The intrinsically disordered N-terminal region of mouse DNA polymerase alpha mediates its interaction with POT1a/b at telomeres

Mouse telomerase and the DNA polymerase alpha-primase complex elongate the leading and lagging strands of telomeres, respectively. To elucidate the molecular mechanism of lagging strand synthesis, we investigated the interaction between DNA polymerase alpha and two paralogs of the mouse POT1 telomere-binding protein (POT1a and POT1b). Yeast two-hybrid analysis and a glutathione S-transferase pull-down assay indicated that the C-terminal region of POT1a/b binds to the intrinsically disordered N-terminal region of p180, the catalytic subunit of mouse DNA polymerase alpha. Subcellular distribution analyses showed that although POT1a, POT1b, and TPP1 were localized to the cytoplasm, POT1a-TPP1 and POT1b-TPP1 coexpressed with TIN2 localized to the nucleus in a TIN2 dose-dependent manner. Coimmunoprecipitation and cell cycle synchronization experiments indicated that POT1b-TPP1-TIN2 was more strongly associated with p180 than POT1a-TPP1-TIN2, and this complex accumulated during the S phase. Fluorescence in situ hybridization and proximity ligation assays showed that POT1a and POT1b interacted with p180 and TIN2 on telomeric chromatin. Based on the present study and a previous study, we propose a model in which POT1a/b-TPP1-TIN2 translocates into the nucleus in a TIN2 dose-dependent manner to target the telomere, where POT1a/b interacts with DNA polymerase alpha for recruitment at the telomere for lagging strand synthesis.     

TRF1 negotiates TTAGGG repeat-associated replication problems by recruiting the BLM helicase and the TPP1/POT1 repressor of ATR signaling

The semiconservative replication of telomeres is facilitated by the shelterin component TRF1. Without TRF1, replication forks stall in the telomeric repeats, leading to ATR kinase signaling upon S-phase progression, fragile metaphase telomeres that resemble the common fragile sites (CFSs), and the association of sister telomeres. In contrast, TRF1 does not contribute significantly to the end protection functions of shelterin. We addressed the mechanism of TRF1 action using mouse conditional knockouts of BLM, TRF1, TPP1, and Rap1 in combination with expression of TRF1 and TIN2 mutants. The data establish that TRF1 binds BLM to facilitate lagging but not leading strand telomeric DNA synthesis. As the template for lagging strand telomeric DNA synthesis is the TTAGGG repeat strand, TRF1-bound BLM is likely required to remove secondary structures formed by these sequences. In addition, the data establish that TRF1 deploys TIN2 and the TPP1/POT1 heterodimers in shelterin to prevent ATR during telomere replication and repress the accompanying sister telomere associations. Thus, TRF1 uses two distinct mechanisms to promote replication of telomeric DNA and circumvent the consequences of replication stress. These data are relevant to the expression of CFSs and provide insights into TIN2, which is compromised in dyskeratosis congenita (DC) and related disorders.     

Cdc13 both positively and negatively regulates telomere replication

Cdc13 is a single-strand telomeric DNA-binding protein that positively regulates yeast telomere replication by recruiting telomerase to chromosome termini through a site on Cdc13 that is eliminated by the cdc13-2 mutation. Here we show that Cdc13 has a separate role in negative regulation of telomere replication, based on analysis of a new mutation, cdc13-5. Loss of this second regulatory activity results in extensive elongation of the G strand of the telomere by telomerase, accompanied by a reduced ability to coordinate synthesis of the C strand. Both the cdc13-5 mutation and DNA polymerase alpha mutations (which also exhibit elongated telomeres) are suppressed by increased expression of the Cdc13-interacting protein Stn1, indicating that Stn1 coordinates action of the lagging strand replication complex with the regulatory activity of CDC13. However, the association between Cdc13 and Stn1 is abolished by cdc13-2, the same mutation that eliminates the interaction between Cdc13 and telomerase. We propose that Cdc13 participates in two regulatory steps-first positive, then negative-as a result of successive binding of telomerase and the negative regulator Stn1 to overlapping sites on Cdc13. Thus, Cdc13 coordinates synthesis of both strands of the telomere by first recruiting telomerase and subsequently limiting G-strand synthesis by telomerase in response to C-strand replication.     

Early and late steps in telomere overhang processing in normal human cells: the position of the final RNA primer drives telomere shortening

Telomere overhangs are essential for telomere end protection and telomerase extension, but how telomere overhangs are generated is unknown. Leading daughter strands synthesized by conventional semiconservation DNA replication are initially blunt, while lagging daughter strands are shorter by at least the size of the final RNA primer, which is thought to be located at extreme chromosome ends. We developed a variety of new approaches to define the steps in the processing of these overhangs. We show that the final lagging RNA primer is not terminal but is randomly positioned ~70-100 nucleotides from the ends and is not removed for more than an hour. This identifies an important intrinsic step in replicative aging. Telomeric termini are processed in two distinct phases. During the early phase, which occupies 1-2 h following replication of the duplex telomeric DNA, several steps occur on both leading and lagging daughters. Leading telomere processing remains incomplete until late S/G2, when the C-terminal nucleotide is specified-referred to as the late phase. These observations suggest the presence of previously unsuspected complexes and signaling events required for the replication of the ends of human chromosomes.     

A POT1 mutation implicates defective telomere end fill-in and telomere truncations in Coats plus

Coats plus (CP) can be caused by mutations in the CTC1 component of CST, which promotes polymerase α (polα)/primase-dependent fill-in throughout the genome and at telomeres. The cellular pathology relating to CP has not been established. We identified a homozygous POT1 S322L substitution (POT1^CP) in two siblings with CP. POT1^CP induced a proliferative arrest that could be bypassed by telomerase. POT1^CP was expressed at normal levels, bound TPP1 and telomeres, and blocked ATR signaling. POT1^CP was defective in regulating telomerase, leading to telomere elongation rather than the telomere shortening observed in other telomeropathies. POT1^CP was also defective in the maintenance of the telomeric C strand, causing extended 3′ overhangs and stochastic telomere truncations that could be healed by telomerase. Consistent with shortening of the telomeric C strand, metaphase chromosomes showed loss of telomeres synthesized by leading strand DNA synthesis. We propose that CP is caused by a defect in POT1/CST-dependent telomere fill-in. We further propose that deficiency in the fill-in step generates truncated telomeres that halt proliferation in cells lacking telomerase, whereas, in tissues expressing telomerase (e.g., bone marrow), the truncations are healed. The proposed etiology can explain why CP presents with features distinct from those associated with telomerase defects (e.g., dyskeratosis congenita).     

Long inverted repeat transiently stalls DNA replication by forming hairpin structures on both leading and lagging strands

Long inverted repeats (LIRs), often found in eukaryotic genomes, are unstable in Escherichia coli where they are recognized by the SbcCD (the bacterial Mre11/Rad50 homologue), an endonuclease/exonuclease capable of cleaving hairpin DNA. It has long been postulated that LIRs form hairpin structures exclusively on the lagging‐strand template during DNA replication, and SbcCD cleaves these hairpin‐containing lagging strands to generate DNA double‐strand breaks. Using a reconstituted oriC plasmid DNA replication system, we have examined how a replication fork behaves when it meets a LIR on DNA. We have shown that leading‐strand synthesis stalls transiently within the upstream half of the LIR. Pausing of lagging‐strand synthesis at the LIR was not clearly observed, but the pattern of priming sites for Okazaki fragment synthesis was altered within the downstream half of the LIR. We have found that the LIR on a replicating plasmid was cleaved by SbcCD with almost equal frequency on both the leading‐ and lagging‐strand templates. These data strongly suggest that the LIR is readily converted to a cruciform DNA, before the arrival of the fork, creating SbcCD‐sensitive hairpin structures on both leading and lagging strands. We propose a model for the replication‐dependent extrusion of LIRs to form cruciform structures that transiently impede replication fork movement.     

Pol12, the B subunit of DNA polymerase alpha, functions in both telomere capping and length regulation

The regulation of telomerase action, and its coordination with conventional DNA replication and chromosome end "capping," are still poorly understood. Here we describe a genetic screen in yeast for mutants with relaxed telomere length regulation, and the identification of Pol12, the B subunit of the DNA polymerase alpha (Pol1)-primase complex, as a new factor involved in this process. Unlike many POL1 and POL12 mutations, which also cause telomere elongation, the pol12-216 mutation described here does not lead to either reduced Pol1 function, increased telomeric single-stranded DNA, or a reduction in telomeric gene silencing. Instead, and again unlike mutations affecting POL1, pol12-216 is lethal in combination with a mutation in the telomere end-binding and capping protein Stn1. Significantly, Pol12 and Stn1 interact in both two-hybrid and biochemical assays, and their synthetic-lethal interaction appears to be caused, at least in part, by a loss of telomere capping. These data reveal a novel function for Pol12 and a new connection between DNA polymerase alpha and Stn1. We propose that Pol12, together with Stn1, plays a key role in linking telomerase action with the completion of lagging strand synthesis, and in a regulatory step required for telomere capping.     

POT1-interacting protein PIP1: a telomere length regulator that recruits POT1 to the TIN2/TRF1 complex

Human telomere length is controlled by a negative feedback loop based on the binding of TRF1 to double-stranded telomeric DNA. The TRF1 complex recruits POT1, a single-stranded telomeric DNA-binding protein necessary for cis-inhibition of telomerase. By mass spectrometry, we have identified a new telomeric protein, which we have named POT1-interacting protein 1 (PIP1). PIP1 bound both POT1 and the TRF1-interacting factor TIN2 and could tether POT1 to the TRF1 complex. Reduction of PIP1 or POT1 levels with shRNAs led to telomere elongation, indicating that PIP1 contributes to telomere length control through recruitment of POT1.     

Telomere ResQue and preservation--roles for the Werner syndrome protein and other RecQ helicases

Werner syndrome is an autosomal recessive disorder resulting from loss of function of the RecQ helicase, WRN protein. WS patients prematurely develop numerous clinical symptoms and diseases associated with aging early in life and are predisposed to cancer. WRN protein and many other RecQ helicases in general, seem to function during DNA replication in the processing of stalled replication forks. Genetic, cellular and biochemical evidence support roles for WRN in proper replication and repair of telomeric DNA, and indicate that telomere dysfunction contributes to the WS disease pathology.     

Fate of DNA replication fork encountering a single DNA lesion during oriC plasmid DNA replication in vitro

BACKGROUND: The inhibition of DNA replication fork progression by DNA lesions can lead to cell death or genome instability. However, little is known about how such DNA lesions affect the concurrent synthesis of leading- and lagging-strand DNA catalysed by the protein machinery used in chromosomal replication. Using a system of semi-bidirectional DNA replication of an oriC plasmid that employs purified replicative enzymes and a replication-terminating protein of Escherichia coli, we examined the dynamics of the replication fork when it encounters a single abasic DNA lesion on the template DNA. RESULTS: A DNA lesion located on the lagging strand completely blocked the synthesis of the Okazaki fragment extending toward the lesion site, but did not affect the progression of the replication fork or leading-strand DNA synthesis. In contrast, a DNA lesion on the leading strand stalled the replication fork in conjunction with strongly inhibiting leading-strand synthesis. However, about two-thirds of the replication forks encountering this lesion maintained lagging-strand synthesis for about 1 kb beyond the lesion site, and the velocity with which the replication fork progressed seemed to be significantly reduced. CONCLUSIONS: The blocking DNA lesion affects DNA replication differently depending on which strand, leading or lagging, contains the lesion.     

Base composition at mtDNA boundaries suggests a DNA triple helix model for human mitochondrial DNA large-scale rearrangements

Different mechanisms have been proposed to account for mitochondrial DNA (mtDNA) instability based on the presence of short homologous sequences (direct repeats, DR) at the potential boundaries of mtDNA rearrangements. Among them, slippage-mispairing of the replication complex during the asymmetric replication cycle of the mammalian mitochondrial DNA has been proposed to account for the preferential localization of deletions. This mechanism involves a transfer of the replication complex from the first neo-synthesized heavy (H) strand of the DR1, to the DR2, thus bypassing the intervening sequence and producing a deleted molecule. Nevertheless, the nature of the bonds between the DNA strands remains unknown as the forward sequence of DR2, beyond the replication complex, stays double-stranded. Here, we have analyzed the base composition of the DR at the boundaries of mtDNA deletions and duplications and found a skewed pyrimidine content of about 75% in the light-strand DNA template. This suggests the possible building of a DNA triple helix between the G-rich neo-synthesized DR1 and the base-paired homologous G.C-rich DR2. In vitro experiments with the purified human DNA polymerase gamma subunits enabled us to show that the third DNA strand may be used as a primer for DNA replication, using a template with the direct repeat forming a hairpin, with which the primer could initiate DNA replication. These data suggest a novel molecular basis for mitochondrial DNA rearrangements through the distributive nature of the DNA polymerase gamma, at the level of the direct repeats. A general model accounting for large-scale mitochondrial DNA deletion and duplication is proposed. These experiments extend to a DNA polymerase from an eucaryote source the use of a DNA triple helix strand as a primer, like other DNA polymerases from phage and bacterial origins.     

Saccharomyces Rrm3p,a 5' to 3' DNA helicase that promotes replication fork progression through telomeric and subtelomeric DNA

In wild-type Saccharomyces cerevisiae, replication forks slowed during their passage through telomeric C(1-3)A/TG(1-3) tracts. This slowing was greatly exacerbated in the absence of RRM3, shown here to encode a 5' to 3' DNA helicase. Rrm3p-dependent fork progression was seen at a modified Chromosome VII-L telomere, at the natural X-bearing Chromosome III-L telomere, and at Y'-bearing telomeres. Loss of Rrm3p also resulted in replication fork pausing at specific sites in subtelomeric DNA, such as at inactive replication origins, and at internal tracts of C(1-3)A/TG(1-3) DNA. The ATPase/helicase activity of Rrm3p was required for its role in telomeric and subtelomeric DNA replication. Because Rrm3p was telomere-associated in vivo, it likely has a direct role in telomere replication.     

Quantitative analysis of WRN exonuclease activity by isotope dilution mass spectrometry

Werner syndrome is a disorder characterized by a premature aging phenotype. The disease is caused by mutations in the WRN gene which encodes a DNA helicase/exonuclease which is involved in multiple aspects of DNA metabolism. Current methods mostly rely on radiometric techniques to assess WRN exonuclease activity. Here we present an alternative, quantitative approach based on non-radioactive isotope dilution mass spectrometry (LC-MS/MS). A oligoduplex substrate mimicking the telomeric sequence was used for method development. Released nucleotides, which correlate with the degree of oligoduplex degradation, were dephosphorylated, purified, and quantified by LC-MS/MS. Heavy-isotope-labeled internal standards were used to account for technical variability. The method was validated in terms of reproducibility, time-course and concentration-dependency of the reaction. As shown in this study, the LC-MS/MS method can assess exonuclease activity of WRN mutants, WRN's substrate and strand specificity, and modulatory effects of WRN interaction partners and posttranslational modifications. Moreover, it can be used to analyze the selectivity and processivity of WRN exonuclease and allows the screening of small molecules for WRN exonuclease inhibitors. Importantly, this approach can easily be adapted to study nucleases other than WRN. This is of general interest, because exonucleases are key players in DNA metabolism and aging mechanisms.     

UV lesions located on the leading strand inhibit DNA replication but do not inhibit SV40 T-antigen helicase activity

DNA replication in eucaryotic cells involves a variety of proteins which synthesize the leading and lagging strands in an asymmetric coordinated manner. To analyse the effect of this asymmetry on the translesion synthesis of UV-induced lesions, we have incubated SV40 origin-containing plasmids with a unique site-specific cis,syn-cyclobutane dimer or a pyrimidine-pyrimidone (6-4) photoproduct on either the leading or lagging strand template with DNA replication-competent extracts made from human HeLa cells. Two dimensional agarose gel electrophoresis analyses revealed a strong blockage of fork progression only when the UV lesion is located on the leading strand template. Because DNA helicases are responsible for unwinding duplex DNA ahead of the fork and are then the first component to encounter any potential lesion, we tested the effect of these single photoproducts on the unwinding activity of the SV40 T antigen, the major helicase in our in vitro replication assay. We showed that the activity of the SV40 T-antigen helicase is not inhibited by UV-induced DNA lesions in double-stranded DNA substrate.     

Molecular basis of telomere syndrome caused by CTC1 mutations

Mutations in CTC1 lead to the telomere syndromes Coats Plus and dyskeratosis congenita (DC), but the molecular mechanisms involved remain unknown. CTC1 forms with STN1 and TEN1 a trimeric complex termed CST, which binds ssDNA, promotes telomere DNA synthesis, and inhibits telomerase-mediated telomere elongation. Here we identify CTC1 disease mutations that disrupt CST complex formation, the physical interaction with DNA polymerase α-primase (polα-primase), telomeric ssDNA binding in vitro, accumulation in the nucleus, and/or telomere association in vivo. While having diverse molecular defects, CTC1 mutations commonly lead to the accumulation of internal single-stranded gaps of telomeric DNA, suggesting telomere DNA replication defects as a primary cause of the disease. Strikingly, mutations in CTC1 may also unleash telomerase repression and telomere length control. Hence, the telomere defect initiated by CTC1 mutations is distinct from the telomerase insufficiencies seen in classical forms of telomere syndromes, which cause short telomeres due to reduced maintenance of distal telomeric ends by telomerase. Our analysis provides molecular evidence that CST collaborates with DNA polα-primase to promote faithful telomere DNA replication.     

Normal human chromosomes have long G-rich telomeric overhangs at one end

Telomeres protect the ends of linear chromosomes from degradation and abnormal recombination events, and in vertebrates may be important in cellular senescence and cancer. However, very little is known about the structure of human telomeres. In this report we purify telomeres and analyze their termini. We show that following replication the daughter telomeres have different terminal overhangs in normal diploid telomerase-negative human fibroblasts. Electron microscopy of those telomeres that have long overhangs yields 200±75 nucleotides of single-stranded DNA. This overhang is four times greater than the amount of telomere shortening per division found in these cells. These results are consistent with models of telomere replication in which leading-strand synthesis generates a blunt end while lagging-strand synthesis produces a long G-rich 3′ overhang, and suggest that variations in lagging-strand synthesis may regulate the rate of telomere shortening in normal diploid human cells. Our results do not exclude the possibility that nuclease processing events following leading strand synthesis result in short overhangs on one end.     

Distinct roles of DNA polymerases delta and epsilon at the replication fork in Xenopus egg extracts

DNA polymerases delta and epsilon (Poldelta and Polepsilon) are widely thought to be the major DNA polymerases that function in elongation during DNA replication in eukaryotic cells. However, the precise roles of these polymerases are still unclear. Here we comparatively analysed DNA replication in Xenopus egg extracts in which Poldelta or Polepsilon was immunodepleted. Depletion of either polymerase resulted in a significant decrease in DNA synthesis and accumulation of short nascent DNA products, indicating an elongation defect. Moreover, Poldelta depletion caused a more severe defect in elongation, as shown by sustained accumulation of both short nascent DNA products and single-stranded DNA gaps, and also by elevated chromatin binding of replication proteins that function more frequently during lagging strand synthesis. Therefore, our data strongly suggest the possibilities that Poldelta is essential for lagging strand synthesis and that this function of Poldelta cannot be substituted for by Polepsilon.     

TRF2 overexpression diminishes repair of telomeric single-strand breaks and accelerates telomere shortening in human fibroblasts

Repair of single strand breaks in telomeric DNA is less efficient than in other genomic regions. This leads to an increased vulnerability of telomeric DNA towards damage induced by reactive oxygen species (ROS) and to accelerated telomere shortening under oxidative stress. The causes for the diminished repair efficacy in telomeres are unknown. We show here that overexpression of the telomere-binding protein TRF2 further reduces telomeric, but not genomic, single strand break repair. This suggests the possibility of strand break repair in telomeres being sterically hindered by the three-dimensional structure of the telomere DNA-protein complex and explains the effect of TRF2 on telomere shortening rates in telomerase-negative cells.     

Unwinding the molecular basis of the Werner syndrome

Werner syndrome (WS) is an autosomal recessive disease manifested by the premature onset of age-related phenotypes, including diseases such as atherosclerosis and cancer. This mimicry of normal aging with the possible exception of central nervous system manifestations has made it a focus of recent molecular studies on the pathophysiology of aging. In culture, cells obtained from patients with WS are genetically unstable, characterized by an increased frequency of nonclonal translocations and extensive DNA deletions. The WS gene product (WRN) is a DNA helicase belonging to the RecQ family, but is unique within this family in that it also contains an exonuclease activity. In addition to unwinding double-stranded DNA, WRN helicase is able to resolve aberrant DNA structures such as G4 tetraplexes, triplexes and 4-way junctions. Concordant with this structure-specificity, WRN exonuclease preferentially hydrolyzes alternative DNA that contains bubbles, extra-helical loops, 3-way junctions or 4-way junctions. WRN has been shown to bind to and/or functionally interact with other proteins, including replication protein A (RPA), proliferating cell nuclear antigen (PCNA), DNA topoisomerase I, Ku 86/70, DNA polymerase delta and p53. Each of these interacting proteins is involved in DNA transactions including those that resolve alternative DNA structures or repair DNA damage. The biochemical activities of WRN and the functions of WRN associated proteins suggest that in vivo WRN resolves DNA topological or structural aberrations that either occur during DNA metabolic processes such as recombination, replication and repair, or are the outcome of DNA damage.     

Functional interaction between telomere protein TPP1 and telomerase

Human chromosome end-capping and telomerase regulation require POT1 (Protection of Telomeres 1) and TPP1 proteins, which bind to the 3′ ssDNA extension of human telomeres. POT1–TPP1 binding to telomeric DNA activates telomerase repeat addition processivity. We now provide evidence that this POT1–TPP1 activation requires specific interactions with telomerase, rather than it being a DNA substrate-specific effect. First, telomerase from the fish medaka, which extends the same telomeric DNA primer as human telomerase, was not activated by human POT1–TPP1. Second, mutation of a conserved glycine, Gly100 in the TEN (telomerase essential N-terminal) domain of TERT, abolished the enhancement of telomerase processivity by POT1–TPP1, in contrast to other single amino acid mutations. Chimeric human–fish telomerases that contained the human TEN domain were active but not stimulated by POT1–TPP1, showing that additional determinants of processivity lie outside the TEN domain. Finally, primers bound to mouse POT1A and human TPP1 were activated for extension by human telomerase, whereas mPOT1A–mTPP1 was most active with mouse telomerase, indicating that these mammalian telomerases have specificity for their respective TPP1 proteins. We suggest that a sequence-specific interaction between TPP1 in the TPP1–POT1–telomeric DNA complex and the G100 region of the TEN domain of TERT is necessary for high-processivity telomerase action.