BMB Reports 2018; 51(5): 255-260
Inhibition of Wntless/GPR177 suppresses gastric tumorigenesis
Jaesung Seo1,#, Hyun Jung Kee2,#, Hye Ji Choi1,2, Jae Eun Lee2, Soo-Yeon Park1, Seung-Hyun Lee1, Mi-Hyeon Jeong1, Garam Guk1, SooYeon Lee1, Kyung-Chul Choi3, Yoon Young Choi2, Hyunki Kim4, Sung Hoon Noh2, Ho-Geun Yoon1,*, and Jae-Ho Cheong1,2,*
1Department of Biochemistry and Molecular Biology, Brain Korea 21 PLUS Project for Medical Sciences, Yonsei University College of Medicine, Seoul 03722, Korea, 2Department of Surgery, Yonsei University College of Medicine, Seoul 03722, Korea, 3Department of Biomedical Sciences, University of Ulsan College of Medicine, Seoul 05505, Korea, 4Department of Pathology, Yonsei University College of Medicine, Seoul 03722, Korea
Correspondence to: Ho-Geun Yoon, Tel: +82-2-2228-1684; Fax: +82-2-312-5041; E-mail:; Jae-Ho Cheong, Tel: +82-2-2228-2094; Fax: +82-2-313-8289; E-mail:
Received: February 26, 2018; Accepted: March 20, 2018; Published online: May 31, 2018.
© Korean Society for Biochemistry and Molecular Biology. All rights reserved.


Wntless/GPR177 functions as WNT ligand carrier protein and activator of WNT/β-catenin signaling, however, its molecular role in gastric cancer (GC) has remained elusive. We investigated the role of GPR177 in gastric tumorigenesis and provided the therapeutic potential of a clinical development of anti-GPR177 monoclonal antibodies. GPR177 mRNA expression was assessed in GC transcriptome data sets (GSE15459, n = 184; GSE66229, n = 300); protein expression was assessed in independent patient tumor tissues (Yonsei TMA, n = 909). GPR177 expression were associated with unfavorable prognosis [log-rank test, GSE15459 (P = 0.00736), GSE66229 (P = 0.0142), and Yonsei TMA (P = 0.0334)] and identified as an independent risk predictor of clinical outcomes: GSE15459 [hazard ratio (HR) 1.731 (95% confidence interval; CI; 1.103–2.715), P = 0.017], GSE66229 [HR 1.54 (95% CI, 1.10–2.151), P = 0.011], and Yonsei TMA [HR 1.254 (95% CI, 1.049–1.500), P = 0.013]. Either antibody treatment or GPR177 knockdown suppressed proliferation of GC cells and sensitized cells to apoptosis. And also inhibition of GPR177 suppresses in vitro and in vivo tumorogenesis in GC cells and inhibits WNT/β-catenin signaling. Finally, targeting and inhibition of GPR177 with antibody suppressed tumorigenesis in PDX model. Together, these results suggest GPR177 as a novel candidate for prognostic marker as well as a promising target for treatment of GC patients.

Keywords: Gastric cancer, GPR177, Monoclonal antibody, PDX, WNT signaling

Gastric cancer (GC) is one of the most common malignancies and the third leading cause of cancer death worldwide (1). Many studies have attempted to elucidate the molecular mechanisms underlying gastric tumorigenesis and develop novel molecular targeted therapeutics (2, 3). Recently, anti-HER2 receptor and anti-VEGFR2 receptor antibodies were developed and approved as targeted therapy for GC patients (46); however, identification and validation of more candidate therapeutic targets are still required (7).

Dysregulation of WNT/β-catenin signaling is commonly observed in cancer, including GC (810). When WNT ligands are secreted and interact with their cognate receptors, β-catenin–dependent or –independent signaling cascades are transduced, resulting in cancer progression. In the absence of WNT ligand, β-catenin is maintained at a low level through degradation by the β-catenin destruction complex. Secreted WNT ligand binds to FZD-LRP receptors, triggering the WNT/β-catenin axis. As a consequence, AXIN complexes with DVL which inhibits β-TrCP to degrade beta catenin, resulting in cytoplasmic accumulation of β-catenin, which then translocates into the nucleus where it binds to the TCF/LEF transcription complex, activating target genes transcription (11). In many types of cancer, mutations in CTNNB1, AXIN, and APC cause hyperactivation of WNT/β-catenin signaling, resulting in cancer progression even in the absence of WNT ligand stimulation. Therefore, various small molecules and antibodies are under development as cancer therapeutics. A recent report suggests that blocking of WNT secretion may be a useful means of treating colorectal cancer (12, 13).

WNTs are secreted as glycosylated/lipid-modified proteins, mediated by the seven-pass transmembrane protein Wntless/GPR177 (1416). GPR177 localizes to compartments of the secretory pathway, including the ER, Golgi apparatus, endosomes, and plasma membrane. GPR177 is overexpressed in several cancer types, and GPR177 knockdown reduced cancer formation in a WNT-dependent manner (17). Growth of colon cancer cells harboring the β-catenin active mutant or APC mutant was inhibited in a GPR177-dependent manner. Thus, these studies suggest that blockade of GPR177 function may be a promising therapeutic target (13, 1820).

Here, we demonstrate that overexpression of GPR177 mRNA and protein correlates with poor prognosis of GC patients. WNT secretion and cell proliferation were inhibited by either anti-GPR177 monoclonal antibody treatment or GPR177 knockdown. Moreover, anti-GPR177 antibody exhibited anticancer efficacy in mouse and patient-derived xenograft (PDX) models.


GPR177 overexpression in GC is correlated with poor survival

To investigate the clinical significance of GPR177 in GC, we analyzed publicly available tumor transcriptome data sets and found that GPR177 mRNA level strongly correlated with poor overall survival in patients with GC (Fig. 1A and B). To evaluate whether GPR177 mRNA level correlates with protein level while maintaining the clinical implications, we analyzed GPR177 protein expression in tissue microarrays (TMAs) prepared using tissue of GC patients (n = 909) and a monoclonal antibody generated for this study (Fig. 1C and Supplementary Table 1). Patient age and sex, tumor histology, Lauren classification, and pathological tumor-node-metastasis (TNM) stage were analyzed as clinicopathological parameters in relation to GPR177 expression level. Intriguingly, all clinical and histological parameters were comparable between GPR177-negative (n = 463) and GPR177-positive (n = 446) GC patients, with the exception of tumor histology (Supplementary Table 1). In general, undifferentiated GC histology would correlate with unfavorable clinical outcomes; however, GPR177-positive tumors were significantly correlated with more highly differentiated histological subtypes, signifying that GPR177 expression may be independently associated with poor clinical outcomes. Indeed, positive GPR177 protein expression correlated significantly with poorer prognosis of GC patients (Fig. 1D). Furthermore, GPR177 expression at both the mRNA and protein levels was identified as an independent risk predictor of clinical outcome of GC patients even after adjusting the covariates as Lauren and TNM stages (Supplementary Table 2). Together, the clinical data suggest that GPR177 expression may be a reliable and legitimate predictor of unfavorable clinical outcome of GC patients, evidence that further investigation of molecular mechanisms in GC tumorigenesis is warranted.

Both GPR177-mediated WNT secretion and proliferation of GC cells are inhibited by anti-GPR177 monoclonal antibody

GPR177 binds cytoplasmic WNT ligand and secretes it into the extracellular milieu. GPR177 domains and their functions are described in Fig. 2A. To analyze its biological function in GC cell lines, we raised monoclonal antibodies that recognize the WNT-binding motif of GPR177. Antibodies were raised against each of five antigens. The monoclonal antibodies raised against antigen 3 (antibody #3) and antigen 4 (antibody #4) were selected and specificity was verified by western analysis with GPR177 blocking peptide and knockdown AGS cells (Fig. 2B and C). And also, GPR177 localization was assessed by immnunocytochemistry with generated antibody and the specificity for the antibody was confirmed by blocking peptide (Fig. 2D). Notably, GPR177 was co-localized and was increased with WNT1 expression as precedent report (Fig. 2E and F) (14).

Considering heterogeneity of GC, we evaluated GPR177 expression levels in several GC cell lines using qPCR. GPR177 expression levels showed a certain degree of variation across cell lines which are AGS, MKN45, YCC6, YCC7, YCC16 and 293FT as positive control for WNT-secreting cells (Fig. 3A). Next, we examined the possibility that GPR177 is required for WNT secretion from GC cells. GC cells transiently expressing HA-tagged WNT1 were cultured with or without anti-GPR177 antibody (Fig. 3B). Levels of WNT ligand in medium were assessed by anti-HA ELISA. All cell lines secreted WNT ligand, and secretion was inhibited by treatment with anti-GPR177 antibody. Based on these observations, we found that anti-GPR177 antibody efficiently blocks a WNT-secretory function of GPR177. We also observed that viability of WNT-secreting cells was suppressed by anti-GPR177 antibody in a concentration-dependent manner (Fig. 3C and D). Whereas WNT overexpression increased the migration of AGS cells compared with control cells, and this effect was reversed by monoclonal antibody treatment (Fig. 3E). Similar results were observed using a colony-forming assay (Fig. 3F). Since we observed the inhibitory activity of anti-GPR177 antibody on the proliferation gastric cancer cells, we next assessed the change of apoptosis in gastric cancer cells with or without anti-GPR177. Anti-GPR177 antibody treatment dramatically increased the annexin V-positive cells in both YCC6 and MKN45 cells, which were again verified with knocking-down of GPR177 (Fig. 3G).

It has been reported that MKN74 cells are capable of brain metastasis upon injection into mouse heart, and the brain metastatic (NI3–3) cells have been established in cell culture (21). NI3–3 cells are sensitive to anti-GPR177 antibody treatment compared with the parental MKN74 cells (Fig. 3H) and expressed high levels of GPR177 (WLS), AXIN2, and cyclin D1 (CCND1) mRNA (Fig. 3I) which are the main targets for the WNT/β-catenin pathway. Taken together, WNT secretion and viability of gastric cancer cells are efficiently inhibited by treatment with anti-GPR177 monoclonal antibodies.

Anti-GPR177 antibody treatment suppresses gastric tumorigenesis in vivo

To evaluate in vivo efficacy of anti-GPR177 monoclonal antibodies, MKN45 cells were injected into nude mice (n = 5 each). After two weeks of injection, anti-GPR177 antibodies were delivered intravenously every 2 days for 3 weeks, and tumor size was measured. Treatment with anti-GPR177 antibodies reduced tumor growth significantly (Fig. 4A). Upon completion of experiments, tumors were removed from mice and further analyzed by western blotting. Intriguingly, we found that the WNT/β-catenin signaling pathway was upregulated in xenograft tumors compared to the parental MKN45 cells (Supplementary Fig. 1A). We hypothesized that this might be the result of selective evolutionary pressure imposed by the tumor environment, favoring stress-resistant molecular traits. Concordant with this, it has recently been reported that metabolic stress induces stem-like phenoconversion through the WNT pathway (22). To confirm this, we generated metabolic–stress-selected MKN45 (sMKN45) cell lines as previously reported. Compared to parental MKN45 lines, sMKN45 cells showed a more aggressive tumor-forming phenotype (Supplementary Fig. 1B). Next, sMKN45 cells were subcutaneously injected into nude mice to establish xenografts. Treatment with anti-GPR177 antibody substantially reduced tumor progression in terms of both volume and weight (Fig. 4B). The sMKN45 cells showed increased GPR177 expression and sensitivity to anti-GPR177 antibody in vitro (Fig. 4C). Previous studies have clearly demonstrated that loss of GPR177 function in other types of cancer suppresses tumor formation in xenograft models (8, 13, 18). Therefore, we tested whether GPR177 knockdown in GC cancer would inhibit tumor formation. Using shRNA targeting GPR177 (shGPR177), we generated AGS cell lines that stably express low levels of GPR177 mRNA and protein. Control (shCON) and stable shGPR177 AGS cells were subcutaneously injected into BALB/C nude mice (n = 5 mice/group). Two weeks later, xenograft tumors were measured with a caliper every 2 days and terminated when volume exceeded 800 mm3. Compared to control cells, shGPR177-expressing AGS cells showed retarded growth rate (Fig. 4D). These data collectively show that targeted inhibition of GPR177 suppresses in vivo tumorigenesis of gastric cancer cells.

Anti-GPR177 antibody treatment suppresses gastric tumorigenesis in PDX model

Previously, we established GC patient-derived xenograft (PDX) model which could be applied to predict cancer patient’s responses to the cancer drug (23). We tested whether this tumor suppression would be reproducible in a PDX model. Among GC patients who had undergone gastrectomy, GPR177 expression level of tumor specimens was determined by immunohistochemistry and designated high, moderate, low or negative (Fig. 4E and F). Case GA083, a GPR177 high expressing model, was expanded and divided randomly into two groups. One group was injected intravenously with anti-GPR177 monoclonal antibody #3 every 2 days for 3 weeks, and the other group was injected with PBS as negative control. Tumor size was measured every 2 days (Fig. 4G). Both tumor size and weight were significantly reduced in antibody treatment group compared with control group (Fig. 4G and H). Taken together, these data show that targeted inhibition of GPR177 suppresses human gastric tumorigenesis.


GPR177 is seven-pass transmembrane protein that binds cytoplasmic WNT ligand and secretes it to the extracellular space (24). Dysregulation of WNT secretion and uncontrolled activation of the WNT/β-catenin signaling pathway is associated with disease, such as cancer, and developmental abnormalities (2529). GPR177 knockout results in WNT loss-of-function phenotypes in species ranging from Drosophila to Mus musculus. In cancer, GPR177 upregulation enhances tumor progression, and downregulation has been proposed as a potential therapeutic target.

Previous studies have shown that inhibition of GPR177 expression efficiently suppresses cancer progression (8, 13, 18). The cancer-promoting activity of GPR177 has been explained in positive upregulation of the WNT/β-catenin signal in most cancer types. In this study, we found that GPR177 is required in WNT/β-catenin, signaling in GC cells.

We examined the role of GPR177 in the WNT-secreting pathway in GC cell lines. We expressed exogenous WNT1 ligand and confirmed that WNT was secreted into the culture medium. To prevent WNT secretion, we treated GC cells with anti-GPR177 monoclonal antibody. Because the antibodies were raised against the middle of the WNT-binding motif, we presumed that they would block this function of GPR177. Antibody treatment reduced not only WNT secretion but also cell viability and migration. As antibody treatment was effective only on WNT-secreting cells, we speculated that, whereas expression level is important for cancer cell proliferation, the presence of intact WNT-secretory machinery, including the ER, Golgi, and cargo carrier systems, was likely a more critical factor in the case of antibody treatment of GC. Thus, we concluded that GC cell lines that secrete WNT ligand are sensitive to monoclonal antibody treatment in vitro.

As a positive component of the WNT/β-catenin signaling pathway, GPR177 is upregulated when the signal is activated. More precisely, β-catenin, which is stabilized and dissociated from the destructive complex, is translocated into the nucleus and transcriptionally activated. Consequently, GPR177 transcription is induced and mRNA expression increases. However, it is still not clear that in this mode of positive feedback regulation, a cell is induced to produce more WNT ligand in an autocrine manner. Regardless of whether WNT ligand synthesis is induced in a WNT–ligand-dependent or –independent manner, increased GPR177 expression is followed by induction of WNT/β-catenin signaling.

Furthermore, we confirm that inhibition of GPR177 function effectively suppressed tumor progression in in vivo xenograft and PDX models. GC patients who are expressing high levels of GPR177 thereafter capable of WNT secretion could be tested whether the treatment of GPR177 antibody will suppress tumor progression. From clinical perspective, if we use the PDX model and personalized molecular information, we can stratify GC patients according to WNT-secretion proficiency and predict the therapeutic outcome of anti-GPR177 monoclonal antibody treatment as a novel therapy as described in Supplementary Fig. 2.

In conclusion, we report for the first time that GPR177 is highly expressed in GC patients and that GPR177 expression level is positively correlated with poor patient prognosis. Further, our findings provide a rationale of GPR177 inhibition as a therapeutic target for GC treatment.


Cell culture

Cell lines were maintained in RPMI-1640 supplemented with 10% heat-inactivated fetal bovine serum and 1% penicillin/streptomycin. 293FT and YCC cells were maintained in DMEM as previously described (30).

Statistical analysis

Prognosis was evaluated by overall survival, from day of surgery to death by any cause. Correlation of gene expression with overall survival was estimated using Kaplan-Meier survival plots and log-rank tests. Multivariable Cox proportional hazards regression analysis was used to evaluate independent prognostic factors associated with overall survival, including age, sex, Lauren type, and TNM-stage groups as covariates. A two-sided P value <0.05 was considered statistically significant. All statistical analyses were conducted in the R language environment (

PDX model

A PDX model was established as previously reported (23). Briefly, a tumor was obtained from a surgical specimen (F0) immediately after gastrectomy. Formation of a tumor greater than 500 mm3 in volume at the implant site was considered a successful engraftment in the case of subcutaneous implantation. The mouse was anaesthetized, and the tumor (F1) was removed for serial transplantation into the next generation (F2, F3). Mice were housed and fed according to the institutional guidelines for animal care. All animal experiments were approved by the Institutional Animal Care and Use Committee (IACUC) of the Yonsei University College of Medicine (2014-0130). Six-week old female athymic nude mice (Japan SLC, Inc., Japan) and male NOG mice (NOD/Shi-scid, IL-2 Rγnull, Ciea, Japan) were used for each PDX model. Before the experiments, the animals were acclimated for seven days to a 12 h light/12 h dark cycle. One case of a GPR177-positive tumor specimen (F0) that was successfully maintained through passages was subcutaneously implanted into a NOG mouse (passage 1 or F1).


This study was supported by a grant of the Korean Health Technology R&D Project, Ministry of Health & Welfare, Republic of Korea (HI14C1840).


The authors have no conflicting interests.

Supplementary Information
Fig. 1. Clinical impact of GPR177 in gastric cancer (GC) patients. (A-D) GPR177 expression correlates with poor prognosis in human GC patients. (A and B) Correlation of GPR177 (WLS) mRNA expression with overall survival for patients (A, n = 184; B, n = 300). Solid and broken lines denote patients whose tumors expressed lower and higher levels, respectively, than the median value. (C) Micrographs of immunohistochemical staining of GPR177 in human GC tumor samples. Representative images of negative (left) and positive (right) staining. Scale bar, 100 μm. (D) Kaplan-Meier analysis of overall survival in a data set of 909 GC samples used in immunohistochemical analysis and classified as having positive (broken line) or negative (solid line) GPR177 expression.
Fig. 2. GPR177 co-localizes with WNT1 in GC cell lines. (A) Schematic diagram of GPR177 structure and function. Upper: linear representation of GPR177. Lower: GPR177, with WNT cargo, spanning plasma membrane. The seven transmembrane domains consist of amino acids 233–252, 265–287, 302–319, 332–354, 379–401, 434–456, and 471–493. (B) AGS cell lysates were loaded and analyzed with GPR177 antibody in western blot with or without blocking peptide. Endogenous GPR177 was not detected in blocking peptide treated condition. (C) Validation of siRNA specific for GPR177. AGS cells were were transiently transfected with siRNA as indicated. Full-length blots merged with protein size markers are presented in . (D) AGS cells were stained with GPR177 antibody with or without blocking peptide. (E) AGS cells were transiently expressed with HA-WNT1 and stained with anti-HA (red) and anti-GPR177 (green). Overexpression of WNT1 induced GPR177 expression. (F) WNT1 and GPR177 were co-localized. Images were processed using Carl Zeiss ZEN software.
Fig. 3. GPR177 monoclonal antibody treatment inhibits WNT-secretion and viability of gastric cancer cells. (A) GPR177 mRNA expression was measured by qPCR. GC cell lines (AGS, MKN25, YCC6, YCC7, and YCC16) and 293FT cells were collected and analyzed. GC cells showed expression levels similar to that of 293FT cells. (B) ELISA detection of secreted HA-WNT1. WNT secretion was reduced by monoclonal antibody treatment. *P < 0.05. (C) GPR177 monoclonal antibody treatment reduced cell viability. AGS, YCC6 and YCC7 were treated with GPR177 monoclonal antibody at the indicated concentration for 24 h. Cells showed reduced viability with antibody treatment. (D) AGS cells were treated with monoclonal antibody at the indicated concentrations and for 24 hr to determine lethal dose (LD)50. Viability was assessed by MTT assay. *P < 0.05. (E) Monoclonal antibody treatment reduced cell migration. AGS cells transiently overexpressing WNT and control cells were seeded on transwell plates, and migrated cells were counted. GPR177 monoclonal antibody suppressed cell migration (concentration 1 μg/ml). *P < 0.05. (F) WNT-secreting AGS and YCC6 cells were seeded at 60-mm dish and treated with monoclonal antibody. Colonies were fixed and stained with crystal violet and counted under microscope. *P < 0.05. (G) YCC6 and MKN45 cells were treated with 5 pmol GPR177 siRNA for 48 h or antibody. Apoptosis was assayed by FACS. (H) MKN74 and NI3-3 cells were treated with 2 or 4 μg/ml monoclonal antibody for 24 h. Suppression was observed only in NI3-3 cells. *P < 0.05. (I) qPCR analysis showed that WNT/β-catenin signaling is upregulated in NI3-3 cells compared to MKN74 cells. GPR177 (WLS), AXIN2, and cyclin D1 (CCND1) mRNA levels were detected.
Fig. 4. GPR177 monoclonal antibody inhibits tumor growth in GC xenograft and human PDX model. (A) Nude BALB/C mice were injected subcutaneously with 105 MKN45 cells. Two weeks later, mice were randomly divided into two groups of 10 mice each. One group was intravenously injected with anti-GPR177 monoclonal antibody #3 ten times over 3 weeks, approximately every 2 days. Control group was injected with vehicle PBS. Tumor size was measured with calipers. At the end of anti-tumor efficacy test, the mice were scarified, and then tumors dissected and weighted. (B) Parental MKN45 (pMKN45) and metabolic–stress-selected MKN45 (sMKN45) cells (105) were subcutaneously injected into nude mice. Two weeks later, mice were randomly divided into two groups of 5 each in both cells. One group was intravenously injected with anti-GPR177 monoclonal antibody #3 eight times over 3 weeks, and the other was treated with vehicle PBS. sMKN45 cells were also significantly inhibited by antibody treatment. P = 0.0023 for monoclonal antibody #3 in tumor weight. (C) Metabolic stress induces GPR177 in sMKN45 cells. GPR177 mRNA levels in pMKN45 and sMKN45 cells were determined by qPCR. Monoclonal antibody treatment (2 μg/ml for 24 h) reduced sMKN45 cell viability to a greater extent than pMKN45 cell viability determined by MTT assay. *P < 0.05. (D) Stable shRNA-mediated knockdown of GPR177 in AGS cells. Control cells were treated with non-targeting shRNA. Cells were subcutaneously injected into nude mice. Tumors were measured 2 weeks later with calipers every 2 days. *P < 0.05. (E) Representative cases of PDX models according to GPR177 expression levels. GPR177 expression was detected by immunohistochemistry using anti-GPR177 antibody #3. (F) Summary of PDX models by GPR177 expressions. Cases were classified based on GPR177 expression level as high, moderate, low and negative expression. (G) GA083 tumors were transplanted to athymic nude mice and treated either with anti-GPR177 monoclonal antibody #3 eight times over 3 weeks (n = 10) or with vehicle PBS (n = 10). (H) Tumor weight of dissected tumors in C).
  1. Tan, P, and Yeoh, KG (2015). Genetics and Molecular Pathogenesis of Gastric Adenocarcinoma. Gastroenterology. 149, 1153-1162 e1153.
    Pubmed CrossRef
  2. Tan, IB, Ivanova, T, and Lim, KH (2011). Intrinsic subtypes of gastric cancer, based on gene expression pattern, predict survival and respond differently to chemotherapy. Gastroenterology. 141, Array-Array.
    Pubmed KoreaMed CrossRef
  3. Corso, S, and Giordano, S (2016). How Can Gastric Cancer Molecular Profiling Guide Future Therapies?. Trends Mol Med. 22, 534-544.
    Pubmed CrossRef
  4. Bang, Y-J, Van Cutsem, E, and Feyereislova, A (2010). Trastuzumab in combination with chemotherapy versus chemotherapy alone for treatment of HER2-positive advanced gastric or gastro-oesophageal junction cancer (ToGA): a phase 3, open-label, randomised controlled trial. The Lancet. 376, 687-697.
  5. Sartore-Bianchi, A, Trusolino, L, and Martino, C (2016). Dual-targeted therapy with trastuzumab and lapatinib in treatment-refractory, KRAS codon 12/13 wild-type, HER2-positive metastatic colorectal cancer (HERACLES): a proof-of-concept, multicentre, open-label, phase 2 trial. Lancet Oncol. 17, 738-746.
    Pubmed CrossRef
  6. Wilke, H, Muro, K, and Van Cutsem, E (2014). Ramucirumab plus paclitaxel versus placebo plus paclitaxel in patients with previously treated advanced gastric or gastrooesophageal junction adenocarcinoma (RAINBOW): a double-blind, randomised phase 3 trial. Lancet Oncol. 15, 1224-1235.
    Pubmed CrossRef
  7. Kahn, M (2014). Can we safely target the WNT pathway?. Nat Rev Drug Discov. 13, 513-532.
    Pubmed KoreaMed CrossRef
  8. Lu, D, Li, Y, and Liu, QR (2015). Wls promotes the proliferation of breast cancer cells via Wnt signaling. Med Oncol. 32, 140.
    Pubmed CrossRef
  9. Mao, J, Fan, S, and Ma, W (2014). Roles of Wnt/beta-catenin signaling in the gastric cancer stem cells proliferation and salinomycin treatment. Cell Death Dis. 5, e1039.
  10. Clevers, H, and Nusse, R (2012). Wnt/beta-catenin signaling and disease. Cell. 149, 1192-1205.
    Pubmed CrossRef
  11. Anastas, JN, and Moon, RT (2013). WNT signalling pathways as therapeutic targets in cancer. Nat Rev Cancer. 13, 11-26.
  12. Proffitt, KD, and Virshup, DM (2012). Precise regulation of porcupine activity is required for physiological Wnt signaling. J Biol Chem. 287, 34167-34178.
    Pubmed KoreaMed CrossRef
  13. Voloshanenko, O, Erdmann, G, and Dubash, TD (2013). Wnt secretion is required to maintain high levels of Wnt activity in colon cancer cells. Nat Commun. 4, 2610.
    Pubmed KoreaMed CrossRef
  14. Banziger, C, Soldini, D, Schutt, C, Zipperlen, P, Hausmann, G, and Basler, K (2006). Wntless, a conserved membrane protein dedicated to the secretion of Wnt proteins from signaling cells. Cell. 125, 509-522.
    Pubmed CrossRef
  15. Bartscherer, K, Pelte, N, Ingelfinger, D, and Boutros, M (2006). Secretion of Wnt ligands requires Evi, a conserved transmembrane protein. Cell. 125, 523-533.
    Pubmed CrossRef
  16. Yu, J, Chia, J, Canning, CA, Jones, CM, Bard, FA, and Virshup, DM (2014). WLS retrograde transport to the endoplasmic reticulum during Wnt secretion. Dev Cell. 29, 277-291.
    Pubmed CrossRef
  17. Maruyama, EO, Yu, HM, Jiang, M, Fu, J, and Hsu, W (2013). Gpr177 deficiency impairs mammary development and prohibits Wnt-induced tumorigenesis. PLoS One. 8, e56644.
    Pubmed KoreaMed CrossRef
  18. Augustin, I, Goidts, V, and Bongers, A (2012). The Wnt secretion protein Evi/Gpr177 promotes glioma tumourigenesis. EMBO Mol Med. 4, 38-51.
    KoreaMed CrossRef
  19. Barrott, J, Cash, GM, Smith, AP, Barrow, JR, and Murtaugh, LC (2011). Deletion of mouse Porcn blocks Wnt ligand secretion and reveals an ectodermal etiology of human focal dermal hypoplasia/Goltz syndrome. Proc Natl Acad Sci U S A. 108, 12752-12757.
    Pubmed KoreaMed CrossRef
  20. Liu, J, Pan, S, and Hsieh, MH (2013). Targeting Wnt-driven cancer through the inhibition of Porcupine by LGK974. Proc Natl Acad Sci U S A. 110, 20224-20229.
    Pubmed KoreaMed CrossRef
  21. Minn, YK, Lee, DH, and Hyung, WJ (2014). MicroRNA-200 family members and ZEB2 are associated with brain metastasis in gastric adenocarcinoma. Int J Oncol. 45, 2403-2410.
    Pubmed CrossRef
  22. Lee, E, Yang, J, and Ku, M (2015). Metabolic stress induces a Wnt-dependent cancer stem cell-like state transition. Cell Death Dis. 6, e1805.
    Pubmed KoreaMed CrossRef
  23. Choi, YY, Lee, JE, and Kim, H (2016). Establishment and characterisation of patient-derived xenografts as paraclinical models for gastric cancer. Sci Rep. 6, 22172.
    Pubmed KoreaMed CrossRef
  24. Kim, W, Kim, M, and Jho, EH (2013). Wnt/beta-catenin signalling: from plasma membrane to nucleus. Biochem J. 450, 9-21.
    Pubmed CrossRef
  25. Fu, J, Ivy Yu, HM, Maruyama, T, Mirando, AJ, and Hsu, W (2011). Gpr177/mouse Wntless is essential for Wnt-mediated craniofacial and brain development. Dev Dyn. 240, 365-371.
    Pubmed KoreaMed CrossRef
  26. Jin, J, Morse, M, Frey, C, Petko, J, and Levenson, R (2010). Expression of GPR177 (Wntless/Evi/Sprinter), a highly conserved Wnt-transport protein, in rat tissues, zebrafish embryos, and cultured human cells. Dev Dyn. 239, 2426-2434.
    Pubmed KoreaMed CrossRef
  27. Yu, HM, Jin, Y, Fu, J, and Hsu, W (2010). Expression of Gpr177, a Wnt trafficking regulator, in mouse embryogenesis. Dev Dyn. 239, 2102-2109.
    Pubmed KoreaMed CrossRef
  28. Carpenter, AC, Smith, AN, and Wagner, H (2015). Wnt ligands from the embryonic surface ectoderm regulate ‘bimetallic strip’ optic cup morphogenesis in mouse. Development. 142, 972-982.
    Pubmed KoreaMed CrossRef
  29. Jiang, M, Ku, WY, Fu, J, Offermanns, S, Hsu, W, and Que, J (2013). Gpr177 regulates pulmonary vasculature development. Development. 140, 3589-3594.
    Pubmed KoreaMed CrossRef
  30. Park, SY, Seo, J, and Choi, HK (2017). Protein serine/threonine phosphatase PPEF-1 suppresses genotoxic stress response via dephosphorylation of DCD5. Sci Rep. 7, 39222.

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