Increased chromosomal stability in cultures of ovarian tumours of low malignant potential compared to cystadenomas

Cell cultures of ovarian cystadenomas transfected with SV40 large T antigen are not immortal because they invariably reach a phenomenon called crisis, which is triggered in part by telomere attrition. Recovery from crisis may be an integral component of the malignant transformation process. We reported earlier that such ovarian cystadenoma cell cultures undergo severe changes in DNA ploidy as they approach crisis and that such changes are an important determinant of crisis independent of telomere attrition. Here, we show that in sharp contrast to these benign ovarian tumours, the DNA content of ovarian tumours of low malignant potential (LMP) was remarkably stable as they approached crisis, suggesting that telomere attrition was the main determinant of this mortality checkpoint. Lack of a ploidy-based crisis was not due to loss of expression of a functional SV40 large T antigen protein. We conclude that ovarian LMP tumours are characterised by increased numerical chromosomal stability compared to cystadenomas. This might account for the fact that most LMP tumours are diploid or near diploid in vivo. This fundamental difference in chromosomal stability between ovarian cystadenomas and LMP tumours also suggests potential differences in predisposition to progression to malignancy between these two ovarian tumour subtypes.     

High telomerase activity correlates with the stabilities of genome and DNA ploidy in renal cell carcinoma

Malignant tumors have telomerase activity, which is thought to play a critical role in tumor growth. However, the relation between telomerase activity and genomic DNA status in tumor cells is poorly understood. In the present study, we examined telomerase activity in 13 clear cell type renal cell carcinomas (CRCCs) with similar clinicopathologic features by telomeric repeat amplification protocol assay (TRAP). Based on TRAP assay results, we divided the CRCCs into two groups: a high telomerase activity group and a low/no telomerase activity group. We then analyzed genomic aberration, DNA ploidy, and telomere status in these two groups by comparative genomic hybridization (CGH), laser scanning cytometry (LSC), and telomere-specific fluorescence in situ hybridization (T-FISH), respectively. CGH showed the high telomerase activity group to have fewer genomic changes than the low/no telomerase activity group, which had many genomic aberrations. Moreover, with LSC, DNA diploid cells were found more frequently in the high telomerase activity group than in the low/no telomerase activity group. In addition, T-FISH revealed strong telomere signal intensity in the high telomerase activity group compared with that of the low/no telomerase activity group. These results suggest that telomerase activity is linked to genomic DNA status and that high telomerase activity is associated with genomic stability, DNA ploidy, and telomere length in CRCC.     

SV40 infection induces telomerase activity in human mesothelial cells

Mesotheliomas are malignant tumors of the pleural and peritoneal membranes which are often associated with asbestos exposure and with Simian virus 40 (SV40) infection. Telomerase activity is repressed in somatic cells and tissues but is activated in immortal and malignant cells. We evaluated telomerase activity in seven primary malignant mesothelioma biopsies and matched lung specimens and 20 mesothelioma cell lines and eight corresponding primary tumor cultures. All the tumor biopsies, and nearly all primary cell mesothelioma cultures and cell lines were telomerase positive. The findings in cell lines paralleled those observed in primary cultures in cases where paired samples were available. Next, we found that SV40, a DNA tumor virus present in approximately 50% of mesothelioma biopsies in the USA, induced telomerase activity in primary human mesothelial cells, but not in primary fibroblasts. Telomerase activity became detectable as early as 72 h following wild-type (strain 776) SV40 infection, and a clear DNA ladder was detectable 1 week after infection. The amount of telomerase activity increased during passage in cell culture and appeared to parallel increases in the cellular amounts of the SV40 large T-antigen. Thus, SV40 infection leads to telomerase activity before the infected mesothelial cells become transformed and immortalized. SV40 infection of human fibroblasts did not cause detectable telomerase activity. We also determined that the SV40 small t-antigen (tag) plays an important role in inducing telomerase activity because this activity was undetectable or minimal in mesothelial cells infected and/or transformed by SV40 tag mutants. Asbestos alone did not induce telomerase activity, and asbestos did not influence telomerase activity in mesothelial cells infected with SV40. Induction of telomerase activity by SV40 may be related to the very high rate of mesothelial cell immortalization that is characteristically associated with SV40 infection of mesothelial cells.     

Alterations of DNA content in human endometrial stromal cells transfected with a temperature-sensitive SV40: tetraploidization and physiological consequences.

The normal genomic stability of human cells is reversed during neoplastic transformation. The SV40 large T antigen alters the DNA content in human endometrial stromal cells in a manner that relates to neoplastic progression. Human endometrial stromal cells were transfected with a plasmid containing the A209 temperature-sensitive mutant of SV40 (tsSV40), which is also defective in the viral origin of replication. Ninety-seven clonal transfectants from seven different primary cell strains were isolated. Initial analysis revealed that 20% of the clonal populations (19/97) had an apparent diploid DNA content, 35% (34/97) had an apparent tetraploid DNA content, and the remainder were mixed populations of diploid and tetraploid cells. No aneuploid populations were observed. Diploid tsSV40 transformed cells always give rise to a population of cells with a tetraploid DNA content when continuously cultured at the permissive temperature. The doubling of DNA content can be vastly accelerated by the sudden reintroduction of large T antigen activity following a shift from non-permissive to permissive temperature. Tetraploid tsSV40 transfected cells have a lower capacity for anchorage-independent growth and earlier entry into 'crisis' than diploid cells. These results indicate that during the pre-crisis, extended lifespan phase of growth, the SV40 large T antigen causes a doubling of DNA content. This apparent doubling of DNA content does not confer growth advantage during the extended lifespan that precedes 'crisis'.     

Role of telomeres and telomerase in cancer

There is mounting evidence for the existence of an important relationship between telomeres and telomerase and cellular aging and cancer. Normal human cells progressively lose telomeres with each cell division until a few short telomeres become uncapped leading to a growth arrest known as replicative aging. In the absence of genomic alterations these cells do not die but remain quiescent producing a different constellation of proteins compared to young quiescent cells. Upon specific genetic and epigenetic alterations, normal human cells bypass replicative senescence and continue to proliferate until many telomere ends become uncapped leading to a phenomenon known as crisis. In crisis cells have critically shortened telomeres but continue to attempt to divide leading to significant cell death (apoptosis) and progressive genomic instability. Rarely, a human cell escapes crisis and these cells almost universally express the ribonucleoprotein, telomerase, and maintain stable but short telomeres. The activation of telomerase may be thought of as a mechanism to slow down the rate genomic instability due to dysfunctional telomeres. While telomerase does not drive the oncogenic process, it is permissive and required for the sustain growth of most advanced cancers. Since telomerase is not expressed in most normal human cells, this has led to the development of targeted telomerase cancer therapeutic approaches that are presently in advanced clinical trials.     

High levels of telomere dysfunction bestow a selective disadvantage during the progression of human oral squamous cell carcinoma

Human epithelial cells experience multiple barriers to cellular immortality in culture (mortality mechanisms 0, 1, and 2). Mortality mechanism 2 (M2) is termed crisis and involves telomere dysfunction due to lack of telomerase. However, proliferating normal keratinocytes in vivo can express telomerase, so it is unclear whether human squamous cell carcinomas (SCCs), which usually have high telomerase levels, develop from preexisting telomerase-positive precursors or by the activation of telomerase in telomerase-deficient somatic cells. We show that 6 of 29 oral SCCs show characteristics of M2 crisis in vivo, as indicated by a high anaphase bridge index (ABI), which is a good correlate of telomere dysfunction, and that 25 of 29 tumors possess some anaphase bridges. ABIs in excess of 0.2 in the primary tumor showed a decrease in the corresponding lymph node metastases. This suggests that high levels of telomere dysfunction (>0.2) and, by inference, M2 crisis bestow a selective disadvantage on SCCs during progression stages of the disease. Supporting this, SCCs with high levels of telomere dysfunction grow poorly in culture, and the ectopic expression of telomerase corrects this, together with other features of M2 crisis. Our data suggest that a substantial proportion of oral SCCs in vivo ultimately arise from telomerase-deficient keratinocytes rather than putative telomerase-proficient cells in the undifferentiated parts of the epithelium. Furthermore, the presence of significant levels of telomere dysfunction in a high proportion of SCCs at diagnosis but not in the normal epithelium implies that the therapeutic inhibition of telomerase should selectively compromise the growth of such tumors.     

Role of BRCA1 in controlling mitotic arrest in ovarian cystadenoma cells

Cancers that develop in BRCA1 mutation carriers are usually near tetraploid/polyploid. This led us to hypothesize that BRCA1 controls the mitotic checkpoint complex, as loss of such control could lead to mitotic errors resulting in tetraploidy/polyploidy and subsequent aneuploidy. We used an in vitro system mimicking premalignant conditions, consisting of cell strains derived from the benign counterparts of serous ovarian carcinomas (cystadenomas) and expressing SV40 large T antigen, conferring the equivalent of a p53 mutation. We previously showed that such cells undergo one or several doublings of their DNA content, as they age in culture and approach the phenomenon of in vitro crisis. Here, we show that such increase in DNA content reflects a cell cycle arrest possibly at the anaphase promoting complex, as evidenced by decreased BrdU incorporation and increased expression of the mitotic checkpoint complex. Down-regulation of BRCA1 in cells undergoing crisis leads to activation of the anaphase promoting complex and resumption of growth kinetics similar to those seen in cells before they reach crisis. Cells recovering from crisis after BRCA1 down-regulation become multinucleated, suggesting that reduced BRCA1 expression may lead to initiation of a new cell cycle without completion of cytokinesis. This is the first demonstration that BRCA1 controls a physiological arrest at the M phase apart from its established role in DNA damage response, a role that could represent an important mechanism for acquisition of aneuploidy during tumor development. This may be particularly relevant to cancers that have a near tetraploid/polyploid number of chromosomes.     

A telomere-independent senescence mechanism is the sole barrier to Syrian hamster cell immortalization

Reactivation of telomerase and stabilization of telomeres occur simultaneously during human cell immortalization in vitro and the vast majority of human cancers possess high levels of telomerase activity. Telomerase repression in human somatic cells may therefore have evolved as a powerful resistance mechanism against immortalization, clonal evolution and malignant progression. The comparative ease with which rodent cells immortalize in vitro suggests that they have less stringent controls over replicative senescence than human cells. Here, we report that Syrian hamster dermal fibroblasts possess substantial levels of telomerase activity throughout their culture life-span, even after growth arrest in senescence. In our studies, telomerase was also detected in uncultured newborn hamster skin, in several adult tissues, and in cultured fibroblasts induced to enter the post-mitotic state irreversibly by serum withdrawal. Transfection of near-senescent dermal fibroblasts with a selectable plasmid vector expressing the SV40 T-antigen gene resulted in high-frequency single-step immortalization without the crisis typically observed during the immortalization of human cells. Collectively, these data provide an explanation for the increased susceptibility of rodent cells to immortalization (and malignant transformation) compared with their human equivalents, and provide evidence for a novel, growth factor-sensitive, mammalian senescence mechanism unrelated to telomere maintenance.     

Telomerase and human tumorigenesis

Human cancer cells, unlike their normal counterparts, have shed the molecular restraints to limited cell growth and are immortal. Exactly how cancer cells manage this at the molecular level is beginning to be understood. Human cells must overcome two barriers to cellular proliferation. The first barrier, referred to as senescence, minimally involves the p53 and Rb tumor-suppressor pathways. Inactivation of these pathways results in some extension of lifespan. However, inactivation of these pathways is insufficient for immortalization. As normal cells undergo repeated rounds of DNA replication, their telomeres shorten due to the inability of traditional DNA polymerases to completely replicate the end of the chromosomal DNA. This shortening continues until the cells reach a second proliferative block referred to as crisis, which is characterized by chromosomal instability, end-to-end fusions, and cell death. Stabilization of the telomeric DNA through either telomerase activation or the activation of the alternative mechanism of telomere maintenance (ALT) is essential if the cells are to survive and proliferate indefinitely. Conversely, loss of telomere stabilization by an already-immortalized cell results in loss of immortality and cell death. Together this indicates that telomere maintenance is a critical component of immortality. In this review we attempt to describe our current understanding of the role of telomere maintenance in senescence, crisis, and tumorigenesis.     

Selective ability of S-phase cell extracts to dephosphorylate SV40 large T antigen in vitro.

Simian virus 40 (SV40) large tumor antigen (T) is an oncoprotein whose biological and biochemical functions appear to be modulated by phosphorylation. Recently, SV40 DNA replication in vitro has been shown to be activated by dephosphorylation involving the activity of a serine/threonine phosphoprotein phosphatase belonging to the type 2A class (PP2A) [Virshup, D.M., Kauffman, M.G. & Kelly, T.J. (1989) EMBO J., 8, 3891-3898]. To address the question of how specificity of PP2A activity towards T is regulated, an in vitro assay to study the process of T dephosphorylation was developed. Unlabeled extracts from cells enriched for various stages of the cell cycle were incubated with 32P-labeled, immunocomplexed T. Extracts from a population of cells enriched for S phase demonstrated a selective ability to dephosphorylate this labeled protein when compared with extracts prepared from G1- and M-phase cells. The time course of release from growth arrest demonstrated that this T-specific phosphatase activity occurred at the onset of host-cell DNA synthesis. In contrast, when using 32P-labeled phosphorylase a as the substrate, phosphatase activity appeared to be present throughout the cell cycle. The data presented here are consistent with the notion that PP2A activity towards T is regulated in a cell cycle-dependent manner.     

Telomerase activation during the linear evolution of human fibroblasts to tumorigenicity in nude mice

The ribonucleoprotein enzyme telomerase is active in most immortalcell lines, most tumors and all tumor-derived cell lines. Theenzyme is important because it prevents continual shorteningof telomeres and therefore plays a significant role in chromosomemaintenance. In man, telomerase is not active in most somaIcells with finite lifespans. Using the SV40 T antigen we immortalizedand transformed to fully tumorigenic a human fibroblast cellstrain. We wished to determine when telomerase was activatedduring this progression to tumorigenicity. Using the PCR-basedTRAP assay we found that eight of eight immortal cell linesthat were either not tumorigenic or rarely formed tumors weretelomerase positive at the time of inoculation. Additionally,10 of 11 newly immortal cell lines contained telomerase activitywithin the first 25–33 population doublings after crisis.None of the precrisis cells from which these immortal cellswere derived were positive for telomerase activity. Thus wefound that telomerase activation is not the final in vivo stepin the transformation of these cells and the window of activationis usually near the escape from crisis or M2. These resultsstrengthen the hypothesis that telomerase activation may allowthe rare cell to escape from crisis in those immortal cell populationsdependent on telomerase for telomere maintenance.     

Neoplastic conversion of human colon smooth muscle cells: No requirement for telomerase

The role of telomerase as an essential requirement for the neoplastic conversion of human cells has been controversial. In the model of conversion of normal human cells to cancer cells by the combination of simian virus 40 (SV40) early region genes and oncogenic Ras (H-Ras(G12V)), telomerase (hTERT) was originally described as essential in conjunction with these other genes. Here we used primary cultures of colon smooth muscle cells isolated from surgical specimens. SV40 large T antigen (TAg) and oncogenic Ras(G12V) were introduced into the cells by retroviral transduction and cells were rapidly transplanted into the subrenal capsule space in immunodeficient mice, without selection in culture. Malignant tumors were formed from transduced cells. Extensive invasion into the kidney occurred even when tumors were small; in contrast, at the same tumor size, oncogene-expressing fibroblasts did not show much invasion. Increased invasiveness was also observed in vitro. However, cells in these cancers showed morphological evidence of crisis, consistent with their lack of telomerase. These experiments on human colon smooth muscle cells support the concept that Ras(G12V) and SV40 TAg form a minimal set of genes that can convert normal human cells to cancer cells without a requirement for hTERT.     

Variation in the loss of O6-methylguanine-DNA methyltransferase during immortalization of human fibroblasts

We have examined O6-methylguanine-DNA methyltransferase (MT) activity in four human fibroblast cell lines during immortalization. Transfection of primary fibroblasts with the plasmid pSV3gpt or pSV3neo, which encode the SV40 large T antigen, confers a transformed phenotype but not immediate immortality. After a period of growth (pre-crisis) the cells enter a quiescent phase (crisis) from which an immortal clone of cells eventually grows out. From measurements of MT activity in extracts of cells taken at different defined stages of the immortalization process, we conclude that the establishment of a Mex- (MT-deficient) cell population is not specifically associated with cellular transformation or with any particular stage of immortalization. It appears that in different cell populations the change from Mex+ to Mex- may occur at different times during the immortalization process and that the change may be very abrupt.     

食管黏膜脱落细胞DNA倍体和端粒酶活性检测对食管癌诊断的价值

目的 :探讨胃镜直视下刷取食管病灶处的黏膜细胞的端粒酶活性及DNA倍体分析对食管良恶性疾病的鉴别诊断价值 ,能否为大规模开展食管拉网细胞进行分子生物水平普查食管癌奠定基础。方法 :采用TRAP PCR银染定性法对78例食管黏膜脱落细胞进行端粒酶活性分析 ,同时进行流式细胞DNA倍体分析 ,经病理组织学证实食管癌 45例 ,食管良性疾病 3 3例。结果 :端粒酶活性在食管癌组中的阳性率为 88 89% ( 4 0 /4 5 )明显高于食管良性疾病组的 9 0 9% ( 3 /3 3 ) ,食管癌组的黏膜脱落细胞DNA倍体的阳性率为77 78% ( 3 5 /4 5 )明显高于食管良性疾病组的3 0 3 % ( 1/3 3 ) ,食管癌组中端粒酶活性和DNA倍体分析同时阳性为 71 11% ( 3 2 /4 5 ) ,食管良性疾病组中端粒酶活性和DNA倍体分析同时阳性为 0 ( 0 /3 3 ) ,端粒酶活性联合DNA倍体分析对食管癌的诊断率为 95 5 6% ( 4 3 /4 5 ) ,端粒酶活性联合DNA倍体分析区别食管病变良恶性的敏感度为 95 5 6% ( 4 3 /4 5 )、特异度为 10 0 0 0 % ( 3 3 /3 3 )。结论 :食管黏膜脱落细胞DNA倍体分析联合端粒酶活性测定是诊断食管癌特异而敏感的方法 ,为大规模开展食管拉网细胞进行分子生物水平普查食管癌奠定基础     

SV40 large T antigen-transformed human primary normal and cancerous mammary epithelial cells are phenotypically similar but can be distinguished in 3D culture with selection medium

Human normal mammary epithelial cells (NMECs) have 2 major in vitro growth restrictions, senescence and crisis. Cellular immortalization is considered a hallmark of malignancy. However, cancerous mammary epithelial cells (CMECs) that are thought to have passed growth barriers in vivo usually cannot be established long-term in vitro. Here we show that CMECs deprived of their natural environment and grown in conventional complete medium behave similar to NMECs, e.g., they stop producing telomerase and become senescent. Like NMECs, CMECs are rescued by SV40 large T (LT) from senescence but not from crisis. The telomere length of both LT-transformed NMEC (N-LT) and CMEC (C-LT) cells first shortens but later partially recovers after telomerase activation. Both cell types upregulate ErbB2 expression, acquire genetic changes, remain long-term dependent on LT and ErbB2 and are nontumorigenic. Despite these similarities, N-LT and C-LT cells cultured in selection medium show different growth characteristics in 3D culture and in vivo tumorigenesis. Thus, CMECs are under a comparable in vitro selective pressure in conventional monolayer culture as NMECs despite their in vivo malignancy. This data demonstrate that most primary breast cancer cells are still unable to overcome the in vitro growth restrictions and suggest that the relationship of in vitro immortalization and in vivo carcinogenesis should be re-evaluated.     

Altered phosphorylation at specific sites confers a mutant phenotype to SV40 wild-type large T antigen in a flat revertant of SV40-transformed cells

The Rev2 cell line is a cellular revertant of the SV40 wild-type transformed rat cell line SV-52 [Bauer, M., Guhl, E., Graessmann, M. & Graessmann, A. (1987). J. Virol., 61, 1821-1827]. To characterize the level of cellular interference with the SV40 large T antigen (large T)-induced transformation pathway in Rev2 cells, we analysed the biological and biochemical properties of large T expressed in Rev2 cells. We found that Rev2 cells encoded an authentic wild-type large T, with regard to its sequence and its transforming functions. No differences were found in the metabolic stability of large T, or in complex formation with the cellular p53 protein, or in p53 metabolic stabilization. In contrast to SV-52 cells, Rev2 cells showed no association of large T with the chromatin fraction of isolated nuclei. This difference correlated with a reduced affinity of the Rev2 large T to SV40 DNA in vitro. The T proteins from both cell lines were phosphorylated at the same multiple sites. However, in Rev2 cells the phosphorylation of large T at specific serine -residues was significantly reduced. Thus the revertant phenotype of Rev2 cells may be due to an altered phosphorylation state of its large T protein, leading to altered nuclear localization and reduced transforming activity. The alterations of Rev2 large T properties and phosphorylation were very similar to the changes observed with mutant large T in FR(tsA58)A cells, an SV40 tsA58 N-type transformant, when the cells had reverted to the normal phenotype at the non-permissive growth temperature. Thus altered phosphorylation might provide a common structural basis for the biological inactivation of the large T proteins in these cells.     

Functional similarity between HPV16E7, SV40 large T and adenovirus E1a proteins

We have analysed the immortalizing function of Human Papillomavirus type 16 (HPV16) in a rat cell line which has been derived by immortalizing rat embryo fibroblasts with a thermolabile SV40 large T antigen and is temperature sensitive for growth. Introduction of wild type SV40 large T antigen or the adenovirus E1a 12s gene product has previously been shown to readily overcome the inability of these cells to divide at the non-permissive temperature. In contrast, the introduction of myc, another known immortalizing gene, cannot complement the growth defect of these cells. This cell line therefore provides a novel assay system which can distinguish two groups of immortalizing oncogenes. We have shown here that expression of HPV16 can readily complement the growth defect in this rat cell line and that this function can be genetically localised to E7. Cells expressing HPV16 E6 sequences are also weakly rescued from growth arrest at the non-permissive temperature. These results demonstrate a functional similarity between HPV16 E7, SV40 large T and adenovirus E1a and suggest that these genes may immortalize cells by a common mechanism. Interestingly, the limited sequence homology between these three gene products is restricted to the domain which has recently been implicated in binding the retinoblastoma gene product.     

Multiple stages of malignant transformation of human endothelial cells modelled by co-expression of telomerase reverse transcriptase,SV40 T antigen and oncogenic N-ras

We have modelled multiple stages of malignant transformation of human endothelial cells (ECs) by overexpressing the catalytic subunit of human telomerase (hTERT), together with SV40 T antigen (SV40T) and oncogenic N-ras. Transfection with hTERT alone, led to the immortalization of two out of three cultures of bone marrow-derived ECs (BMECs). One hTERT transduced BMEC culture underwent a long proliferative lag before resuming proliferation. BMECs transfected with hTERT alone were functionally and phenotypically normal. BMECs transfected with SV40T (BMSVTs) had an extended lifespan, but eventually succumbed to crisis. BMSVTs exhibited a partially transformed phenotype, demonstrating growth factor independence, altered antigen expression and forming tiny, infrequent colonies in vitro. Transduction of BMSVTs with hTERT resulted in immortalization of 4 out of 4 cultures. BMSVTs immortalized with hTERT formed large colonies in vitro and small transient tumours in vivo. BMECs co-expressing SV40T, hTERT and N-ras exhibited an overtly transformed phenotype; forming very large colonies with an altered morphology and generating rapidly growing tumours in vivo. These investigations demonstrate transformation of human ECs to an overtly malignant phenotype. This model will be useful for understanding mechanisms underlying vascular and angiogenic neoplasias, as well as for testing drugs designed to curtail aberrant EC growth.