BRCA1 knock-down causes telomere dysfunction in mammary epithelial cells.

A breast cancer predisposing gene, BRCA1, is a major suppressor of chromosomal instability and its dysfunction affects multiple pathways involved in DNA damage response. There is increasing evidence that the mechanisms involved in maintenance of telomeres, specialized structures at chromosome ends, are linked with DNA damage response. We therefore investigated whether BRCA1 dysfunction affects telomere maintenance. To achieve this we knocked-down BRCA1 in two mammary epithelial cell lines using RNA interference. Subsequent analysis by immunofluorescence, RT-PCR and Western blotting revealed that a short interfering RNA oligonucleotide used was able to knock-down BRCA1 efficiently. This knock-down did not have any effect on telomerase enzyme activity and telomere length. However, BRCA1 knock-down correlated with the increase in chromatin bridges in anaphase cells which usually reflect telomere dysfunction. Therefore, this study suggests that BRCA1 knockdown in mammary epithelial cells causes telomere dysfunction.

Effects of hTERT on metal ion-induced genomic instability.

There is currently a great interest in delayed chromosomal and other damaging effects of low-dose exposure to a variety of pollutants which appear collectively to act through induction of stress-response pathways related to oxidative stress and ageing. These have been studied mostly in the radiation field but evidence is accumulating that the mechanisms can also be triggered by chemicals, especially heavy metals. Humans are exposed to metals, including chromium (Cr) (VI) and vanadium (V) (V), from the environment, industry and surgical implants. Thus, the impact of low-dose stress responses may be larger than expected from individual toxicity projections. In this study, a short (24 h) exposure of human fibroblasts to low doses of Cr (VI) and V (V) caused both acute chromosome damage and genomic instability in the progeny of exposed cells for at least 30 days after exposure. Acutely, Cr (VI) caused chromatid breaks without aneuploidy while V (V) caused aneuploidy without chromatid breaks. The longer-term genomic instability was similar but depended on hTERT positivity. In telomerase-negative hTERT- cells, Cr (VI) and V (V) caused a long lasting and transmissible induction of dicentric chromosomes, nucleoplasmic bridges, micronuclei and aneuploidy. There was also a long term and transmissible reduction of clonogenic survival, with an increased beta-galactosidase staining and apoptosis. This instability was not present in telomerase-positive hTERT+ cells. In contrast, in hTERT+ cells the metals caused a persistent induction of tetraploidy, which was not noted in hTERT- cells. The growth and survival of both metal-exposed hTERT+ and hTERT- cells differed if they were cultured at subconfluent levels or plated out as colonies. Genomic instability is considered to be a driving force towards cancer. This study suggests that the type of genomic instability in human cells may depend critically on whether they are telomerase-positive or -negative and that their sensitivities to metals could depend on whether they are clustered or diffuse.

Accelerated telomere shortening and telomere abnormalities in radiosensitive cell lines.

We examined telomere maintenance in cells of 11 primary fibroblast cell lines with differing genetic defects that confer sensitivity to ionizing radiation. These included cell lines derived from patients with ataxia telangiectasia, Nijmegen breakage syndrome, Fanconi anemia, defective Artemis, DNA ligase I and DNA ligase IV, an immunodeficient patient with a defect in DNA double-strand break repair, and a patient diagnosed with xeroderma pigmentosum who, in addition, showed severe clinical sensitivity to ionizing radiation. Our results, based on Southern blot, flow-FISH and Q-FISH (quantitative FISH) measurements, revealed an accelerated rate of telomere shortening in most cell lines derived from the above patients compared to cell lines from normal individuals or a cell line isolated from a heterozygotic parent of one radiosensitive patient. This accelerated telomere shortening was accompanied by the formation of chromatin bridges in anaphase cells, indicative of the early loss of telomere capping function and in some cases low levels of chromosome abnormalities in metaphase cells. We also analyzed telomere maintenance in mouse embryonic stem cells deficient in Brca1, another defect that confers radiosensitivity. Similarly, these cells showed accelerated telomere shortening and mild telomere dysfunction in comparison to control cells. Our results suggest that mechanisms that confer sensitivity to ionizing radiation may be linked with mechanisms that cause telomere dysfunction.

Telomerase activity and expression of telomerase reverse transcriptase correlated with cell proliferation in meningiomas and malignant brain tumors in vivo.

Telomerase activity was examined in intracranial tumors and compared with gene expression of the two core components of telomerase--the reverse transcriptase subunit (hTERT) and the RNA subunit (hTR)--and the proliferative index. We investigated 32 tumors across three to five sampled regions (20 meningiomas, 1 acoustic schwannoma, 1 pituitary adenoma, 8 gliomas, and 2 medulloblastomas). Telomerase activity was demonstrated by the telomeric repeat amplification protocol (TRAP) assay in seven (22%) intracranial tumors (four malignant brain tumors, two atypical meningiomas and one ependymoma) but could not be detected in the 18 (100%) benign meningiomas. hTERT and hTR mRNA were detected using reverse-transcription polymerase chain reaction (RT-PCR). hTERT mRNA was present in 20 (63%) intracranial tumors. Whereas hTERT mRNA transcripts were consistently low or absent in meningiomas, malignant brain tumors exhibited elevated hTERT mRNAs. Multiple regions of glioblastomas showed differences in telomerase activity and in the presence of hTERT mRNA. RT-PCR analysis revealed, for the first time in intracranial tumors, the presence of hTERT mRNA spliced products, corresponding to full-length mRNA as well as spliced mRNAs with critical reverse transcriptase motifs deleted. Only tumors with marked telomerase activity showed all hTERT spliced messages simultaneously. The absence of a positive correlation between telomerase activity and hTERT mRNA could not be attributed to the presence of hTERT spliced variants. We found a significant correlation between telomerase activity scores and Ki-67 proliferation index. A positive association is also seen between Ki-67 staining and the degree of hTERT mRNA expression. This shows that there seems to be a relationship between telomerase activity or the degree of hTERT expression and proliferation rate in intracranial tumors.