POT1 protects telomeres from a transient DNA damage response and determines how human chromosomes end

The hallmarks of telomere dysfunction in mammals are reduced telomeric 3' overhangs, telomere fusions, and cell cycle arrest due to a DNA damage response. Here, we report on the phenotypes of RNAi-mediated inhibition of POT1, the single-stranded telomeric DNA-binding protein. A 10-fold reduction in POT1 protein in tumor cells induced neither telomere fusions nor cell cycle arrest. However, the 3' overhang DNA was reduced and all telomeres elicited a transient DNA damage response in G1, indicating that extensive telomere damage can occur without cell cycle arrest or telomere fusions. RNAi to POT1 also revealed its role in generating the correct sequence at chromosome ends. The recessed 5' end of the telomere, which normally ends on the sequence ATC-5', was changed to a random position within the AATCCC repeat. Thus, POT1 determines the structure of the 3' and 5' ends of human chromosomes, and its inhibition generates a novel combination of telomere dysfunction phenotypes in which chromosome ends behave transiently as sites of DNA damage, yet remain protected from nonhomologous end-joining.     

Identification and characterization of a putative telomere end-binding protein from Tetrahymena thermophila.

Telomeric DNA of Tetrahymena thermophila consists of a long stretch of (TTGGGG)n double-stranded repeats with a single-stranded (TTGGGG)2 3' overhang at the end of the chromosome. We have identified and characterized a protein that specifically binds to a synthetic telomeric substrate consisting of duplex DNA and the 3' telomeric repeat overhang. This protein is called TEP (telomere end-binding protein). A change from G to A in the third position of the TTGGGG overhang repeat converts the substrate to a human telomere analog and reduces the binding affinity approximately threefold. Changing two G's to C's in the TTGGGG repeats totally abolishes binding. However, permutation of the Tetrahymena repeat sequence has only a minor effect on binding. A duplex structure adjacent to the 3' overhang is required for binding, although the duplex need not contain telomeric repeats. TEP does not bind to G-quartet DNA, which is formed by many G-rich sequences. TEP has a greatly reduced affinity for RNA substrates. The copy number of TEP is at least 2 x 10(4) per cell, and it is present under different conditions of cell growth and development, although its level varies. UV cross-linking experiments show that TEP has an apparent molecular mass of approximately 65 kDa. Unlike other telomere end-binding proteins, TEP is sensitive to high salt concentrations.     

Distinct requirements for Pot1 in limiting telomere length and maintaining chromosome stability

The fission yeast Pot1 (protection of telomeres) protein binds to the single-stranded extensions at the ends of telomeres, where its presence is critical for the maintenance of linear chromosomes. Homologs of Pot1 have been identified in a wide variety of eukaryotes, including plants, animals, and humans. We now show that Pot1 plays dual roles in telomere length regulation and chromosome end protection. Using a series of Pot1 truncation mutants, we have defined distinct areas of the protein required for chromosome stability and for limiting access to telomere ends by telomerase. We provide evidence that a large portion of Pot1, including the N-terminal DNA binding domain and amino acids close to the C terminus, is essential for its protective function. C-terminal Pot1 fragments were found to exert a dominant-negative effect by displacing endogenous Pot1 from telomeres. Reducing telomere-bound Pot1 in this manner resulted in dramatic lengthening of the telomere tract. Upon further reduction of Pot1 at telomeres, the opposite phenotype was observed: loss of telomeric DNA and chromosome end fusions. Our results demonstrate that cells must carefully regulate the amount of telomere-bound Pot1 to differentiate between allowing access to telomerase and catastrophic loss of telomeres.     

The Saccharomyces cerevisiae chromosome III left telomere has a type X, but not a type Y'', ARS region.

A yeast Saccharomyces cerevisiae telomeric region was isolated by chromosome walking from HML alpha, the most distal known gene on the chromosome III left (IIIL) end. The terminal heterodisperse 3.3-kilobase (kb) SalI fragment on chromosome IIIL, 8.6 kb distal to HML alpha, was cloned in a circular vector to generate a telomeric probe. Southern hybridization and DNA sequencing analyses indicated that 0.6 kb (+/- 200 base pairs) of 5'-C1-3A-3' simple tandem repeat sequence, adjacent to a 1.2-kb type X ARS region, constitutes the telomere on the chromosome IIIL end, and no type Y' ARS region homologies exist between HML alpha and the IIIL terminus.     

Interaction of an Arabidopsis RNA-binding protein with plant single-stranded telomeric DNA modulates telomerase activity

Telomeres are the specialized structures at the end of linear chromosomes and terminate with a single-stranded 3' overhang of the G-rich strand. The primary role of telomeres is to protect chromosome ends from recombination and fusion and from being recognized as broken DNA ends. This protective function can be achieved through association with specific telomere-binding proteins. Although proteins that bind single-stranded G-rich overhang regulate telomere length and telomerase activity in mammals and lower eukaryotes, equivalent factors have yet to be identified in plants. Here we have identified proteins capable of interacting with the G-rich single-stranded telomeric repeat from the Arabidopsis extracts by affinity chromatography. Matrix-assisted laser desorption ionization time-of-flight mass spectrometry analysis indicates that the isolated protein is a chloroplast RNA-binding protein (and a truncated derivative). The truncated derivative, which we refer to as STEP1 (single-stranded telomere-binding protein 1), binds specifically the single-stranded G-rich plant telomeric DNA sequences but not double-stranded telomeric DNA. Unlike the chloroplast-localized full-length RNA-binding protein, STEP1 localizes exclusively to the nucleus, suggesting that it plays a role in plant telomere biogenesis. We also demonstrated that the specific binding of STEP1 to single-stranded telomeric DNA inhibits telomerase-mediated telomere extension. The evidence presented here suggests that STEP1 is a telomere-end binding protein that may contribute to telomere length regulation by capping the ends of chromosomes and thereby repressing telomerase activity in plants.     

POT1b protects telomeres from end-to-end chromosomal fusions and aberrant homologous recombination

POT1 (protection of telomere 1) is a highly conserved single-stranded telomeric binding protein that is essential for telomere end protection. Here, we report the cloning and characterization of a second member of the mouse POT family. POT1b binds telomeric DNA via conserved DNA binding oligonucleotide/oligosaccharide (OB) folds. Compared to POT1a, POT1b OB-folds possess less sequence specificity for telomeres. In contrast to POT1a, truncated POT1b possessing only the OB-folds can efficiently localize to telomeres in vivo. Overexpression of a mutant Pot1b allele that cannot bind telomeric DNA initiated a DNA damage response at telomeres that led to p53-dependent senescence. Furthermore, a reduction of the 3' G-rich overhang, increased chromosomal fusions and elevated homologous recombination (HR) were observed at telomeres. shRNA mediated depletion of endogenous Pot1b in Pot1a deficient cells resulted in increased chromosomal aberrations. Our results indicate that POT1b plays important protective functions at telomeres and that proper maintenance of chromosomal stability requires both POT proteins.     

Cooperative binding of single-stranded telomeric DNA by the Pot1 protein of Schizosaccharomyces pombe

The fission yeast Pot1 (protection of telomeres) protein is a single-stranded telomeric DNA-binding protein and is required to protect the ends of chromosomes. Its N-terminal DNA-binding domain, Pot1pN, shows sequence similarity to the first OB fold of the telomere-binding protein alpha subunit of Oxytricha nova. The minimal-length telomeric ssDNA required to bind Pot1pN was determined to consist of six nucleotides, GGTTAC, by gel filtration chromatography and filter-binding assay (K(D) = 83 nM). Pot1pN is a monomer, and each monomer binds one hexanucleotide. Experiments with nucleotide substitutions demonstrated that the central four nucleotides are crucial for binding. The dependence of Pot1pN-ssDNA binding on salt concentration was consistent with a single ionic contact between the protein and the ssDNA phosphate backbone, such that at physiological salt condition 83% of the free energy of binding is nonelectrostatic. Subsequent binding experiments with longer ssDNAs indicated that Pot1pN binds to telomeric ssDNA with 3' end preference and in a highly cooperative manner that mainly results from DNA-induced protein-protein interactions. Together, the binding properties of Pot1pN suggest that the protein anchors itself at the very 3' end of a chromosome and then fills in very efficiently, coating the entire single-stranded overhang of the telomere.     

Drosophila telomeres: A variation on the telomerase theme

In Drosophila, the role of telomerase is carried out by three specialized retrotransposable elements, HeT-A, TART and TAHRE. Telomeres contain long tandem head-to-tail arrays of these elements. Within each array, the three elements occur in random, but polarized, order. Some are truncated at the 5' end, giving the telomere an enriched content of the large 3' untranslated regions, which distinguish these telomeric elements from other retrotransposons. Thus, Drosophila telomeres resemble other telomeres because they are long arrays of repeated sequences, albeit more irregular arrays than those produced by telomerase. The telomeric retrotransposons are reverse-transcribed directly onto the end of the chromosome, extending the end by successive transpositions. Their transposition uses exactly the same method by which telomerase extends chromosome ends--copying an RNA template. In addition to these similarities in structure and maintenance, Drosophila telomeres have strong functional similarities to other telomeres and, as variants, provide an important model for understanding general principles of telomere function and evolution.     

Genetic dissection of the Kluyveromyces lactis telomere and evidence for telomere capping defects in TER1 mutants with long telomeres

In the yeast Kluyveromyces lactis, the telomeres are composed of perfect 25-bp repeats copied from a 30-nucleotide RNA template defined by 5-nucleotide terminal repeats. A genetic dissection of the K. lactis telomere was performed by using mutant telomerase RNA (TER1) alleles to incorporate mutated telomeric repeats. This analysis has shown that each telomeric repeat contains several functional regions, some of which may physically overlap. Mutations in the terminal repeats of the template RNA typically lead to telomere shortening, as do mutations in the right side of the Rap1p binding site. Mutations in the left half of the Rap1p binding site, however, lead to the immediate formation of long telomeres. When mutated, the region immediately 3' of the Rap1p binding site on the TG-rich strand of the telomere leads to telomeres that are initially short but eventually undergo extreme telomere elongation. Mutations between this region and the 3' terminal repeat cause elevated recombination despite the presence of telomeres of nearly wild-type length. Mutants with highly elongated telomeres were further characterized and exhibit signs of telomere capping defects, including elevated levels of subtelomeric recombination and the formation of extrachromosomal and single-stranded telomeric DNA. Lengthening caused by some Rap1 binding site mutations can be suppressed by high-copy-number RAP1. Mutated telomeric repeats from a delayed elongation mutant are shown to be defective at regulating telomere length in cells with wild-type telomerase, indicating that the telomeric repeats are defective at telomere length regulation.     

HeT-A, a transposable element specifically involved in "healing" broken chromosome ends in Drosophila melanogaster.

Eight terminally deleted Drosophila melanogaster chromosomes have now been found to be "healed." In each case, the healed chromosome end had acquired sequence from the HeT DNA family, a complex family of repeated sequences found only in telomeric and pericentric heterochromatin. The sequences were apparently added by transposition events involving no sequence homology. We now report that the sequences transposed in healing these chromosomes identify a novel transposable element, HeT-A, which makes up a subset of the HeT DNA family. Addition of HeT-A elements to broken chromosome ends appears to be polar. The proximal junction between each element and the broken chromosome end is an oligo(A) tract beginning 54 nucleotides downstream from a conserved AATAAA sequence on the strand running 5' to 3' from the chromosome end. The distal (telomeric) ends of HeT-A elements are variably truncated; however, we have not yet been able to determine the extreme distal sequence of a complete element. Our analysis covers approximately 2,600 nucleotides of the HeT-A element, beginning with the oligo(A) tract at one end. Sequence homology is strong (greater than 75% between all elements studied). Sequence may be conserved for DNA structure rather than for protein coding; even the most recently transposed HeT-A elements lack significant open reading frames in the region studied. Instead, the elements exhibit conserved short-range sequence repeats and periodic long-range variation in base composition. These conserved features suggest that HeT-A elements, although transposable elements, may have a structural role in telomere organization or maintenance.     

DNA-induced dimerization of the single-stranded DNA binding telomeric protein Pot1 from Schizosaccharomyces pombe

Eukaryotic chromosome ends are protected from illicit DNA joining by protein-DNA complexes called telomeres. In most studied organisms, telomeric DNA is composed of multiple short G-rich repeats that end in a single-stranded tail that is protected by the protein POT1. Mammalian POT1 binds two telomeric repeats as a monomer in a sequence-specific manner, and discriminates against RNA of telomeric sequence. While addressing the RNA discrimination properties of SpPot1, the POT1 homolog in Schizosaccharomyces pombe, we found an unanticipated ssDNA-binding mode in which two SpPot1 molecules bind an oligonucleotide containing two telomeric repeats. DNA binding seems to be achieved via binding of the most N-terminal OB domain of each monomer to each telomeric repeat. The SpPot1 dimer may have evolved to accommodate the heterogeneous spacers that occur between S. pombe telomeric repeats, and it also has implications for telomere architecture. We further show that the S. pombe telomeric protein Tpz1, like its mammalian homolog TPP1, increases the affinity of Pot1 for telomeric single-stranded DNA and enhances the discrimination of Pot1 against RNA.     

The Arabidopsis Pot1 and Pot2 proteins function in telomere length homeostasis and chromosome end protection

Pot1 (protection of telomeres 1) is a single-stranded telomere binding protein that is essential for chromosome end protection and telomere length homeostasis. Arabidopsis encodes two Pot1-like proteins, dubbed AtPot1 and AtPot2. Here we show that telomeres in transgenic plants expressing a truncated AtPot1 allele lacking the N-terminal oligonucleotide/oligosaccharide binding fold (P1DeltaN) are 1 to 1.5 kb shorter than in the wild type, suggesting that AtPot1 contributes to the positive regulation of telomere length control. In contrast, telomere length is unperturbed in plants expressing the analogous region of AtPot2. A strikingly different phenotype is observed in plants overexpressing the AtPot2 N terminus (P2DeltaC) but not the corresponding region in AtPot1. Although bulk telomeres in P2DeltaC mutants are 1 to 2 kb shorter than in the wild type, these plants resemble late-generation telomerase-deficient mutants with severe growth defects, sterility, and massive genome instability, including bridged chromosomes and aneuploidy. The genome instability associated with P2DeltaC mutants implies that AtPot2 contributes to chromosome end protection. Thus, Arabidopsis has evolved two Pot genes that function differently in telomere biology. These findings provide unanticipated information about the evolution of single-stranded telomere binding proteins.     

Extended DNA binding site in Pot1 broadens sequence specificity to allow recognition of heterogeneous fission yeast telomeres

The Pot1 (protection of telomeres) protein binds to single-stranded telomeric DNA and is essential for the protection of chromosome ends from degradation and end-to-end fusions. The Pot1 amino-terminal DNA binding domain, Pot1N, adopts an oligonucleotide/oligosaccharide binding fold and binds GGTTAC motifs cooperatively and with exceptionally high sequence specificity. We have now examined DNA binding to naturally occurring telomeric substrates based on the analysis of 100 cloned chromosome ends and in the context of the full-length Pot1 protein. Here, we describe several important differences between Pot1 and Pot1N with apparent consequences for chromosome end protection. Specifically, full-length Pot1.DNA complexes are more stable, and the minimal binding site for a Pot1 monomer is extended into two adjacent telomeric repeats. We provide evidence that Pot1 contains a second DNA binding motif that recognizes DNA with reduced sequence specificity compared with the domain present in Pot1N. The two DNA binding motifs cooperate, whereby the amino-terminal oligonucleotide/oligosaccharide binding fold determines the registry of binding, and the internal DNA binding motif stabilizes the complex and expands the protected region toward the 3' -end. Consistent with a role in chromosome end capping, Pot1 prevents access of telomerase to the 3'-end and protects against exonucleolytic degradation.     

Human POT1 facilitates telomere elongation by telomerase

Mammalian telomeric DNA is mostly composed of double-stranded 5'-TTAGGG-3' repeats and ends with a single-stranded 3' overhang. Telomeric proteins stabilize the telomere by protecting the overhang from degradation or by remodeling the telomere into a T loop structure. Telomerase is a ribonucleoprotein that synthesizes new telomeric DNA. In budding yeast, other proteins, such as Cdc13p, that may help maintain the telomere end by regulating the recruitment or local activity of telomerase have been identified. Pot1 is a single-stranded telomeric DNA binding protein first identified in fission yeast, where it was shown to protect telomeres from degradation [10]. Human POT1 (hPOT1) protein is known to bind specifically to the G-rich telomere strand. We now show that hPOT1 can act as a telomerase-dependent, positive regulator of telomere length. Three splice variants of hPOT1 were overexpressed in a telomerase-positive human cell line. All three variants lengthened telomeres, and splice variant 1 was the most effective. hPOT1 was unable to lengthen the telomeres of telomerase-negative cells unless telomerase activity was induced. These data suggest that a normal function of hPOT1 is to facilitate telomere elongation by telomerase.     

A new model for Schizosaccharomyces pombe telomere recognition: the telomeric single-stranded DNA-binding activity of Pot11-389

The protection of telomeres 1 (Pot1) proteins specifically recognize the single-stranded 3' end of the telomere, an activity essential for sustained cellular viability and proliferation. The current model for the telomeric single-stranded DNA (ssDNA) binding activity of Schizosaccharomyces pombe Pot1 is based on a 20 kDa fragment, Pot1pN. Recent biochemical studies suggest that SpPot1 contains a larger ssDNA-binding domain and we have identified a novel ssDNA-binding domain similar in size to the human Pot1 domain. This domain, Pot1(1-389), binds extremely tightly to an oligonucleotide consisting of two conserved hexameric S. pombe telomere repeats, d(GGTTACGGTTAC), with an affinity approximately 4000-fold tighter than Pot1pN binds its cognate ssDNA. The Pot1(1-389)/ssDNA complex exhibits a half-life of 53 min, consistent with that estimated for full-length SpPot1 and significantly longer than that of Pot1pN. Single nucleotide substitutions reveal that, in contrast to Pot1pN, tandem trinucleotide repeats (GTT) within d(GGTTACGGTTAC) are specifically recognized by Pot1(1-389). Interestingly, certain single nucleotide substitutions that impacted Pot1pN binding exhibited no effect on binding affinity by Pot1(1-389). However, these substitutions reduced binding affinity when simultaneously substituted in each hexameric repeat. The non-additive nature of these substitutions suggests that certain nucleotides are coupled through the ability of the flexible ssDNA oligonucleotide to adopt alternate, thermodynamically equivalent conformations. The biochemical behavior of Pot1(1-389) is more similar to that of the full-length SpPot1 protein than to that of Pot1pN, making Pot1(1-389) a valuable domain for the future study of how full-length SpPot1 interacts with telomeric ssDNA.     

Tetrahymena Pot2 Is a Developmentally Regulated Paralog of Pot1 That Localizes to Chromosome Breakage Sites but Not to Telomeres

Tetrahymena telomeres are protected by a protein complex composed of Pot1, Tpt1, Pat1, and Pat2. Pot1 binds the 3′ overhang and serves multiple roles in telomere maintenance. Here we describe Pot2, a paralog of Pot1 which has evolved a novel function during Tetrahymena sexual reproduction. Pot2 is unnecessary for telomere maintenance during vegetative growth, as the telomere structure is unaffected by POT2 macronuclear gene disruption. Pot2 is expressed only in mated cells, where it accumulates in developing macronuclei around the time of two chromosome processing events: internal eliminated sequence (IES) excision and chromosome breakage. Chromatin immunoprecipitation (ChIP) demonstrated Pot2 localization to regions of chromosome breakage but not to telomeres or IESs. Pot2 association with chromosome breakage sites (CBSs) occurs slightly before chromosome breakage. Pot2 did not bind CBSs or telomeric DNA in vitro, suggesting that it is recruited to CBSs by another factor. The telomere proteins Pot1, Pat1, and Tpt1 and the IES binding factor Pdd1 fail to colocalize with Pot2. Thus, Pot2 is the first protein found to associate specifically with CBSs. The selective association of Pot2 versus Pdd1 with CBSs or IESs indicates a mechanistic difference between the chromosome processing events at these two sites. Moreover, ChIP revealed that histone marks characteristic of IES processing, H3K9me3 and H3K27me3, are absent from CBSs. Thus, the mechanisms of chromosome breakage and IES excision must be fundamentally different. Our results lead to a model where Pot2 directs chromosome breakage by recruiting telomerase and/or the endonuclease responsible for DNA cleavage to CBSs.