Project description:Among epigenetic modifiers, telomeres, represent attractive modulators of the genome in part through position effects. Telomere Position Effect – Over Long Distances (TPE-OLD) modulates genes expression by changes in telomeric-dependent long-distance loops, with a reach of 10Mb from the telomeres. However, TPE-OLD remain poorly defined. We used cells with controlled telomere length combined to a genome wide approach revealing its transcriptome and methylome. We identified a common cis element that behaved as an insulator/ enhancer. By using reporter assays integrating this element, we disclosed additional trans partners further validated by in silico data. Exploiting our cellular model we observed the depletion of one candidate (RBPJ) at TPE-OLD associated loci concomitant to telomere shortening. Therefore, we conclude that TPE-OLD is orchestrated by Alu-like elements acting as enhancers in association with RBPJ. We propose that TPE-OLD functions by the coordinated action of newly evolved enhancers; an associated protein RBPJ and telomere length to produce an adapted response to external stimuli (i.e., Aging)

Project description:Among epigenetic modifiers, telomeres, represent attractive modulators of the genome in part through position effects. Telomere Position Effect – Over Long Distances (TPE-OLD) modulates genes expression by changes in telomeric-dependent long-distance loops, with a reach of 10Mb from the telomeres. However, TPE-OLD remain poorly defined. We used cells with controlled telomere length combined to a genome wide approach revealing its transcriptome and methylome. We identified a common cis element that behaved as an insulator/ enhancer. By using reporter assays integrating this element, we disclosed additional trans partners further validated by in silico data. Exploiting our cellular model we observed the depletion of one candidate (RBPJ) at TPE-OLD associated loci concomitant to telomere shortening. Therefore, we conclude that TPE-OLD is orchestrated by Alu-like elements acting as enhancers in association with RBPJ. We propose that TPE-OLD functions by the coordinated action of newly evolved enhancers; an associated protein RBPJ and telomere length to produce an adapted response to external stimuli (i.e., Aging)

Project description:Telomeres, the nucleoprotein structures located at the end of eukaryotic DNA, protect chromosomal integrity. These structures undergo changes during development and aging, including length shortening and alterations in the levels of the proteins associated to them called shelterin, all this affecting genome stability as the cells age. However, telomeres also behave as transcriptional regulators acting not only on genes present at subtelomeres but also on more distantly located genes presented throughout the genome. This process is referred as Telomere Position Effect (TPE). Here we set to determine whether telomere shortening in senescent cells impact TPE and senescent cells transcriptome. We also investigate whether TRF2 (a shelterin protein) and Lamin B1 (a member of nuclear lamina) are involved in TPE by doing RNA sequencing of young and senescent cells in which we modulated TRF2 and Lamin B1 expression.

Project description:Telomeres have the ability to adopt a lariat conformation and hence, engage in long and short distance intra-chromosome interactions. Budding yeast telomeres were proposed to fold back into subtelomeric regions, but a robust assay to quantitatively characterize this structure has been lacking. Therefore, it is not well understood how the interactions between telomeres and non-telomeric regions are established and regulated. We employ a telomere chromosome conformation capture (Telo-3C)approach to directly analyze telomere folding and its maintenance in S. cerevisiae. We identify the histone modifiers Sir2, Sin3 and Set2 as critical regulators for telomere folding, which suggests that a distinct telomeric chromatin environment is a major requirement for the folding of yeast telomeres. We demonstrate that telomeres are not folded when cells enter replicative senescence, which occurs independently of short telomere length. Indeed, Sir2, Sin3 and Set2 protein levels are decreased during senescence and their absence may thereby prevent telomere folding. Additionally, we show that the homologous recombination machinery, including the Rad51 and Rad52 proteins, as well as the checkpoint component Rad53 are essential for establishing the telomere fold-back structure. This study outlines a method to interrogate telomere-subtelomere interactions at a single unmodified yeast telomere. Using this method, we provide insights into how the spatial arrangement of the chromosome end structure is established and demonstrate that telomere folding is compromised throughout replicative senescence.

Project description:The factors that underlie the increasing incidence of diabetes with age are poorly understood. We examined whether telomere length, known to decrease with age, plays a role in the age-dependent increased incidence of diabetes. We show that in mice with short telomeres, insulin secretion is impaired and leads to glucose intolerance despite the presence of an intact M-NM-2-cell mass. Islets from mice with short telomeres displayed evidence of M-NM-2-cell dysfunction, and in response to glucose, had defective mitochondrial membrane depolarization as well as Ca2+ handling which limited insulin release. Short telomeres induced the hallmarks of senescence including premature accumulation of p16INK4a, and altered gene expression of key pathways essential for signaling and insulin secretion. Short telomeres also had an additive damaging effect to endoplasmic reticulum stress which occurs in the late stages of type 2 diabetes. This manifested as more severe hyperglycemia in insulin mutant Akita mice which had a more profound loss of M-NM-2-cell mass and increased M-NM-2-cell apoptosis. Our data identify impaired signaling in the setting of senescence as a novel mechanism of telomere-mediated disease, and implicate telomere length as a determinant of risk and pathogenesis in diabetes. The experiment is designed to analyze gene expression profiles of islets from mice with short telomeres compared to those of wildtype mice.

Project description:Telomere shortening rates must be regulated to prevent premature replicative senescence. TERRA R-loops become stabilized at critically short telomeres to promote their elongation through homology-directed repair (HDR), thereby counteracting senescence onset. Using a non-bias proteomic approach to identify telomere binding factors, we identified Npl3, an RNA-binding protein previously implicated in multiple RNA biogenesis processes. Using Chromatin- and RNA immunoprecipitation, we demonstrate that Npl3 interacts with TERRA and telomeres. Furthermore, we show that Npl3 associates to telomeres in an R-loop dependent manner, as changes in R-loop levels, e.g. at short telomeres, modulate the recruitment of Npl3 to chromosome ends. Through a series of genetic and biochemical approaches we demonstrate that Npl3 binds to TERRA and stabilizes R-loops at short telomeres, which in turn promotes HDR and prevents premature replicative senescence onset. This may have implications for diseases associated with excessive telomere shortening.

Project description:Telomere homeostasis, crucial for various biological processes, relies on telomerase activity. We identified ZC3H15 as a novel telomerase-interacting protein. Its deletion unexpectedly increased telomerase activity but led to shortened telomeres and cellular senescence. ZC3H15 interacts with telomerase and itself, regulating telomerase activity in an RNA-dependent manner. Proximity labeling showed ZC3H15's interaction with proteins involved in organelle assembly and RNA processes. Loss of ZC3H15 sequestered TERC in the Cajal body, reducing telomerase recruitment to telomeres during S phase. These findings unveil ZC3H15's role in telomere dynamics and cellular senescence, suggesting its potential as a target for cancer therapy or anti-aging interventions.

Project description:At critically short telomeres TERRA RNA-DNA hybrids become stabilized and drive homology-directed repair (HDR) to delay replicative senescence. However, even at long- and intermediate-length telomeres, not subject to HDR, transient TERRA RNA-DNA hybrids form, suggestive of additional roles. Here, we report that hybrids at telomeres prevent resection by the Exo1 nuclease when telomeres become non-functional. We employed the well-characterized cdc13-1 allele, where telomere resection can be induced in a temperature dependent manner, to demonstrate that ssDNA generation at telomeres is either prevented or augmented when RNA-DNA hybrids are stabilized or destabilized, respectively. The viability of cdc13-1 cells is affected by the presence or absence of hybrids accordingly. These results give insights into an additional role of TERRA at dysfunctional telomeres suggesting that it not only affects replicative senescence rates through HDR activation at critically short telomeres, but may also affect resection rates at intermediate length telomeres in pre-senescent cells.

Project description:We examined differential expression of genes within 10MBs of telomeres in myoblasts with long or short telomeres We offer telomere looping with telomere length as a partial mechanistic explanation for the changes gene expression that is observed. Compare expression of genes within 10MB of the telomere in normal myoblasts with long (15 kb) and short (6 kb) telomeres.

Project description:The factors that underlie the increasing incidence of diabetes with age are poorly understood. We examined whether telomere length, known to decrease with age, plays a role in the age-dependent increased incidence of diabetes. We show that in mice with short telomeres, insulin secretion is impaired and leads to glucose intolerance despite the presence of an intact β-cell mass. Islets from mice with short telomeres displayed evidence of β-cell dysfunction, and in response to glucose, had defective mitochondrial membrane depolarization as well as Ca2+ handling which limited insulin release. Short telomeres induced the hallmarks of senescence including premature accumulation of p16INK4a, and altered gene expression of key pathways essential for signaling and insulin secretion. Short telomeres also had an additive damaging effect to endoplasmic reticulum stress which occurs in the late stages of type 2 diabetes. This manifested as more severe hyperglycemia in insulin mutant Akita mice which had a more profound loss of β-cell mass and increased β-cell apoptosis. Our data identify impaired signaling in the setting of senescence as a novel mechanism of telomere-mediated disease, and implicate telomere length as a determinant of risk and pathogenesis in diabetes.