Entry into S phase is inhibited in two immortal cell lines fused to senescent human diploid cells.

Senescent human diploid cells (HDC) were fused to T98G human glioblastoma cells and to RK13 rabbit kidney cells, and DNA synthesis was analyzed in the heterodikaryons. T98G and RK13 cells are “partially transformed” cell lines that have some characteristics of normal cells, yet are transformed to immortality, i.e., they do not senesce. Previous experiments have shown that “fully transformed” HeLa and SV80 cells induce DNA synthesis in senescent HDC nuclei, whereas normal young HDC do not. Our experiments show that T98G and RK13 cells do not induce DNA synthesis in senescent HDC nuclei. These results demonstrate that the ability to induce DNA synthesis in senescent HDC is not correlated with immortality per se. Our results show further that a T98G cell in S phase at the time of fusion to a senescent HDC will continue to make DNA. However, a T98G cell in G1 phase at the time of fusion is prevented from initiating DNA synthesis. RK13 cells behave similarly to T98G. These results are consistent with the hypothesis that the molecular basis for the senescent phenotype involves a block that prevents cells in G1 phase from entering S phase. Thus, we conclude that the senescent phenotype can be dominant in heterokaryons composed of senescent HDC fused with certain immortal cell lines. To explain the different results obtained with various immortal cell lines, we present a model that suggests that T98G and RK13 cells are immortal because they have lost a normal regulatory factor, whereas HeLa and SV80 are immortal because they have gained a dominant transformation factor.