Mammalian telomeres consist of non-coding TTAGGG repeats that are bound by the multi-protein complex 'shelterin', thus protecting chromosome ends from DNA repair mechanisms and degradation. Mammalian telomeric chromatin is enriched for the constitutive heterochromatin marks H3K9me3, H4K20me3 and HP1 (refs 2, 3, 4, 5, 6, 7). Similar to pericentric heterochromatin, telomeric heterochromatin is thought to be fundamental for the maintenance of chromosomal integrity. Here, we report that telomeric repeats are transcribed by DNA-dependent RNA polymerase II, which, in turn, interacts with the TRF1 shelterin protein. Telomeric RNAs (TelRNAs) contain UUAGGG repeats, are polyadenylated and are transcribed from the telomeric C-rich strand. Transcription of mammalian telomeres is regulated by several mechanisms, including developmental status, telomere length, cellular stress, tumour stage and chromatin structure. Using RNA-flourescent in situ hybridization (FISH), we show that TelRNAs are novel structural components of telomeric chromatin. Importantly, we provide evidence that TelRNAs block the activity of telomerase in vitro, suggesting that TelRNAs may regulate telomerase activity at chromosome ends. Our results indicate that TelRNAs are novel components of mammalian telomeres, which are anticipated to be fundamental for understanding telomere biology and telomere-related diseases, such as cancer and ageing.
Telomere shortening is associated with organismal aging. iPS cells have been recently derived from old patients; however, it is not known whether telomere chromatin acquires the same characteristics as in ES cells. We show here that telomeres are elongated in iPS cells compared to the parental differentiated cells both when using four (Oct3/4, Sox2, Klf4, cMyc) or three (Oct3/4, Sox2, Klf4) reprogramming factors and both from young and aged individuals. We demonstrate genetically that, during reprogramming, telomere elongation is usually mediated by telomerase and that iPS telomeres acquire the epigenetic marks of ES cells, including a low density of trimethylated histones H3K9 and H4K20 and increased abundance of telomere transcripts. Finally, reprogramming efficiency of cells derived from increasing generations of telomerase-deficient mice shows a dramatic decrease in iPS cell efficiency, a defect that is restored by telomerase reintroduction. Together, these results highlight the importance of telomere biology for iPS cell generation and functionality.
In mammals X inactivation is initiated by expression of Xist RNA and involves the recruitment of Polycomb repressive complex 1 (PRC1) and 2 (PRC2), which mediate chromosome-wide ubiquitination of histone H2A and methylation of histone H3, respectively. Here, we show that PRC1 recruitment by Xist RNA is independent of gene silencing. We find that Eed is required for the recruitment of the canonical PRC1 proteins Mph1 and Mph2 by Xist. However, functional Ring1b is recruited by Xist and mediates ubiquitination of histone H2A in Eed deficient embryonic stem (ES) cells, which lack histone H3 lysine 27 tri-methylation. Xist expression early in ES cell differentiation establishes a chromosomal memory, which allows efficient H2A ubiquitination in differentiated cells and is independent of silencing and PRC2. Our data show that Xist recruits PRC1 components by both PRC2 dependent and independent modes and in the absence of PRC2 function is sufficient for the establishment of Polycombbased memory systems in X inactivation.
Dicer initiates RNA interference by generating small RNAs involved in various silencing pathways. Dicer participates in centromeric silencing, but its role in the epigenetic regulation of other chromatin domains has not been explored. Here we show that Dicer1 deficiency in Mus musculus leads to decreased DNA methylation, concomitant with increased telomere recombination and telomere elongation. These DNA-methylation defects correlate with decreased expression of Dnmt1, Dnmt3a and Dnmt3b DNA methyltransferases (Dnmts), and methylation levels can be recovered by their overexpression. We identify the retinoblastoma-like 2 protein (Rbl2) as responsible for decreased Dnmt expression in Dicer1-null cells, suggesting the existence of Dicer-dependent small RNAs that target Rbl2. We identify the miR-290 cluster as being downregulated in Dicer1-deficient cells and show that it silences Rbl2, thereby controlling Dnmt expression. These results identify a pathway by which miR-290 directly regulates Rbl2-dependent Dnmt expression, indirectly affecting telomere-length homeostasis.
Rap1 is a component of the shelterin complex at mammalian telomeres, but its in vivo role in telomere biology has remained largely unknown to date. Here we show that Rap1 deficiency is dispensable for telomere capping but leads to increased telomere recombination and fragility. We generated cells and mice deleted for Rap1; mice with Rap1 deletion in stratified epithelia were viable but had shorter telomeres and developed skin hyperpigmentation in adulthood. By performing chromatin immunoprecipitation coupled with ultrahigh-throughput sequencing, we found that Rap1 binds to both telomeres and to extratelomeric sites through the (TTAGGG)(2) consensus motif. Extratelomeric Rap1-binding sites were enriched at subtelomeric regions, in agreement with preferential deregulation of subtelomeric genes in Rap1-deficient cells. More than 70% of extratelomeric Rap1-binding sites were in the vicinity of genes, and 31% of the genes deregulated in Rap1-null cells contained Rap1-binding sites, suggesting a role for Rap1 in transcriptional control. These findings place a telomere protein at the interface between telomere function and transcriptional regulation.
Protection of chromosome ends from DNA repair and degradation activities is mediated by specialized protein complexes bound to telomere repeats. Recently, it has become apparent that epigenetic regulation of the telomeric chromatin template critically impacts on telomere function and telomere-length homeostasis from yeast to man. Across all species, telomeric repeats as well as the adjacent subtelomeric regions carry features of repressive chromatin. Disruption of this silent chromatin environment results in loss of telomere-length control and increased telomere recombination. In turn, progressive telomere loss reduces chromatin compaction at telomeric and subtelomeric domains. The recent discoveries of telomere chromatin regulation during early mammalian development, as well as during nuclear reprogramming, further highlights a central role of telomere chromatin changes in ontogenesis. In addition, telomeres were recently shown to generate long, noncoding RNAs that remain associated to telomeric chromatin and will provide new insights into the regulation of telomere length and telomere chromatin. In this review, we will discuss the epigenetic regulation of telomeres across species, with special emphasis on mammalian telomeres. We will also discuss the links between epigenetic alterations at mammalian telomeres and telomere-associated diseases.
TRF1 is a component of the shelterin complex at mammalian telomeres; however, a role for TRF1 in telomere biology in the context of the organism is unclear. In this study, we generated mice with transgenic TRF1 expression targeted to epithelial tissues (K5TRF1 mice). K5TRF1 mice have shorter telomeres in the epidermis than wild-type controls do, and these are rescued in the absence of the XPF nuclease, indicating that TRF1 acts as a negative regulator of telomere length by controlling XPF activity at telomeres, similar to what was previously described for TRF2-overexpressing mice (K5TRF2 mice). K5TRF1 cells also show increased end-toend chromosomal fusions, multitelomeric signals, and increased telomere recombination, indicating an impact of TRF1 on telomere integrity, again similar to the case in K5TRF2 cells. Intriguingly, K5TRF1 cells, but not K5TRF2 cells, show increased mitotic spindle aberrations. TRF1 colocalizes with the spindle assembly checkpoint proteins BubR1 and Mad2 at mouse telomeres, indicating a link between telomeres and the mitotic spindle. Together, these results demonstrate that TRF1, like TRF2, negatively regulates telomere length in vivo by controlling the action of the XPF nuclease at telomeres; in addition, TRF1 has a unique role in the mitotic spindle checkpoint.
Telomeres consist of DNA tandem repeats that recruit the multiprotein complex shelterin to build a chromatin structure that protects chromosome ends. Although cancer formation is linked to alterations in telomere homeostasis, there is little understanding of how shelterin function is limited in cancer cells. Using a small-scale screening approach, we identified miR-155 as a key regulator in breast cancer cell expression of the shelterin component TERF1 (TRF1). miR-155 targeted a conserved sequence motif in the 3 0 UTR of TRF1, resulting in its translational repression. miR-155 was upregulated commonly in breast cancer specimens, as associated with reduced TRF1 protein expression, metastasis-free survival, and relapse-free survival in estrogen receptor-positive cases. Modulating miR-155 expression in cells altered TRF1 levels and TRF1 abundance at telomeres. Compromising TRF1 expression by elevating miR-155 increased telomere fragility and altered the structure of metaphase chromosomes. In contrast, reducing miR-155 levels improved telomere function and genomic stability. These results implied that miR-155 upregulation antagonizes telomere integrity in breast cancer cells, increasing genomic instability linked to poor clinical outcome in estrogen receptor-positive disease. Our work argued that miRNAdependent regulation of shelterin function has a clinically significant impact on telomere function, suggesting the existence of "telo-miRNAs" that have an impact on cancer and aging. Cancer Res; 74(15); 4145-56. Ó2014 AACR.
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