This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Ito, K. Articles by Ito, Y. Search for Related Content PubMed PubMed Citation Articles by Ito, K. Articles by Ito, Y.

RUNX3, A Novel Tumor Suppressor, Is Frequently Inactivated in Gastric Cancer by Protein Mislocalization

¹ Institute of Molecular and Cell Biology, Proteos; ² Oncology Research Institute; and Departments of ³ Pathology and ⁴ Medicine, Faculty of Medicine, National University of Singapore, Singapore

Requests for reprints: Yoshiaki Ito, Institute of Molecular and Cell Biology, Proteos, 61 Biopolis Drive, Singapore 138673. Phone: 65-6586-9646; Fax: 65-6779-1117; E-mail: itoy{at}imcb.a-star.edu.sg.

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Loss of RUNX3 expression is suggested to be causally related to gastric cancer as 45% to 60% of gastric cancers do not express RUNX3 mainly due to hypermethylation of the RUNX3 promoter. Here, we examined for other defects in the properties of RUNX3 in gastric cancers that express RUNX3. Ninety-seven gastric cancer tumor specimens and 21 gastric cancer cell lines were examined by immunohistochemistry using novel anti-RUNX3 monoclonal antibodies. In normal gastric mucosa, RUNX3 was expressed most strongly in the nuclei of chief cells as well as in surface epithelial cells. In chief cells, a significant portion of the protein was also found in the cytoplasm. RUNX3 was not detectable in 43 of 97 (44%) cases of gastric cancers tested and a further 38% showed exclusive cytoplasmic localization, whereas only 18% showed nuclear localization. Evidence is presented suggesting that transforming growth factor-ß is an inducer of nuclear translocation of RUNX3, and RUNX3 in the cytoplasm of cancer cells is inactive as a tumor suppressor. RUNX3 was found to be inactive in 82% of gastric cancers through either gene silencing or protein mislocalization to the cytoplasm. In addition to the deregulation of mechanisms controlling gene expression, there would also seem to be at least one other mechanism controlling nuclear translocation of RUNX3 that is impaired frequently in gastric cancer.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Gastric cancer is the second leading cause of cancer death worldwide, with 560,000 new cases and 405,000 deaths each year. The prognosis for stage IV gastric cancer is still poor, with a 5-year survival rate of 10% (1). However, with advances in diagnostic techniques and treatment methods, the outlook for gastric cancer has considerably improved. If it is diagnosed at an early stage, the prognosis is favorable and the disease may even be curable.

Despite its prominence, the molecular mechanisms leading to gastric carcinogenesis are still poorly understood and only a few genes have been clearly implicated. Germ line mutations of E-cadherin were first found in a large family from New Zealand in which diffuse-type gastric cancers developed at an early age (2). Subsequently, the somatic mutations were also observed in sporadic diffuse-type gastric cancers. The oncogenic activation of ß-catenin (17-27% in differentiated type) and K-ras (0-18% in both diffuse and differentiated types) have been found in human gastric cancer. In addition, the c-erbB2 or c-met gene is amplified in 10% of both cancer types. Among tumor suppressor genes, APC mutations are found frequently in gastric adenomas but only rarely in gastric cancers. Similarly, mutation of the p16 gene is infrequent (3). Mutations in p53 have been reported for gastric cancers of the diffuse and intestinal types, but the role of p53, if any, in gastric carcinogenesis remains obscure.

We reported recently that loss of expression of RUNX3 is causally related to the genesis and progression of gastric cancer. About 45% to 60% of surgically resected gastric cancer specimens and cell lines derived from these cancers do not express RUNX3 due to hemizygous deletion of the gene or hypermethylation of its promoter region. Inactivation of RUNX3 appears to occur at an early stage as well as during progression, because silencing of RUNX3 has been observed in 40% of stage I and 90% of stage IV gastric cancers. A mutation found in a gastric cancer patient, RUNX3 (R122C), which causes a single amino acid substitution within the conserved DNA-binding domain, completely abolishes the tumor suppressor activity of RUNX3 in a nude mouse assay. Hyperplasia of the gastric epithelium, as observed in a Runx3–/– experimental mouse system, seems to be caused by decreased sensitivity to transforming growth factor-ß (TGF-ß), which inhibits cell cycle progression and induces apoptosis. Furthermore, experiments with stomach epithelial cell lines isolated from Runx3+/+ and Runx3–/– mice with the p53–/– background revealed that only those lines derived from Runx3–/–p53–/– mice were tumorigenic in nude mice (4). Although these results strongly suggested that RUNX3 is a gastric cancer tumor suppressor and that its loss is involved in roughly half of the cases of gastric cancer, we assumed that it functions normally in the remaining cases. We report in this article that this assumption was likely incorrect.

Hanai et al. (5) have shown that RUNX3 forms complexes with receptor-regulated Smads (R-Smads) that regulate target gene expression; RUNX3 is thus a downstream target of the TGF-ß signaling pathway. This signaling pathway is often called a tumor suppressor pathway, because certain of its components are frequently genetically or epigenetically altered in many types of cancers, especially those of the gastrointestinal tract (6). TGF-ß is a multifunctional growth factor that has profound regulatory effects on many developmental and physiologic processes. In TGF-ß1-null animals, gastric epithelial proliferation is stimulated and epithelial hyperplasia is observed together with dysregulation of differentiation and intestinal metaplasia (7). These phenotypes are also seen in Runx3–/– gastric epithelial cells (8). Thus, TGF-ß signaling may regulate the growth and differentiation of gastric epithelial cells at least partly by mediating molecular interactions between RUNX3 and R-Smads (8, 9). RUNX3 is located in the 1p36 locus, a region that is considered to carry a tumor suppressor gene(s) implicated in various types of cancers, especially those of the gastrointestinal tract. Therefore, at least one of the long sought-after tumor suppressors on 1p36 could be RUNX3, which seems to be an integral component of the TGF-ß tumor suppressor pathway (10).

In this study, monoclonal antibodies were generated for the immunohistochemical analysis of RUNX3 in human gastric tissue sections. Surprisingly, in 67% of 55 human gastric cancer specimens and in all 5 gastric cancer cell lines expressing RUNX3 thus far tested, RUNX3 was found in the cytoplasm. Because RUNX3 is a transcription factor, these results suggest that it is mislocalized and thus nonfunctional in a large fraction of gastric cancer cases. Therefore, RUNX3 seems to play a more prominent role in gastric carcinogenesis than previously estimated.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Generation of anti-RUNX3 monoclonal antibodies. Polypeptide antigens were expressed in an Escherichia coli system and purified with the QIAexpressionist protein purification kit (Qiagen, Germany). Purified antigens were suspended as 25 µg polypeptide in 0.1 mL PBS, which was emulsified with 0.1 mL Freund's complete adjuvant and injected s.c. into 7-week-old female BALB/c mice. Booster injections of 25 and 12 µg polypeptide in 0.1 mL PBS with 0.1 mL incomplete adjuvant were given i.p. or s.c. at days 14 and 60, respectively. On day 69, animals were bled and the presence of antibodies against RUNX3 was determined by Western blot analysis (see below). On day 70, mice were boosted again with an i.v. injection of 12 µg polypeptide in 0.2 mL PBS. On day 74, spleens were removed from immunized mice and the splenocytes (lymphocytes) were fused with the SP2-K13 murine myeloma cell line, a subclonal line derived from SP2/0-Ag14 myeloma cells, as described (11), using 50% polyethylene glycol (4000).

Individual hybridomas were cloned by the limiting dilution technique with thymocyte feeder cells from BALB/c mice. Hybridoma culture fluids were screened for secreted antibodies against RUNX3 by Western blot analysis using extracts from COS7 cells exogenously expressing human full-length RUNX3. Three cycles of cloning and recloning to screen hybridoma cells were done to obtain cells that secrete anti-RUNX3 antibodies and that show no reactivities to human RUNX1 and RUNX2. Subsequently, cells producing specific antibodies were adapted to serum-free culture and IgG was purified by protein G-Sepharose.

Characterization of anti-RUNX3 monoclonal antibodies. Extracts of COS7 cells harboring derivatives of the expression vector pEF-Bos that express human full-length RUNX1, RUNX2, or RUNX3 or murine full-length Runx1, Runx2, or Runx3 (refs. 12–16; the murine Runx3 cDNA, accession no. AF155880, was inserted into the EcoRI sites of pEF-Bos) were used as test antigens for examining antibody specificities. The extracts were separated by 10% SDS-PAGE and subjected to Western blot analysis.

Extracts of COS7 cells harboring derivatives of the expression vector pcDNA3 that express Flag-tagged full-length RUNX3 or Flag-tagged truncated forms of RUNX3 (1-187, 1-234, 1-283, 1-325, and 1-373 amino acids; refs. 5, 17) were used as antigens for epitope mapping. The extracts were separated by 10% SDS-PAGE and subjected to Western blot analysis. Flag-tagged full-length RUNX3 or Flag-tagged truncated forms of RUNX3 were visualized with an anti-Flag monoclonal antibody (M2; Sigma, St. Louis, MO).

Cell culture and stable transfection of SNU16 cells. The gastric cancer cell lines MKN1, MKN7, MKN28, MKN45, MKN74, AGS, NUGC3, SCH, KATOIII, Ist1, SNU1, SNU5, SNU16, GMK, TMK1, AZ521, NCI-N87, and Takigawa and a cell line derived from a B-cell lymphoma, RF48, were maintained in RPMI 1640 supplemented with 10% fetal bovine serum (some lots of FCS contain TGF-ß, which affects subcellular localization of RUNX3 in SNU16 cells). The gastric cancer cell lines IM95 and Hs746T were maintained in DMEM supplemented with 10% fetal bovine serum.

SNU16 cells were transfected with pcDNA3.1/HisC, pcDNA-Flag-RUNX3 (1-187 amino acids; ref. 17), and pEF-Bos-neo-RUNX3-AS using Lipofectamine 2000 and Lipofectamine Plus reagents (Invitrogen, Carlsbad, CA) to generate stable transfectants, control SNU16 cells, SNU16 cells expressing RUNX3 (1-187 amino acids), and SNU16 cells expressing antisense RUNX3 DNA, respectively. pEF-Bos-neo-RUNX3-AS was constructed by subcloning a RUNX3 cDNA fragment (accession no. Z35278; ref. 14) into the XbaI site of pEF-Bos-neo (18) in reverse orientation by blunt end ligation. Stable transfectants were selected on 0.5 mg/mL G418 (Invitrogen). Independent clones that stably expressed Flag-RUNX3 (1-187 amino acids) and reduced levels of RUNX3 mRNA were identified by Western blot analysis using an anti-Flag monoclonal antibody (M2) and by reverse transcription-PCR (RT-PCR) using the primers 5'-CTACGGGACATCCTCTGGCTCC-3' (1,008-1,029) and 5'-CATCTCTGCCAGCAGCGTGCTG-3' (1,825-1,846) to amplify 839 bp of RUNX3 cDNA, which is not included in pEF-Bos-neo-RUNX3-AS, respectively.

Immunohistochemistry, immunocytochemistry, immunoblotting, and in situ hybridization. Ten percent formalin-fixed human gastric tissues or 4% paraformaldehyde-fixed tumors formed by 1 x 10⁷ SNU16 or MKN74 cells in nude mice 60 days after inoculation were embedded in paraffin and cut into 5 µm sections. Alternatively, 5 µm sections of tissue microarrays from gastric cancer and normal counterparts, constructed as described elsewhere (19), were prepared. The rehydrated sections were warmed in a target retrieval solution (DAKO, Denmark) at 96°C for 40 minutes. Rehydrated tissue sections or 4% paraformaldehyde-fixed cells on the slides were treated with a serum-free blocking solution (DAKO) and incubated at 4°C overnight with 1 µg/mL R3-6E9 in the absence or presence of 0.5 µg/mL purified antigens (amino acids 8-72 or 191-300) in a diluent solution (DAKO). A peroxidase-3,3'-diaminobenzidine–based detection system (EnVision+ kit, DAKO) was used to detect the immunoreactivity of R3-6E9 on the sections. Biotinylated anti-mouse IgG (Vector, Burlingame, CA) and fluorescein-avidin D (Vector) were used for immunofluorescence imaging. Cases with the majority of the cells (>80%) showing RUNX3 expression (nuclear or cytoplasmic) were counted positive. Cases with no expression or only with minimal and equivocal expression in a minority of cells (<10%) were counted negative.

Whole cell extract was prepared by sonicating cells in the presence of 9 mol/L urea and 2% Triton X-100. Nuclear and cytoplasmic extracts were prepared using NE-PER Nuclear and Cytoplasmic Extraction reagents (Pierce, Rockford, IL) and a 27-gauge needle. Twenty micrograms each of whole cell extracts or nuclear and cytoplasmic extracts from 5 x 10⁴ of SNU5 and RF48 cells were separated by 10% SDS-PAGE and subjected to Western blot analysis with 0.05 µg/mL R3-5G4.

RUNX3 mRNA in paraffin sections of human gastric tissues was detected by in situ hybridization as described previously (4).

Luciferase assay. SNU16 cells were transfected with (TßRE-WT)₃, (TßRE-mP)₃, and (TßRE-mS)₃ luciferase reporter constructs, which contain three copies each of the wild-type TGF-ß response element in the Ig C promoter or of derivatives with mutations affecting the RUNX or Smad binding sites, respectively (5). Human TGF-ß1 (2 µg/mL; R&D Systems, Minneapolis, MN) was added to the culture medium 48 hours after the transfection. Luciferase activity was measured using the Dual-Luciferase Reporter Assay System (Promega, Madison, WI) and normalized to the luciferase activity expressed by the pRL-TK vector.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Isolation of monoclonal antibodies against RUNX3. To generate anti-RUNX3 mouse monoclonal antibodies, 6x His-tagged purified polypeptides consisting of 65 and 110 amino acids from the human RUNX3 protein (amino acids 8-72 and 191-300, respectively) were used as antigens to immunize mice (see Materials and Methods). Of >200 hybridoma clones producing specific antibodies against RUNX3 as detected by Western analysis, antibodies from two clones, R3-2A4 (raised against the amino acids 8-72 antigen) and R3-6E9 (raised against the amino acids 191-300 antigen), were found useful for immunohistochemical analysis. The R3-5G4 clone, which reacts with the amino acids 191 to 300 antigen, was suitable for Western blot analysis. A previously isolated clone raised against the conserved Runt domain of RUNX1, Rp-3D9, recognizes the Runt domain of all three RUNX proteins equally well.⁵

The specificity of the R3-6E9 antibody against RUNX3 proteins is shown in Fig. 1A. R3-6E9 reacted only with human RUNX3 and mouse Runx3 but recognized the human protein more efficiently than the mouse protein (Fig. 1A). R3-6E9 reacted with all COOH-terminally truncated forms of RUNX3, except for RUNX3 (1-187 amino acids), indicating that the epitope recognized by R3-6E9 lies within the 188– to 234–amino acid region (Fig. 1A). Because the antigen used to immunize mice was RUNX3 (191-300 amino acids), this epitope likely resides between amino acids 191 and 234. The specificity of R3-6E9 for RUNX3 was rigorously examined by several assays (data not shown).

View larger version (71K): [in this window] [in a new window]   Figure 1. Immunodetection of RUNX3 in normal human gastric epithelial cells with the specific monoclonal antibody R3-6E9. A,left,top, Western blot analysis with Rp-3D9 of human RUNX1 (lane 1), human RUNX2 (lane 2), human RUNX3 (lane 3), murine Runx1 (lane 4), murine Runx2 (lane 5), and murine Runx3 (lane 6) expressed in COS7 cells; left, bottom, Western blot analysis with R3-6E9; right,top, mapping the epitope recognized by R3-6E9 on RUNX3. Immunodetection of Flag-tagged full-length (lane 1) and truncated forms of RUNX3 (lane 2, 1-373 amino acids; lane 3, 1-325 amino acids; lane 4, 1-283 amino acids; lane 5, 1-234 amino acids; lane 6, 1-187 amino acids) by Western blot analysis with an anti-Flag monoclonal antibody; right,bottom, immunodetection of Flag-tagged full-length and truncated forms of RUNX3 by Western blot analysis with R3-6E9. B, immunodetection of RUNX3 in normal human gastric epithelial cells in corpus and pyloric antra with R3-6E9. Top and bottom boxed regions are enlarged on the right. Immunostaining with R3-6E9 without counterstaining in a section similar to the lower enlarged region is shown (without hematoxylin). Arrows, parietal cells with weaker immunoreactivity than adjacent chief cells. C,left, immunodetection of RUNX3 in normal human gastric epithelial cells in corpus and pyloric antra with R3-2A4 or normal mouse IgG. Counterstaining was done with hematoxylin; right, detection of RUNX3 mRNA by in situ hybridization with a RUNX3 antisense or sense probe. D, immunostaining of normal gastric mucosa with R3-6E9 preincubated with purified polypeptides, amino acids 8 to 72 or 191 to 300 of RUNX3. Bars, 200 µm.

Interestingly, R3-6E9 detected a significant amount of RUNX3 protein in the cytoplasm as well as in the nuclei of chief cells (pyloric gland cells in the pyloric antrum; Fig. 1B). RUNX3 was localized primarily in the nuclei of surface epithelial cells (Fig. 1B). The presence of a substantial amount of RUNX3 in the cytoplasm suggests at least two possibilities: RUNX3 has an as yet unknown function in the cytoplasm and/or it is retained in the cytoplasm in an inert form until it is mobilized to the nucleus under appropriate conditions.

Cytoplasmic retention of RUNX3 in gastric cancer cells. Paraffin sections of 97 clinical samples from gastric cancer patients were subjected to immunohistochemistry with R3-6E9. We found three types of staining pattern for RUNX3: (a) negative in the both nucleus and cytoplasm (negative), (b) positive in the nucleus and positive or negative in the cytoplasm (positive in nucleus), and (c) positive in the cytoplasm and negative in the nucleus (positive in cytoplasm). These three patterns were observed in both differentiated type (intestinal type; Fig. 2A and C) and diffuse type (Fig. 2B) of gastric cancer, and their frequencies are summarized in Table 1. The fraction of gastric cancer cases in which RUNX3 was not expressed was 44% (43 of 97 cases tested); this frequency is consistent with our previous results obtained by in situ hybridization (4). Surprisingly, 69% of RUNX3-positive gastric cancers (38% of total cases) fell into the third class, as shown in Fig. 2 A (iii), B (iii), and C, and only 18% fell into the second class.

View larger version (83K): [in this window] [in a new window]   Figure 2. Immunodetection of RUNX3 in gastric cancer cells with R3-6E9. A and C, sections prepared from differentiated (intestinal) gastric cancers. B, sections prepared from diffuse gastric cancers. Three types of staining patterns for RUNX3 were observed: (i) negative [A (i) and B (i)], (ii) positive in nucleus [A (ii) and B (ii)], and (iii) positive in cytoplasm [A (iii), B (iii), and C]. The boxed regions on top are enlarged on the bottom (A and B). The boxed region is enlarged on the right (C). Counterstaining was done with hematoxylin. Immunostaining without hematoxylin was done on a serial section (C). Bars, 200 µm.

View larger version (46K): [in this window] [in a new window]   Figure 3. Immunodetection of endogenous RUNX3 in gastric cancer cell lines. A and B, Western blot analysis with the R3-5G4 antibody on whole cell extract of indicated cell lines (A); cytoplasmic (c) and nuclear (n) extracts of SNU5 and RF48 cells (B). C, immunofluorescence analysis with the R3-6E9 antibody of the MKN1, MKN45, SNU5, SNU16, NCI-N87, RF48, MKN28, and SNU1 cells. Nuclei were visualized by staining with 4',6-diamidino-2-phenylindole (DAPI).

View larger version (33K): [in this window] [in a new window]   Figure 4. Nuclear translocation of RUNX3 in SNU16 cells induced by TGF-ß. A, distribution of endogenous RUNX3 in control SNU16 cells, SNU16 cells expressing RUNX3 (1-187 amino acids), and SNU5 cells as revealed by immunofluorescence using R3-6E9 and the distribution of exogenous RUNX3 (1-187 amino acids) in SNU16 cells expressing RUNX3 (1-187 amino acids) as revealed by immunofluorescence using an anti-Flag antibody over a period of 24 hours after treatment with TGF-ß (2 ng/mL). B,left, immunodetection of exogenous RUNX3 (1-187 amino acids) by Western blot analysis with the anti-Flag antibody; right, endogenous RUNX3 expression is reduced in SNU16 cells expressing antisense RUNX3 DNA as detected by RT-PCR. C, sensitivity of control SNU16 cells, SNU16 cells expressing RUNX3 (1-187 amino acids), SNU16 cells expressing antisense DNA of RUNX3, and SNU5 cells to TGF-ß. The growth of each cell type in the presence (solid columns) of TGF-ß (2 ng/mL) for 48 hours is normalized to growth in its absence (open columns). D, luciferase activities of (TßRE-WT)3 (WT), (TßRE-mP)3 (mR), and (TßRE-mS)3 (mS) reporter constructs (see Materials and Methods) in control SNU16 cells (open columns) and SNU16 cells expressing RUNX3 (1-187 amino acids; solid columns) over a period of 24 hours after treatment with TGF-ß (2 ng/mL). All luciferase activities were normalized to the activity of luciferase expressed from the vector pRL-TK as an internal transfection control.

Ig C

Ig C

Unexpectedly, transfection of Flag-tagged RUNX3 (1-187) into SNU16 cells inhibited the TGF-ß-activated nuclear translocation of endogenous RUNX3 (Fig. 4A). The R3-6E9 antibody detected only endogenous full-length RUNX3 but not transfected RUNX3 (1-187), which lacks the epitope recognized by R3-6E9 (Fig. 1A). Surprisingly, Flag-tagged RUNX3 (1-187 amino acids) also was not translocated into the nucleus (Fig. 4A; see Discussion for possible explanation).

Cytoplasmic retention of RUNX3 increases the tumorigenicity of SNU16 cells. We examined the effect of the RUNX3 (1-187)–mediated cytoplasmic retention of endogenous RUNX3 on the tumorigenicity of SNU16 cells by using xenografts in nude mice. As shown in Fig. 5A and B, SNU16 cells stably expressing RUNX3 (1-187) formed significantly larger tumors than those formed by control SNU16 cells (P < 0.05). Control SNU16 cells formed small-sized diffuse tumors, in which the accumulation of endogenous RUNX3 in the nucleus was observed by immunodetection with R3-6E9 antibody (Fig. 5C). In contrast, endogenous RUNX3 was detected mainly in the cytoplasm of larger tumors formed by SNU16 cells expressing RUNX3 (1-187; Fig. 5C). Moreover, some nuclei in the tumors formed by control SNU16 cells showed apoptosis as revealed by the TUNEL method (data not shown). Endogenous RUNX3 was very weakly detectable in tumors formed by MKN74 cells (Fig. 5C) and NUGC3 (data not shown). Because both of these cell lines express Smad2, Smad3, Smad4 and the TGF-ß type II receptor (data not shown), their tumorigenicity is consistent with the lack of RUNX3 expression.

View larger version (58K): [in this window] [in a new window]   Figure 5. The increase of tumorigenicity of SNU16 cells promoted by the cytoplasmic retention of RUNX3. A, tumors formed by control SNU16 cells (white arrowheads) and SNU16 cells stably expressing RUNX3 (1-187 amino acids; black arrowheads) in nude mice. B, sizes of tumors formed by control SNU16 cells and SNU16 cells stably expressing RUNX3 (1-187 amino acids) in nude mice. Columns, mean of seven determinations; bars, SD. C, detection of endogenous RUNX3 in tumors formed by control SNU16 cells, SNU16 cells expressing exogenous RUNX3 (1-187 amino acids), and MKN74 cells in nude mice by immunofluorescence with R3-6E9. Nuclei were visualized by staining with DAPI.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
We showed the expression patterns of RUNX3 protein in human gastric epithelial cells and cancer cells by immunohistochemistry with newly isolated monoclonal antibodies. Consistent with our previous report of Runx3 RNA expression in the adult mouse stomach (4), the RUNX3 protein is expressed most strongly in chief cells and surface epithelial cells and to a lesser degree in parietal cells in the normal human adult gastric mucosa. In this study, however, we observed a novel cytoplasmic localization of a substantial fraction of RUNX3 in chief cells. In line with our previous report, RUNX3 was not detected in 44% of the 97 gastric cancer cases tested. Surprisingly however, we could only detect nuclear localization of RUNX3 in 18% of the remaining cases. In the other 38%, it was detected primarily, if not exclusively, in the cytoplasm as an apparently nonfunctional form.

In many signaling pathways, signal transducers are transcription factors that are restricted by the nuclear envelope from gaining access to target genes. Therefore, the nuclear import of transcription factors is an essential element of many of these pathways.Transcription factors localized in the cytoplasm are thought to be in a basal, inactive state. For transcription factors, such as signal tranducers and activators of transcription (STAT) and Smads, which require receptor-mediated phosphorylation for conversion to the active state, the cytoplasm constitutes a reservoir for the storage of unstimulated forms (25).

The observation that a substantial fraction of RUNX3 resides in the cytoplasm of chief cells suggests that these proteins are in a basal state. TGF-ß was identified as an agent that stimulates the nuclear translocation of RUNX3. The cytoplasmic retention of RUNX3 observed in many cases of gastric cancer may be due to one or more missing components in a signaling pathway required for RUNX3 nuclear localization or by the presence of factors that impede the function of these components. In the gastric cancer–derived cell lines MKN1, MKN45, SNU5, and NCI-N87, RUNX3 is expressed but localized to the cytoplasm, presumably as a nonfunctional transcription factor. In these cells, it is known that the components of the TGF-ß signaling cascade are often altered. Reduced expression of TGF-ß type I/II receptors in MKN1 and Smad4 in MKN45 and NCI-N87 cells and mutation of the TGF-ß type II receptor in SNU5 cells have been described (22, 26).⁷ RUNX3 was imported into the nucleus of SNU16 cells only several hours after stimulation with TGF-ß, suggesting that TGF-ß effect may be indirect and that there might be more proximal signals that stimulate RUNX3 for nuclear translocation. Nevertheless, it is remarkable that many of the components of the TGF-ß signaling cascade are frequently impaired in gastric cancer cells, which prompts the conclusion that this cascade is primarily involved in regulating the nuclear translocation of RUNX3. It is important to determine why it takes longer for RUNX3 to be translocated into the nucleus of SNU16 cells after TGF-ß stimulation. Because SNU16 is a gastric cancer–derived cell line, there may be a mild defect in this signaling cascade.

Because the TGF-ß–induced signal could be transmitted to targets in SNU16 cells, we examined the significance of the cytoplasmic retention of RUNX3 by comparing SNU16 cells stably expressing RUNX3 (1-187) with parental cells in a nude mouse assay and found that cells expressing RUNX3 (1-187) induced larger tumors than did control cells. We confirmed that RUNX3 was primarily in the cytoplasm of cells from RUNX3 (1-187)–induced tumors, whereas a substantial fraction of RUNX3 was in the nucleus of cells from control tumors. These results are consistent with the notion that RUNX3 does not elicit tumor suppressive activity when it is restricted to the cytoplasm, suggesting that the cytoplasmic retention of RUNX3 that we observed in a large fraction of gastric cancer cases is a novel mechanism for inactivating RUNX3 function.

How is RUNX3 held in the cytoplasm? Recently, accelerated osteogenesis has been observed in STAT1-null mice. It was found that, in its latent form, osteogenic Runx2 is bound to STAT1, which retains Runx2 in the cytoplasm. In the absence of STAT1, Runx2 is translocated into the nucleus, where it stimulates osteogenesis (27). These results clearly show that the cytoplasmic retention of Runx2 by STAT1 attenuates Runx2 function. A further involvement of STAT signaling in gastric carcinogenesis has also been described in a recent study using gp130 mutant mice (28). It is attractive to speculate that one of the STAT proteins interacts with RUNX3 and modulates its function in gastric epithelial cells.

How does exogenous RUNX3 (1-187) inhibit the nuclear translocation of endogenous RUNX3 in SNU16 cells? We presume that the agent that retains RUNX3 in the cytoplasm interacts with the NH₂-terminal 187–amino acid region of the protein. One possibility is that RUNX3 must be modified, for example, by phosphorylation, within the missing COOH-terminal region to allow its translocation into the nucleus. It is also worth noting that RUNX3 interacts with R-Smads via its COOH-terminal region (5), suggesting that COOH-terminally truncated RUNX3 is retained in the cytoplasm because it can no longer interact with Smads. Transcriptionally active members of the RUNX family of proteins are heterodimers composed of and ß subunits. The ß subunit, PEBP2ß/CBFß, protects the RUNX proteins from proteolysis (23, 29). Furthermore, COOH-terminally truncated RUNX proteins have a higher affinity for PEBP2ß/CBFß than for full-length RUNX proteins (23). Therefore, the sequestration of PEBP2ß/CBFß by an excess of exogenous RUNX3 (1-187) may inhibit the nuclear translocation of endogenous RUNX3. Further studies are required to clarify the exact mechanism.

The cytoplasmic retention of RUNX3 is a useful "molecular marker" to detect inactivity of RUNX3 as a tumor suppressor and impairment of the TGF-ß signaling pathway. Therefore, the monoclonal antibodies R3-6E9 and R3-2A4 are powerful tools for the characterization of gastric cancer cells. We are currently studying whether these antibodies can be used to detect early stages of gastric cancer and precancerous states in gastric epithelium.

Recently, the possible involvement of RUNX3 in other types of cancer as well as in gastric cancer has been reported. These include lung (30–32), breast (32), pancreas (33), liver (32, 34), bile duct (33), colon (35, 36), gallbladder (37), prostate (38), larynx (32), esophageal (39), and gastric (40, 41) cancers and testicular yolk sac tumors in infants (42). These studies focused on the lack of RUNX3 expression caused by hypermethylation of the RUNX3 promoter region. In the light of the results presented here, it would be interesting to study the subcellular localization of RUNX3 in these cancers using R3-6E9 and R3-2A4 antibodies. This might reveal that RUNX3 is much more widely inactivated in cancer than previously thought, which would pose further questions, and perhaps shed light on the true role of RUNX3 in cancerogenesis.

	Acknowledgments

 
Grant support: Agency for Science, Technology and Research, Singapore and Human Frontier Science Program RGP0375/2001-M202. Q. Liu, M. Salto-Tellez, and K.G. Yeoh received funding support from SCS Grants GN-15 & MN-05, awarded by the Singapore Cancer Syndicate, Agency for Science, Technology and Research, Singapore.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

We thank Dr. Y. Groner for the kind gift of murine Runx3 cDNA, and E. Tai, P.Y. Chong, B.H. Neo, and Y.K. Loh for technical assistance.

	Footnotes

 
¹ K. Ito, unpublished data.

⁶ T. Yano et al., submitted for publication.

⁷ H. Ida, unpublished data.

Received 3/ 2/05. Revised 5/25/05. Accepted 6/16/05.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Yagi Y, Seshimo A, Kameoka S. Prognostic factors in stage IV gastric cancer: univariate and multivariate analyses. Gastric Cancer 2000;3:71–80.[CrossRef][Medline]
2. Guilford P, Hopkins J, Harraway J, et al. E-cadherin germline mutations in familial gastric cancer. Nature 1998;392:402–5.[CrossRef][Medline]
3. Ushijima T, Sasako M. Focus on gastric cancer. Cancer Cell 2004;5:121–5.[CrossRef][Medline]
4. Li QL, Ito K, Sakakura C, et al. Causal relationship between the loss of RUNX3 expression and gastric cancer. Cell 2002;109:113–24.[CrossRef][Medline]
5. Hanai JI, Chen LF, Kanno T, et al. Interaction and functional cooperation of PEBP2/CBF with Smads. Synergistic induction of the immunoglobulin germline C promoter. J Biol Chem 1999;274:31577–82.[Abstract/Free Full Text]
6. Derynck R, Akhurst RJ, Balmain A. TGF-ß signaling in tumor suppression and cancer progression. Nat Genet 2001;29:117–29.[CrossRef][Medline]
7. Crawford SE, Stellmach V, Murphy-Ullrich JE, et al. Thrombospondin-1 is a major activator of TGFß1 in vivo. Cell 1998;93:1159–70.[CrossRef][Medline]
8. Fukamachi H, Ito K, Ito Y. Runx3–/– gastric epithelial cells differentiate into intestinal type cells. Biochem Biophys Res Commun 2004;321:58–64.[CrossRef][Medline]
9. Fukamachi H, Ito K. Growth regulation of gastric epithelial cells by Runx3. Oncogene 2004;23:4330–5.[CrossRef][Medline]
10. Ito Y, Miyazono K. RUNX transcription factors as key targets of TGF-ß superfamily signaling. Curr Opin Genet Dev 2003;13:43–7.[CrossRef][Medline]
11. Galfre G, Howe SC, Milstein C, Butcher GW, Howard JC. Antibodies to major histocompatibility antigens produced by hybrid cell lines. Nature 1997;266:550–2.
12. Zhang YW, Bae SC, Huang G, et al. A novel transcript encoding an N-terminally truncated AML1/PEBP2B protein interferes with transactivation and blocks granulocytic differentiation of 32Dcl3 myeloid cells. Mol Cell Biol 1997;17:4133–45.[Abstract]
13. Zhang YW, Yasui N, Ito K, et al. A RUNX2/PEBP2A/CBFA1 mutation displaying impaired transactivation and Smad interaction in cleidocranial dysplasia. Proc Natl Acad Sci U S A 2000;97:10549–54.[Abstract/Free Full Text]
14. Bae SC, Takahashi E, Zhang YW, et al. Cloning, mapping and expression of PEBP2C, a third gene encoding the mammalian Runt domain. Gene 1995;159:245–8.[CrossRef][Medline]
15. Bae SC, Ogawa E, Maruyama M, et al. PEBP2B/mouse AML1 consists of multiple isoforms that possess differential transactivation potentials. Mol Cell Biol 1994;14:3242–52.[Abstract/Free Full Text]
16. Ogawa E, Maruyama M, Kagoshima H, et al. PEBP2/PEA2 represents a family of transcription factors homologous to the products of the Drosophila runt gene and the human AML1 gene. Proc Natl Acad Sci U S A 1993;90:6859–63.[Abstract/Free Full Text]
17. Guo W, Weng L, Ito K, et al. Inhibition of growth of mouse gastric cancer cells by Runx3, a novel tumor suppressor. Oncogene 2002;21:8351–5.[CrossRef][Medline]
18. Mizushima S, Nagata S. pEF-BOS, a powerful mammalian expression vector. Nucleic Acids Res 1990;18:5322.[Free Full Text]
19. Salto-Tellez M, Lee SC, Chiu LL, Lee CK, Yong MC, Koay ESC. Microsatellite instability in colorectal cancer—considerations for molecular diagnosis and high-throughput screening of archival tissues. Clin Chem 2004;50:1082–6.[Free Full Text]
20. Ji J, Chen X, Leung SY, et al. Comprehensive analysis of the gene expression profiles in human gastric cancer cell lines. Oncogene 2002;21:6549–56.[CrossRef][Medline]
21. Lu J, Maruyama M, Satake M, et al. Subcellular localization of the and ß subunits of the acute myeloid leukemia-linked transcription factor PEBP2/CBF. Mol Cell Biol 1995;15:1651–61.[Abstract]
22. Han SU, Kim HT, Seong DH, et al. Loss of the Smad3 expression increases susceptibility to tumorigenicity in human gastric cancer. Oncogene 2004;23:1333–41.[CrossRef][Medline]
23. Ito Y. Molecular basis of tissue-specific gene expression mediated by the Runt domain transcription factor PEBP2/CBF. Genes Cells 1999;4:685–96.[Abstract]
24. Chi XZ, Yang JO, Lee KY, et al. RUNX3 suppresses gastric epithelial cell growth by inducing p21^WAP1/Cip1 expression in cooperation with TGF-ß–activated SMAD. Mol Cell Biol. In press 2005.
25. Xu L, Massagué J. Nucleocytoplasmic shuttling of signal transducers. Nat Rev Mol Cell Biol 2004;5:209–19.[CrossRef][Medline]
26. Yokozaki H. Molecular characteristics of eight gastric cancer cell lines established in Japan. Pathol Int 2000;50:767–77.[CrossRef][Medline]
27. Kim S, Koga T, Isobe M, et al. Stat1 functions as a cytoplasmic attenuator of Runx2 in the transcriptional program of osteoblast differentiation. Genes Dev 2003;17:1979–91.[Abstract/Free Full Text]
28. Tebbutt NC, Giraud AS, Inglese M, et al. Reciprocal regulation of gastrointestinal homeostasis by SHP2 and STAT-mediated trefoil gene activation in gp130 mutant mice. Nat Med 2002;8:1089–97.[CrossRef][Medline]
29. Huang G, Shigesada K, Ito K, Wee HJ, Yokomizo T, Ito Y. Dimerization with PEBP2ß protects RUNX1/AML1 from ubiqutin-proteasome-mediated degradation. EMBO J 2001;20:723–33.[CrossRef][Medline]
30. Yanagawa N, Tamura G, Oizumi H, Takahashi N, Motoyama T. Promoter hypermethylation of tumor suppressor and tumor-related genes in non-small cell lung cancers. Cancer Sci 2003;94:589–92.[Medline]
31. Li QL, Kim HR, Kim WJ, et al. Transcriptional silencing of RUNX3 gene by CpG hypermethylation is associated with lung cancer. Biochem Biophys Res Commun 2004;314:223–8.[CrossRef][Medline]
32. Kim TY, Lee HJ, Hwang KS, et al. Methylation of RUNX3 in various types of human cancers and premalignant stages of gastric carcinoma. Lab Invest 2004;84:479–84.[CrossRef][Medline]
33. Wada M, Yazumi S, Takaishi S, et al. Frequent loss of RUNX3 gene expression in human bile duct and pancreatic cancer cell lines. Oncogene 2004;23:2401–7.[CrossRef][Medline]
34. Xiao WH, Liu WW. Hemizygous deletion and hypermethylation of RUNX3 gene in hepatocellular carcinoma. World J Gastroenterol 2004;10:376–80.[Medline]
35. Ku JL, Kang SB, Shin YK, et al. Promoter hypermethylation downregulates RUNX3 gene expression in colorectal cancer cell lines. Oncogene 2004;23:6736–42.[CrossRef][Medline]
36. Goel A, Arnold CN, Tassone P, et al. Epigenetic inactivation of RUNX3 in microsatellite unstable sporadic colon cancers. Int J Cancer 2004;112:754–9.[CrossRef][Medline]
37. Takahashi T, Shivapurkar N, Riquelme E, et al. Aberrant promoter hypermethylation of multiple genes in gallbladder carcinoma and chronic cholecystitis. Clin Cancer Res 2004;10:6126–33.[Abstract/Free Full Text]
38. Kang GH, Lee S, Lee HJ, Hwang KS. Aberrant CpG island hypermethylation of multiple genes in prostate cancer and prostatic intraepithelial neoplasia. J Pathol 2004;202:233–40.[CrossRef][Medline]
39. Torquati A, O'Rear L, Longobardi L, Spagnoli A, Richards WO, Daniel Beauchamp R. RUNX3 inhibits cell proliferation and induces apoptosis by reinstating transforming growth factor ß responsiveness in esophageal adenocarcinoma cells. Surgery 2004;136:310–6.[CrossRef][Medline]
40. Waki T, Tamura G, Sato M, Terashima M, Nishizuka S, Motoyama T. Promoter methylation status of DAP-kinase and RUNX3 genes in neoplastic and non-neoplastic gastric epithelia. Cancer Sci 2003;94:360–4.[Medline]
41. Oshimo Y, Oue N, Mitani Y, et al. Frequent loss of RUNX3 expression by promoter hypermethylation in gastric carcinoma. Pathobiology 2004;71:137–43.[CrossRef][Medline]
42. Kato N, Tamura G, Fukase M, Shibuya H, Motoyama T. Hypermethylation of the RUNX3 gene promoter in testicular yolk sac tumor of infants. Am J Pathol 2003;163:387–91.[Abstract/Free Full Text]

This article has been cited by other articles:

				S. Fujii, K. Ito, Y. Ito, and A. Ochiai Enhancer of Zeste Homologue 2 (EZH2) Down-regulates RUNX3 by Increasing Histone H3 Methylation J. Biol. Chem., June 20, 2008; 283(25): 17324 - 17332. [Abstract] [Full Text] [PDF]

				Z. Peng, D. Wei, L. Wang, H. Tang, J. Zhang, X. Le, Z. Jia, Q. Li, and K. Xie RUNX3 Inhibits the Expression of Vascular Endothelial Growth Factor and Reduces the Angiogenesis, Growth, and Metastasis of Human Gastric Cancer. Clin. Cancer Res., November 1, 2006; 12(21): 6386 - 6394. [Abstract] [Full Text] [PDF]

				Q. C. Lau, E. Raja, M. Salto-Tellez, Q. Liu, K. Ito, M. Inoue, T. C. Putti, M. Loh, T. K. Ko, C. Huang, et al. RUNX3 Is Frequently Inactivated by Dual Mechanisms of Protein Mislocalization and Promoter Hypermethylation in Breast Cancer. Cancer Res., July 1, 2006; 66(13): 6512 - 6520. [Abstract] [Full Text] [PDF]

				T. Yano, K. Ito, H. Fukamachi, X.-Z. Chi, H.-J. Wee, K.-i. Inoue, H. Ida, P. Bouillet, A. Strasser, S.-C. Bae, et al. The RUNX3 Tumor Suppressor Upregulates Bim in Gastric Epithelial Cells Undergoing Transforming Growth Factor {beta}-Induced Apoptosis Mol. Cell. Biol., June 15, 2006; 26(12): 4474 - 4488. [Abstract] [Full Text] [PDF]

				Cytoplasmic Retention of RUNX3 Cancer Res., March 15, 2006; 66(6): 3345 - 3345. [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Ito, K. Articles by Ito, Y. Search for Related Content PubMed PubMed Citation Articles by Ito, K. Articles by Ito, Y.