Telomerase regulation at the crossroads of cell fate.

Telomeres are specialized structures at the ends of eukaryotic chromosomes and are crucial for genome stability, cell growth control and carcinogenesis. Normally, they protect chromosomes from end to end fusion, degradation and recombination. Telomerase is a ribonucleoprotein essential for maintenance of telomeres and it is active in germ cells, stem cells and approximately 90% of cancers but not in most normal somatic cells. Human telomerase catalytic protein subunit hTERT is crucial for telomerase activity. Although hTERT expression is sufficient to immortalize normal human cells in culture, spontaneous immortalization is extremely rare which suggests that its expression is under strong negative control. Characterization of the hTERT promoter has allowed for the analysis of potential mechanisms of hTERT expression and regulation. The hTERT promoter is very complex and contains a great number of canonical and non-canonical sequences that bind or potentially bind a variety of transcription factors. In this review we focus on the positive and negative regulators of hTERT transcription and their role in normal cell growth and immortalization.

Telomere dynamics and genome stability in the human pancreatic tumor cell line MIAPaCa-2.

Telomeres are specialized structures found at the ends of eukaryotic chromosomes serving as guardians of genome stability. In normal cells telomeres shorten with each cell division, but immortal cells undergoing multiple divisions constantly have to maintain telomere lengths above a critical level. This is accomplished either through expression of telomerase or the alternative recombination pathway (ALT). In the present study, we analyzed telomere dynamics of the telomerase positive human pancreatic tumor cell line MIAPaCa-2. The cells demonstrated genomic instability with a high frequency of chromosomal aberrations resulting in differences between individual karyotypes within the same cell population. The telomeres were short when compared with normal human fibroblasts, and about 39% of the chromosome ends did not have detectable telomere repeats as demonstrated by PNA-FISH. In many cases telomere signals were missing even when sister chromatids were strongly labeled. In addition, we used an internal PNA probe specific for the X chromosome, present in a single copy in these cells, in order to follow telomere dynamics on individual chromatids. High heterogeneity in telomere signals among individual X chromosomes as well as between their sister chromatids suggested sudden and stochastic loss or gain of telomere repeats. Such constant genomic instability often results in apoptosis and death of a fraction of cells present in the culture at all times. We discuss possible molecular mechanisms that may explain this observed telomere heterogeneity and possible adaptive repair mechanisms by which these cells maintain their chromosomes in order to survive such extreme and permanent genomic instability.

Telomere dynamics: the means to an end.

Telomeres are among the most important structures in eukaryotic cells. Creating the physical ends of linear chromosomes, they play a crucial role in maintaining genome stability, control of cell division, cell growth and senescence. In vertebrates, telomeres consist of G-rich repetitive DNA sequences (TTAGGG)n and specific proteins, creating a specialized structure called the telosome that through mutual interactions with many other factors in the cell give rise to dynamic regulation of chromosome maintenance. In this review, we survey the structural and mechanistic aspects of telomere length regulation and how these processes lead to alterations in normal and immortal cell growth.

Spontaneous senescence in the MDA-MB-231 cell line.

Normal human somatic cells have a limited division potential when they grow in vitro. It is believed that shortening of telomeres, specialized structures at the ends of chromosomes, controls cell growth. When one telomere achieves a critical minimal length, the cell cycle control mechanism recognizes it as DNA damage and causes the cell's exit from the cycle in G1-phase. Because it is not possible to extend telomeres in normal cells, this non-dividing state is prolonged indefinitely, and is known as cellular senescence. The immortal cell line MDA-MB-231 has active telomerase, which prevents telomere shortening and allows cells' permanent divisions. However, there is a fraction of cells that do not divide over several days in culture as documented for some other tumour cell lines. Combination of methods has made it possible to isolate these non-growing cells and compare them with the fraction of fast-growing cells from the same culture. Although the non-growing fraction contains a significant percentage of typical senescent cells, both fractions have equal telomerase activity and telomere length. In this paper we discuss possible mechanisms that cause the appearance of this non-growing fraction of cells in cultures of MDA-MB-231, which indicate stress and genome instability rather than variation in telomerase activity or telomere shortening to affect individual cells.

Sudden senescence syndrome plays a major role in cell culture proliferation.

Normal human cells of various types have a finite and predictable proliferative potential in vitro. This limited life span is due to a gradually increasing fraction of senescent cells that appear in the culture in a sudden and stochastic fashion due to a phenomenon referred to as sudden senescence syndrome (SSS). Because nondividing cells increasingly accumulate in the culture, dividing cells have to compensate for nondividers in order to accomplish additional population doubling (PD). Thus, individual dividing cells undergo more divisions, called cell generations (CG), than the number of PDs. Based on integrated experimental data, we calculated maximum CG for normal human diploid fibroblasts (HDF). It appears that for a HDF culture that undergoes 65 PD, the calculated final CG is at least 126. Based on the obtained value for CG we calculated the total size of the culture, both with and without effect of SSS. If no SSS takes place and cells divide by geometrical progression, the culture will grow up to 2(126) or 10(38) cells. By constantly eliminating cells from further divisions, causing cell loss (CL), SSS reduces the total size of the culture at every point during its proliferation. The calculated value for CL is enormous, so that the culture of 10(38) cells is reduced to only 10(19) cells, thus as little as 10(-17)% of its size! Accordingly, by preventing virtually every cell in the culture from reaching its original maximum doubling capacity, SSS appears to be the most important mechanism that influences cell culture proliferation.

Stochastic mechanism of cellular aging--abrupt telomere shortening as a model for stochastic nature of cellular aging.

A strong stochastic component has been described for the appearance of senescent cells in cultures that have not completed their in vitro lifespan. The proliferative potential of individual clones show a bimodal distribution. Additionally, two cells arising from a single mitotic event can exhibit large differences in their doubling capacities. In this report we present a model and a computer simulation of the model that explains the observed stochastic phenomena. The model is based on both gradual and abrupt telomere shortening. Gradual telomere shortening (GTS) occurs during each cell division as a consequence of the inability of DNA polymerase to replicate the very ends of chromosomal DNA. It is responsible for the gradual decline in proliferative potential of a cell culture, but does not explain the stochastic aspects of cellular aging. Abrupt telomere shortening (ATS) occurs either through DNA recombination or nuclease digestion at the subtelomeric/telomeric border region of the chromosome. Recombination involves the invasion of a telomere single-strand three-prime protruding end at this border in the telomere of the same chromosome or in another subtelomeric/telomeric region. Shortening of one or more telomeres in the cell causes a sudden onset of cell senescence, referred to as sudden senescence syndrome (SSS). This is manifested as a stochastic and abrupt transition of cells from the larger to the smaller proliferative potential pool and can cause cell cycle arrest within one cell division. The computer simulation matches well with experimental data supporting the prediction that abrupt telomere shortening underlies the stochastic onset of cell senescence. Sudden senescence syndrome appears to be the most important mechanism in the control of the extent of proliferation of a cell culture because it prevents virtually every cell in the culture from reaching its maximum doubling capacity, that would otherwise be allowed by telomere shortening via the end-replication mechanism alone.

Loss of T-antigen sequences allows SV40-transformed human cells in crisis to acquire a senescent-like phenotype.

Normal human cells transfected with SV40 DNA exhibit an extended proliferative potential compared with controls, but they eventually enter a phase known as "crisis." During crisis, extensive cell death occurs and the cells exhibit some gene expression changes similar to senescent cells. This article presents results which indicate that crisis most likely depends on expression of the viral gene T-antigen. We have obtained a unique subpopulation of cells that have deleted the T-antigen gene and, rather than dying as cells do in crisis, remain viable and exhibit some senescent-like characteristics. We also found that the SV40 promoter is poorly expressed in senescent versus young cells. We hypothesize that decreased activity of the viral promoter may result in decreased expression of T-antigen, which is challenged by over-expression of the cell cycle inhibitors such as p21Sdi1. Conflicting signals to proceed/halt cells cycle progression result in the cell death associated with crisis.

A biomarker that identifies senescent human cells in culture and in aging skin in vivo.

Normal somatic cells invariably enter a state of irreversibly arrested growth and altered function after a finite number of divisions. This process, termed replicative senescence, is thought to be a tumor-suppressive mechanism and an underlying cause of aging. There is ample evidence that escape from senescence, or immortality, is important for malignant transformation. By contrast, the role of replicative senescence in organismic aging is controversial. Studies on cells cultured from donors of different ages, genetic backgrounds, or species suggest that senescence occurs in vivo and that organismic lifespan and cell replicative lifespan are under common genetic control. However, senescent cells cannot be distinguished from quiescent or terminally differentiated cells in tissues. Thus, evidence that senescent cells exist and accumulate with age in vivo is lacking. We show that several human cells express a beta-galactosidase, histochemically detectable at pH 6, upon senescence in culture. This marker was expressed by senescent, but not presenescent, fibroblasts and keratinocytes but was absent from quiescent fibroblasts and terminally differentiated keratinocytes. It was also absent from immortal cells but was induced by genetic manipulations that reversed immortality. In skin samples from human donors of different age, there was an age-dependent increase in this marker in dermal fibroblasts and epidermal keratinocytes. This marker provides in situ evidence that senescent cells may exist and accumulate with age in vivo.

SV40-transformed human cells in crisis exhibit changes that occur in normal cellular senescence.

SV40 T antigen can induce senescent human diploid fibroblasts to synthesize DNA; however, the cells fail to go through mitosis. In this study, we examined the expression of the cdc2 and cyclin B genes, which are required for completion of mitosis, to determine whether defects in their expression occurred when SV40-transformed human cells entered the phase of crisis. If defects were observed it would indicate that immortalization by the virus involved reexpression of these genes. We found that the expression of cdc2 was unimpaired at both the RNA and protein levels, but that cyclin B expression was decreased in cells in crisis when compared with precrisis (mortal) and postcrisis (immortal) cells. Tritiated thymidine uptake demonstrated that the majority of cells in crisis were not actively cycling. Consistent with the latter observation we found that cyclin A, which is required for cells to traverse through S to G2, was downregulated in these cells. Since many of the results obtained with cells in crisis were similar to what is observed in normal human cells when they become senescent, we analyzed the expression of the genes fibronectin and sdi1 (a gene recently cloned from senescent cells that codes for an inhibitor of DNA synthesis). Both genes were overexpressed in cells during crisis, as is the case with senescent cells. The results are discussed in terms of the two-stage model previously proposed to explain the process of immortalization of human diploid fibroblasts by SV40.

Evidence for two types of complexes formed by yeast tyrosyl-tRNA synthetase with cognate and non-cognate tRNA. Effect of ribonucleoside triphosphates.

Polyacrylamide gel electrophoresis at pH 8.3 was used to detect and quantitate the formation of the yeast tyrosyl-tRNA synthetase (an alpha 2-type enzyme) complex with its cognate tRNA. Electrophoretic mobility of the complex is intermediate between the free enzyme and free tRNA; picomolar quantities can be readily detected by silver staining and quantitated by densitometry of autoradiograms when [32P]tRNA is used. Two kinds of complexes of Tyr-tRNA synthetase with yeast tRNA(Tyr) were detected. A slower-moving complex is formed at ratios of tRNA(Tyr)/enzyme less than or equal to 0.5; it is assigned the composition tRNA.(alpha 2)2. At higher ratios, a faster-moving complex is formed, approaching saturation at tRNA(Tyr)/enzyme = 1; any excess of tRNA(Tyr) remains unbound. This complex is assigned the composition tRNA.alpha 2. The slower, i.e. tRNA.(alpha 2)2 complex, but not the faster complex, can be formed even with non-cognate tRNAs. Competition experiments show that the affinity of the enzyme towards tRNA(Tyr) is at least 10-fold higher than that for the non-cognate tRNAs. ATP and GTP affect the electrophoretic mobility of the enzyme and prevent the formation of tRNA.(alpha 2)2 complexes both with cognate and non-cognate tRNAs, while neither tyrosine, as the third substrate of Tyr tRNA synthetase, nor AMP, AMP/PPi, or spermidine, have such effects. Hence, the ATP-mediated formation of the alpha 2 structure parallels the increase in specificity of the enzyme towards its cognate tRNA.