Vaseem A. Palejwala

SV40-Mediated Immortalization

Human diploid cells have a limited life span, ending in replicative senescence, in contrast to cell lines derived from tumors, which show an indefinite life span and are immortal, suggesting that replicative senescence is a tumor suppression mechanism. We have utilized introduction of SV40 sequences to develop matched sets of nonimmortal and immortal cell lines to help dissect the mechanism of immortalization and have found that it has multiple facets, involving both SV40-dependent and -independent aspects. These studies have led to the identification of a novel growth suppressor gene (SEN6) as well as providing a model system for the study of cellular aging, apoptosis, and telomere stabilization among other things. It is anticipated that SV40-transformed cells will continue to provide a very useful experimental system leading to insights into the behavior of cells with altered expression of oncogenes and growth suppressor gene products.

PHF10 Is Required for Cell Proliferation in Normal and SV40-Immortalized Human Fibroblast Cells

Normal human diploid fibroblasts have limited life span in culture and undergo replicative senescence after 50–60 population doublings. On the contrary, cancer cells typically divide indefinitely and are immortal. Expression of SV40 large T and small t antigens in human fibroblasts transiently extends their life span by 20–30 population doublings and facilitates immortalization. We have identified a rearrangement in chromosome 6 shared by SV40-transformed human fibroblasts. Rearrangements involving chromosome 6 are among the most frequent in human carcinogenesis. In this paper, we extend analysis of the 6q26–q27 region, a putative site for a growth suppressor gene designated SEN6 involved in immortalization of SV40-transformed cells. Detailed molecular characterization of the rearranged chromosomes (6q*, normal appearing; and 6qt, translocated) in the SV40-immortalized cell line HALneo by isolating each of these 2 chromosomes in mouse/HAL somatic cell hybrids is presented. Analysis of these mouse/HAL somatic cell hybrids with polymorphic and nonpolymorphic markers revealed that the 6q* has undergone a chromosomal break in the MLLT4 gene (alias AF6). This result in conjunction with previous published observations leads us to conclude that SEN6 lies between MLLT4 and TBP at chromosomal region 6q27. Examination of different genes (MLLT4, DLL1, FAM120B, PHF10) located within this interval that are expressed in HS74 normal fibroblast cells reveals that overexpression of epitope-tagged truncated PHF10 cDNAs resulted in reduced cell proliferation in multiple cell lines. Paradoxically, down-regulation of PHF10 by RNAi also resulted in loss of cell proliferation in normal fibroblast cells, indicating PHF10 function is required for cell growth. Taken together, these observations suggest that decreased cell proliferation with epitope-tagged truncated PHF10 proteins may be due to dominant negative effects or due to unregulated expression of these mutant proteins. Hence we conclude that PHF10 is not SEN6 but is required for cell growth.

Differential gene expression in SV40-mediated immortalization of human fibroblasts.

Normal human diploid fibroblasts (HF) have a limited life span, undergo senescence, and rarely, if ever, spontaneously immortalize in culture. Introduction of the gene for T antigen encoded by the DNA virus SV40 extends the life span of HF and increases the frequency of immortalization; however, immortalization requires both T‐dependent and T‐independent functions. We previously generated independent SV40‐transformed non‐immortal (pre‐immortal) HF cell lines from which we then obtained immortal sublines as part of a multifaceted approach to identify functions responsible for immortalization. In this study we undertook a search for cellular mRNAs which are differentially expressed upon immortalization. A λcDNA library was prepared from a pre‐immortal SV40‐transformed HF (HF‐C). We screened the library with a subtracted probe enriched for sequences present in HF‐C and reduced in immortal AR5 cells. A more limited screen was also employed for sequences overexpressed in AR5 using a different strategy. Alterations in the level of mRNAs in AR5 encoding functions relevant to signal transduction pathways were identified; however, most cDNAs encoded novel sequences. In an effort to clarify which of the altered mRNAs are most relevant to immortalization, we performed Northern analysis with RNA prepared from three paired sets of independent pre‐immortal and immortal (4 cell lines) SV40‐transformants using eight cloned cDNAs which show reduced expression in AR5. Three of these were reduced in additional immortal cell lines as well; one, J4‐4 (unknown function) is reduced in all the immortal cell lines tested; a second, J4‐3 (possible PP2C type phosphatase) is reduced in 2 of the 3 matched sets; and a third, J2‐2 (unknown function) is redu ced in 2 unrelated immortal cell lines. Although the roles of these genes are as yet unclear, their further analysis should extend our understanding of the molecular bases for immortalization. In particular, the patterns of expression of J4‐4 and J4‐3 strongly suggest that they are involved in the process of immortalization and/or can serve as target genes for assessing regulators of gene expression in this process. J. Cell. Physiol. 171:325–335, 1997.

Base incorporation and extension at a site-specific ethenocytosine by Escherichia coli DNA polymerase I Klenow fragment

Ethenocytosine (epsilon C) is a highly mutagenic exocyclic DNA lesion induced by carcinogens vinyl chloride and urethane. We have examined base incorporation and extension at a site-specific epsilon C residue by a quantitative gel electrophoretic assay using an exonuclease-deficient version of Escherichia coli DNA polymerase I (Klenow fragment) as the model enzyme. The data show that the KM for incorporation of adenine or thymine opposite epsilon C by is about 5 orders of magnitude higher than that for the incorporation of guanine opposite normal cytosine. The KM for base extension past epsilon C:A and epsilon C:T pairs is 1-2 orders of magnitude higher than that observed for a C:G pair. Although adenine misinsertion is favored over that of thymine, base extension occurs more readily when the base incorporated opposite epsilon C is thymine.