Telomerase in the human organism

Collins, Kathleen; Mitchell, James R.

doi:10.1038/sj.onc.1205083

Cited by 553 publications

(440 citation statements)

References 139 publications

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“…Stem cells are capable of generating a very large number of committed progenitors and their descendants during a small number of self-renewal divisions. As such, individual stem cell turnover at any given point would be minimal and the upregulation of telomerase activity in stem cells could be minimal, preventing the generation of overly long telomeres (Collins and Mitchell, 2002). Transient activation of telomerase activity induced during periods of rapid cellular proliferation could reduce telomere loss in lineage-committed progenitor cells.…”

Section: Telomeres and Telomerase In Haematopoietic Stem Cellsmentioning

confidence: 99%

“…During a process of DNA synthesis and cell division, telomeres shorten as a result of the incomplete replication of linear chromosomes, the so-called 'end-replication problem'. This progressive telomere shortening is one of the molecular mechanisms underlying ageing, as critically short telomeres trigger chromosome senescence and loss of cell viability (Collins and Mitchell, 2002;Blasco, 2005;Wright and Shay, 2005). To prevent degradation by exonucleases or processing as damaged DNA, the telomere 3 0 single-strand overhang folds back into the D-loop of duplex telomeric DNA to form a protective 'T-loop', which is reinforced with TRF2 and other telomeric DNA-binding proteins named Shelterin (de Lange, 2005).…”

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confidence: 99%

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Telomere and telomerase in stem cells

2007

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Telomeres, guanine-rich tandem DNA repeats of the chromosomal end, provide chromosomal stability, and cellular replication causes their loss. In somatic cells, the activity of telomerase, a reverse transcriptase that can elongate telomeric repeats, is usually diminished after birth so that the telomere length is gradually shortened with cell divisions, and triggers cellular senescence. In embryonic stem cells, telomerase is activated and maintains telomere length and cellular immortality; however, the level of telomerase activity is low or absent in the majority of stem cells regardless of their proliferative capacity. Thus, even in stem cells, except for embryonal stem cells and cancer stem cells, telomere shortening occurs during replicative ageing, possibly at a slower rate than that in normal somatic cells. Recently, the importance of telomere maintenance in human stem cells has been highlighted by studies on dyskeratosis congenital, which is a genetic disorder in the human telomerase component. The regulation of telomere length and telomerase activity is a complex and dynamic process that is tightly linked to cell cycle regulation in human stem cells. Here we review the role of telomeres and telomerase in the function and capacity of the human stem cells.

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Section: Telomeres and Telomerase In Haematopoietic Stem Cellsmentioning

confidence: 99%

mentioning

confidence: 99%

Telomere and telomerase in stem cells

2007

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“…This hypothesis was investigated in a population-based case -control study of breast cancer study in Poland, in which we genotyped 24 common SNPs that captured most of the common genetic variation in five genes important in telomere biology. The studied genes included telomerase (TERT (protein name), TERT (HUGO gene name), 5p15.33) (Collins and Mitchell, 2002), telomerase-associated protein (TP1, TEP1, 14q11.2) (Poderycki et al, 2005), telomeric repeat-binding factor 1 (TRF1, TERF1, 8q13) (Smogorzewska et al, 2000), telomeric repeat-binding factor 2 (TRF2, TERF2, 16q22.1) (Chong et al, 1995;Broccoli et al, 1997) and protection of telomeres 1 (POT1, POT1, 7q31.33) (Baumann and Cech, 2001). …”

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Genetic variation in five genes important in telomere biology and risk for breast cancer

et al. 2007

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Telomeres, consisting of TTAGGG nucleotide repeats and a protein complex at chromosome ends, are critical for maintaining chromosomal stability. Genomic instability, following telomere crisis, may contribute to breast cancer pathogenesis. Many genes critical in telomere biology have limited nucleotide diversity, thus, single nucleotide polymorphisms (SNPs) in this pathway could contribute to breast cancer risk. In a population-based study of 1995 breast cancer cases and 2296 controls from Poland, 24 SNPs representing common variation in POT1, TEP1, TERF1, TERF2 and TERT were genotyped. We did not identify any significant associations between individual SNPs or haplotypes and breast cancer risk; however, data suggested that three correlated SNPs in TERT (À1381C4T, À244C4T, and Ex2-659G4A) may be associated with reduced risk of breast cancer among individuals with a family history of breast cancer (odds ratios 0.73, 0.66, and 0.57, 95% confidence intervals 0.53 -1.00, 0.46 -0.95 and 0.39 -0.84, respectively). In conclusion, our data do not support substantial overall associations between SNPs in telomere pathway genes and breast cancer risk. Intriguing associations with variants in TERT among women with a family history of breast cancer warrant follow-up in independent studies.

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“…Telomeres are distinctive protein-DNA structures at the end of the chromosomes that are essential for maintaining the integrity and stability of the genome (1)(2)(3). To counteract the loss of telomere repeats with each cell division, germline cells, highly proliferating cells from the skin, the gut and hematopoietic tissues as well as tumor cells express telomerase, an enzyme complex with reverse transcriptase activity, which adds new telomere repeats onto chromosome ends (4,5).…”

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confidence: 99%

Telomere length measurements in leukocyte subsets by automated multicolor flow‐FISH

2003

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Background:Telomeres are essential protein-DNA structures at the end of chromosomes which are implicated in genome stability and cell replication. The average length of telomere repeats can be measured by in situ hybridization and flow cytometry [flow-FISH]. Such telomere length values reflect telomere shortening (resulting from cell divisions, oxidative damage and other causes) and telomere elongation (mainly resulting from telomerase activity) of the chromosome-specific telomere length inherited in the gametes. Here we report improvements in flow-FISH methodology that enable measurements of telomere length in subsets of human nucleated blood cells. Methods and Results:In order to measure the telomere length in granulocytes, naive T cells, memory T cells, B cells and natural killer (NK)/NKT cells within a blood sample, we combined flow-FISH with antibody-staining

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Telomerase in the human organism

Cited by 553 publications

References 139 publications

Telomere and telomerase in stem cells

Telomere and telomerase in stem cells

Genetic variation in five genes important in telomere biology and risk for breast cancer

Telomere length measurements in leukocyte subsets by automated multicolor flow‐FISH

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