Rika Satoyoshi’s research while affiliated with Akita University and other places

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Publications (4)


Agr2 Mediates Paracrine Effects on Stromal Fibroblasts That Promote Invasion by Gastric Signet-Ring Carcinoma Cells
  • Article

December 2014

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58 Reads

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39 Citations

Cancer Research

Tadahiro Tsuji

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Rika Satoyoshi

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Namiko Aiba

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[...]

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Agr2 is a member of the endoplasmic reticulum (ER) protein disulfide isomerase, which physiologically regulates protein folding and plays a pivotal role in resistance to ER stress. Agr2 is expressed primarily in adenocarcinomas of various organs, and Agr2 protein overexpression participates in neoplastic transformation and metastasis, therefore acts as a pro-oncogenic protein. Besides the normal ER-localization, extracellular Agr2 is present in serum and urine of cancer patients. However, the physiological significance of extracellular Agr2 is poorly understood. In this study, we demonstrated a novel function of extracellular Agr2 that activated stromal fibroblasts and promoted fibroblast-associated cancer invasion. Agr2 is highly expressed in gastric signet-ring cell carcinoma (SRCC). Agr2 secreted from SRCC cells was incorporated by the surrounding gastric fibroblasts and promoted invasion by these cells. In turn, activated fibroblasts promote the coordinated invasion by fibroblasts and cancer cells. Thus Agr2 plays pivotal roles in the progression of gastric SRCC by exerting paracrine effects on the surrounding fibroblasts. Furthermore, Agr2 increased the growth and resistance of SRCC cells to oxidative and hypoxic stress as cell autonomous effects. Our results indicate that Agr2 may be a suitable therapeutic target for gastric SRCC. Copyright © 2014, American Association for Cancer Research.


Tks5 activation in mesothelial cells creates invasion front of peritoneal carcinomatosis

August 2014

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22 Reads

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29 Citations

Oncogene

Scirrhous gastric cancer is frequently associated with peritoneal dissemination, and the interaction of cancer cells with peritoneal mesothelial cells (PMCs) is crucial for the establishment of the metastasis in the peritoneum. Although cells derived from PMCs are detected within tumors of peritoneal carcinomatosis, how PMCs are incorporated into tumor architecture is not understood. The present study shows that PMCs create the invasion front of peritoneal carcinomatosis, which depends on activation of Tks5 in PMCs. In peritoneal tumor implants, PMCs represent majority of cells located at the invasive edge of the cancer tissue. Exogenously implanted PMCs and host PMCs aggressively invade into abdominal wall upon the peritoneal inoculation of cancer cells, and PMCs locate ahead of cancer cells in the direction of invasion. Tks5, a substrate of Src kinase, is predominantly expressed in the PMCs of cancer tissue, and promotes the invasion of PMCs and cancer cells. Expression and activation of Tks5 was induced in PMCs following their exposure to gastric cancer cells, and increased Tks5 expression was detected in PMCs located at the invasion front. Reduced Tks5 expression in PMCs blocked PMC invasion, which in turn prevents cancer cell invasion both in vitro and in vivo. The peritoneal dissemination of gastric cancer was significantly increased by mixing cancer cells and PMCs, and was suppressed by knockdown of Tks5 in PMCs. These results suggest that cancer-activated PMCs create invasion front by guiding cancer cells. Signaling leading to Tks5 activation in PMCs may be a suitable therapeutic target for prevention of peritoneal carcinomatosis.Oncogene advance online publication, 4 August 2014; doi:10.1038/onc.2014.246.


Figure 1: Asporin is predominantly expressed in CAFs of gastric cancer. (A) Left: total cell lysates were prepared from CAFs or NFs (established from three patients with scirrhous gastric cancer) and from 44As3 cells. Lysates were subjected to IB with anti-Asporin and anti-Decorin antibodies. Right: total RNA was isolated from each cell type and used for RT–PCR detection of mRNAs encoding Biglycan, Tsukushi and α-SMA. (B) Left: NF-37 (1.0 × 106) and 44As3 cells (2.0 × 106) were subcutaneously implanted into nude mice, separately or together, for 5 days. Right: NF-37 cells were cultured in CM of 44As3 cells for 4 days. Lysates were prepared from the subcutaneous nodules or cells, respectively, and immunoblotted with anti-Asporin antibody. (C) Asporin expression in human scirrhous gastric cancer tissue. Immunohistochemistry with anti-Asporin antibody. Enlargement of square a is shown at right. Ca indicates the cancer cell. Bottom: the same specimen was immunostained with anti-Asporin (red), anti-α-smooth muscle actin (green) and DAPI (blue). Regions corresponding to squares a, b and c are shown. M, mucosa; MP, muscularis propria; SM, submucosa. (a–c) Bar, 50 μm. Bar in the large picture indicates 200 μm.
Figure 6: Asporin promotes invasion of fibroblasts and cancer cells in vivo. DiI-labeled fibroblasts (red) and DiO-labeled 44As3 (green) were mixed (2 × 105 each) and implanted into the submucosal layer of nude mouse stomachs. Mice were sacrificed 6 days (a, c–f) or 15 days (b) after implantation. Dissected stomachs were sliced into 100-μm sections, and then observed under a confocal microscope. Merged images with bright fields are shown. Bar, 100 μm. MP, muscularis propria. Two-way arrows indicate the layer of the MP. Five mice were analyzed for each group, and the experiments were repeated twice. Representative pictures are shown. Invasion index was calculated as described in Materials and Methods, and defined as the ratio relative to the amount of invasion in mice injected 44As3 with NF-37. In f, invasion index was calculated at day 6. The results are shown as means ±s.d. *P<0.01.
Asporin activates coordinated invasion of scirrhous gastric cancer and cancer-associated fibroblasts
  • Article
  • Full-text available

January 2014

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174 Reads

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101 Citations

Oncogene

Scirrhous gastric cancer, which has the worst prognosis among the various types of gastric cancer, is highly invasive and associated with abundant stromal fibroblasts. Although cancer-associated fibroblasts (CAFs) have been proposed to generate a tumor-supportive extracellular matrix that promotes the expansion of this type of cancer, the molecular mechanisms by which CAFs assist cancer cells are not yet fully understood. Here, we show for the first time that Asporin, a small leucine-rich proteoglycan (SLRP), is predominantly expressed in CAFs, and has essential roles in promoting co-invasion of CAFs and cancer cells. CAFs of scirrhous gastric cancer possess high potential for invasion, and invasion by CAFs frequently proceeded invasion by cancer cells, both in vitro and in vivo. Expression of Asporin was induced in fibroblasts by exposure to gastric cancer cells. Asporin secreted from CAFs activates Rac1 via an interaction with CD44 and promotes invasion by CAFs themselves. Moreover, Asporin promoted invasion by neighboring cancer cells, via paracrine effects mediated by activation of the CD44-Rac1 pathway. These results suggest that Asporin is a unique SLRP that promotes progression of scirrhous gastric cancer and is required for coordinated invasion by CAFs and cancer cells. Therefore, Asporin may represent a new therapeutic target molecule for the development of drugs aimed at manipulating the cancer microenvironment.Oncogene advance online publication, 20 January 2014; doi:10.1038/onc.2013.584.

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Figure 1. Sequence analyses of KRAS, BRAF and PIK3CA. The representative sequence analysis is shown for each case. Heterozygous mutations are shown by perpendicular lines.  
Figure 2. Immunohistochemical analyses of EGFR, KRAS and GSTP. (A) Negative immunoreactivity for EGFR at the primary lesion and (B) positive immuno reactivity at the site of lung metastasis in case 7, (C) negative immunoreactivity for KRAS (G12D) at the primary lesion and (D) positive immunoreactivity for KRAS (G12D) at the site of lung metastasis in case 5, (E) immunoreactivity for GSTP is denoted by (++) at the primary lesion, (F) (+++) at the site of liver metastasis, and (G) (-) at the site of lung metastasis in case 5; all sites had the same KRAS G12D mutation. EGFR, epidermal growth factor receptor; GSTP, glutathione S-transferase II; G12D, glycine to aspartic acid mutation at codon 12.
Acquired/intratumoral mutation of KRAS during metastatic progression of colorectal carcinogenesis

March 2012

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57 Reads

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10 Citations

Oncology Letters

Mutations at codons 12 and 13 of the KRAS gene have been identified as level I predictive biomarkers against the treatment of advanced colorectal cancer with anti-epidermal growth factor receptor (EGFR) monoclonal antibodies. It is thought that the genetic analysis of KRAS mutations associated with metastatic colorectal cancer can be routinely conducted using DNA obtained on one occasion from one organ, from the primary or a metastatic site, whichever is preferentially available. However, the issue of tumor heterogeneity resulting from acquired/intratumoral mutations remains. Recently, the possibility of acquired/intratumoral mutations in the KRAS gene has been reported by two research groups and has ranged from 7.4 to 15.4%. Specimens were collected from advanced colorectal cancer patients with resected primary, and at least one metastatic, site. Direct sequence analysis was performed for KRAS, BRAF and PIK3CA, and immunohistochemistry for glutathione S-transferase II (GSTP) and EGFR. In the current study, we identified an acquired mutation rate of approximately 11.1% in the KRAS gene (1/9). This figure is not negligible. Our observation indicates, particularly in the case of metastatic recurrence after a long interval, that there may be considerable tumor heterogeneity resulting from acquired or intratumoral mutations of the KRAS gene.

Citations (4)


... Anterior gradient homolog 2 (AGR2) belongs to the protein disulfide isomerase family and serves as an ER retention protein [158]. It has been demonstrated that the extracellular AGR2 protein was shown to be up-regulated in SGC cells and was closely correlated with the capacity to prompt stromal fibroblasts and stimulate invasion, as well as the resistance to oxidative and hypoxic stresses [159]. ...

Reference:

Molecular Mechanism for Malignant Progression of Gastric Cancer Within the Tumor Microenvironment
Agr2 Mediates Paracrine Effects on Stromal Fibroblasts That Promote Invasion by Gastric Signet-Ring Carcinoma Cells
  • Citing Article
  • December 2014

Cancer Research

... Sandoval et al. observed that peritoneal MAFs from biopsies of ovarian cancer co-expressed CAF-specific marker α-SMA alongside with the mesothelial markers cytokeratin and calretinin [62]. Similarly, in scirrhous gastric carcinoma, invading lead cells exhibited partial overlap in α-SMA and calretinin [64]. Fig. 3 The multi-cellular origins of cancer-associated fibroblasts (CAFs) in peritoneal surface malignancies. ...

Tks5 activation in mesothelial cells creates invasion front of peritoneal carcinomatosis
  • Citing Article
  • August 2014

Oncogene

... Indeed, asporin competes with decorin in collagen binding and promotes osteoblast collagen mineralization [49]. Due to its ubiquitous expression, asporin has been implicated as an activator of invasion in schirrhous gastric carcinomas [50], as well as growth and migration of gastric cancers cells [51,52]. Moreover, stromalderived asporin is a biomarker associated with prostate cancer progression [53], bladder cancer where asporin levels correlate with the degree of malignancy [54]. ...

Asporin activates coordinated invasion of scirrhous gastric cancer and cancer-associated fibroblasts

Oncogene