In this study, we investigated the role of E1AF, a member of ets family transcription factor, in the acquisition of metastatic capacity by non-metastatic mouse ®brosarcoma cell clone, QR-32. The QR-32 cell clone grows progressively after co-implantation with gelatin sponge in syngeneic C57BL/6 mice. The cell lines (QRsP) established from arising tumors after the co-implantation exhibited enhanced tumorigenicity and pulmonary metastasis in vivo as compared with parent QR-32 cells. The enhanced pulmonary metastasis of QRsP cells was correlated well with augmented production of matrix metalloproteinase-2 (MMP-2) and increased expression of membrane-type 1-MMP (MT1-MMP). The QRsP cells also acquired higher chemokinetic activities to ®bronectin and higher invasive activities through a reconstituted basement membrane. Furthermore we observed the elevated mRNA expression of E1AF in QRsP cells compared to parent QR-32 cells. Therefore, we transfected QR-32 cells with E1AF cDNA. Overexpression of E1AF in the QR-32 cells resulted in the induction of MT1-MMP expression and converting an exogenously added precursor MMP-2 into active form. E1AF transfectants exhibited more motile and invasive activities, and moderately increased pulmonary metastatic activities than parental QR-32 cells in vivo, although their metastatic activities were lower than those of QRsP cells. These ®ndings suggest that the increased expression of E1AF in ®brosarcoma contributes to invasive phenotypes including MT1-MMP expression and enhanced cell migration, but not sucient for exhibiting highly metastatic activity in vivo.
Previously we reported the malignant progression of QR-32, a regressor-type tumor clone, following co-implantation with foreign bodies (gelatin sponge or plastic plate) in normal syngeneic C57BL/6 mice. We also reported that the progression of QR-32 cells by a gelatin sponge was significantly inhibited in the mice administered polysaccharide K (PSK) and that PSK induced an increase of radical scavengers, especially manganese superoxide dismutase (Mn-SOD), locally at the site of tumor tissues. In this study, to reveal the possible mechanism by which PSK induced Mn-SOD in the tumor tissues, we examined the mRNA expression and protein levels of inflammatory cytokines in the tissues. We found that mRNAs of tumor necrosis factor alpha (TNFalpha) and interleukin-1alpha (IL-1alpha) were considerably expressed in both PSK-treated and phosphate-buffered-saline-treated tumors, and that the mRNA expression and protein level of interferon gamma (IFNgamma) increased in the tumor tissues treated with PSK. In vitro treatment of QR-32 cells with IFNgamma did not significantly increase the production of Mn-SOD; however, the combination of IFNgamma with TNFalpha increased the Mn-SOD production more effectively than did any of the cytokines used singly. Furthermore, we observed the down-regulation of the mRNA expression and protein level of transforming growth factor beta (TGFbeta) in the tumor tissues treated with PSK, and that in vitro treatment of QR-32 cells with TGFbeta decreased the production of Mn-SOD. These results suggest that PSK suppresses the progression of QR-32 cells by increasing Mn-SOD via the modulation of inflammatory cytokines; that is, by decreasing TGF-beta and increasing IFN-gamma.
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