Chang Q. Piao

Downregulation of Betaig-h3 gene is causally linked to tumorigenic phenotype in asbestos treated immortalized human bronchial epithelial cells

Although Betaig-h3 gene has been suggested to modulate cell adhesion and tumor formation, its physiological functions are not well understood. Using human papillomavirus immortalized human bronchial epithelial (BEP2D) cells, we found that Betaig-h3 expression was markedly decreased in asbestos-induced tumorigenic cells. Fusion of tumorigenic and control BEP2D cells resulted in the recovery of Betaig-h3 gene expression to control level and the loss of tumorigenic phenotype. Furthermore, ectopic expression of Betaig-h3 gene in asbestos-induced tumorigenic cells inhibited cell growth in vitro, anchorage independent phenotype, as well as tumorigenicity in nude mice. Betaig-h3 gene is ubiquitously expressed in various normal human tissues, with the exception of the brain, where there is little or no expression. In contrast, there was a decrease or absence in expression of the Betaig-h3 gene in 14 human tumor cell lines of diverse histological types examined, when compared with normal human cells or tissues. The result strongly suggests that loss of Betaig-h3 expression is a frequent event in human cancer and causally related to acquisition of tumorigenic phenotype in asbestos-treated BEP2D cells.

Taxol and ionizing radiation: Interaction and mechanisms

PURPOSE Taxol has been shown to be clinically active against several types of human tumors. To assess the potential oncogenic effect of taxol, the in vitro cytotoxic and oncogenic transforming effects of taxol, either alone or in combination with gamma-irradiation, were examined. METHODS AND MATERIALS Exponentially growing mouse C3H 10T1/2 cells were treated with taxol with or without concurrent gamma-irradiation. After treatment, cultures were replated for both clonogenic survival and transformation assays. To determine the effects of taxol on cell cycle kinetics, treated cells were concurrently labelled with bromodeoxyuridine coupled with fluorescein. Accumulated mitotic cells were isolated by the shake-off technique and their plating efficiency and radiosensitivity were determined. RESULTS Taxol induced a dose dependent toxicity in 10T1/2 cells. In contrast to human tumor cells in culture, the mitotic block induced by a 100 nM dose of taxol in 10T1/2 cells was only partial. While taxol was ineffective in transformant induction, it enhanced the oncogenic transforming potential of gamma-rays in a supra-additive manner. The fact that approximately 15% of taxol-induced mitotic cells were clonogenically viable and at a cell cycle stage that was most radiosensitive suggests a mechanistic basis for the observed enhancement in transformation incidence by ionizing radiation. CONCLUSION Taxol enhances the oncogenicity of radiation by partially blocking the 10T1/2 cells in G2/M phases of the cell cycle, phases that are most sensitive to radiation induced oncogenic transformation.

Overexpression of Betaig-h3 gene downregulates integrin α5β1 and suppresses tumorigenicity in radiation-induced tumorigenic human bronchial epithelial cells

Interaction between cell and extracellular matrix plays a crucial role in tumour invasion and metastasis. Using an immortalised human bronchial epithelial (BEP2D) cell model, the study here shows that expression of Betaig-h3 gene, which encodes a secreted adhesion molecule induced by transforming growth factor-β, is markedly decreased in several independently generated, radiation-induced tumour cell lines (TL1–TL5) relative to parental BEP2D cells. Transfection of Betaig-h3 gene into tumour cells resulted in a significant reduction in tumour growth. While integrin receptor α5β1 was overexpressed in tumour cells, its expression was corrected to the level found in control BEP2D cells after Betaig-h3 transfection. These data suggest that Betaig-h3 gene is involved in tumour progression by regulating integrin receptor α5β1. The findings provide strong evidence that the Betaig-h3 gene has tumour suppressor function in human BEP2D cell model and suggest a potential target for interventional therapy.

Down-regulation of Betaig-h3 Gene is Involved in the Tumorigenesis in Human Bronchial Epithelial Cells Induced by Heavy-Ion Radiation

Abstract Zhao, Y., Shao, G., Piao, C. Q., Berenguer, J. and Hei, T. K. Down-regulation of Betaig-h3 Gene is Involved in the Tumorigenesis in Human Bronchial Epithelial Cells Induced by Heavy-Ion Radiation. Radiat. Res. 162, 655–659 (2004). High-energy (HZE) heavy ions, when compared to low-LET radiation, are highly effective in inducing gene mutation, chromosomal aberrations and neoplastic transformation. However, the underlying molecular mechanisms are not clearly understood. We have recently shown that the down-regulation of Betaig-h3 expression is causally linked to the tumorigenic phenotype of papillomavirus-immortalized human bronchial epithelial (BEP2D) cells treated with high-LET α-particle radiation. Using the BEP2D cell culture system, a radiation-induced transformation model has been established by a single 60-cGy dose of 56Fe heavy-ion radiation. To determine whether the Betaig-h3 gene is involved in 56Fe ion-induced tumorigenesis, the expression levels of the Betaig-h3 gene in tumorigenic cell lines and the ability of in vivo tumor suppression through the reintroduction of the Betaig-h3 gene in tumorigenic cells were determined. We found that the expression level of this gene is markedly decreased in three tumorigenic cell lines (56FeT1–T3) compared with parental BEP2D cells. Ectopic expression of its cDNA in the 56FeT2 tumorigenic cells significantly suppressed their tumorigenicity. Although biologically active TGFB1 is elevated in two of three tumorigenic cell lines, all these cell lines are resistant to the induction of Betaig-h3 expression by incubating the transformed cells with exogenous TGFB1 relative to control cells. Our data strongly suggest that down-regulation of Betaig-h3 expression results from the defect in the TGFB1 signaling pathway and plays a pivotal role in the tumorigenic process induced by 56Fe heavy-ion radiation.

Cellular and molecular alterations in human epithelial cells transformed by high let radiation

An understanding of the radiobiological effects of high LET radiation is essential for human risk estimation and radiation protection. In the present study, we show that a single, 30 cGy dose of 150 keV/micrometer 4He ions can malignantly transform human papillomavirus immortalized human bronchial epithelial [BEP2D] cells. Transformed cells produce progressively growing tumors in nude mice. The transformation frequency by the single dose of alpha particles is estimated to be approximately 4 X 10(-7). Based on the average cross-sectional area of BEP2D cells, it can be calculated that a mean traversal of 1.4 particles per cell is sufficient to induce tumorigenic conversion of these cells 3 to 4 months post-irradiation. Tumorigenic BEP2D cells overexpress mutated p53 tumor suppressor oncoproteins in addition to the cell cycle control gene cyclin D1 and D2. This model provides an opportunity to study the cellular and molecular changes at the various stages in radiation carcinogenesis involving human cells.

Molecular alterations in tumorigenic human bronchial and breast epithelial cells induced by high let radiation

Carcinogenesis is a multi-stage process with sequence of genetic events governing the phenotypic expression of a series of transformation steps leading to the development of metastatic cancer. In the present study, immortalized human bronchial (BEP2D) and breast (MCF-10F) cells were irradiated with graded doses of either 150 keV/micrometer alpha particles or 1 GeV/nucleon 56Fe ions. Transformed cells developed through a series of successive steps before becoming tumorigenic in nude mice. Cell fusion studies indicated that radiation-induced tumorigenic phenotype in BEP2D cells could be completely suppressed by fusion with non-tumorigenic BEP2D cells. The differential expressions of known genes between tumorigenic bronchial and breast cells induced by alpha particles and their respective control cultures were compared using cDNA expression array. Among the 11 genes identified to be differentially expressed in BEP2D cells, three (DCC, DNA-PK and p21(CIP1)) were shown to be consistently down-regulated by 2 to 4 fold in all the 5 tumor cell lines examined. In contrast, their expressions in the fusion cell lines were comparable to control BEP2D cells. Similarly, expression levels of a series of genes were found to be altered in a step-wise manner among tumorigenic MCF-10F cells. The results are highly suggestive that functional alterations of these genes may be causally related to the carcinogenic process.

Mechanisms of Radiation-Induced Neoplastic Transformation of Human Bronchial Epithelial Cells

Abstract Zhao, Y. L., Piao, C. Q., Hall, E. J. and Hei, T. K. Mechanisms of Radiation-Induced Neoplastic Transformation of Human Bronchial Epithelial Cells. Carcinogenesis is a multistage process with sequences of genetic events that govern the phenotypic expression of a series of transformation steps that lead to the development of metastatic cancer. To better understand the mechanisms involved in human bronchial carcinogenesis induced by α particles from radon, we have developed a model of neoplastic transformation based on human papillomavirus-immortalized human bronchial epithelial (BEP2D) cells. Cells exposed to α particles become tumorigenic after progressing through a series of sequential stages including altered growth pattern, resistance to serum-induced terminal differentiation, agar-positive growth, tumorigenicity, and metastasis, with each step representing a necessary yet insufficient step toward the later, more malignant phase. Cell fusion studies indicated that the radiation-induced tumorigenic phenotype in BEP2D cells can be completely suppressed by fusion with nontumorigenic BEP2D cells. Several cellular differentiation and growth regulation genes such as DCC (deleted in colorectal cancer), CDKN1A (also known as p21C1P1) and the gene that encodes DNA-PK were frequently found to be modulated in tumorigenic BEP2D cells and may be related to the process of carcinogenesis.

Genomic instability and tumorigenic induction in immortalized human bronchial epithelial cells by heavy ions

Carcinogenesis is postulated to be a progressive multistage process characterized by an increase in genomic instability and clonal selection with each mutational event endowing a selective growth advantage. Genomic instability as manifested by the amplification of specific gene fragments is common among tumor and transformed cells. In the present study, immortalized human bronchial (BEP2D) cells were irradiated with graded doses of either 1GeV/nucleon 56Fe ions or 150 keV/micrometer alpha particles. Transformed cells developed through a series of successive steps before becoming tumorigenic in nude mice. Tumorigenic cells showed neither ras mutations nor deletion in the p16 tumor suppressor gene. In contrast, they harbored mutations in the p53 gene and over-expressed cyclin D1. Genomic instability among transformed cells at various stage of the carcinogenic process was examined based on frequencies of PALA resistance. Incidence of genomic instability was highest among established tumor cell lines relative to transformed, non-tumorigenic and control cell lines. Treatment of BEP2D cells with a 4 mM dose of the aminothiol WR-1065 significantly reduced their neoplastic transforming response to 56Fe particles. This model provides an opportunity to study the cellular and molecular mechanisms involved in malignant transformation of human epithelial cells by heavy ions.

Tumor suppressor function of Betaig-H3 gene in radiation carcinogenesis

Interaction between cell and extracellular matrix (ECM) plays a crucial role in tumor invasiveness and metastasis. Using an immortalized human bronchial epithelial (BEP2D) cell model, we showed previously that expression of a list of genes including Betaig-h3 (induced by transforming growth factor-beta), DCC (deleted in colorectal cancer), p21(cipl), c-fos, Heat shock protein (HSP27) and cytokeratin 14 were differentially expressed in several independently generated, radiation-induced tumor cell lines (TL1-TL5) relative to parental BEP2D cells. Our previous data further demonstrated that loss of tumor suppressor gene(s) as a likely mechanism of radiation carcinogenesis. In the present study, we chose Betaig-h3 and DCC that were downregulated in tumorigenic cells for further study. Restored expression of Betaig-h3 gene, not DCC gene, by transfecting cDNA into tumor cells resulted in a significant reduction in tumor growth. While integrin receptor alpha 5 beta 1 was overexpressed in tumor cells, its expression was corrected to the level found in control BEP2D cells after Betaig-h3 transfection. These data suggest that Betaig-h3 gene is involved in tumor progression by regulating integrin alpha 5 beta 1 receptor. Furthermore, exogenous TGF- beta 1 induced expression of Betaig-h3 gene and inhibited the growth of both control and tumorigenic BEP2D cells. Therefore, downregulation of Betaig-h3 gene may results from the decreased expression of upstream mediators such as TGF-beta. The findings provide strong evidence that the Betaig-h3 gene has tumor suppressor function in radiation-induced tumorigenic human bronchial epithelial cells and suggest a potential target for interventional therapy.

Gene Amplification and Microsatellite Instability Induced in Tumorigenic Human Bronchial Epithelial Cells by Alpha Particles and Heavy Ions

Abstract Piao, C. Q. and Hei, T. K. Gene Amplification and Microsatellite Instability Induced in Tumorigenic Human Bronchial Epithelial Cells by Alpha Particles and Heavy Ions. Gene amplification and microsatellite alteration are useful markers of genomic instability in tumor and transformed cell lines. It has been suggested that genomic instability contributes to the progression of tumorigenesis by accumulating genetic changes. In this study, amplification of the carbamyl-P-synthetase, aspartate transcarbamylase, dihydro-orotase (CAD) gene in transformed and tumorigenic human bronchial epithelial (BEP2D) cells induced by either α particles or 56Fe ions was assessed by measuring resistance to N-(phosphonacetyl)-l-aspartate (PALA). In addition, alterations of microsatellite loci located on chromosomes 3p and 18q were analyzed in a series of primary and secondary tumor cell lines generated in nude mice. The frequency of PALA-resistant colonies was 1–3 × 10–3 in tumor cell lines, 5–8 × 10–5 in transformed cells prior to inoculation into nude mice, and less than 10–7 in control BEP2D cells. Microsatellite alterations were detected in all 11 tumor cell lines examined at the following loci: D18S34, D18S363, D18S877, D3S1038 and D3S1607. No significant difference in either PALA resistance or microsatellite instability was found in tumor cell lines that were induced by α particles compared to those induced by 56Fe ions.