Microenvironmental Regulation of Telomerase Isoforms in Human Embryonic Stem Cells

Radan, Lida; Hughes, Chris; Teichroeb, Jonathan H.; Zamora, Flora M. Vieira; Jewer, Michael; Postovit, Lynne-Marie; Betts, Dean H.

doi:10.1089/scd.2013.0373

Cited by 29 publications

(26 citation statements)

References 106 publications

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“…Splicing role of HIF-1 and hypoxia on hTERT. hypoxia is known to enhance hTERT expression through activation of the hTERT promoter in stem cells as well as in cancer (50,51). In hypoxic tumor conditions, hIF-1 is overexpressed and activates the hTERT promoter by binding at two sites between -165 and +51.…”

Section: Role Of Transcription Factor Binding On Splicingmentioning

confidence: 99%

Human telomerase reverse transcriptase regulation by DNA methylation, transcription factor binding and alternative splicing (Review)

Avin

Umbricht

Zeiger

2016

International Journal of Oncology

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The catalytic subunit of telomerase, human telomerase reverse transcriptase (hTERT), plays an essential role in telomere maintenance to oppose cellular senescence and, is highly regulated in normal and cancerous cells. Regulation of hTERT occurs through multiple avenues, including a unique pattern of CpG promoter methylation and alternative splicing. Promoter methylation affects the binding of transcription factors, resulting in changes in expression of the gene. In addition to expression level changes, changes in promoter binding can affect alternative splicing in a cotranscriptional manner. The alternative splicing of hTERT results in either the full length transcript which can form the active telomerase complex with hTR, or numerous inactive isoforms. Both regulation strategies are exploited in cancer to activate telomerase, however, the exact mechanism is unknown. Therefore, unraveling the link between promoter methylation status and alternative splicing for hTERT could expose yet another level of hTERT regulation. In an attempt to provide insight into the cellular control of active telomerase in cancer, this review will discuss our current perspective on CpG methylation of the hTERT promoter region, summarize the different forms of alternatively spliced variants, and examine examples of transcription factor binding that affects splicing.

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Section: Role Of Transcription Factor Binding On Splicingmentioning

confidence: 99%

Human telomerase reverse transcriptase regulation by DNA methylation, transcription factor binding and alternative splicing (Review)

Avin

Umbricht

Zeiger

2016

International Journal of Oncology

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“…Correlations of expression levels of alternatively spliced hTERT mRNAs relative to full‐length hTERT mRNA with cell proliferation, cell differentiation and cancer subtype have also been reported (Ulaner et al., ; Brenner et al., ; Fajkus et al., ; Hisatomi et al., ; Petrenko et al., ; Listerman et al., ). Relative levels of specific hTERT isoforms are also important for human embryonic stem (ES) cell self‐renewal and differentiation, with specific isoforms possibly enriching differentiation towards specific cell lineages (Radan et al., ).…”

Section: Introductionmentioning

confidence: 99%

An intact putative mouse telomerase essential N‐terminal domain is necessary for proper telomere maintenance

Rousseau

Khondaker

Zhu

et al. 2016

Biology of the Cell

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“…In partial agreement, chemical inhibition of hTERT activity in hESCs leads to lowered pluripotency and increased differentiation, while curiously, similar blocking of telomerase activity through TERC steric inhibition has no effect suggesting an extra-telomeric role for TERT in maintaining self-renewal in the undifferentiated state. 85 In contrast, Sexton et al did not observe any reduction in pluripotency (as measured by sustained OCT3/4 expression only) after establishing stable hESC lines through zinc finger-mediated knockout of hTERT. 86 However, Sexton et al do observe a loss of selfrenewal and differentiation beginning around 75 days post TERT-knockout, when the cells reach a critical telomere length of 2-3kb.…”

Section: Pluripotency and Canonical Tert Functionsmentioning

confidence: 92%

“…138 However, Listerman et al and our group have recently shown that the b-variant transcript associates with polyribosomes, escapes NMD, and is likely translated. 24,85 Surprisingly, the b-deletion transcript not only survives degradation but is one of the most highly expressed TERT transcripts in various cell types including human embryonic stem cells. 24,128,132,147,151 A recent discovery suggests that the b-variant inhibits telomerase activity by sequestering TERC.…”

Section: 135mentioning

confidence: 99%

The role of telomeres and telomerase reverse transcriptase isoforms in pluripotency induction and maintenance

2016

Self Cite

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Telomeres are linear guanine-rich DNA structures at the ends of chromosomes. The length of telomeric DNA is actively regulated by a number of mechanisms in highly proliferative cells such as germ cells, cancer cells, and pluripotent stem cells. Telomeric DNA is synthesized by way of the ribonucleoprotein called telomerase containing a reverse transcriptase (TERT) subunit and RNA component (TERC). TERT is highly conserved across species and ubiquitously present in their respective pluripotent cells. Recent studies have uncovered intricate associations between telomeres and the self-renewal and differentiation properties of pluripotent stem cells. Interestingly, the past decade's work indicates that the TERT subunit also has the capacity to modulate mitochondrial function, to remodel chromatin structure, and to participate in key signaling pathways such as the Wnt/b-catenin pathway. Many of these non-canonical functions do not require TERT's catalytic activity, which hints at possible functions for the extensive number of alternatively spliced TERT isoforms that are highly expressed in pluripotent stem cells. In this review, some of the established and potential routes of pluripotency induction and maintenance are highlighted from the perspectives of telomere maintenance, known TERT isoform functions and their complex regulation.

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Microenvironmental Regulation of Telomerase Isoforms in Human Embryonic Stem Cells

Cited by 29 publications

References 106 publications

Human telomerase reverse transcriptase regulation by DNA methylation, transcription factor binding and alternative splicing (Review)

Human telomerase reverse transcriptase regulation by DNA methylation, transcription factor binding and alternative splicing (Review)

An intact putative mouse telomerase essential N‐terminal domain is necessary for proper telomere maintenance

The role of telomeres and telomerase reverse transcriptase isoforms in pluripotency induction and maintenance

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