Interactions of TLC1 (Which Encodes the RNA Subunit of Telomerase), TEL1, and MEC1 in Regulating Telomere Length in the Yeast Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, chromosomes terminate with a repetitive sequence [poly(TG(1-3))] 350 to 500 bp in length. Strains with a mutation of TEL1, a homolog of the human gene (ATM) mutated in patients with ataxia telangiectasia, have short but stable telomeric repeats. Mutations of TLC1 (encoding the RNA subunit of telomerase) result in strains that have continually shortening telomeres and a gradual loss of cell viability; survivors of senescence arise as a consequence of a Rad52p-dependent recombination events that amplify telomeric and subtelomeric repeats. We show that a mutation in MEC1 (a gene related in sequence to TEL1 and ATM) reduces telomere length and that tel1 mec1 double mutant strains have a senescent phenotype similar to that found in tlc1 strains. As observed in tlc1 strains, survivors of senescence in the tel1 mec1 strains occur by a Rad52p-dependent amplification of telomeric and subtelomeric repeats. In addition, we find that strains with both tel1 and tlc1 mutations have a delayed loss of cell viability compared to strains with the single tlc1 mutation. This result argues that the role of Tel1p in telomere maintenance is not solely a direct activation of telomerase.     

Fission Yeast Tel1ATM and Rad3ATR Promote Telomere Protection and Telomerase Recruitment

The checkpoint kinases ATM and ATR are redundantly required for maintenance of stable telomeres in diverse organisms, including budding and fission yeasts, Arabidopsis, Drosophila, and mammals. However, the molecular basis for telomere instability in cells lacking ATM and ATR has not yet been elucidated fully in organisms that utilize both the telomere protection complex shelterin and telomerase to maintain telomeres, such as fission yeast and humans. Here, we demonstrate by quantitative chromatin immunoprecipitation (ChIP) assays that simultaneous loss of Tel1^ATM and Rad3^ATR kinases leads to a defect in recruitment of telomerase to telomeres, reduced binding of the shelterin complex subunits Ccq1 and Tpz1, and increased binding of RPA and homologous recombination repair factors to telomeres. Moreover, we show that interaction between Tpz1-Ccq1 and telomerase, thought to be important for telomerase recruitment to telomeres, is disrupted in tel1Δ rad3Δ cells. Thus, Tel1^ATM and Rad3^ATR are redundantly required for both protection of telomeres against recombination and promotion of telomerase recruitment. Based on our current findings, we propose the existence of a regulatory loop between Tel1^ATM/Rad3^ATR kinases and Tpz1-Ccq1 to ensure proper protection and maintenance of telomeres in fission yeast.     

Rad59-Facilitated Acquisition of Y′ Elements by Short Telomeres Delays the Onset of Senescence

Telomerase-negative yeasts survive via one of the two Rad52-dependent recombination pathways, which have distinct genetic requirements. Although the telomere pattern of type I and type II survivors is well characterized, the mechanistic details of short telomere rearrangement into highly evolved pattern observed in survivors are still missing. Here, we analyze immediate events taking place at the abruptly shortened VII-L and native telomeres. We show that short telomeres engage in pairing with internal Rap1-bound TG_1–3-like tracts present between subtelomeric X and Y′ elements, which is followed by BIR-mediated non-reciprocal translocation of Y′ element and terminal TG_1–3 repeats from the donor end onto the shortened telomere. We found that choice of the Y′ donor was not random, since both engineered telomere VII-L and native VI-R acquired Y′ elements from partially overlapping sets of specific chromosome ends. Although short telomere repair was associated with transient delay in cell divisions, Y′ translocation on native telomeres did not require Mec1-dependent checkpoint. Furthermore, the homeologous pairing between the terminal TG_1–3 repeats at VII-L and internal repeats on other chromosome ends was largely independent of Rad51, but instead it was facilitated by Rad59 that stimulates Rad52 strand annealing activity. Therefore, Y′ translocation events taking place during presenescence are genetically separable from Rad51-dependent Y′ amplification process that occurs later during type I survivor formation. We show that Rad59-facilitated Y′ translocations on X-only telomeres delay the onset of senescence while preparing ground for type I survivor formation.     

The Rad51 pathway of telomerase-independent maintenance of telomeres can amplify TG1-3 sequences in yku and cdc13 mutants of Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, Cdc13, Yku, and telomerase define three parallel pathways for telomere end protection that prevent chromosome instability and death by senescence. We report here that cdc13-1 yku70delta mutants generated telomere deprotection-resistant cells that, in contrast with telomerase-negative senescent cells, did not display classical crisis events. cdc13-1 yku70delta cells survived telomere deprotection by exclusively amplifying TG(1-3) repeats (type II recombination). In a background lacking telomerase (tlc1delta), this process predominated over type I recombination (amplification of subtelomeric Y' sequences). Strikingly, inactivation of the Rad50/Rad59 pathway (which is normally required for type II recombination) in cdc13-1 yku70delta or yku70delta tlc1delta mutants, but also in cdc13-1 YKU70(+) tlc1delta mutants, still permitted type II recombination, but this process was now entirely dependent on the Rad51 pathway. In addition, delayed senescence was observed in cdc13-1 yku70delta rad51delta and cdc13-1 tlc1delta rad51delta cells. These results demonstrate that in wild-type cells, masking by Cdc13 and Yku prevents the Rad51 pathway from amplifying telomeric TG(1-3) sequences. They also suggest that Rad51 is more efficient than Rad50 in amplifying the sequences left uncovered by the absence of Cdc13 or Yku70.     

Fission Yeast Shelterin Regulates DNA Polymerases and Rad3ATR Kinase to Limit Telomere Extension

Studies in fission yeast have previously identified evolutionarily conserved shelterin and Stn1-Ten1 complexes, and established Rad3^ATR/Tel1^ATM-dependent phosphorylation of the shelterin subunit Ccq1 at Thr93 as the critical post-translational modification for telomerase recruitment to telomeres. Furthermore, shelterin subunits Poz1, Rap1 and Taz1 have been identified as negative regulators of Thr93 phosphorylation and telomerase recruitment. However, it remained unclear how telomere maintenance is dynamically regulated during the cell cycle. Thus, we investigated how loss of Poz1, Rap1 and Taz1 affects cell cycle regulation of Ccq1 Thr93 phosphorylation and telomere association of telomerase (Trt1^TERT), DNA polymerases, Replication Protein A (RPA) complex, Rad3^ATR-Rad26^ATRIP checkpoint kinase complex, Tel1^ATM kinase, shelterin subunits (Tpz1, Ccq1 and Poz1) and Stn1. We further investigated how telomere shortening, caused by trt1Δ or catalytically dead Trt1-D743A, affects cell cycle-regulated telomere association of telomerase and DNA polymerases. These analyses established that fission yeast shelterin maintains telomere length homeostasis by coordinating the differential arrival of leading (Polε) and lagging (Polα) strand DNA polymerases at telomeres to modulate Rad3^ATR association, Ccq1 Thr93 phosphorylation and telomerase recruitment.     

Activation of Mrc1, a mediator of the replication checkpoint, by telomere erosion

Background information. In budding yeast, the loss of either telomere sequences (in telomerase‐negative cells) or telomere capping (in mutants of two telomere end‐protection proteins, Cdc13 and Yku) lead, by distinct pathways, to telomeric senescence. After DNA damage, activation of Rad53, which together with Chk1 represents a protein kinase central to all checkpoint pathways, normally requires Rad9, a checkpoint adaptor. Results. We report that in telomerase‐negative (tlc1Δ) cells, activation of Rad53, although diminished, could still take place in the absence of Rad9. In contrast, Rad9 was essential for Rad53 activation in cells that entered senescence in the presence of functional telomerase, namely in senescent cells bearing mutations in telomere end‐protection proteins (cdc13‐1 yku70Δ). In telomerase‐negative cells deleted for RAD9, Mrc1, another checkpoint adaptor previously implicated in the DNA replication checkpoint, mediated Rad53 activation. Rad9 and Rad53, as well as other DNA damage checkpoint proteins (Mec1, Mec3, Chk1 and Dun1), were required for complete DNA‐damage‐induced cell‐cycle arrest after loss of telomerase function. However, unexpectedly, given the formation of an active Rad53–Mrc1 complex in tlc1Δ rad9Δ cells, Mrc1 did not mediate the cell‐cycle arrest elicited by telomerase loss. Finally, we report that Rad9, Mrc1, Dun1 and Chk1 are activated by phosphorylation after telomerase inactivation. Conclusions. These results indicate that loss of telomere capping and loss of telomere sequences, both of which provoke telomeric senescence, are perceived as two distinct types of damages. In contrast with the Rad53–Rad9‐mediated cell‐cycle arrest that functions in a similar way in both types of telomeric senescence, activation of Rad53–Mrc1 might represent a specific response to telomerase inactivation and/or telomere shortening, the functional significance of which has yet to be uncovered.     

Recombination-Mediated Telomere Maintenance in Saccharomyces cerevisiae Is Not Dependent on the Shu Complex

In cells lacking telomerase, telomeres shorten progressively during each cell division due to incomplete end-replication. When the telomeres become very short, cells enter a state that blocks cell division, termed senescence. A subset of these cells can overcome senescence and maintain their telomeres using telomerase-independent mechanisms. In Saccharomyces cerevisiae, these cells are called ‘survivors’ and are dependent on Rad52-dependent homologous recombination and Pol32-dependent break-induced replication. There are two main types of survivors: type I and type II. The type I survivors require Rad51 and maintain telomeres by amplification of subtelomeric elements, while the type II survivors are Rad51-independent, but require the MRX complex and Sgs1 to amplify the C_1–3A/TG_1–3 telomeric sequences. Rad52, Pol32, Rad51, and Sgs1 are also important to prevent accelerated senescence, indicating that recombination processes are important at telomeres even before the formation of survivors. The Shu complex, which consists of Shu1, Shu2, Psy3, and Csm2, promotes Rad51-dependent homologous recombination and has been suggested to be important for break-induced replication. It also promotes the formation of recombination intermediates that are processed by the Sgs1-Top3-Rmi1 complex, as mutations in the SHU genes can suppress various sgs1, top3, and rmi1 mutant phenotypes. Given the importance of recombination processes during senescence and survivor formation, and the involvement of the Shu complex in many of the same processes during DNA repair, we hypothesized that the Shu complex may also have functions at telomeres. Surprisingly, we find that this is not the case: the Shu complex does not affect the rate of senescence, does not influence survivor formation, and deletion of SHU1 does not suppress the rapid senescence and type II survivor formation defect of a telomerase-negative sgs1 mutant. Altogether, our data suggest that the Shu complex is not important for recombination processes at telomeres.     

Tpz1-Ccq1 and Tpz1-Poz1 Interactions within Fission Yeast Shelterin Modulate Ccq1 Thr93 Phosphorylation and Telomerase Recruitment

In both fission yeast and humans, the shelterin complex plays central roles in regulation of telomerase recruitment, protection of telomeres against DNA damage response factors, and formation of heterochromatin at telomeres. While shelterin is essential for limiting activation of the DNA damage checkpoint kinases ATR and ATM at telomeres, these kinases are required for stable maintenance of telomeres. In fission yeast, Rad3^ATR and Tel1^ATM kinases are redundantly required for telomerase recruitment, since Rad3^ATR/Tel1^ATM-dependent phosphorylation of the shelterin subunit Ccq1 at Thr93 promotes interaction between Ccq1 and the telomerase subunit Est1. However, it remained unclear how protein-protein interactions within the shelterin complex (consisting of Taz1, Rap1, Poz1, Tpz1, Pot1 and Ccq1) contribute to the regulation of Ccq1 Thr93 phosphorylation and telomerase recruitment. In this study, we identify domains and amino acid residues that are critical for mediating Tpz1-Ccq1 and Tpz1-Poz1 interaction within the fission yeast shelterin complex. Using separation of function Tpz1 mutants that maintain Tpz1-Pot1 interaction but specifically disrupt either Tpz1-Ccq1 or Tpz1-Poz1 interaction, we then establish that Tpz1-Ccq1 interaction promotes Ccq1 Thr93 phosphorylation, telomerase recruitment, checkpoint inhibition and telomeric heterochromatin formation. Furthermore, we demonstrate that Tpz1-Poz1 interaction promotes telomere association of Poz1, and loss of Poz1 from telomeres leads to increases in Ccq1 Thr93 phosphorylation and telomerase recruitment, and telomeric heterochromatin formation defect. In addition, our studies establish that Tpz1-Poz1 and Tpz1-Ccq1 interactions redundantly fulfill the essential telomere protection function of the shelterin complex, since simultaneous loss of both interactions caused immediate loss of cell viability for the majority of cells and generation of survivors with circular chromosomes. Based on these findings, we suggest that the negative regulatory function of Tpz1-Poz1 interaction works upstream of Rad3^ATR kinase, while Tpz1-Ccq1 interaction works downstream of Rad3^ATR kinase to facilitate Ccq1 Thr93 phosphorylation and telomerase recruitment.     

Tel1 and Rif2 oppositely regulate telomere protection at uncapped telomeres in Saccharomyces cerevisiae

It has been well documented that Tel1 positively regulates telomere-end resection by promoting Mre11-Rad50-Xrs2(MRX) activity, while Rif2 negatively regulates telomere-end resection by inhibiting MRX activity. At uncapped telomeres, whether Tel1 or Rif2 plays any role remains largely unknown. In this work, we examined the roles of Tel1 and Rif2 at uncapped telomeres in yku70△ and/or cdc13-1 mutant cells cultured at non-permissive temperature. We found that deletion of TEL1 exacerbates the temperature sensitivity of both yku70△ and cdc13-1 cells. Further epistasis analysis indicated that MRX and Tel1 function in the same pathway in telomere protection. Consistently, TEL1 deletion increases accumulation of Exo1-dependent telomeric single-stranded DNA(ssDNA) at uncapped telomeres, which stimulates checkpoint-dependent cell cycle arrest. Moreover, TEL1 deletion in yku70△ cells facilitates Rad51-dependent Y0 recombination. In contrast, RIF2 deletion in yku70△ cells decreases the accumulation of telomeric ssDNA after 8 h of incubation at the non-permissive temperature of 37℃ and suppresses the temperature sensitivity of yku70△ cells, likely due to the increase of Mre11 association at telomeres.Collectively, our findings indicate that Tel1 and Rif2 regulate telomere protection at uncapped telomeres via their roles in balancing MRX activity in telomere resection.     

Break-Induced Replication Requires DNA Damage-Induced Phosphorylation of Pif1 and Leads to Telomere Lengthening

Broken replication forks result in DNA breaks that are normally repaired via homologous recombination or break induced replication (BIR). Mild insufficiency in the replicative ligase Cdc9 in budding yeast Saccharomyces cerevisiae resulted in a population of cells with persistent DNA damage, most likely due to broken replication forks, constitutive activation of the DNA damage checkpoint and longer telomeres. This telomere lengthening required functional telomerase, the core DNA damage signaling cascade Mec1-Rad9-Rad53, and the components of the BIR repair pathway – Rad51, Rad52, Pol32, and Pif1. The Mec1-Rad53 induced phosphorylation of Pif1, previously found necessary for inhibition of telomerase at double strand breaks, was also important for the role of Pif1 in BIR and telomere elongation in cdc9-1 cells. Two other mutants with impaired DNA replication, cdc44-5 and rrm3Δ, were similar to cdc9-1: their long telomere phenotype was dependent on the Pif1 phosphorylation locus. We propose a model whereby the passage of BIR forks through telomeres promotes telomerase activity and leads to telomere lengthening.     

“Poisoning” yeast telomeres distinguishes between redundant telomere capping pathways

In most eukaryotes, telomeres are composed of tandem arrays of species-specific DNA repeats ending with a G-rich 3′ overhang. In budding yeast, Cdc13 binds this overhang and recruits Ten1–Stn1 and the telomerase protein Est1 to protect (cap) and elongate the telomeres, respectively. To dissect and study the various pathways employed to cap and maintain the telomere end, we engineered telomerase to incorporate Tetrahymena telomeric repeats (G₄T₂) onto the telomeres of the budding yeast Kluyveromyces lactis. These heterologous repeats caused telomere–telomere fusions, cell cycle arrest at G2/M, and severely reduced viability—the hallmarks of telomere uncapping. Fusing Cdc13 or Est1 to universal minicircle sequence binding protein (UMSBP), a small protein that binds the single-stranded G₄T₂ repeats, rescued the cell viability and restored telomere capping, but not telomerase-mediated telomere maintenance. Surprisingly, Cdc13–UMSBP-mediated telomere capping was dependent on the homologous recombination factor Rad52, while Est1–UMSBP was not. Thus, our results distinguish between two, redundant, telomere capping pathways.     

Telomerase-dependent repeat divergence at the 3' ends of yeast telomeres

Yeast telomeres consist of ~300 nt of degenerate repeats with the consensus sequence G_2–3(TG)_1–6. We developed a method for the amplification of a genetically marked telomere by PCR, allowing precise length and sequence determination of the G-rich strand including the 3′ terminus. We examined wild-type cells, telomerase RNA deficient cells and a strain deleted for YKU70, which encodes for a protein involved in telomere maintenance and DNA double strand break repair. The 3′ end of the G-rich strand was found to be at a variable position within the telomeric repeat. No preference for either thymine or guanine as the 3′ base was detected. Comparison of telomere sequences from clonal populations revealed that telomeres consist of a centromere-proximal region of stable sequence and a distal region with differing degenerate repeats. In wild-type as well as yku70-Δ cells, variation in the degenerate telomeric repeats was detected starting 40–100 nt from the 3′ end. Sequence divergence was abolished after deletion of the telomerase RNA gene. Thus, this region defines the domain where telomere shortening and telomerase-mediated extension occurs. Since this domain is much larger than the number of nucleo­tides lost per generation in the absence of telomerase, we propose that telomerase does not extend a given telomere in every cell cycle.     

RAD50 and RAD51 define two pathways that collaborate to maintain telomeres in the absence of telomerase

Telomere length is maintained by the de novo addition of telomere repeats by telomerase, yet recombination can elongate telomeres in the absence of telomerase. When the yeast telomerase RNA component, TLC1, is deleted, telomeres shorten and most cells die. However, gene conversion mediated by the RAD52 pathway allows telomere lengthening in rare survivor cells. To further investigate the role of recombination in telomere maintenance, we assayed telomere length and the ability to generate survivors in several isogenic DNA recombination mutants, including rad50, rad51, rad52, rad54, rad57, xrs2, and mre11. The rad51, rad52, rad54, and rad57 mutations increased the rate of cell death in the absence of TLC1. In contrast, although the rad50, xrs2, and mre11 strains initially had short telomeres, double mutants with tlc1 did not affect the rate of cell death, and survivors were generated at later times than tlc1 alone. While none of the double mutants of recombination genes and tlc1 (except rad52 tlc1) blocked the ability to generate survivors, a rad50 rad51 tlc1 triple mutant did not allow the generation of survivors. Thus RAD50 and RAD51 define two separate pathways that collaborate to allow cells to survive in the absence of telomerase.     

At Short Telomeres Tel1 Directs Early Replication and Phosphorylates Rif1

The replication time of Saccharomyces cerevisiae telomeres responds to TG_1–3 repeat length, with telomeres of normal length replicating late during S phase and short telomeres replicating early. Here we show that Tel1 kinase, which is recruited to short telomeres, specifies their early replication, because we find a tel1Δ mutant has short telomeres that nonetheless replicate late. Consistent with a role for Tel1 in driving early telomere replication, initiation at a replication origin close to an induced short telomere was reduced in tel1Δ cells, in an S phase blocked by hydroxyurea. The telomeric chromatin component Rif1 mediates late replication of normal telomeres and is a potential substrate of Tel1 phosphorylation, so we tested whether Tel1 directs early replication of short telomeres by inactivating Rif1. A strain lacking both Rif1 and Tel1 behaves like a rif1Δ mutant by replicating its telomeres early, implying that Tel1 can counteract the delaying effect of Rif1 to control telomere replication time. Proteomic analyses reveals that in yku70Δ cells that have short telomeres, Rif1 is phosphorylated at Tel1 consensus sequences (S/TQ sites), with phosphorylation of Serine-1308 being completely dependent on Tel1. Replication timing analysis of a strain mutated at these phosphorylation sites, however, suggested that Tel1-mediated phosphorylation of Rif1 is not the sole mechanism of replication timing control at telomeres. Overall, our results reveal two new functions of Tel1 at shortened telomeres: phosphorylation of Rif1, and specification of early replication by counteracting the Rif1-mediated delay in initiation at nearby replication origins.     

Two pathways recruit telomerase to Saccharomyces cerevisiae telomeres

The catalytic subunit of yeast telomerase, Est2p, is a telomere associated throughout most of the cell cycle, while the Est1p subunit binds only in late S/G2 phase, the time of telomerase action. Est2p binding in G1/early S phase requires a specific interaction between telomerase RNA (TLC1) and Ku80p. Here, we show that in four telomerase-deficient strains (cdc13-2, est1Ä, tlc1-SD, and tlc1-BD), Est2p telomere binding was normal in G1/early S phase but reduced to about 40–50% of wild type levels in late S/G2 phase. Est1p telomere association was low in all four strains. Wild type levels of Est2p telomere binding in late S/G2 phase was Est1p-dependent and required that Est1p be both telomere-bound and associated with a stem-bulge region in TLC1 RNA. In three telomerase-deficient strains in which Est1p is not Est2p-associated (tlc1-SD, tlc1-BD, and est2Ä), Est1p was present at normal levels but its telomere binding was very low. When the G1/early S phase and the late S/G2 phase telomerase recruitment pathways were both disrupted, neither Est2p nor Est1p was telomere-associated. We conclude that reduced levels of Est2p and low Est1p telomere binding in late S/G2 phase correlated with an est phenotype, while a WT level of Est2p binding in G1 was not sufficient to maintain telomeres. In addition, even though Cdc13p and Est1p interact by two hybrid, biochemical and genetic criteria, this interaction did not occur unless Est1p was Est2p-associated, suggesting that Est1p comes to the telomere only as part of the holoenzyme. Finally, the G1 and late S/G2 phase pathways for telomerase recruitment are distinct and are likely the only ones that bring telomerase to telomeres in wild-type cells.     

Kinase-Independent Functions of TEL1 in Telomere Maintenance

TEL1 is important in Saccharomyces cerevisiae telomere maintenance, and its kinase activity is required. Tel1p associates with telomeres in vivo, is enriched at short telomeres, and enhances the binding of telomerase components to short telomeres. However, it is unclear how the kinase activity and telomere association contribute to Tel1p''s overall function in telomere length maintenance. To investigate this question, we generated a set of single point mutants and a double point mutant (tel1^KD) of Tel1p that were kinase deficient and two Xrs2p mutants that failed to bind Tel1p. Using these separation-of-function alleles in a de novo telomere elongation assay, we found, surprisingly, that the tel1^KD allele and xrs2 C-terminal mutants were both partially functional. Combining the tel1^KD and xrs2 C-terminal mutants had an additive effect and resembled the TEL1 null (tel1Δ) phenotype. These data indicate that Tel1p has two separate functions in telomere maintenance and that the Xrs2p-dependent recruitment of Tel1p to telomeres plays an important role even in the absence of its kinase activity.The telomere is a highly ordered complex of proteins and DNA found at the ends of linear chromosomes that functions to protect the ends and prevents them from being recognized as double-strand DNA breaks (51). Telomeres shorten gradually due to incomplete replication (1, 20), and this shortening is counteracted by telomerase, which elongates telomeres (18, 19).Saccharomyces cerevisiae telomeres are composed of 300 ± 50 bp of the sequence TG_1-3/C_1-3A. The yeast telomerase complex consists of Est2p (catalytic subunit), the RNA component TLC1, and two accessory proteins, Est1p and Est3p (50). Cells deficient for any of these telomerase components undergo progressive telomere shortening and a simultaneous decrease in growth rate, described as senescence (24, 27). Typically, a small fraction of cells, termed survivors, escape senescence and maintain telomere length by utilizing RAD52-dependent recombination (24, 26).In addition to the telomerase complex, a number of yeast proteins are important in maintaining telomere length and integrity. These include Tel1p and Mec1p, the yeast homologues of mammalian ATM and ATR, respectively (39). While deletion of TEL1 results in short but stable telomeres, MEC1 deletion has little effect on average telomere length. However, cells lacking TEL1 that have a mutant mec1-21 allele undergo senescence, similar to telomerase null cells (36), suggesting that MEC1 plays a minor but essential role in telomere length maintenance in tel1Δ cells. It has been shown that the protein kinase activities of Tel1p and Mec1p are essential in telomere maintenance, since tel1^KD cells have short telomeres and tel1Δ mec1^KD cells undergo senescence (29).In current models, Tel1p acts to maintain telomere length by regulating the access of telomerase to short telomeres. TEL1 is required for the association of Est1p and Est2p with telomeres in the late S/G₂ phase of the cell cycle (16), the time when telomeres are elongated (9, 31). Additionally, in both yeast and mammalian cells, telomerase preferentially elongates the shortest telomeres (22, 30, 47). Therefore, TEL1 seems to be required mainly for the association of telomerase to short telomeres in yeast. Indeed, Tel1p preferentially binds to short telomeres (4, 21, 38) and is essential for the increased association of Est1p and Est2p to short telomeres during late S/G₂ (38). However, the kinase activity of Tel1p is not required for the telomere association (21). In addition to its role in telomerase recruitment, TEL1 may also regulate telomere length by enhancing the processivity of telomerase at short telomeres (7).The Mre11p, Rad50p, and Xrs2p (MRX) complex also plays important roles in telomere maintenance. Cells lacking any one of these components (mrxΔ) have short and stable telomeres. Since combining mrxΔ with tel1Δ has no synergistic effect on telomere shortening and mrxΔ mec1Δ cells undergo senescence, it was proposed that the MRX complex and Tel1p function in the same telomere maintenance pathway (37). In agreement with this model, the C-terminal region of Xrs2p is essential in recruiting Tel1p both to double-strand breaks (32) and to short telomeres (38). Interestingly, the mammalian functional homologue of Xrs2p, NBS1, interacts with ATM via its extreme C terminus (13), suggesting that the recruitment of Tel1p to telomeres and the recruitment of ATM to DNA damage sites are conserved.It remains a question what exact roles the kinase activity of Tel1p and its telomere binding play in telomere maintenance. Tel1p''s telomere maintenance function seems to be dependent on its kinase activity, since tel1^KD cells have short telomeres (29). It has been proposed that Tel1p may regulate the recruitment of Est1p, and thus the rest of the telomerase complex (12, 23, 54), to telomeres by phosphorylating Cdc13p (3, 48). Other experiments suggest the association of Tel1p to the telomere plays a major role. The preferential binding of Tel1p to short telomeres is lost in xrs2-664 cells (38), which lack the C-terminal 190 amino acids of Xrs2p and have short telomeres, similar to xrs2Δ (41). It has been suggested that the association of Tel1p to telomeres is required for its substrate phosphorylation and, therefore, telomere length maintenance (3, 39).To further analyze the functions of Tel1p in telomere maintenance, we generated a novel kinase-dead allele of TEL1 and new alleles of XRS2 that do not interact with Tel1p. Through these separation-of-function mutants, we show that both sets of alleles are partially active in a de novo telomere elongation assay. However, combining both the tel1^KD and either of the Tel1p interaction-deficient xrs2 alleles resulted in a phenotype resembling the tel1Δ phenotype, suggesting that Tel1p has kinase-dependent and kinase-independent, but telomere binding-dependent, functions in telomere maintenance.     

The role of the Mre11-Rad50-Xrs2 complex in telomerase- mediated lengthening of Saccharomyces cerevisiae telomeres.

BACKGROUND: The Saccharomyces Mre11p, Rad50p, and Xrs2p proteins form a complex, called the MRX complex, that is required to maintain telomere length. Cells lacking any one of the three MRX proteins and Mec1p, an ATM-like protein kinase, undergo telomere shortening and ultimately die, phenotypes characteristic of cells lacking telomerase. The other ATM-like yeast kinase, Tel1p, appears to act in the same pathway as MRX: mec1 tel1 cells have telomere phenotypes similar to those of telomerase-deficient cells, whereas the phenotypes of tel1 cells are not exacerbated by the loss of a MRX protein. RESULTS: The nuclease activity of Mre11p was found to be dispensable for the telomerase-promoting activity of the MRX complex. The association of the single-stranded TG1-3 DNA binding protein Cdc13p with yeast telomeres occurred efficiently in the absence of Tel1p, Mre11p, Rad50p, or Xrs2p. Targeting of catalytically active telomerase to the telomere suppressed the senescence phenotype of mec1 mrx or mec1 tel1 cells. Moreover, when telomerase was targeted to telomeres, telomere lengthening was robust in mec1 mrx and mec1 tel1 cells. CONCLUSIONS: These data rule out models in which the MRX complex is necessary for Cdc13p binding to telomeres or in which the MRX complex is necessary for the catalytic activity of telomerase. Rather, the data suggest that the MRX complex is involved in recruiting telomerase activity to yeast telomeres.     

Roles of the checkpoint sensor clamp Rad9-Rad1-Hus1 (911)-complex and the clamp loaders Rad17-RFC and Ctf18-RFC in Schizosaccharomyces pombe telomere maintenance

While telomeres must provide mechanisms to prevent DNA repair and DNA damage checkpoint factors from fusing chromosome ends and causing permanent cell cycle arrest, these factors associate with functional telomeres and play critical roles in the maintenance of telomeres. Previous studies have established that Tel1 (ATM) and Rad3 (ATR) kinases play redundant but essential roles for telomere maintenance in fission yeast. In addition, the Rad9-Rad1-Hus1 (911) and Rad17-RFC complexes work downstream of Rad3 (ATR) in fission yeast telomere maintenance. Here, we investigated how 911, Rad17-RFC and another RFC-like complex Ctf18-RFC contribute to telomere maintenance in fission yeast cells lacking Tel1 and carrying a novel hypomorphic allele of rad3 (DBD-rad3), generated by the fusion between the DNA binding domain (DBD) of the fission yeast telomere capping protein Pot1 and Rad3. Our investigations have uncovered a surprising redundancy for Rad9 and Hus1 in allowing Rad1 to contribute to telomere maintenance in DBD-rad3 tel1 cells. In addition, we found that Rad17-RFC and Ctf18-RFC carry out redundant telomere maintenance functions in DBD-rad3 tel1 cells. Since checkpoint sensor proteins are highly conserved, genetic redundancies uncovered here may be relevant to telomere maintenance and detection of DNA damage in other eukaryotes.