wild-type mouse stomachs (Gene Expression Omnibus (GEO) accession GSE43145). Using the microarray results, we extracted genes that were upregulated ⩾twofold in Tnf+/+ Gan mouse tumors compared with wild-type mouse stomachs (Figure 5a). We next extracted the genes that were significantly downregulated in Tnf−/− Gan mouse tumors compared with Tnf+/+ Gan mice. By comparing these two gene sets, 157 genes were identified that were upregulated in gastric tumors in a TNF-α-dependent manner (Figure 5b and Supplementary Table 1). Interestingly, CD44, Prom1, Sox9 and EphB3 were significantly donwregulated in Tnf−/− Gan mouse tumors, which are known markers of stem cells or progenitor cells in the intestine and liver,24, 25 suggesting that differentiation of tumor cells was induced by inhibition of TNF-α signaling.
We have previously demonstrated that expression of CD44 is induced in Gan mouse tumors.26, 27 Because CD44 is a marker of normal and cancer stem cells,28 we examined CD44 expression and differentiation status of epithelial cells in Tnf−/− Gan mouse tumors. In the Tnf+/+ or Tnf+/− Gan mouse tumors, CD44 mRNA levels increased significantly, by more than eightfold, the level observed in wild-type mice (Supplementary Figure 3a). In the Tnf−/− Gan mouse tumors, however, the CD44 induction was only about 4.5-fold than that of the wild-type stomachs. Notably, expression of differentiation markers, Muc5AC and H+K+/ATPase, was detected in the CD44-negative epithelial cells in Tnf−/− Gan mouse tumors, whereas CD44-positive tumor cells did not express these markers (Supplementary Figure 3b). Moreover, Ki-67-positive cells were predominantly found in the CD44-positive cell population. These results suggest that disruption of TNF-α gene causes differentiation of tumor epithelial cells, resulting in suppression of proliferation.
Candidate tumor-promoting factors induced by TNF-α
To select candidate genes whose products function to maintain the undifferentiated status, we compared the selected 157 genes with a gene set that was upregulated ⩾twofold in Lgr5+ gastric stem cells.29 As a result, we found that 11 out of the 157 genes were upregulated also in gastric stem cells (Figure 5c). We next transfected small interfering RNAs (siRNAs) against these 11 genes into Kato-III cells, and examined the cell growth in soft agar. Notably, inhibition of Noxo1, Gna14 and Prom1 expression resulted in a significant decrease of cell proliferation in soft agar (Figure 6a). We further examined the tumorigenicity of Kato-III, MKN45 and MKN74 gastric cancer cells by transfection with siRNAs targeting different sequences of Noxo1, Gna14, and Prom1. Notably, siRNAs for Noxo1 or Gna14 suppressed the soft agar colony formation in all cell lines, while Prom1 siRNAs suppressed only in Kato-III cells (Figure 6b and Supplementary Figure 4). Moreover, we found by reverse transcription-PCR (RT–PCR) that expression of Noxo1 and Gna14 was induced in gastric tumor epithelial cells as well as the tumor tissues of Gan mice (Figures 6c and d). Accordingly, it is possible that TNF-α plays a tumor-promoting role through the induction of Noxo1 and Gna14 in tumor epithelial cells.
Role of Noxo1 and Gna14 in differentiation and cancer cell stemness
Differentiation of the primary cultured gastric epithelial cells was associated with the downregulation of a Sox9 and induction of Muc5AC expression (Figure 6e). Sox9 and Muc5AC are markers for undifferentiated and differentiated status, respectively. Notably, expression of both Noxo1 and Gna14 was decreased significantly in the differentiated epithelial cells compared with the undifferentiated cells, suggesting a role for Noxo1 and Gna14 in maintenance of undifferentiated status. We therefore examined the role of Noxo1 and Gna14 in the sphere formation of gastric cancer cells. MKN74 cells formed sphere colonies under hypoxic conditions, which were thought to reflect the characteristic of cancer stem cells. Notably, inhibition of Noxo1 and Gna14 expression by transfection of siRNAs resulted in a significant decrease in the number of sphere colonies, suggesting that Noxo1 and Gna14 have a role in maintaining the stemness of gastric cancer cells (Figures 6f and g).
TNF-α and CD44 in human gastric cancer tissues
Finally, we examined the expression of TNF-α and CD44 in human primary gastric cancers by real-time RT–PCR. The expression of TNF-α and CD44 was upregulated in 65% and 74% of gastric cancer tissues, respectively, and the expression of TNF-α and CD44 was positively correlated (Supplementary Figure 5). Therefore, it is possible that undifferentiated status of cancer cells is related to the level of TNF-α signaling also in the human gastric cancer.
Discussion
Polymorphism of TNF-α gene is associated with an increased risk of gastric cancer, suggesting a role for TNF-α in gastric tumorigenesis.7, 9 In the present study, we have demonstrated, for the first time, that the induction of TNF-α signaling through TNFR1 promotes gastric tumorigenesis through inducing tumor-promoting factors, Noxo1 and Gna14, in tumor epithelial cells (Figure 7).
One of the most important points of the present study is that we have successfully separated TNF-α signaling from COX-2/PGE2-associated inflammatory responses in tumor tissues. Inflammatory cytokine signaling, including TNF-α, IL-6 and CXCL12, is induced simultaneously in tumor tissues, and the cytokine pathways activate each other by constructing a cytokine network.30 Some of the inflammatory mediators have been shown to have a role in tumorigenesis. For example, we and other groups31, 32, 33 have demonstrated that the COX-2/PGE2 pathway has an essential role in gastrointestinal tumorigenesis by inducing angiogenesis and activation of Wnt signaling. Moreover, IL-6 and Stat3 are important for the development of colitis-associated colon cancer,34, 35 and constitutive activation of IL-1β signaling can induce gastric tumorigenesis.10 It has also been reported that CXCL1/2 expression is linked to chemoresistance and metastasis.36 Notably, the COX-2/PGE2, IL-1β, IL-6 and CXCL1/2 pathways were still induced in the Tnf−/− Gan mouse tumors, possibly as a result of the transgenic expression of Ptgs2 and Ptges. Accordingly, the present results clearly indicate that TNF-α signaling is required for gastric tumor development, even when an inflammatory network of other cytokines/chemokines is present.
It has been shown that the TNF-α receptor, TNFR1, signaling has a role in tumor development in chemically induced skin tumor and colitis-associated colon cancer mouse models.16, 17 In this study, we also showed that disruption of the TNFR1 gene resulted in significant suppression of gastric tumorigenesis. Accordingly, it is possible that TNFR1 is the major receptor of TNF-α involved in gastric tumor promotion. In the present study, we found that TNF-α/TNFR1 signaling in BMDCs is important for gastric tumor growth. However, blocking TNFR1 signaling did not induce an effective regression of tumors even at 8 weeks after BM transplantation. It is possible that more than 8 weeks are required for established gastric tumors to regress by blocking the TNF/TNFR1 pathway. Moreover, TNFR1 is also expressed in the epithelial cells. Thus, it is conceivable that TNF-α signaling through TNFR1 on epithelial cells also contributes to gastric tumorigenesis, although it remains to be investigated.
Here, we have identified two tumor-promoting factors, Noxo1 and Gna14, which have a role in maintaining the tumorigenicity and stemness of gastric cancer cells. It is possible that one of the tumor-promoting mechanisms of TNF-α signaling is the maintenance of the stemness of cancer cells. Noxo1 encodes NOX-organizing protein 1, which is a component of the cytosolic regulatory subunits of NOX, and is associated with catalytic isoform NOX1.37 NOX1 is one of the NOX family members, which are reactive oxygen species-generating enzymes that regulate the redox-sensitive signaling pathways. It has been reported that NOX1 expression is upregulated by oncogenic Ras activation and is required for transformation of cancer cells.38, 39 Moreover, a microarray analysis indicated that Noxo1 expression is upregulated in a subpopulation of colon cancers.40 Accordingly, it is possible that Noxo1 is induced in cancer cells, together with NOX1, in the inflammatory microenvironment, contributing to an oncogene-induced transformation phenotype through the generation of reactive oxygen species.
In contrast to NOX1, little is known about the role(s) of Gna14 in tumor development. Gna14 encodes guanine nucleotide-binding protein subunit alpha14 (Gα14), a member of the Gqα subfamily of G proteins.41 Gα14 is employed by a variety of G protein-coupled receptors, including somatostatin type 2 receptor and chemokine receptor CCR1, which activate the NF-κB pathway.42, 43 Recently, it has been reported that activation of NF-κB in the Wnt-activated cells induces dedifferentiation in intestinal epithelial cells, resulting in the acquisition of tumor-initiating property.44 Accordingly, it is possible that Gna14 expression contributes to maintaining tumor cells in an undifferentiated status through activation of NF-κB, which leads to tumor development.
Noxo1 and Gna14 were induced in the tumor epithelial cells, whereas TNF-α/TNFR1 signaling was predominantly activated in the BMDCs of Gan mouse tumors. Accordingly, it is possible that the expression of Noxo1 and Gna14 in tumor cells is not directly regulated by TNF-α signaling, but indirectly through BMDC-expressing molecule(s) that are induced by the TNF-α/NF-κB pathway. It is therefore conceivable that such a molecule would be an effective target for the prevention or treatment of gastric cancer.
In conclusion, we demonstrated that TNF-α/TNFR1 signaling in the tumor microenvironment promotes gastric cancer development. Noxo1 and Gna14 are induced in tumor epithelial cells by a TNF-α-dependent manner, which is important for gastric tumorigenesis. Accordingly, it is possible that targeting TNF-α signaling in the microenvironment, or inhibition of Noxo1 and Gna14 induction or their functions in tumor cells, may represent a preventive or therapeutic strategy against gastric cancer.
Materials and methods
Animal models
K19-Wnt1 mice express Wnt1 driven by the Krt19 gene promoter, which is transcriptionally active in gastric epithelial cells, whereas Gan mice express Wnt1, Ptgs2 and Ptges, driven by the Krt19 promoter.18, 19 Tnf mutant mice were purchased from Jackson Laboratories (Bar Harbor, ME, USA), and Tnfrsf1a mutant mice were described previously.17 For the tumor phenotype analyses, Gan mice were euthanized and examined at 50 weeks of age (n=8 for Tnf+/+ Gan mice and Tnf−/− Gan mice, and n=10 for Tnf+/− Gan mice) or examined by a X-rayCT analysis at 25 weeks of age (n=9 for Tnfrsfr1a+/+ Gan mice, and n=5 for Tnfrsf1a−/− Gan mice). All animal experiments were carried out according to the protocol approved by the Committee on Animal Experimentation of Kanazawa University, Japan.
Measurement of tumor volume and scoring of preneoplastic lesions
The tumor area was measured by the ImageJ 1.46 software program (NIH, Bethesda, MD, USA) using photographs that were taken under a dissecting microscope. The mucosal thickness (tumor height) of the gastric tumors was measured using histology sections. The ‘tumor size’ was calculated by multiplying the tumor area by the tumor height (‘tumor area’ × ‘tumor height’). The relative tumor size was calculated in comparison with the mean of the control Gan mouse tumor size. The X-ray CT images of the gastric tumors were examined using a LaTheta LCT-100 instrument (Aloka, Tokyo, Japan). The tumor areas of the slice images were measured using the ImageJ 1.46 software program (NIH), and three serial images, including the largest tumor image, were selected from all scanned images for each mouse, and the mean tumor area of the three images was calculated and compared with the mean value of the control Gan mice. The number of preneoplastic lesions in the glandular stomachs of K19-Wnt1 mice (n=6 for each genotype) was counted using eight independent histology sections, and the mean number per section was calculated.
Real-time RT-PCR
Gastric tumors of Tnf+/+ Gan (n=7) and Tnf−/− Gan mice (n=8), and normal stomachs of wild-type mice (n=6), were used for RNA extraction. For human tissue samples, paired samples of human gastric cancer tissues and adjacent normal stomach tissues (n=23) were collected at Kanazawa University Hospital, Japan. For experiments using human tissue samples, approval for the project was obtained from the Kanazawa University Medical Ethics Committee, and written informed consent was obtained before specimen collection. The total RNAs of tissue samples were extracted using ISOGEN (Nippon Gene, Tokyo, Japan), reverse-transcribed using the PrimeScript RT reagent kit (Takara, Tokyo, Japan) and were PCR-amplified by a Stratagene Mx3000P instrument (Agilent Technologies, Santa Clara, CA, USA) using SYBR Premix ExTaqII (Takara). To avoid location-related differences in the differentiation and proliferation status within a Gan mouse tumor tissue, two samples were collected from different regions of the same tumors. The primers used for the real-time RT–PCR were purchased from Takara. For laser microdissection-based RT–PCR, epithelial cells and stromal cells were separately collected from frozen sections of Gan mouse tumors (n=4) using laser microdissection LMD7000 (Leica Microsystems, Wetzler, Germany), and the total RNAs were extracted using a RNeasy Micro kit (Qiagen, Valencia, CA, USA).
BM transplantation
BM cells were prepared from the femurs and tibias of donor mice. Recipient mice were irradiated with 9 Gy, followed by intravenous injection of 2 × 106 BM cells. Tnf+/+ GFP mouse BM was transplanted into Tnf−/− Gan mice and Tnf−/− mice BM was transplanted into Tnf−/− Gan mice as a control. Tnfrsf1a−/− BM was transplanted into Tnfrsf1a+/+ Gan mice and wild-type mouse BM was transplanted into Tnfrsf1a+/+ Gan mice as a control. The X-ray CT images of the gastric tumors were examined at 0 and 8 weeks after BM transplantation.
Histology and immunohistochemistry
Tissues were fixed in 4% paraformaldehyde, paraffin-embedded and sectioned at 4 μm thickness. Sections were stained with hematoxylin and eosin (H&E) or processed for the immunohistochemistry. Antibodies against Ki-67 (Dako, Carpinteria, CA, USA), F4/80 (Serotec, Oxford, UK), GFP (Life Technologies, Grand Island, NY, USA), E-cadherin (R&D, Minneapolis, MN, USA), CD3ɛ (Santa Cruz Biotechnology, Santa Cruz, CA, USA), CD44 (Millipore, Billerica, MA, USA), Muc5AC (Thermo Fisher Scientific, Rockford, IL, USA) and H+K+/ATPase (MBL, Nagoya, Japan) were used as the primary antibodies. Staining signals were visualized using the Vectastain Elite Kit (Vector Laboratories, Burlingame, CA, USA). For fluorescence immunohistochemistry, Alexa Fluor 594 or Alexa Fluor 488 antibodies (Molecular Probes, Eugene, OR, USA) were used as the secondary antibody. One milliliter of BrdU was injected intraperitoneally (1 mg/ml; Roche Diagnostics, Indianapolis, IN, USA) 1.5 h before euthanasia, and tissue sections were immunostained with an anti-BrdU antibody (Roche).
Immunoblotting analysis
Tissues were homogenized in lysis buffer, and 10 μg of the supernatant protein sample was separated in a 10% SDS-polyacrylamide gel. Antibodies against phosphorylated IκBα at Ser32/36 and phosphorylated Stat3 at Tyr705 (Cell Signaling, Danvers, MA) were used. An anti-β-actin antibody (Sigma, St Louis, MO, USA) was used as the internal loading control. The ECL detection system (GE Healthcare, Buckinghamshire, UK) was used to detect the signals.
Microarray analysis
Total RNA was extracted from the gastric tumors of Tnf+/+ Gan mice and Tnf−/− Gan mice and wild-type mouse stomachs (n=3 for each) using ISOGEN (Nippon Gene). GeneChip Mouse Genome 430 2.0 Arrays (Affymetrix, Santa Clara, CA, USA) were used for the expression profile analyses. The labeled cRNA was prepared using standard Affymetrix protocols, and the chips were scanned using a GeneChip Scanner 3000 7G (Affymetrix). The microarray results were deposited in the GEO as accession GSE43145.
Cell culture experiments
Gastric cancer cell lines, MKN45, MKN74 and Kato-III (Riken Bioresource Center, Tsukuba, Japan) were cultured in RPMI1640 or DMEM supplemented with 10% fetal bovine serum. Knockdown experiments were performed using Silencer Select Pre-designed siRNA and negative control siRNA (Life Technologies, Carlsbad, CA, USA). For the soft agar proliferation/colony formation assay, cells were mixed in 0.4% agar and seeded in a 96-well or six-well plate and cultured for 1 or 3 weeks, respectively. Then, 96-well plates were stained with AlamarBlue reagent (Life Technologies), and the fluorescence intensity was measured to examine the cell number. Six-well plates were stained with Giemsa solution (Wako, Osaka, Japan) and colony numbers were scored. For the sphere formation assay, MKN74 cells were plated in ultra-low attachment plates (Corning, Corning, NY, USA) and were cultured under hypoxic conditions at 3% O2 and 5% CO2. After 10 days, the number of spheres was counted.
The primary culture of gastric epithelial cells was described previously.45 Briefly, mouse glandular stomachs were treated with 0.1% collagenase, followed by centrifugation at 20 g for 3 min to isolate gastric glands. Isolated glands were digested with trypsin and cultured on collagen-coated dishes. On day 2, the cells were passaged to induce differentiation. The primary cultured cells on day 2 and day 6 were used as undifferentiated and differentiated gastric epithelial cells, respectively.
Statistical analysis
The data were analyzed using the unpaired t-test and are presented as the means±s.d. A value of P<0.05 was considered to be statistically significant.
Accession codes
References
Parkin DM, Bray F, Ferlay J, Pisani P . Global cancer statistics, 2002. CA Cancer J Clin 2005; 55: 74–108.
Peek RM Jr, Blaser MJ . Helicobacter pylori and gastrointestinal tract adenocarcinomas. Nat Rev Cancer 2002; 2: 28–37.
Fox JG, Wang TC . Inflammation, atrophy, and gastric cancer. J Clin Invest 2007; 117: 60–69.
Coussens LM, Werb Z . Inflammation and cancer. Nature 2002; 420: 860–867.
Grivennikov SI, Greten FR, Karin M . Immunity, inflammation, and cancer. Cell 2010; 140: 883–899.
El-Omar EM, Carrington M, Chow W-H, McColl KE, Bream JH, Young HA et al. Interleukin-1 polymorphisms associated with increased risk of gastric cancer. Nature 2000; 404: 398–402.
EL-Omar EM, Rabkin CS, Gammon MD, Vaughan TL, Risch HA, Schoenberg JB et al. Increased risk of noncardia gastric cancer associated with proinflammatory cytokine gene polymorphisms. Gastroenterology 2003; 124: 1193–1201.
Mochado JC, Figueiredo C, Canedo P, Pharoah P, Carvalho R, Nabais S et al. A proinflammatory genetic profile increases the risk for chronic atrophic gastritis and gastric carcinoma. Gastroenterology 2003; 125: 364–371.
El-Omar EM . Role of host genes in sporadic gastric cancer. Best Pract Res Clin Gastroenterology 2006; 20: 675–686.
Tu S, Bhagat G, Cui G, Takaishi S, Kurt-Jones EA et al. Overexpression of interleukin-1β induces gastric inflammation and cancer mobilizes myeloid-derived suppressor cells in mice. Cancer Cell 2008; 14: 408–419.
Tebbutt NC, Giraud AS, Inglese M, Jenkins B, Waring P, Clay FJ et al. Reciprocal regulation of gastrointestinal homeostasis by SHP2 and STAT-mediated trefoil gene activation in gp130 mutant mice. Nat Med 2002; 8: 1089–1097.
Tye H, Kennedy CL, Najdovska M, McLeod L, McCormack W, Hughes N et al. STAT3-driven upregulation of TLR2 promotes gastric tumorigenesis independent of tumor inflammation. Cancer Cell 2012; 22: 466–478.
Balkwill F . TNF-α in promotion and progression of cancer. Cancer Metastasis Rev 2006; 25: 409–416.
Balkwill F . Tumor necrosis factor and cancer. Nat Rev Cancer 2009; 9: 361–371.
Moore RJ, Owens DM, Stamp G, Arnott C, Burke F, East N et al. Mice deficient in tumor necrosis factor-α are resistant to skin carcinogenesis. Nat Med 1999; 5: 828–831.
Arnott CH, Scott KA, Moore RJ, Robinson SC, Thompson RG, Balkwill FR . Expression of both TNF-α receptor subtypes is essential for optimal skin tumour development. Oncogene 2004; 23: 1902–1910.
Popivanova BK, Kitamura K, Wu Y, Kondo T, Kagaya T, Kanoko S et al. Blocking TNF-α in mice reduces colorectal carcinogenesis associated with chronic colitis. J Clin Invest 2008; 118: 560–570.
Oshima H, Matsunaga A, Fujimura T, Tsukamoto T, Taketo MM, Oshima M . Carcinogenesis in mouse stomach by simultaneous activation of the Wnt signaling and prostaglandin E2 pathway. Gastroenterology 2006; 131: 1086–1095.
Oshima H, Oguma K, Du YC, Oshima M . Prostaglandin E2, Wnt and BMP in gastric tumor mouse models. Cancer Sci 2009; 100: 1779–1785.
Clements WM, Wang J, Sarnaik A, Kim OJ, MacDonald J, Fenoglio-Preiser C et al. β-Catenin mutation is a frequent cause of Wnt pathway activation in gastric cancer. Cancer Res 2002; 62: 3503–3506.
Wang D, DuBois RN . Eicosanoids and cancer. Nat Rev Cancer 2010; 10: 181–193.
Itadani H, Oshima H, Oshima M, Kotani H . Mouse gastric tumor models with prostaglandin E2 pathway activation show similar gene expression profiles to intestinal-type human gastric cancer. BMC Genomics 2009; 10: 615.
Oshima H, Hioki K, Popivanova BK, Oguma K, van Rooijen N, Ishikawa TO et al. Prostaglandin E2 signaling and bacterial infection recruit tumor-promoting macrophages to mouse gastric tumors. Gastroenterology 2011; 140: 596–607.
Itzkovitz S, Lyubimova A, Blat IC, Maynard M, van Es J, Lees J et al. Single-molecule transcript counting of stem-cell markers in the mouse intestine. Nat Cell Biol 2012; 14: 106–114.
Huch M, Dorrell C, Boj SF, van Es JH, Li VS, van de Watering M et al. In vitro expansion of single Lgr5+ liver stem cells induced by Wnt-driven regeneration. Nature 2013; 494: 247–250.
Ishimoto T, Oshima H, Oshima M, Kai K, Torii R, Masuko T et al. CD44+ slow-cycling tumor cell expansion is triggered by cooperative actions of Wnt and prostaglandin E2 in gastric tumorigenesis. Cancer Sci 2010; 101: 673–678.
Ishimoto T, Nagano O, Yae T, Tamada M, Motohara T, Oshima H et al. CD44 variant regulates redox status in cancer cells by stabilizing the xCT subunit of system xc(-) and thereby promotes tumor growth. Cancer Cell 2011; 19: 387–400.
Zöller M . CD44: can a cancer-initiating cell profit from an abundantly expressed molecule? Nat Rev Cancer 2011; 11: 254–267.
Barker N, Huch M, Kujala P, van de Wetering M, Snippert HJ, van Es JH et al. Lgr5+ve stem cells drive self-renewal in the stomach and build long-lived gastric units in vitro. Cell Stem Cell 2011; 6: 25–36.
Kulbe H, Chakravarty P, Leinster DA, Charles KA, Kwong J, Thompson RG et al. A dynamic inflammatory cytokine network in the human ovarian cancer microenvironment. Cancer Res 2012; 71: 66–75.
Seno H, Oshima M, Ishikawa TO, Oshima H, Takaku K, Chiba T et al. Cyclooxygenase 2-and prostaglandin E2 receptor EP2-dependent angiogenesis in ApcΔ716 mouse intestinal polyps. Cancer Res 2002; 62: 506–511.
Castellone MD, Teramoto H, Williams BO, Druey KM, Gutkind JS . Prostaglandin E2 promotes colon cancer cell growth through a Gs-axin-β-catenin signaling axis. Science 2005; 310: 1504–1510.
Oguma K, Oshima H, Aoki M, Uchio R, Naka K, Nakamura S et al. Activated macrophages promote Wnt signalling through tumour necrosis factor-αin gastric tumour cells. EMBO J 2008; 27: 1671–1681.
Bollrath J, Phesse TJ, von Burstin VA, Putoczki T, Bennecke M, Bateman T et al. gp130-mediated Stat3 activation in enterocytes regulates cell survival and cell-cycle progression during colitis-associated tumorigenesis. Cancer Cell 2009; 15: 91–102.
Grivennikov S, Karin E, Terzic J, Mucida D, Yu G-Y, Vallabhapurapu S et al. IL-6 and Stat3 are required for survival of intestinal epithelial cells and development of colitis-associated cancer. Cancer Cell 2009; 15: 103–113.
Acharyya S, Oskarsson T, Vanharanta S, Malladi S, Kim J, Morris PG et al. A CXCL1 paracrine network links cancer chemoresistance and metastasis. Cell 2012; 150: 165–178.
Block D, Gorin Y . Aiding and abetting roles of NOX oxidases in cellular transformation. Nat Rev Cancer 2012; 12: 627–637.
Mitsushita J, Lambeth JD, Kamata T . The superoxide-generating oxidase Nox1 is functionally required for Ras oncogene transformation. Cancer Res 2004; 64: 3580–3585.
Adachi Y, Shibai Y, Mitsushita J, Shang WH, Hirose K, Kamata T . Oncogenic Ras upregulates NADPH oxidase 1 gene expression through MEK-ERK-dependent phosphorylation of GATA-6. Oncogene 2008; 27: 4921–4932.
Juhasz A, Ge Y, Markel S, Chiu A, Matsumoto L, van Balgooy J et al. Expression of NADPH oxidase homologues and accessory genes in human cancer cell lines, tumours and adjacent normal tissues. Free Radic Res 2009; 43: 523–532.
Kostenis E, Waelbroeck M, Milligan G . Techniques: Promiscous Gα proteins in basic research and drug discovery. TrendsPham Sci 2005; 26: 595–602.
Liu AMF, Wong YH . Activation of nuclear factor κB by somatostatin type 2 receptor in pancreatic acinar AR42J cells involves Gα14 and multiple signaling components. J Biol Chem 2005; 280: 34617–34625.
Lee MMK, Wong YH . CCR1-mediated activation of nuclear factor-κB in THP-1 monocytic cells involves pertussis toxin-insensitive Gα14 and Gα16 signaling cascade. J Leukoc Biol 2009; 86: 1319–1329.
Schwitalla S, Fingerle AA, Cammareri P, Nebelsiek T, Göktuna SI, Ziegler PK et al. Intestinal tumorigenesis initiated by dedifferentiation and acquisition of stem-cell-like properties. Cell 2013; 152: 25–38.
Kong D, Piao Y-S, Yamashita S, Oshima H, Oguma K, Fushida S et al. Inflammation-induced repression of tumor suppressor miR-7 in gastric tumor cells. Oncogene 2012; 31: 3949–3960.
Acknowledgements
We thank Manami Watanabe and Ayako Tsuda for their excellent technical assistance. This work was supported by Grants-in-Aid for Scientific Research on Innovative Areas (no. 22114005) from the Ministry of Education, Culture, Sports, Science and Technology of Japan; and CREST, the Japan Science and Technology Agency, Japan.
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Oshima, H., Ishikawa, T., Yoshida, G. et al. TNF-α/TNFR1 signaling promotes gastric tumorigenesis through induction of Noxo1 and Gna14 in tumor cells. Oncogene 33, 3820–3829 (2014). https://doi.org/10.1038/onc.2013.356
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DOI: https://doi.org/10.1038/onc.2013.356
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