David Wynford-Thomas

Extensive allelic variation and ultrashort telomeres in senescent human cells

By imposing a limit on the proliferative lifespan of most somatic cells, telomere erosion represents an innate mechanism for tumor suppression and may contribute to age-related disease. A detailed understanding of the pathways that link shortened telomeres to replicative senescence has been severely hindered by the inability of current methods to analyze telomere dynamics in detail. Here we describe single telomere length analysis (STELA), a PCR-based approach that accurately measures the full spectrum of telomere lengths from individual chromosomes. STELA analysis of human XpYp telomeres in fibroblasts identifies several features of telomere biology. We observe bimodal distributions of telomeres in normal fibroblasts; these distributions result from inter-allelic differences of up to 6.5 kb, indicating that unexpectedly large-scale differences in zygotic telomere length are maintained throughout development. Most telomeres shorten in a gradual fashion consistent with simple losses through end replication, and the rates of erosion are independent of allele size. Superimposed on this are occasional, more substantial changes in length, which may be the consequence of additional mutational mechanisms. Notably, some alleles show almost complete loss of TTAGGG repeats at senescence.

Telomerase prevents the accelerated cell ageing of Werner syndrome fibroblasts.

Werner syndrome (WS) is a rare disorder inherited in an autosomal recessive manner and characterized by accelerated ageing. WS fibroblasts display an accelerated rate of senescence in vitro, which has been linked to this progeroid phenotype. The senescence of normal human fibroblasts is triggered by telomere shortening, whereas the premature senescence of WS fibroblasts has been assumed to reflect the accumulation of DNA damage. Here we show that forced expression of telomerase in WS confers extended cellular lifespan and probable immortality.

Cellular senescence and cancer

The proliferative lifespan of normal mammalian cells is limited by intrinsic controls, which desensitize the cell‐cycle machinery to extrinsic stimulation after a given number of cell divisions. One underlying clock driving this process of ‘replicative senescence’ is the progressive erosion of chromosome telomeres, which occurs with each round of DNA replication. This appears to trigger growth inhibition via activation of the tumour suppressor gene (TSG) product, p53, and the consequent up‐regulation of the cell‐cycle inhibitor p21WAF1. Other inhibitory pathways are also activated (possibly by additional clocks), including the TSG p16INK4a and the less well‐defined complementation group genes. Loss of one pathway can be compensated, after a limited extension of lifespan, by further up‐regulation of the others, so that to escape mortality a developing tumour must overcome multiple ‘proliferative lifespan barriers’ (PLBs) by successive genetic events, each conferring a new wave of clonal expansion. This provides one explanation for the existence of multiple genetic abnormalities in human cancers; furthermore, the diversity in the nature and timing of these PLBs between different cell types may explain the variation in the spectrum of abnormalities observed between the corresponding cancers. Even if all senescence pathways are inactivated, immortalization can only be achieved if erosion of telomeres is halted, before their end‐protecting function is lost. This usually requires either activation of telomerase during tumour development, if the cell of origin is telomerase‐negative, or up‐regulation if the normal cell already has some activity, but not enough to prevent erosion. In either case, cancers often maintain near‐critical telomere lengths; hence pharmacological inhibition of telomerase remains an attractive approach to the selective killing of tumour cells. Copyright

Posttranslational Modifications of p53 in Replicative Senescence Overlapping but Distinct from Those Induced by DNA Damage

ABSTRACT Replicative senescence in human fibroblasts is absolutely dependent on the function of the phosphoprotein p53 and correlates with activation of p53-dependent transcription. However, no evidence for posttranslational modification of p53 in senescence has been presented, raising the possibility that changes in transcriptional activity result from upregulation of a coactivator. Using a series of antibodies with phosphorylation-sensitive epitopes, we now show that senescence is associated with major changes at putative regulatory sites in the N and C termini of p53 consistent with increased phosphorylation at serine-15, threonine-18, and serine-376 and decreased phosphorylation at serine-392. Ionizing and UV radiation generated overlapping but distinct profiles of response, with increased serine-15 phosphorylation being the only common change. These results support a direct role for p53 in signaling replicative senescence and are consistent with the generation by telomere erosion of a signal which shares some but not all of the features of DNA double-strand breaks.

DNA damage checkpoint kinase Chk2 triggers replicative senescence.

Telomere shortening in normal human cells causes replicative senescence, a p53‐dependent growth arrest state, which is thought to represent an innate defence against tumour progression. However, although it has been postulated that critical telomere loss generates a ‘DNA damage’ signal, the signalling pathway(s) that alerts cells to short dysfunctional telomeres remains only partially defined. We show that senescence in human fibroblasts is associated with focal accumulation of γ‐H2AX and phosphorylation of Chk2, known mediators of the ataxia‐telangiectasia mutated regulated signalling pathway activated by DNA double‐strand breaks. Both these responses increased in cells grown beyond senescence through inactivation of p53 and pRb, indicating that they are driven by continued cell division and not a consequence of senescence. γ‐H2AX (though not Chk2) was shown to associate directly with telomeric DNA. Furthermore, inactivation of Chk2 in human fibroblasts led to a fall in p21waf1 expression and an extension of proliferative lifespan, consistent with failure to activate p53. Thus, Chk2 forms an essential component of a common pathway signalling cell cycle arrest in response to both telomere erosion and DNA damage.

Reinitiation of DNA Synthesis and Cell Division in Senescent Human Fibroblasts by Microinjection of Anti-p53 Antibodies

ABSTRACT In human fibroblasts, growth arrest at the end of the normal proliferative life span (induction of senescence) is dependent on the activity of the tumor suppressor protein p53. In contrast, once senescence has been established, it is generally accepted that reinitiation of DNA synthesis requires loss of multiple suppressor pathways, for example, by expression of Simian virus 40 (SV40) large T antigen, and that even this will not induce complete cell cycle traverse. Here we have used microinjection of monoclonal antibodies to the N terminus of p53, PAb1801 and DO-1, to reinvestigate the effect of blocking p53 function in senescent human fibroblasts. Unexpectedly, we found that both antibodies induce senescent cells to reenter S phase almost as efficiently as SV40, accompanied by a reversion to the “young” morphology. Furthermore, this is followed by completion of the cell division cycle, as shown by the appearance of mitoses, and by a four- to fivefold increase in cell number 9 days after injection. Immunofluorescence analysis showed that expression of the p53-inducible cyclin/kinase inhibitor p21 sdi1/WAF1 was greatly diminished by targeting p53 with either PAb1801 or DO-1 but remained high and, moreover, still p53 dependent in cells expressing SV40 T antigen. As previously observed for induction, the maintenance of fibroblast senescence therefore appears to be critically dependent on functional p53. We suggest that the previous failure to observe this by using SV40 T-antigen mutants to target p53 was most probably due to incomplete abrogation of p53 function.

Sporadic ret‐rearranged papillary carcinoma of the thyroid: a subset of slow growing, less aggressive thyroid neoplasms?

Despite the large amount of information accumulated on the role played by ret activation in the oncogenesis of papillary thyroid carcinoma (PTC), the biological and clinical significance of such activation ‘in vivo’ remains controversial. The aim of this study was to address some of the existing controversies by comparing two groups of unselected PTCs, one with and the other without ret rearrangement, with regard to several clinicopathological and biological features. Thirty‐three PTCs were selected at random. ret rearrangement was found in eight cases (24·2 per cent) using Southern blot analysis. The mean age of the patients with tumours displaying ret rearrangement (28±3·1 years) was significantly lower than that of the patients harbouring cases that did not present rearrangement (45±2·9 years). The large majority of the tumours with ret rearrangement displayed a papillary or mixed follicular–papillary pattern and very low proliferative activity. ret rearrangement correlated significantly with decreased cytoplasmic expression of E‐cadherin. No significant differences were found regarding the gender of the patients, tumour size, multicentricity, extrathyroidal growth, vascular invasion, lymphocytic infiltration, lymph node involvement or the expression of E‐cadherin (membrane), c‐erb‐B2, c‐met, Bcl‐2, and vimentin. It is proposed that sporadic PTCs harbouring a ret rearrangement occur frequently as slow growing, papillary, or predominantly papillary tumours that do not usually progress towards less differentiated neoplasms representing what might be described as a Bonsai phenotype.

Papillary Thyroid Carcinoma Oncogene (RET/PTC) Alters the Nuclear Envelope and Chromatin Structure

Current evidence suggests the papillary thyroid carcinoma oncogene (RET/PTC) generates papillary thyroid carcinomas in one genetic step. We tested a resulting prediction that RET/PTC expression in thyroid epithelium should be sufficient to cause the changes in nuclear morphology diagnostic of this tumor. Primary cultures of human thyroid epithelial cells were infected with a RET/PTC retroviral construct. Morphological scoring by two independent cytopathologists shows RET/PTC expression by immunohistochemistry to be highly associated (p << 0.0001) with an irregular nuclear contour and a euchromatic appearance compared with non-expressing cells in the same cultures. The altered nuclear morphology is not due to gene transfer or transformation per se as primary thyroid cell cultures infected with a retroviral H-RAS construct differ from RET/PTC-infected cells by showing round nuclear envelopes and coarser chromatin, as determined by the independent scoring of two cytopathologists (p << 0.0001). In addition, RET/ PTC-transfected cells appear to disperse, whereas RAS-transfected cells grow as discrete colonies. The results provide additional support for the hypothesis that RET/PTC is sufficient to cause papillary thyroid carcinomas. A signaling pathway downstream of RET/ PTC leads to restructuring of the nuclear envelope and chromatin, and the signal does not depend entirely, if at all, on a RAS pathway.

Characterisation of human thyroid epithelial cells immortalised in vitro by simian virus 40 DNA transfection

Human primary thyroid follicular epithelial cells were transfected with a plasmid containing an origin-defective SV40 genome (SVori-) to produce several immortal cell lines. Two of the 10 cell lines analysed expressed specific features of thyroid epithelial function (iodide-trapping and thyroglobulin production). These two lines were characterised in detail and found to be growth factor-independent, capable of anchorage-independent growth at low frequency but non-tumorigenic in nude mice. These differentiated, These differentiated, partially transformed cell lines were shown to be suitable for gene transfer at high frequency using simple coprecipitation techniques.

Use of Bromodeoxyuridine For Cell Kinetic Studies In Intact Animals

Abstract. A method is described for the use of BUdR for tracing cell proliferation patterns in the intestinal mucosa of intact mice.