Both N-ras and c-myc are activated in the SHAC human stomach fibrosarcoma cell line

Expressional profiles of transcription factors in the progression of Helicobacter pylori-associated gastric carcinoma based on protein/DNA array analysis

Transcription factors (TFs) are crucial modulators of gene expression during the development and progression of gastric carcinoma. Helicobacter pylori (H. pylori) is one of the most significant risk factors of gastric carcinoma, and it is widely known that chronic inflammation with H. pylori infection triggers gastric carcinogenesis through inflammation-carcinoma chain [gastric carcinogenesis stages: non-atrophic gastritis, chronic atrophic gastritis, intestinal metaplasia, dysplasia and gastric carcinoma (GC)], but its mechanism regarding changed TFs remains unknown. In this study, we investigated the expressional profiles of 345 transcription factors in gastric mucosa of healthy volunteers and patients at different gastric carcinogenesis stages using protein/DNA array-based approach. The data demonstrated the up-regulated TFs such as GATA-3, AP4, c-Myc and Pbx1 in the gastric mucosa of GC patients compared with the healthy volunteers, while other TFs, particularly CCAAT and CACC, showed the consistently decreasing trend along the gastric carcinogenesis. The increased expressions of AP4, Pbx1 and C/EBPα were further validated by quantitative real-time PCR and Western blot in various H. pylori-infected models such as clinical gastric tissues, gastric epithelial cell lines and Mongolian gerbils. This study provides insights into and potential laws for gene transcriptional regulation by identifying potential TFs targets against the development of H. pylori-associated gastric carcinoma.

Malignant transformation of human skin fibroblasts by two alternative pathways

We developed a telomerase-positive, infinite life span human fibroblast cell strain (MSU-1.0) by transfection of a v-MYC oncogene and spontaneous over-expression of transcription factors SP1/SP3. Loss of expression of p14(ALT) and enhanced expression of SPRY2 gave rise to the MSU-1.1 cell strain. Unlike MSU-1.0 cells, the MSU-1.1 cells can be malignantly transformed by expression of N-RAS(LYS61) or H-Ras(v12) oncoproteins (driven by their original promoters) and expression of a SRC-family protein, v-FES. MSU-1.1 cells can also be malignantly transformed by high expression of these RAS oncogenes or the v-K-RAS oncogene. PDGF-B transformed MSU-1.1 cells give rise to benign tumors (fibromas) in athymic mice. A second route to malignant transformation of the MSU-1.1 cells involves loss of functional TP53 protein by carcinogen treatment and loss of expression of wild type p16(INK). These studies indicate 6-8 "hits" are required to activate the oncogenes and inactivate the suppressor genes we identified.

v-myb transformation of Xeroderma pigmentosum human fibroblasts: overexpression of the c-Ha-ras oncogene in the transformed cells

Human Xeroderma pigmentosum "normal" fibroblasts AS16 (XP4 VI) were transformed after transfection with a recombinant v-myb clone. In this clone (pKXA 3457) derived from avian myeloblastosis virus (AMV), the expression of the oncogene sequences is driven by the AMV U-5 LTR promoter. The transformed cells (ASKXA), which have integrated a rearranged v-myb oncogene, grow in agar, are not tumorigenic in nude mice, and express a 45-kDa v-myb protein. The HMW DNA of these cells transform chicken embryo fibroblasts. The c-Ha-ras oncogene is overexpressed in the ASKXA cells but not in the parental "normal" AS16 cells and a revertant clone (ASKXA Cl 1.1 G). Our results lead to the conclusion that the XP fibroblasts are phenotypically transformed by the presence of the transfected v-myb oncogene, which is able to induce an overexpression of the c-Ha-ras gene.

Malignant transformation of human fibroblasts caused by expression of a transfected T24 HRAS oncogene

We showed previously that diploid human fibroblasts that express a transfected HRAS oncogene from the human bladder carcinoma cell line T24 exhibit several characteristics of transformed cells but do not acquire an infinite life-span and are not tumorigenic. To extend these studies of the T24 HRAS in human cells, we have utilized an infinite life-span, but otherwise phenotypically normal, human fibroblast cell strain, MSU-1.1, developed in this laboratory after transfection of diploid fibroblasts with a viral v-myc oncogene. Transfection of MSU-1.1 cells with the T24 HRAS flanked by two transcriptional enhancer elements (pHO6T1) yielded foci of morphologically transformed cells. No such transformation occurred if the plasmid containing T24 HRAS had only one enhancer or none at all or if the normal human HRAS gene was transfected in the pHO6 vector (pHO6N1). Cell strains derived from such foci expressed high levels of T24 HRAS product p21, formed colonies in soft agar at high frequency, proliferated rapidly in serum-free medium that does not support growth of the parental cell line, and formed progressively growing, invasive fibrosarcomas. These foci-derived T24 HRAS-transformed cell strains, as well as cells from the tumors derived from them, had the same near-diploid karyotype as that of the parental MSU-1.1 cells. Transfection of pHO6T1 into two other infinite life-span human fibroblast cell lines, cells that had not been transfected with v-myc, also resulted in malignant transformation, suggesting that the infinite life-span phenotype of MSU-1.1 cells, and not necessarily expression of the v-myc oncogene, was the factor that complemented T24 HRAS expression to cause malignant transformation.