Escape from senescence in hybrid cell clones involves deletions of two regions located on human chromosome 1q.

Human normal cells have been shown to undergo a limited number of cell doublings, a phenomenon termed cellular senescence. Human chromosome 1 has been implicated in this process, and several lines of evidence indicate that there is a senescence-inducing gene or genes on human chromosome 1q. Our approach to analyze the senescence-inducing effect of chromosome 1 includes the use of somatic cell hybrid revertants. We show here that fusion of a hypoxanthine phosphoribosyl transferase-negative mouse cell line (A9) containing a human neo-tagged chromosome 1 with an immortal hamster cell line (10W-2) results in cell hybrids that senesce after a few population doublings. Rare revertants that had escaped senescence were obtained after one large fusion experiment. Thirty-five nonsenescent hybrids were obtained from a total of approximately 1 million hybrids, and 25 of these were subjected to further analysis. The presence of a single copy of human chromosome 1 in the revertant hybrids was confirmed by fluorescence in situ hybridization analysis using a chromosome 1-specific painting probe. No visible translocations or deletions of chromosome 1 were observed in any of the hybrids. Deletion mapping revealed that 11 (56%) of the hybrids analyzed had lost one or more markers on chromosome 1q. Two regions with deletions were detected, one of which has been shown to be implicated in the senescence-inducing effect exerted by chromosome 1 following monochromosome transfer (P. J. Vojta et al., manuscript submitted for publication). The present study suggests that two separate loci on human chromosome 1q may be of importance for the induction of senescence. Moreover, this set of nonsenescent revertants could be useful for future detailed analyses of the senescence-inducing loci.

[1]  M. Potter,et al.  Detection of immunoglobulin/c-myc recombinations in mice that are resistant to plasmacytoma induction. , 1996, Cancer research.

[2]  M. Oshimura,et al.  Evidence for multiple pathways to cellular senescence. , 1994, Cancer research.

[3]  K. Jha,et al.  Senescence of immortal human fibroblasts by the introduction of normal human chromosome 6. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[4]  C. Morelli,et al.  Induction of senescence and control of tumorigenicity in BK virus transformed mouse cells by human chromosome 6 , 1994, Genes, chromosomes & cancer.

[5]  T. Matise,et al.  Report of the first international workshop on human chomosome 1 mapping 1994 , 1994 .

[6]  M. Oishi,et al.  Chromosome 7 suppresses indefinite division of nontumorigenic immortalized human fibroblast cell lines KMST-6 and SUSM-1. , 1993, Molecular and cellular biology.

[7]  J. Murray,et al.  Linkage localization of TGFB2 and the human homeobox gene HLX1 to chromosome 1q. , 1993, Genomics.

[8]  Y. Nakamura,et al.  Allelotype of non-small cell lung carcinoma--comparison between loss of heterozygosity in squamous cell carcinoma and adenocarcinoma. , 1992, Cancer research.

[9]  R. Lebo,et al.  Loss of heterozygosity at chromosome 1q22 in basal cell carcinomas and exclusion of the basal cell nevus syndrome gene from this site. , 1992, Cancer research.

[10]  J. R. Smith,et al.  Genetic analysis of indefinite division in human cells: evidence for a cell senescence-related gene(s) on human chromosome 4. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[11]  E. Stanbridge,et al.  Dissociation of suppression of tumorigenicity and differentiation in vitro effected by transfer of single human chromosomes into human neuroblastoma cells. , 1991, Cell growth & differentiation : the molecular biology journal of the American Association for Cancer Research.

[12]  J. Barrett,et al.  Senescence of nickel-transformed cells by an X chromosome: possible epigenetic control. , 1991, Science.

[13]  U. Francke,et al.  Genes for two autosomal recessive forms of chronic granulomatous disease assigned to 1q25 (NCF2) and 7q11.23 (NCF1). , 1990, American journal of human genetics.

[14]  M. Oshimura,et al.  Multiple chromosomes carrying tumor suppressor activity for a uterine endometrial carcinoma cell line identified by microcell-mediated chromosome transfer. , 1990, Oncogene.

[15]  M. Oshimura,et al.  Induction of cellular senescence in immortalized cells by human chromosome 1. , 1990, Science.

[16]  L. Chen,et al.  Loss of heterozygosity on chromosome 1q in human breast cancer. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[17]  J. R. Smith,et al.  Genetic analysis of indefinite division in human cells: identification of four complementation groups. , 1988, Proceedings of the National Academy of Sciences of the United States of America.

[18]  M. Oshimura,et al.  An early, nonrandom karyotypic change in immortal Syrian hamster cell lines transformed by asbestos: trisomy of chromosome 11. , 1986, Cancer genetics and cytogenetics.

[19]  J. R. Smith,et al.  Existence of high abundance antiproliferative mRNA's in senescent human diploid fibroblasts. , 1986, Science.

[20]  J. R. Smith,et al.  Senescent and quiescent cell inhibitors of DNA synthesis. Membrane-associated proteins. , 1985, Experimental cell research.

[21]  D. Röhme Evidence for a relationship between longevity of mammalian species and life spans of normal fibroblasts in vitro and erythrocytes in vivo. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[22]  C. Bunn,et al.  Limited lifespan in somatic cell hybrids and cybrids. , 1980, Experimental cell research.

[23]  E. Schneider,et al.  The relationship between in vitro cellular aging and in vivo human age. , 1976, Proceedings of the National Academy of Sciences of the United States of America.

[24]  L. Hayflick,et al.  The serial cultivation of human diploid cell strains. , 1961, Experimental cell research.