Project description:Telomere end-protection by the shelterin complex prevents DNA damage signalling and promiscuous repair at chromosome ends. Evidence suggests that the 3’ single-stranded telomere end can assemble into a lasso-like t-loop configuration, which has been proposed to safeguard chromosome ends from being recognized as DNA double strand breaks. Mechanisms must also exist to transiently disassemble t-loops to allow faithful telomere replication and to permit telomerase access to the 3’-end to solve the end replication problem. However, the regulation and physiological importance of t-loops in end-protection remains uncertain. Here, we identify a CDK phosphorylation site in the shelterin subunit, TRF2 (Ser365), whose dephosphorylation in S-phase by the PP6C/R3 phosphatase provides a narrow window during which the helicase RTEL1 is able to transiently access and unwind t-loops to facilitate telomere replication. Re-phosphorylation of TRF2 on Ser365 outside of S-phase is required to release RTEL1 from telomeres, which not only protects t-loops from promiscuous unwinding and inappropriate ATM activation, but also counteracts replication conflicts at DNA secondary structures arising within telomeres and across the genome. Hence, a phospho-switch in TRF2 coordinates assembly and disassembly of t-loops during the cell cycle, which protects telomeres from replication stress and an unscheduled DNA damage response.

Project description:We investigated the reported binding of telomere associated factor TERF1 and TERF2 to internal telomere sites using ChIP-Seq for these two factors in a lymphoblastoid cell line. We mapped over 40 million reads for each sample to a custom reference genome that incorporates our subtelomere assembly, and generated signal tracks using only uniquely mapping reads, and also using a multimapping pipeline we developed. We find that peaks are misshapen and made up of reads that cannot be distinguished from true telomere sequence. Removing telomere identified reads removes all internal signal. Examination of TRF1 and TRF2

Project description:Here we found that ILF3 prefers to bind telomere R-loops and protects telomere from aberrant homologous recombination. ILF3 knockout induces TERRA aggregation onto telomere and activates telomere DNA damage response (DDR). Furthermore, ILF3 deficiency disrupts telomere homeostasis and induces abnormal ALT-mediated telomere lengthening

Project description:Telomeres are nucleoprotein structures at the ends of linear chromosomes. In humans, they consist of TTAGGG repeats, which are bound by dedicated proteins such as the shelterin complex. This complex consists of six proteins (TRF1, TRF2, RAP1, POT1, TPP1 and TIN2) and blocks unwanted DNA damage repair at telomeres, e.g. by suppressing non-homologous end joining (NHEJ) through its subunit TRF2. While shelterin does not work autonomously, additional direct telomere binding proteins have been described to function in a supplementary role. We here describe ZNF524, a zinc finger protein that directly binds to telomeric repeats with nanomolar affinity and reveal the base-specific sequence recognition by co-crystallization with telomeric DNA. ZNF524 localizes to telomeres and specifically maintains the presence of the TRF2/RAP1 subcomplex at telomeres without affecting the other shelterin members. Loss of ZNF524 concomitantly results in an increase in DNA damage signaling and recombination events. Overall, we identified ZNF524 as a direct telomere binding protein and propose that ZNF524 is involved in the maintenance of telomere integrity by promoting TRF2/RAP1 subcomplex binding.

Project description:Telomeres are nucleoprotein structures at the ends of linear chromosomes. In humans, they consist of TTAGGG repeats, which are bound by dedicated proteins such as the shelterin complex. This complex consists of six proteins (TRF1, TRF2, RAP1, POT1, TPP1 and TIN2) and blocks unwanted DNA damage repair at telomeres, e.g. by suppressing non-homologous end joining (NHEJ) through its subunit TRF2. While shelterin does not work autonomously, additional direct telomere binding proteins have been described to function in a supplementary role. We here describe ZNF524, a zinc finger protein that directly binds to telomeric repeats with nanomolar affinity and reveal the base-specific sequence recognition by co-crystallization with telomeric DNA. ZNF524 localizes to telomeres and specifically maintains the presence of the TRF2/RAP1 subcomplex at telomeres without affecting the other shelterin members. Loss of ZNF524 concomitantly results in an increase in DNA damage signaling and recombination events. Overall, we identified ZNF524 as a direct telomere binding protein and propose that ZNF524 is involved in the maintenance of telomere integrity by promoting TRF2/RAP1 subcomplex binding.

Project description:Telomere binding factor 2 (TRF2), is a protein that plays a major role in the maintenance of telomere integrity. In mitotic normal and transformed cells, TRF2 inhibition triggers a rapid telomere DNA damage response that results in cell senescence or apoptosis. Here we provide evidence that TRF2 plays a role suppressing neuronal differentiation. TRF2 interacts with the RE1-silencing transcription factor (REST) in nuclear PML protein-containing compartments of neuronal cells in vivo. Inhibition of TRF2 function with a dominant-negative form of TRF2 elicits a telomeric DNA damage response, and disrupts the TRF2-REST complex resulting in proteasomal degradation of REST. Overexpression of REST impairs the ability of DN-TRF2 to induce neuronal differentiation, indicating that enhanced degradation of REST is sufficient to account for the differentiation-inducing effect of DN-TRF2. REST degradation derepresses RE1-regulated genes (L1CAM, BDNF, b3-tubulin, syntaxin and others) resulting in morphological and functional differentiation of neurons. Our findings identify a novel interaction between the telomeric protein TRF2 and REST which regulates the molecular differentiation program of neurons. Keywords: transfection and molecular inhibition

Project description:The study of the proteins that bind to telomeric DNA in mammals has provided a deep understanding of the mechanisms of chromosome-end protection. However, very little is known on the binding of these proteins to nontelomeric DNA sequences. The TTAGGG DNA repeat proteins 1 and 2 (TRF1 and TRF2) bind to mammalian telomeres as part of the shelterin complex and are essential for maintaining chromosome end stability. In this study, we combined chromatin immunoprecipitation with high-throughput sequencing to map at high sensitivity and resolution, the human chromosomal sites to which TRF1 and TRF2 bind. While most of the identified sequences correspond to telomeric regions, we showed that these two proteins also bind to extratelomeric sites. The vast majority of these extra-telomeric sites contains interstitial telomeric sequences (or ITSs). However we also identified non-ITS sites, which are also satellite DNA but the ones mainly constitutive of centromeric and pericentromeric regions. Interestingly, the TRF-binding sites are often located in the proximity of genes or within introns. We propose that, by binding to extratelomeric sequences, TRF1 and TRF2 couple the functional state of telomeres to the long-range organization of chromosomes and gene regulation networks. ChIP-SEQ experiment of transformed human fibroblast BJ cells with 3 antibodies (1 monoclonal anti-TRF1, 1 monoclonal anti-TRF2, 1 polyclonal anti-TRF2) and a negative control (proteinG without antibody used as the ChIP background)

Project description:Tubulointerstitial fibrosis associated to chronic kidney disease represents a global healthcare problem. We showed previously that short and dysfunctional telomeres lead to interstitial renal fibrosis, however, the cell-of-origin of kidney fibrosis associated to telomere dysfunction was unknown to date. To identify the specific cell type responsible for this type of renal fibrosis, we induced telomere dysfunction by deleting the Trf1 telomere-binding factor both in renal fibroblasts and pericytes both in short-term and long-term life-long experiments in mice. Short-term Trf1 deletion in renal fibroblasts and pericytes was not sufficient to trigger kidney fibrosis. However, long-term persistent deletion of Trf1 in fibroblasts, triggered inflammation, cell cycle arrest, fibrogenesis, and vascular rarefaction. These cellular responses lead to macrophage-to-myofibroblast transition (MMT), Endothelial-to-mesenchymal transition (EndMT), and epithelial-to-mesenchymal transition (EMT), ultimately causing kidney fibrosis at humane-endpoint when deletion of Trf1 in fibroblasts was maintained throughout the lifespan of mice. In contrast, Trf1 deletion in pericytes did not lead to any kidney phenotypes both in short-term and long-term experiments.

Project description:Telomeric repeat sequences are prone to induce replication stress and one of the core telomere binding proteins, TRF1, is thought to counteract these problems. The molecular mechanisms coming into play upon TRF1 loss were not clearly defined though. This study combines an inducible TRF1 loss with telomere-targeted proteomics to analyze the incurring changes. The results show that loss of TRF1 causes important alterations in telomere associated proteins and the new profile resembles in a number of ways that of cells in which telomeres are maintained by telomerase-independent mechanisms, named ALT. The presence of DNA repair proteins (MRN complex, the SMC5/6 complex), some increases in telomere colocalization with PML bodies, sister chromatid exchanges and clear signs of increased TERRA transcription and mitotic break-induced replication are part of these phenotypes. The data also show that these early ALT phenotypes can be differentiated from drug induced replication stress, and part of this ALT response is conserved in human cells. These studies therefore point to a critical role for TRF1 in preventing the emergence of ALT and hence immortalization of cells. Given that the details for how ALT actually is initiated remained unclear, these findings are an important step forward and will spur new research into that question.

Project description:Lentiviral accessory genes enhance replication through diverse mechanisms. HIV-1 accessory protein Vpr modulates the host DNA damage response (DDR) at multiple steps through DNA damage, cell cycle arrest, the degradation of host proteins, and both the activation and repression of DDR signaling. Vpr also alters host and viral transcription; however, the connection between Vpr-mediated DDR modulation and transcriptional activation remains unclear. Here, we determined the cellular consequences of Vpr-induced DNA damage using Vpr mutants that allow us to separate the ability of Vpr to induce DNA damage from cell cycle arrest and other DDR phenotypes including host protein degradation and repression of DDR. RNA-sequencing of cells expressing Vpr or Vpr mutants identified that Vpr alters cellular transcription through mechanisms both dependent and independent of cell cycle arrest. In tissue-cultured U2OS cells and primary human monocyte-derived macrophages (MDMs), Vpr-induced DNA damage activates the ATM-NEMO pathway and alters cellular transcription via NF-κB/RelA signaling. HIV-1 infection of primary MDMs validated Vpr-dependent NF-κB transcriptional activation during infection. Both virion delivered and de novo expressed Vpr induced DNA damage and activated ATM-NEMO dependent NF-κB transcription, suggesting that engagement of the DDR and transcriptional reprogramming can occur during early and late stages of viral replication. Together, our data identifies a mechanism by which Vpr activates NF-κB through DNA damage and the ATM-NEMO pathway, which occur independent of cell cycle arrest. We propose this is essential to overcoming restrictive environments, such as in macrophages, to enhance viral transcription and replication.