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 lambda cDNA 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 reduced 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.

A role for apoptosis in the pathogenesis of AIDS-related idiopathic esophageal ulcers.

Lack of understanding of the mechanism of tissue destruction associated with idiopathic esophageal ulcers (IEUs) poses a diagnostic and therapeutic dilemma for the clinician. The possible role of apoptosis in IEUs, as suggested by endoscopic and histologic observations, was investigated by examination of archival tissues for apoptosis-related DNA fragmentation using in situ nick end labeling (TUNEL). High levels of apoptosis were observed in mucosal cells immediately adjacent to IEUs. Apoptotic cells were virtually absent in normal control tissues, while the edges and bases of lesions and sloughed-off tissues in IEUs in human immunodeficiency virus (HIV)-infected patients showed elevated levels of apoptotic cell death. However, tissue samples from patients with esophageal ulcerations of known etiology showed no apoptosis of mucosal cells. These data support a role for apoptosis in the pathogenesis of IEUs and suggest a mechanism involving HIV-associated bystander killing of uninfected mucosal cells.

Maintenance of telomeres in SV40-transformed pre-immortal and immortal human fibroblasts.

Shortening of telomeres has been hypothesized to contribute to cellular senescence and may play a role in carcinogenesis of human cells. Furthermore, activation of telomerase has frequently been demonstrated in tumor-derived and in vitro immortalized cells. In this study, we have assessed these phenomena during the life span of simian virus 40 (SV40)-transformed preimmortal and immortal human fibroblasts. We observed progressive reduction in telomere length in preimmortal transformed cells with extended proliferative capacity, with the most dramatic shortening at late passage. Telomere lengths became stabilized (or increased) in immortal fibroblasts accompanied, in one case, by the activation of telomerase. However, an independent immortal cell line that displayed stable telomeres did not have detectable telomerase activity. Furthermore, we found significant telomerase activity in two preimmortal derivatives. Our results provide further evidence for maintenance of telomeres in immortalized human fibroblasts, but they suggest a lack of causal relationship between telomerase activation and immortalization.

Characterization of c-myc-transformed rat fibroblasts resistant to apoptosis induced ny growth factor deprivation.

Under appropriate conditions (e.g., growth factor withdrawal), the deregulated expression of c-myc in rodent fibroblasts leads to substantial cell death due to apoptosis. To better understand this process, we selected for c-myc-transformed Rat1A fibroblasts that were resistant to growth factor deprivation-induced cell death. One clonal isolate exhibited prolonged survival in serum-free medium and displayed reduced levels of apoptosis-related DNA fragmentation. These cells were also resistant to induction of apoptosis by the protein kinase inhibitor staurosporine. They retained a transformed cell phenotype and expressed the proviral human c-myc allele in an unaltered fashion, strongly indicating that the mutation of a cellular gene other than c-myc accounts for the apoptosis-resistant phenotype. The results of somatic cell hybrid analysis of this cell line are consistent with a recessive mutation. Our findings suggest a novel mechanism for abrogation of apoptosis in neoplastic cells and provide a model system for the study of its role in tumorigenesis and resistance to antineoplastic therapy.

Alteration of DNA and RNA binding activity of human telomere binding proteins occurs during cellular senescence.

The loss of telomere sequences during in vitro and in vivo aging suggests that mechanisms affecting telomere length may have important consequences in cellular senescence. In this study, we have found that the activity of single-stranded telomere binding proteins is increased in nuclear extracts prepared from senescent human diploid fibroblasts compared to actively growing cells. Since single-stranded telomere binding proteins are closely related to RNA binding proteins, we examined the binding activity of several major RNA binding proteins to RNA by uv cross-linking. The level of activity was greatly diminished and the overall pattern of uv cross-linked products were altered in extracts prepared from senescent cells. Furthermore, Western analysis revealed a concurrent decrease in senescent extracts of the protein level for many RNA binding proteins, including those which bind to telomere sequence. Although the reduction in the level of these proteins parallels the reduced activity in RNA binding, the paradoxical increased telomere binding activity exhibited by extracts from older cells suggests a complex relationship between these proteins with RNA and DNA. Moreover, the reduced RNA binding activity of these proteins indicates that the biochemical function of several RNA binding proteins is compromised during cellular senescence, raising an intriguing possibility that a change in pre-mRNA metabolism may contribute to the multitude of changes in gene expression observed in cellular senescence.

Myc-mediated apoptosis is blocked by ectopic expression of Bcl-2.

The product of the c-myc proto-oncogene is an important positive regulator of cell growth and proliferation. Recently, c-Myc has also been demonstrated to be a potent inducer of apoptosis when expressed in the absence of serum or growth factors. To further examine Myc-induced apoptosis, we coexpressed the proto-oncogene bcl2, which has been shown to block apoptosis in other systems, with c-myc in serum-deprived Rat 1a fibroblasts. Here we report that ectopic expression of bcl2 specifically blocks apoptosis induced by constitutive c-myc expression. Constitutive c-myc expression in serum-deprived Rat 1a cells caused a > 15-fold increase in the number of dead cells, accompanied by DNA fragmentation. However, coexpression of bcl2 with c-myc in these cells led to a 10-fold increase in the number of live cells and a significant decrease in DNA fragmentation. Thus, Bcl-2 effectively inhibits Myc-induced apoptosis in serum-deprived Rat 1a fibroblasts without blocking entry into the cell cycle. These results imply that apoptosis serves as a protective mechanism to prevent tumorigenicity elicited by deregulated Myc expression. This protective mechanism is abrogated, however, by Bcl-2 and therefore may explain the synergism between Myc and Bcl-2 observed in certain tumor cells.

Apoptosis and signal transduction: clues to a molecular mechanism.

Apoptosis, or programmed cell death, plays an essential role in specific cell deletion during normal embryonic and adult development in vertebrate and invertebrate species. Recent evidence suggests that signal transduction pathways governing cellular proliferation and cell cycle progression also mediate the physiological response to changes in the extracellular environment that trigger the anti-proliferative state characteristic of apoptosis.

Neoplastic transformation by the human gene N-myc.

Amplification and abundant expression of a gene known as N-myc are found frequently in advanced stages of human neuroblastoma and may play a role in the genesis of several malignant human tumors. Previous studies have shown that N-myc can cooperate with a mutant allele of the proto-oncogene c-Ha-ras to transform embryonic rat cells in culture. Here we show that N-myc can also act alone to elicit neoplastic growth of an established line of rat fibroblasts (Rat-1). We used recombinant DNA vectors to express either N-myc or its kindred gene c-myc in transfected cells. Both genes caused morphological transformation, anchorage-independent growth, and tumorigenicity. We noticed two variables that appeared to influence the ability to isolate cells transformed by N-myc and c-myc: the abundance in which the genes were expressed and biological selection to eliminate untransformed cells from the cultures. Our findings sustain the belief that N-myc is an authentic proto-oncogene, lend further credibility to the role of N-myc in the genesis of human tumors, and establish a convenient assay that can be used to explore further the properties of both N-myc and c-myc.