Chromosome Tips Damaged in Anaphase Inhibit Cytokinesis

Genome maintenance is ensured by a variety of biochemical sensors and pathways that repair accumulated damage. During mitosis, the mechanisms that sense and resolve DNA damage remain elusive. Studies have demonstrated that damage accumulated on lagging chromosomes can activate the spindle assembly checkpoint. However, there is little known regarding damage to DNA after anaphase onset. In this study, we demonstrate that laser-induced damage to chromosome tips (presumptive telomeres) in anaphase of Potorous tridactylis cells (PtK2) inhibits cytokinesis. In contrast, equivalent irradiation of non-telomeric chromosome regions or control irradiations in either the adjacent cytoplasm or adjacent to chromosome tips near the spindle midzone during anaphase caused no change in the eventual completion of cytokinesis. Damage to only one chromosome tip caused either complete absence of furrow formation, a prolonged delay in furrow formation, or furrow regression. When multiple chromosome tips were irradiated in the same cell, the cytokinesis defects increased, suggesting a potential dose-dependent mechanism. These results suggest a mechanism in which dysfunctional telomeres inhibit mitotic exit

ATM/ATR-dependent responses to dysfunctional telomeres at the G2/M transition

Mammalian telomeres are nucleoprotein complexes at the end of chromosomes containing a specific protein complex, called shelterin. Shelterin protects chromosome ends from the DNA damage response (DDR), by facilitating the formation of a telomeric capping structure, called the T-loop. During their elongation in S phase, telomeres become transiently uncapped and can be sensed as DNA damage in G2 phase. This leads to the recruitment of DDR factors, such as phosphorylated histone H2AX (γH2AX), to the telomeres forming the so-called, telomere dysfunction-induced foci (TIFs). My PhD work described here, indicates that DNA damage occurring during interphase can persist after entry into mitosis, indicated by the detection of γH2AX at a subset of mitotic telomeres in human and mouse cells. This accumulation of γH2AX to mitotic telomeres is ATM-dependent and the γH2AX-labelled uncapped telomeres that persist, are shorter than the average telomere length for the entire cell population.Most importantly, my work suggests that telomere uncapping, naturally occurring or artificially induced, is detected by two parallel ATM/ATR-dependent pathways at the G2/M transition: a p53/p21-dependent pathway through the ATM/ATR-mediated phosphorylation of p53 at Ser15 and a CHK1/CHK2-dependent pathway that acts through negative regulation of CDC25 phosphatases. In particular, telomere uncapping triggered by TRF2 depletion leads to CHK2-dependent CDC25A degradation, while POT1 depletion results in CHK1-mediated CDC25A and CDC25C degradation. Both pathways act as sensors of unprotected telomeres at the G2/M transition and block cell cycle progression through inhibition of CDK1/Cyclin B complex, allowing telomere re-capping before entry into mitosis. This mechanism protects telomere integrity by the maintenance of a cell cycle stage conducive for capping reactions and thereby prevents genomic instability induced by telomere dysfunction. Finally, I studied the cellular functions of 3 poorly characterised shelterin components, TRF1, RAP1 and TPP1, in telomere protection. TRF1 and to a lesser extent RAP1 were shown to be important for telomere protection by suppressing DDR at the telomeres, while TPP1 was shown to be mainly responsible for the recruitment of the catalytic subunit of telomerase, TERT , to the chromatin, contributing to telomere maintenance.In conclusion, my work on both human and mouse models, reveals an important part of the DDR pathways activated by dysfunctional telomeres, as well as the molecular mechanisms underlying the cell cycle specific regulation of telomere capping, which ensures that only cells with intact telomeres enter mitosis.</p

ATM/ATR checkpoint activation downregulates CDC25C to prevent mitotic entry with uncapped telomeres

Shelterin component TRF2 prevents ATM activation, while POT1 represses ATR signalling at telomeres. Here, we investigate the mechanism of G2/M arrest triggered by telomeres uncapped through TRF2 or POT1 inhibition in human cells. We find that telomere damage-activated ATR and ATM phosphorylate p53, as well as CHK1 and CHK2, thus activating two independent pathways to prevent progression into mitosis with uncapped telomeres. Surprisingly, telomere damage targets the CDC25C phosphatase for proteasome degradation in G2/M. CHK1/CHK2-dependent phosphorylation of CDC25C at Ser 216 is required for CDC25C nuclear export and destruction, which in turn acts to sustain the G2/M arrest elicited by TRF2- or POT1-depleted telomeres. In addition, CDC25C is transcriptionally downregulated by p53 in response to telomere damage. These mechanisms are distinct from the canonical DNA damage response to ionizing radiation, which triggers cell-cycle arrest through CDC25A destruction. Thus, dysfunctional telomeres promote ATM/ATR-dependent degradation of CDC25C phosphatase to block mitotic entry, thereby preventing telomere dysfunction-driven genomic instability. © 2012 European Molecular Biology Organization

p53 prevents entry into mitosis with uncapped telomeres.

Telomeres are protected by capping structures consisting of core protein complexes that bind with sequence specificity to telomeric DNA. In their absence, telomeres trigger a DNA damage response, materialized in accumulation at the telomere of damage response proteins, e.g., phosphorylated histone H2AX (gammaH2AX), into telomere-dysfunction-induced foci. Telomere uncapping occurs transiently in every cell cycle in G2, following DNA replication, but little is known about how protective structures are reassembled or whether this process is controlled by the cell-cycle surveillance machinery. Here, we report that telomere capping is monitored at the G2/M transition by the p53/p21 damage response pathway. Unlike their wild-type counterparts, human and mouse cells lacking p53 or p21 progress into mitosis prematurely with persisting uncapped telomeres. Furthermore, artificially uncapped telomeres delay mitotic entry in a p53- and p21-dependent manner. Uncapped telomeres that persist in mitotic p53-deficient cells are shorter than average and religate to generate end-to-end fusions. These results suggest that a p53-dependent pathway monitors telomere capping after DNA replication and delays G2/M progression in the presence of unprotected telomeres. This mechanism maintains a cell-cycle stage conducive for capping reactions and prevents progression into stages during which uncapped telomeres are prone to deleterious end fusions

Basis of catalytic assembly of the mitotic checkpoint complex.

In mitosis, for each daughter cell to inherit an accurate copy of the genome from the mother cell, sister chromatids in the mother cell must attach to microtubules emanating from opposite poles of the mitotic spindle, a process known as bi-orientation. A surveillance mechanism, termed the spindle assembly checkpoint (SAC), monitors the microtubule attachment process and can temporarily halt the separation of sister chromatids and the completion of mitosis until bi-orientation is complete(1). SAC failure results in abnormal chromosome numbers, termed aneuploidy, in the daughter cells, a hallmark of many tumours. The HORMA-domain-containing protein mitotic arrest deficient 2 (MAD2) is a subunit of the SAC effector mitotic checkpoint complex (MCC). Structural conversion from the open to the closed conformation of MAD2 is required for MAD2 to be incorporated into the MCC1. In vitro, MAD2 conversion and MCC assembly take several hours(2-4), but in cells the SAC response is established in a few minutes(5-7). Here, to address this discrepancy, we reconstituted a near-complete SAC signalling system with purified components and monitored assembly of the MCC in real time. A marked acceleration in MAD2 conversion and MCC assembly was observed when monopolar spindle 1 (MPS1) kinase phosphorylated the MAD1-MAD2 complex, triggering it to act as the template for MAD2 conversion and therefore contributing to the establishment of a physical platform for MCC assembly. Thus, catalytic activation of the SAC depends on regulated protein-protein interactions that accelerate the spontaneous but rate-limiting conversion of MAD2 required for MCC assembly

TPP1 is required for TERT recruitment, telomere elongation during nuclear reprogramming, and normal skin development in mice.

The TPP1/ACD protein (hereafter TPP1) is a component of the shelterin complex at mammalian telomeres. Here we find that Tpp1-deficient mouse embryonic fibroblasts (MEFs) show increased chromosomal instability including sister chromatid fusions and chromosomes with multitelomeric signals related to telomere fragility. Tpp1 deletion decreases both TERT (the telomerase catalytic subunit) binding to telomeres in MEFs and telomerase function at chromosome ends in vivo. Abrogation of Tpp1 abolished net telomere elongation in the context of nuclear reprogramming of MEFs into induced pluripotent stem cells, whereas Tpp1 deletion in stratified epithelia of Tpp1(Delta/Delta)K5-Cre mice resulted in perinatal death, severe skin hyperpigmentation, and impaired hair follicle morphogenesis. p53 deficiency rescues skin hyperpigmentation and hair growth in these mice, indicating that p53 restricts proliferation of Tpp1-deficient cells. These results suggest a telomere-capping model where TPP1 protects telomere integrity and regulates telomerase recruitment to telomeres, thereby preventing early occurrence of degenerative pathologies

Mammalian Rap1 controls telomere function and gene expression through binding to telomeric and extratelomeric sites.

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

Mammalian Rap1 controls telomere function and gene expression through binding to telomeric and extratelomeric sites.

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

Mammalian Rap1 controls telomere function and gene expression through binding to telomeric and extratelomeric sites

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

Increased telomere fragility and fusions resulting from TRF1 deficiency lead to degenerative pathologies and increased cancer in mice

The telomere repeat-binding factor 1 (TERF1, referred to hereafter as TRF1) is a component of mammalian telomeres whose role in telomere biology and disease has remained elusive. Here, we report on cells and mice conditionally deleted for TRF1. TRF1-deleted mouse embryonic fibroblasts (MEFs) show rapid induction of senescence, which is concomitant with abundant telomeric γ-H2AX foci and activation of the ATM/ATR downstream checkpoint kinases CHK1 and CHK2. DNA damage foci are rescued by both ATM and ATM/ATR inhibitors, further indicating that both signaling pathways are activated upon TRF1 deletion. Abrogation of the p53 and RB pathways bypasses senescence but leads to chromosomal instability including sister chromatid fusions, chromosome concatenation, and occurrence of multitelomeric signals (MTS). MTS are also elevated in ATR-deficient MEFs or upon treatment with aphidicolin, two conditions known to induce breakage at fragile sites, suggesting that TRF1-depleted telomeres are prone to breakage. To address the impact of these molecular defects in the organism, we deleted TRF1 in stratified epithelia of TRF1Δ/ΔK5-Cre mice. These mice die perinatally and show skin hyperpigmentation and epithelial dysplasia, which are associated with induction of telomere-instigated DNA damage, activation of the p53/p21 and p16 pathways, and cell cycle arrest in vivo. p53 deficiency rescues mouse survival but leads to development of squamous cell carcinomas, demonstrating that TRF1 suppresses tumorigenesis. Together, these results demonstrate that dysfunction of a telomere-binding protein is sufficient to produce severe telomeric damage in the absence of telomere shortening, resulting in premature tissue degeneration and development of neoplastic lesions