Masayoshi Namba

Inhibitory effects of antioxidants on neonatal rat cardiac myocyte hypertrophy induced by tumor necrosis factor-α and angiotensin II

BACKGROUNDnTumor necrosis factor-alpha (TNF-alpha) and angiotensin II (Ang II) modulate heart failure in part by provoking the hypertrophic response. Signal transduction pathways of those factors are implicated in reactive oxygen intermediates (ROIs). Therefore, we hypothesized that TNF-alpha and Ang II might cause myocyte hypertrophy via the generation of ROIs.nnnMETHODS AND RESULTSnTo test the hypothesis, we tested whether TNF-alpha and Ang II could induce the generation of ROIs and whether antioxidants such as butylated hydroxyanisole (BHA), vitamin E, and catalase might inhibit the hypertrophy in cultured neonatal rat cardiac myocytes. ROIs were measured by the ROI-specific probe 2,7-dichlorofluorescin diacetate in cultured cardiac myocytes. We demonstrated that TNF-alpha and Ang II induced the generation of ROIs in a dose-dependent manner. TNF-alpha (10 ng/mL) and Ang II (100 nmol/L) enlarged cardiac myocytes and increased [3H]leucine uptake, and BHA (10 micromol/L) significantly inhibited both effects. Other antioxidants, such as vitamin E (1 microg/mL) and catalase (100 U/mL), also inhibited the enlargement of cardiac myocytes induced by TNF-alpha.nnnCONCLUSIONSnThese results indicate that TNF-alpha and Ang II cause hypertrophy in part via the generation of ROIs in cardiac myocytes.

Screening the p53 status of human cell lines using a yeast functional assay

We have screened the p53 status of 156 human cell lines, including 142 tumor cell lines from 27 different tumor types and 14 cell lines from normal tissues by using functional analysis of separated alleles in yeast. This assay enables us to score wild‐type p53 expression on the basis of the ability of expressed p53 to transactivate the reporter gene HIS3 via the p53‐responsive GAL1 promoter in Saccharomyces cerevisiae. Of 142 tumor cell lines, at least 104 lines (73.2%) were found to express the mutated p53 gene: 94 lines (66.2%) were mutated in both alleles, three lines (2.1%) were heterozygous, and no p53 cDNA was amplified from seven lines (4.9%). Of the 14 cell lines originating from normal tissues, all the transformed or immortalized cell lines expressed mutant p53 only. Yeast cells expressing mutant p53 derived from 94 cell lines were analyzed for temperature‐sensitive growth. p53 cDNA from eight cell lines showed p53‐dependent temperature‐sensitive growth, growing at 30°C but not at 37°C. Four temperature‐sensitive p53 mutations were isolated: CAT→CGT at codon 214 (H214R), TAC→TGC at codon 234 (Y234C), GTG→ATG at codon 272 (V272M), and GAG→AAG (E285K). Functionally wild‐type p53 was detected in 38 tumor cell lines (26.8%) and all of the diploid fibroblasts at early and late population doubling levels. These results strongly support the previous findings that p53 inactivation is one of the most frequent genetic events that occurs during carcinogenesis and immortalization. Mol. Carcinog. 19:243–253, 1997.

Transformation of normal human fibroblasts into immortalized cells with the mutant p53 gene and X-rays.

In vitro cell transformation is a valuable approach for studying the mechanisms of multistep carcinogenesis of human cells. Since immortalization is an essential step for in vitro neoplastic transformation of human cells, this study addresses the question of whether mutant p53 contributes to the immortalization process of human cells. The mutant p53 gene (mp53: codon273Arg‐His) was introduced into normal human fibroblasts (OUMS‐24 line) and a G418‐resistant clone, OUMS‐24/P6 line, was obtained. This clone showed an extended life span and chromosome abnormalities, but senesced at the 79th population doubling level (PDL). When these cells were subjected to intermittent X‐ray treatment, they became an immortalized cell line (OUMS‐24/P6X). Although these immortalized cells showed chromosome abnormalities, they were not tumorigenic. On the other hand, normal OUMS‐24 cells into which mp53 had not been introduced were not immortalized by the same X‐ray treatment. These results indicate that introduction and expression of mp53 alone were not sufficient for immortalization of human cells, and that mutations of the remaining wild‐type p53 or other genes may have been necessary for immortalization. In fact, no expression of the wild‐type p53 was detected in the immortalized cells by RT‐PCR. Expression of p21, which is located downstream of p53, was remarkably reduced in the immortalized cells, resulting in an increase in cdk2 and cdc2 kinase activity. These findings indicate that the p53‐p21 cascade may play some role in the immortalization of human cells. On the other hand, there was no significant difference in expression of proteins such as Rb, p16, cdk4, cdk6, cyclin A and cyclin D1 between the normal and immortalized human fibroblasts.

IMMORTALIZATION OF MUTANT p53-TRANSFECTED HUMAN FIBROBLASTS BY TREATMENT WITH EITHER 4-NITROQUINOLINE 1-OXIDE OR X-RAYS

SummaryThe study of in vitro cell transformation is valuable for understanding the multistep carcinogenesis of human cells. The difficulty in inducing neoplastic transformation of human cells by treatment with chemical or physical agents alone is due to the difficulty in immortalizing normal human cells. Thus, the immortalization step is critical for in vitro neoplastic transformation of human cells. We transfected a mutant p53 gene (mp53: codon 273Arg-His) into normal human fibroblasts and obtained two G418-resistant mp53-containing clones. These clones showed an extended life span but ultimately senesced. However, when they were treated with either 4-nitroquinoline 1-oxide or X rays, they were immortalized. The immortalized cells showed both numerical and structural chromosome abnormalities, but they were not tumorigenic. The expression of mutant but not wild type p53 was detected in the immortalized cells by RT-PCR. Expression of p21, which is located downstream of p53, was remarkably reduced in the immortalized cells, resulting in increased cdk2 and cdc2 kinase activity. However, there was no significant difference between the normal and immortalized human cells in expression of another tumor suppressor gene, p16. These findings indicate that the p53-p21 cascade may play an important role in the immortalization of human cells.

Effects of okadaic acid on cell growth, anchorage-independent growth, and co-cultures of normal (KMS-6), immortalized (KMST-6), and neoplastically transformed (KMST-6T and KMST-6/RAS) human fibroblasts

The effects of okadaic acid (OA) on normal human (KMS-6), its immortalized (KMST-6) and neoplastically transformed (KMST-6T and KMST-6/RAS) cells were investigated as a model of two-stage carcinogenesis. The presence of OA inhibited cell growth of the normal and immortalized cells but not that of the neoplastic KMST-6T cells. In contrast, cell growth of the other neoplastic KMST-6/RAS cells transformed with the Ha-ras oncogene was inhibited by OA. OA enhanced colony formation of KMST-6T cells in soft agar, but it suppressed that of KMST-6/RAS cells. Co-cultures of KMST-6T cells with normal KMS-6 cells showed an increase in focus formation of KMST-6T cells in the presence of OA, whereas focus formation of KMST-6/RAS cells decreased. These results indicate that OA has growth-promoting effects on certain types of transformed human cells.

Establishment of a human fibroblast cell line producing tumor necrosis factor α (KMST-6/TNF) and growth inhibitory effects of its conditioned medium on malignant cells in culture

SummaryTo develop a new gene therapy model for cancer, a clonal cell line (KMST-6/TNF) which produces human tumor necrosis factor α (hTNF-α) has been developed by introducing hTNF-α cDNA into a human immortal fibroblast cell line (KMST-6). The conditioned medium (CM) of KMST-6/TNF cells inhibited the growth of various malignant human cell lines, but not that of normal human fibroblasts. Although the growth inhibitory effects of KMST-6/TNF CM were neutralized to a considerable degree by anti-TNF-α antibody, its inhibitory effects were more marked than the purified human natural TNF-α itself in the same units, suggesting that KMST-6/TNF CM contains some growth inhibitory substances other than TNF-α. However, interferons α, β, and γ were undetectable in the KMST-6/TNF CM.