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.     

Dynamics of telomeric DNA turnover in yeast.

Telomerase adds telomeric DNA repeats to telomeric termini using a sequence within its RNA subunit as a template. We characterized two mutations in the Kluyveromyces lactis telomerase RNA gene (TER1) template. Each initially produced normally regulated telomeres. One mutation, ter1-AA, had a cryptic defect in length regulation that was apparent only if the mutant gene was transformed into a TER1 deletion strain to permit extensive replacement of basal wild-type repeats with mutant repeats. This mutant differs from previously studied delayed elongation mutants in a number of properties. The second mutation, TER1-Bcl, which generates a BclI restriction site in newly synthesized telomeric repeats, was indistinguishable from wild type in all phenotypes assayed: cell growth, telomere length, and in vivo telomerase fidelity. TER1-Bcl cells demonstrated that the outer halves of the telomeric repeat tracts turn over within a few hundred cell divisions, while the innermost few repeats typically resisted turnover for at least 3000 cell divisions. Similarly deep but incomplete turnover was also observed in two other TER1 template mutants with highly elongated telomeres. These results indicate that most DNA turnover in functionally normal telomeres is due to gradual replicative sequence loss and additions by telomerase but that there are other processes that also contribute to turnover.     

Evidence for an Additional Base-Pairing Element between the Telomeric Repeat and the Telomerase RNA Template in Kluyveromyces lactis and Other Yeasts

In all telomerases, the template region of the RNA subunit contains a region of telomere homology that is longer than the unit telomeric repeat. This allows a newly synthesized telomeric repeat to translocate back to the 3′ end of the template prior to a second round of telomeric repeat synthesis. In the yeast Kluyveromyces lactis, the telomerase RNA (Ter1) template has 30 nucleotides of perfect homology to the 25-bp telomeric repeat. Here we provide strong evidence that three additional nucleotides at positions −2 through −4 present on the 3′ side of the template form base-pairing interactions with telomeric DNA. Mutation of these bases can lead to opposite effects on telomere length depending on the sequence permutation of the template in a manner consistent with whether the mutation increases or decreases the base-pairing potential with the telomere. Additionally, mutations in the −2 and −3 positions that restore base-pairing potential can suppress corresponding sequence changes in the telomeric repeat. Finally, multiple other yeast species were found to also have telomerase RNAs that encode relatively long 7- to 10-nucleotide domains predicted to base pair, often with imperfect pairing, with telomeric DNA. We further demonstrate that K. lactis telomeric fragments produce banded patterns with a 25-bp periodicity. This indicates that K. lactis telomeres have preferred termination points within the 25-bp telomeric repeat.Telomeres are DNA and protein complexes present at the ends of eukaryotic chromosomes that function to protect chromosome ends from terminal sequence losses and fusions (3, 36). Telomeric DNA is typically composed of tandem 5- to 26-bp repeats that are sufficient for telomere function and that serve as binding sites for telomeric proteins (32). The ribonucleoprotein enzyme telomerase adds telomeric repeats to chromosome ends and prevents the gradual shortening that would otherwise occur. Telomerase synthesizes new telomeric repeats onto chromosome ends by using part of its RNA subunit as a template (13, 14, 31). Cells without telomerase encounter growth and viability problems once telomeres begin to become too short to properly function. In most human cells, telomerase activity is greatly reduced or absent and the ensuing telomere shortening functions to inhibit the formation of cancer by limiting the number of divisions that cells can undergo (4, 7, 16, 30).Recognition of a telomeric end by telomerase in vivo is complex and requires a number of different interactions between components of telomerase and components of the telomere (32). Specialized proteins that bind the 3′ single-stranded overhangs of telomeres, including the yeast Cdc13 protein, can interact directly with telomerase (9, 28). A critical aspect of telomerase''s interaction with the telomeres comes through base pairing between the telomeric overhang and the template region of the telomerase RNA. In all known telomerases, the template region of the RNA subunit contains a region of telomere homology that is longer than the unit telomeric repeat. This presence of short sequence identities at the 3′ and 5′ borders of the template allow a newly synthesized telomeric repeat to translocate back to the 3′ end of the template prior to a second round of telomeric repeat synthesis (38).Kluyveromyces lactis is an ascomycetous yeast species that is a valuable model organism for studying telomeres and telomerase. Unlike the better-studied yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, K. lactis has telomeres composed of repeats of uniform size (25 bp) and sequence (24). This indicates that the translocation step during a round of DNA synthesis by the telomerase enzyme normally occurs between precise positions at the two ends of the telomerase RNA template region. Point mutations at any of multiple positions within either of the two 5-nucleotide (nt)-long direct repeats that border the telomerase RNA template result in telomeric repeats of abnormal size (35). These appear to result from disruption of the normal base-pairing interactions between template and telomeric DNA during the translocation step.Here we present genetic data that argue strongly that three additional nucleotides 3′ of the template and outside the region of continuous homology with the telomeric repeat are involved in the base pairing between telomeric DNA and the telomerase RNA template in K. lactis. Sequence data suggest that similar extended base-pairing regions are widespread in other yeast species.     

Screening for telomeric recombination in wild-type Kluyveromyces lactis

Both subtelomeric and telomeric recombination events can be greatly enhanced in Kluyveromyces lactis mutants lacking telomerase and having abnormally short telomeres. In this study, we utilized cells containing a single telomere composed of mutant repeats carrying a phenotypically silent mutation to test whether the exchange of telomeric repeats was a frequent event in mitotic and meiotic wild-type K. lactis cells. Amongst more than 100 subclones followed during multiple passages of mitotic growth, one instance of a terminal duplication extending into a subtelomeric sequence was observed, but no occurrences of intertelomeric recombination were found. This suggests that intertelomeric recombination is not an important contributor to telomere maintenance in normal K. lactis cells. Rare recombination events resulting in the replacement of a subtelomeric marker with a sequence from another chromosome end also led to the replacement of the telomeric repeat tract. This is consistent with these events being a result of break-induced replication. Movement of a subtelomeric or telomeric sequence from one chromosome end to another was not observed in haploid cells derived from mating and sporulation. This suggests that the exchange of telomeric repeats is not a routine occurrence in K. lactis meiosis.     

Secondary structure of vertebrate telomerase RNA

Telomerase is a ribonucleoprotein enzyme that maintains telomere length by adding telomeric sequence repeats onto chromosome ends. The essential RNA component of telomerase provides the template for telomeric repeat synthesis. To determine the secondary structure of vertebrate telomerase RNA, 32 new telomerase RNA genes were cloned and sequenced from a variety of vertebrate species including 18 mammals, 2 birds, 1 reptile, 7 amphibians, and 4 fishes. Using phylogenetic comparative analysis, we propose a secondary structure that contains four structural domains conserved in all vertebrates. Ten helical regions of the RNA are universally conserved while other regions vary significantly in length and sequence between different classes of vertebrates. The proposed vertebrate telomerase RNA structure displays a strikingly similar topology to the previously determined ciliate telomerase RNA structure, implying an evolutionary conservation of the global architecture of telomerase RNA.     

Uncapping and deregulation of telomeres lead to detrimental cellular consequences in yeast

Telomeres are the protein-nucleic acid structures at the ends of eukaryote chromosomes. Tandem repeats of telomeric DNA are templated by the RNA component (TER1) of the ribonucleoprotein telomerase. These repeats are bound by telomere binding proteins, which are thought to interact with other factors to create a higher-order cap complex that stabilizes the chromosome end. In the budding yeast Kluyveromyces lactis, the incorporation of certain mutant DNA sequences into telomeres leads to uncapping of telomeres, manifested by dramatic telomere elongation and increased length heterogeneity (telomere deregulation). Here we show that telomere deregulation leads to enlarged, misshapen "monster" cells with increased DNA content and apparent defects in cell division. However, such deregulated telomeres became stabilized at their elongated lengths upon addition of only a few functionally wild-type telomeric repeats to their ends, after which the frequency of monster cells decreased to wild-type levels. These results provide evidence for the importance of the most terminal repeats at the telomere in maintaining the cap complex essential for normal telomere function. Analysis of uncapped and capped telomeres also show that it is the deregulation resulting from telomere uncapping, rather than excessive telomere length per se, that is associated with DNA aberrations and morphological defects.     

Loss of cap structure causes mitotic defect in<Emphasis Type="Italic"> Tetrahymena thermophila</Emphasis> telomerase mutants

Mutation of the telomeric repeat sequence has severe cellular consequences in a variety of systems. A Tetrahymena thermophila telomerase template mutant, ter1-43AA, displays an acute mitotic chromosome segregation defect. In the study described here we investigated the molecular basis for this lethality. Although cloned ter1-43AA macronuclear telomeres had long tracts of wild-type G4T2 repeats, they were capped by a mixture of G4T3 repeats, shown previously to be non-lethal, and G4T4 repeats, the telomeric sequence normally found in hypotrichous ciliates such as Oxytricha. To test further the functionality of the G4T4 repeat sequence in T. thermophila, we devised a new template mutation, ter1-44+AA, that resulted in more uniform synthesis of this sequence at telomere caps in vivo. The ter1-44+AA mutant displayed the most severe mitotic defect reported to date, with up to 85% of the population having micronuclei in anaphase, providing firm evidence that the hypotrich repeat sequence is not functional in Tetrahymena. Surprisingly, in spite of the telomeric sequence mutation, neither the ter1-43AA nor ter1-44+AA mutant displayed any significant loss of telomere length regulation. These results demonstrate that loss of telomere cap integrity, rather than length regulation, leads to the anaphase defect.     

Variable telomeric repeat synthesis in Paramecium tetraurelia is consistent with misincorporation by telomerase.

Telomeric DNA at the ends of chromosomes consist of short, tandem repeat sequences. The telomeres of Paramecium tetraurelia are made up of variable repeats, whereas Paramecium caudatum telomeric repeats are largely invariant. To investigate variable repeat synthesis in P. tetraurelia, mutated telomerase RNA genes were expressed in vivo. We demonstrate that the P. caudatum telomerase RNA can participate in telomere synthesis when expressed in the P. tetraurelia macronucleus, despite 24% primary sequence divergence of the RNAs between the two species. De novo telomeric repeats from transformants indicate that P. tetraurelia telomerase fidelity is dramatically affected by template substitutions and that misincorporation at a single templating position is likely to account for the majority of P. tetraurelia telomeric DNA variability. Furthermore, we show that fidelity is not solely a function of the RNA moiety, as the P. caudatum telomerase RNA does not impart high fidelity to the chimeric enzyme.     

Developmentally programmed healing of chromosomes by telomerase in Tetrahymena

Healing of a broken chromosome and in eukaryotes involves acquisition of a telomere. During macronuclear development in ciliated protozoans, germline chromosomes are fragmented into linear subchromosomes, whose ends are healed by de novo addition of telomeres. We showed previously that the ribonucleoprotein enzyme telomerase elongates preexisting telomeres by synthesizing one telomeric DNA strand, using a template sequence in the RNA moiety of the enzyme. By marking telomerase with a mutation in the telomerase RNA template, which causes synthesis of novel telomeric sequences, we now show that in the ciliate Tetrahymena, telomerase directly adds telomeric DNA onto nontelomeric sequences during developmentally controlled chromosome healing. Unexpectedly, one telomerase RNA template mutation converted telomerase from an enzyme that normally synthesizes precisely templated sequences to a less precise polymerase that sometimes synthesizes irregular telomeric repeats in vivo.     

Mutational analysis of the Tetrahymena telomerase RNA: identification of residues affecting telomerase activity in vitro.

Telomere-specific repeat sequences are essential for chromosome end stability. Telomerase maintains telomere length by adding sequences de novo onto chromosome ends. The template domain of the telomerase RNA component dictates synthesis of species-specific telomeric repeats and other regions of the RNA have been suggested to be important for enzyme structure and/or catalysis. Using enzyme reconstituted in vitro with RNAs containing deletions or substitutions we identified nucleotides in the RNA component that are important for telomerase activity. Although many changes to conserved features in the RNA secondary structure did not abolish enzyme activity, levels of activity were often greatly reduced, suggesting that regions other than the template play a role in telomerase function. The template boundary was only altered by changes in stem II that affected the conserved region upstream of the template, not by changes in other regions, such as stems I, III and IV, consistent with a role of the conserved region in defining the 5' boundary of the template. Surprisingly, telomerase RNAs with substitutions or deletion of residues potentially abolishing the conserved pseudoknot structure had wild-type levels of telomerase activity. This suggests that this base pairing interaction may not be required for telomerase activity per se but may be conserved as a regulatory site for the enzyme in vivo.     

Recombinational telomere elongation promoted by DNA circles

Yeast mutants lacking telomerase are capable of maintaining telomeres by an alternate mechanism that depends on homologous recombination. We show here, by using Kluyveromyces lactis cells containing two types of telomeric repeats, that recombinational telomere elongation generates a repeating pattern common in most or all telomeres in survivors that retain both repeat types. We propose that these patterns arise from small circles of telomeric DNA being used as templates for rolling-circle gene conversion and that the sequence from the lengthened telomere is spread to other telomeres by additional, more typical gene conversion events. Consistent with this, artificially constructed circles of DNA containing telomeric repeats form long tandem arrays at telomeres when transformed into K. lactis cells. Mixing experiments done with two species of telomeric circles indicated that all of the integrated copies of the transforming sequence arise from a single original circular molecule.     

The Rap1p-telomere complex does not determine the replicative capacity of telomerase-deficient yeast

Telomeres are nucleoprotein structures that cap the ends of chromosomes and thereby protect their stability and integrity. In the presence of telomerase, the enzyme that synthesizes telomeric repeats, telomere length is controlled primarily by Rap1p, the budding yeast telomeric DNA binding protein which, through its C-terminal domain, nucleates a protein complex that limits telomere lengthening. In the absence of telomerase, telomeres shorten with every cell division, and eventually, cells enter replicative senescence. We have set out to identify the telomeric property that determines the replicative capacity of telomerase-deficient budding yeast. We show that in cells deficient for both telomerase and homologous recombination, replicative capacity is dependent on telomere length but not on the binding of Rap1p to the telomeric repeats. Strikingly, inhibition of Rap1p binding or truncation of the C-terminal tail of Rap1p in Kluyveromyces lactis and deletion of the Rap1p-recruited complex in Saccharomyces cerevisiae lead to a dramatic increase in replicative capacity. The study of the role of telomere binding proteins and telomere length on replicative capacity in yeast may have significant implications for our understanding of cellular senescence in higher organisms.     

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.