Reactivation of Chromosomally Integrated Human Herpesvirus-6 by Telomeric Circle Formation

More than 95% of the human population is infected with human herpesvirus-6 (HHV-6) during early childhood and maintains latent HHV-6 genomes either in an extra-chromosomal form or as a chromosomally integrated HHV-6 (ciHHV-6). In addition, approximately 1% of humans are born with an inheritable form of ciHHV-6 integrated into the telomeres of chromosomes. Immunosuppression and stress conditions can reactivate latent HHV-6 replication, which is associated with clinical complications and even death. We have previously shown that Chlamydia trachomatis infection reactivates ciHHV-6 and induces the formation of extra-chromosomal viral DNA in ciHHV-6 cells. Here, we propose a model and provide experimental evidence for the mechanism of ciHHV-6 reactivation. Infection with Chlamydia induced a transient shortening of telomeric ends, which subsequently led to increased telomeric circle (t-circle) formation and incomplete reconstitution of circular viral genomes containing single viral direct repeat (DR). Correspondingly, short t-circles containing parts of the HHV-6 DR were detected in cells from individuals with genetically inherited ciHHV-6. Furthermore, telomere shortening induced in the absence of Chlamydia infection also caused circularization of ciHHV-6, supporting a t-circle based mechanism for ciHHV-6 reactivation.     

Evolution of the linear DNA replicons of the Borrelia spirochetes.

Members of the spirochete genus Borrelia carry numerous linear DNA replicons with covalently closed hairpin telomeres. The genome of one member of this genus, B. burgdorferi B31, has now been completely characterized and contains a linear chromosome, twelve linear plasmids and nine circular extra-chromosomal elements. The phylogenetic position of the Borrelia spirochetes strongly suggests that a progenitor with circular replicons acquired the ability to replicate linear DNA molecules.     

Vaccinia virus telomeres: interaction with the viral I1, I6, and K4 proteins

The 192-kb linear DNA genome of vaccinia virus has covalently closed hairpin termini that are extremely AT rich and contain 12 extrahelical bases. Vaccinia virus telomeres have previously been implicated in the initiation of viral genome replication; therefore, we sought to determine whether the telomeres form specific protein-DNA complexes. Using an electrophoretic mobility shift assay, we found that extracts prepared from virions and from the cytoplasm of infected cells contain telomere binding activity. Four shifted complexes were detected using hairpin probes representing the viral termini, two of which represent an interaction with the "flip" isoform and two with the "flop" isoform. All of the specificity for protein binding lies within the terminal 65-bp hairpin sequence. Viral hairpins lacking extrahelical bases cannot form the shifted complexes, suggesting that DNA structure is crucial for complex formation. Using an affinity purification protocol, we purified the proteins responsible for hairpin-protein complex formation. The vaccinia virus I1 protein was identified as being necessary and sufficient for the formation of the upper doublet of shifted complexes, and the vaccinia virus I6 protein was shown to form the lower doublet of shifted complexes. Competition and challenge experiments confirmed that the previously uncharacterized I6 protein binds tightly and with great specificity to the hairpin form of the viral telomeric sequence. Incubation of viral hairpins with extracts from infected cells also generates a smaller DNA fragment that is likely to reflect specific nicking at the apex of the hairpin; we show that the vaccinia virus K4 protein is necessary and sufficient for this reaction. We hypothesize that these telomere binding proteins may play a role in the initiation of vaccinia virus genome replication and/or genome encapsidation.     

Telomerase enzymatic component hTERT shortens long telomeres in human cells

Telomere lengths are tightly regulated within a narrow range in normal human cells. Previous studies have extensively focused on how short telomeres are extended and have demonstrated that telomerase plays a central role in elongating short telomeres. However, much about the molecular mechanisms of regulating excessively long telomeres is unknown. In this report, we demonstrated that the telomerase enzymatic component, hTERT, plays a dual role in the regulation of telomere length. It shortens excessively long telomeres and elongates short telomeres simultaneously in one cell, maintaining the optimal telomere length at each chromosomal end for efficient protection. This novel hTERT-mediated telomere-shortening mechanism not only exists in cancer cells, but also in primary human cells. The hTERT-mediated telomere shortening requires hTERT’s enzymatic activity, but the telomerase RNA component, hTR, is not involved in that process. We found that expression of hTERT increases telomeric circular DNA formation, suggesting that telomere homologous recombination is involved in the telomere-shortening process. We further demonstrated that shelterin protein TPP1 interacts with hTERT and recruits hTERT onto the telomeres, suggesting that TPP1 might be involved in regulation of telomere shortening. This study reveals a novel function of hTERT in telomere length regulation and adds a new element to the current molecular model of telomere length maintenance.     

Telomere dynamics in a human cancer cell line

Telomere maintenance is thought to be essential for immortalization of human cancer cells to compensate for the loss of DNA from the ends of chromosomes and to prevent chromosome fusion. We have investigated telomere dynamics in the telomerase-positive squamous cell carcinoma cell line SCC-61 by marking the ends of chromosomes with integrated plasmid sequences so that changes in the length of individual telomeres could be monitored. Despite having very short telomeres, SCC-61 has a relatively stable genome and few telomere associations. The marked telomeres in different SCC-61 clones have similar mean lengths which show little change with increasing time in culture. Thus, each marked telomere is maintained at a specific length, which we term the equilibrium mean length (EML). The Gaussian distribution in the length of the marked telomeres demonstrates that telomeres continuously fluctuate in length. Consistent with this observation, the mean lengths of the marked telomere in subclones of these cell lines initially differ, but then gradually return to the EML of the original clone with increasing time in culture. The analysis of a clone with two marked telomeres demonstrated that changes in telomere length can occur on each marked telomere independently or coordinately on both telomeres. These results suggest that the short telomeres in many tumor cell lines do not result from an inability to properly maintain telomeres at a specific length.     

Cloning of the vaccinia virus telomere in a yeast plasmid vector

The vaccinia virus DNA telomere, which contains a covalently closed hairpin structure, has been cloned in a yeast plasmid vector. Restriction mapping indicates that the cloned vaccinia telomere is maintained in yeast not in its native hairpin configuration but as an inverted repeat structure, within a circular plasmid, with the sequences of the viral hairpin now at the axis of symmetry of an imperfect palindrome. As such, the cloned telomere resembles the telomeric replicative intermediate observed during vaccinia virus DNA replication. Small deletions and duplications in the viral inverted repeats of different clones suggest a model in which the observed circular plasmids were generated in yeast by the replication of hybrid linear DNA molecules consisting of the linearized yeast vector flanked by two hairpin-containing vaccinia termini.     

Bidirectional replication from an internal ori site of the linear N15 plasmid prophage

The prophage of coliphage N15 is not integrated into the chromosome but exists as a linear plasmid molecule with covalently closed hairpin ends (telomeres). Upon infection the injected phage DNA circularizes via its cohesive ends. Then, a phage-encoded enzyme, protelomerase, cuts the circle and forms the hairpin telomeres. N15 protelomerase acts as a telomere-resolving enzyme during prophage DNA replication. We characterized the N15 replicon and found that replication of circular N15 miniplasmids requires only the repA gene, which encodes a multidomain protein homologous to replication proteins of bacterial plasmids replicated by a theta-mechanism. Replication of a linear N15 miniplasmid also requires the protelomerase gene and telomere regions. N15 prophage replication is initiated at an internal ori site located within repA and proceeds bidirectionally. Electron microscopy data suggest that after duplication of the left telomere, protelomerase cuts this site generating Y-shaped molecules. Full replication of the molecule and subsequent resolution of the right telomere then results in two linear plasmid molecules. N15 prophage replication thus appears to follow a mechanism that is distinct from that employed by eukaryotic replicons with this type of telomere and suggests the possibility of evolutionarily independent appearances of prokaryotic and eukaryotic replicons with covalently closed telomeres.     

Infectious circular DNA of human adenovirus type 5: regeneration of viral DNA termini from molecules lacking terminal sequences.

A series of plasmids containing the entire human adenovirus genome with viral DNA termini joined 'head to tail' has been isolated. Several plasmids were able to generate infectious virus following transfection of human cells in spite of having small deletions and rearrangements at the junctions of termini. One plasmid has lost 2 bp of DNA from one end of the viral genome and 11 bp from the other end yet produced viruses with complete wild-type sequences at both ends of the genome. We propose a model for replication of viral DNA off circular templates in which regeneration of terminal information involves translocation of primer and polymerase during initiation of DNA replication. The model suggests a novel mechanism for extension of the 5' ends of linear DNA molecules which could be applicable to chromosomal telomeres.     

Chinese hamster telomeres are comparable in size to mouse telomeres.

We report here the results of a telomere length analysis in four male Chinese hamsters by quantitative fluorescence in situ hybridization (Q-FISH). We were able to measure telomere length of 64 (73%) of 88 Chinese hamster telomeres. We could not measure telomere length in chromosome 10 or in the short arms of chromosomes 5, 6, 7 and 8 because of the overlaps between the interstitial and terminal telomeric signals. Our analysis in the 73% of Chinese hamster telomeres indicate that their average length is approximately 38 kb. Therefore, Chinese hamster telomeres are comparable in length to mouse telomeres, but are much longer than human telomeres. Similar to previous Q-FISH studies on human and mouse chromosomes, our results indicate that individual Chinese hamster chromosomes may have specific telomere lengths, suggesting that chromosome-specific factors may be involved in telomere length regulation.     

Analysis of a YAC with human telomeres and oriP from epstein-barr virus in yeast and 293 cells.

One approach to the construction and propagation of a mammalian artificial chromosome is to build it up in Saccharomyces cerevisiae, using a yeast artificial chromosome (YAC) base. We have demonstrated that circular YACs carrying the Epstein-Barr virus origin of plasmid replication ( oriP ) are maintained as stable, episomal elements in human cells. We wished to determine whether this technology could be extended, to generate linear extrachromosomal elements. Here, we describe the generation of retrofitting constructs, which permit the addition of human telomeres and the oriP domain to YACs. The constructs contain 0.8 kb of human telomere sequence separated by a unique Not I site from 0.7 kb of Tetrahymena telomere sequence. These constructs seed telomere formation with approximately 40-60% efficiency in human 293-EBNA and HT1080 cells whether or not the Tetrahymena sequence is removed by Not I digestion. A detailed analysis demonstrates that YACs carrying the human telomere cassettes on both arms show instability of the telomere sequences in S.cerevisiae at a frequency of approximately 50%. Introduction of correctly retrofitted, linear oriP YACs into human 293-EBNA cells by lipofection resulted in the generation of circular extrachromosomal elements varying in size from 8 to 300 kb. However, no apparently linear YACs could be detected, suggesting that extrachromosomal maintenance of DNA with the oriP /EBNA-1 system is not compatible with linear molecules capped by telomeres.     

Telomere resolution in the Lyme disease spirochete.

The genus Borrelia includes the causative agents of Lyme disease and relapsing fever. An unusual feature of these bacteria is a genome that includes linear DNA molecules with covalently closed hairpin ends referred to as telomeres. We have investigated the mechanism by which the hairpin telomeres are processed during replication. A synthetic 140 bp sequence having the predicted structure of a replicated telomere was shown to function as a viable substrate for telomere resolution in vivo, and was sufficient to convert a circular replicon to a linear form. Our results suggest that the final step in the replication of linear Borrelia replicons is a site-specific DNA breakage and reunion event to regenerate covalently closed hairpin ends. The telomere substrate described here will be valuable both for in vivo manipulation of linear DNA in Borrelia and for in vitro studies to identify and characterize the telomere resolvase.     

Telomerase can inhibit the recombination-based pathway of telomere maintenance in human cells

Telomere length can be maintained by telomerase or by a recombination-based pathway. Because individual telomeres in cells using the recombination-based pathway of telomere maintenance appear to periodically become extremely short, cells using this pathway to maintain telomeres may be faced with a continuous state of crisis. We expressed telomerase in a human cell line that uses the recombination-based pathway of telomere maintenance to test whether telomerase would prevent telomeres from becoming critically short and examine the effects that this might have on the recombination-based pathway of telomere maintenance. In these cells, telomerase maintains the length of the shortest telomeres. In some cases, the long heterogeneous telomeres are completely lost, and the cells now permanently contain short telomeres after only 40 population doublings. This corresponds to a telomere reduction rate of 500 base pairs/population doubling, a rate that is much faster than expected for normal telomere shortening but is consistent with the rapid telomere deletion events observed in cells using the recombination-based pathway of telomere maintenance (Murnane, J. P., Sabatier, L., Marder, B. A., and Morgan, W. F. (1994) EMBO J. 13, 4953-4962). We also observed reductions in the fraction of cells containing alternative lengthening of telomere-associated promyelocytic leukemia bodies and extrachromosomal telomere repeats; however, no alterations in the rate of sister chromatid exchange were observed. Our results demonstrate that human cells using the recombination-based pathway of telomere maintenance retain factors required for telomerase to maintain telomeres and that once the telomerase-based pathway of telomere length regulation is engaged, recombination-based elongation of telomeres can be functionally inhibited.     

Within the genome,long telomeres are more informative than short telomeres with respect to fitness components in a long‐lived seabird

Telomeres, DNA‐protein structures at chromosome ends, shorten with age, and telomere length has been linked to age‐related diseases and survival. In vitro studies revealed that the shortest telomeres trigger cell senescence, but whether the shortest telomeres are also the best biomarker of ageing is not known. We measured telomeres in erythrocytes of wild common terns Sterna hirundo using terminal restriction fragment analysis. This yields a distribution of telomere lengths for each sample, and we investigated how different telomere subpopulations (percentiles) varied in their relation to age and fitness proxies. Longer telomeres within a genome lost more base pairs with age and were better predictors of survival than shorter telomeres. Likewise, fitness proxies such as arrival date at the breeding grounds and reproductive success were best predicted by telomere length at the higher percentiles. Our finding that longer telomeres within a genome predict fitness components better than the shorter telomeres indicates that they are a more informative ageing biomarker. This finding contrasts with the fact that cell senescence is triggered by the shortest telomeres. We suggest that this paradox arises, because longer telomeres lose more base pairs per unit time and thus better reflect the various forms of stress that accelerate telomere shortening, and that telomeres primarily function as biomarker because their shortening reflects cumulative effects of various stressors rather than reflecting telomere‐induced cell senescence.     

Use of alkaline sucrose gradients in a zonal rotor to detect integrated and unintegrated avian sarcoma virus-specific DNA in cells.

We have attempted to distinguish integrated and unintegrated forms of avian sarcoma virus-specific DNA in cells by sedimentaton through an alkaline sucrose gradient in a slowly reorienting zonal rotor. Results obtained with this procedure are similar to those obtained by the more convenient analysis of networks of high-molecular-weight cell DNA. Most, if not all, viral DNA appears completely integrated into the host cell genome in an avian sarcoma virus-transformed mammalian cell and in normal chicken cells (in which viral DNA is genetically transmitted). Fully transformed duck cells and duck embryo fibroblasts infected for 20 to 72 h contain both integrated and unintegrated viral DNA; up to one copy per cell is integrated within 20 h after infection, and four to eight copies are integrated in fully transformed cells. The amount of unintegrated DNA varies but may comprise over 75% of the viral DNA in acutely infected cells and from 20 to 70% of the viral DNA in fully transformed cells. The unintegrated DNA in either case consists principally of duplexes with "minus" strands the length of a subunit of the viral genome (2.5 X 10(6) to 3 X 10(6) daltons) and relatively short "plus" strands (0.5 X 10(6) to 1.0 X 10(6) daltons).     

Fusion of hairpin telomeres by the B. burgdorferi telomere resolvase ResT implications for shaping a genome in flux

Spirochetes of the genus Borrelia include the causative agents of Lyme disease and relapsing fever. These bacteria have a highly segmented genome where most replicons are linear molecules terminated by covalently closed hairpin telomeres. Moreover, these genomes appear to be in a state of flux with extensive and ongoing DNA rearrangements by unknown mechanisms. The B. burgdorferi telomere resolvase ResT generates the hairpin telomeres from replication intermediates in a reaction with mechanistic similarities to that catalyzed by type IB topoisomerases and tyrosine recombinases. We report here the unexpected ability of ResT to catalyze the fusion of hairpin telomeres in a reversal of the telomere resolution reaction. We propose that stabilized ResT-mediated telomere fusions are an underlying force for maintaining the B. burgdorferi genome in a state of flux.     

Telomere resolution by Borrelia burgdorferi ResT through the collaborative efforts of tethered DNA binding domains

Borrelia burgdorferi, a causative agent of Lyme disease, has a highly unusual segmented genome composed of both circular molecules and linear DNA replicons terminated by covalently closed hairpin ends or telomeres. Replication intermediates of the linear molecules are processed into hairpin telomeres via the activity of ResT, a telomere resolvase. We report here the results of limited proteolysis and mass spectroscopy to identify two main structural domains in ResT, separated by a chymotrypsin cleavage site between residues 163 and 164 of the 449 amino acid protein. The two domains have been overexpressed and purified. DNA electrophoretic mobility shift assays revealed that the C-terminal domain (ResT(164-449)) displays sequence-specific DNA binding to the box 3,4,5 region of the telomere, while the N-terminal domain (ResT(1-163)) exhibits sequence-independent DNA binding activity. Further analysis by DNase I footprinting supports a model for telomere resolution in which the hairpin binding module of the N-terminal domain is delivered to the box 1,2 region of the telomere through its tethering to ResT(164-449). Conversely, ResT(1-164) may play an important regulatory role by modulating both sequence-specific DNA binding activity and catalysis by the C-terminal domain.     

Short Telomeres are Sufficient to Cause the Degenerative Defects Associated with Aging

Telomerase function is critical for telomere maintenance. Mutations in telomerase components lead to telomere shortening and progressive bone marrow failure in the premature aging syndrome dyskeratosis congenita. Short telomeres are also acquired with aging, yet the role that they play in mediating age-related disease is not fully known. We generated wild-type mice that have short telomeres. In these mice, we identified hematopoietic and immune defects that resembled those present in dyskeratosis congenita patients. When mice with short telomeres were interbred, telomere length was only incrementally restored, and even several generations later, wild-type mice with short telomeres still displayed degenerative defects. Our findings implicate telomere length as a unique heritable trait that, when short, is sufficient to mediate the degenerative defects of aging, even when telomerase is wild-type.     

Reversible manipulation of telomerase expression and telomere length. Implications for the ionizing radiation response and replicative senescence of human cells

Most human cells do not express telomerase and irreversibly arrest proliferation after a finite number of divisions (replicative senescence). Several lines of evidence suggest that replicative senescence is caused by short dysfunctional telomeres, which arise when DNA is replicated in the absence of adequate telomerase activity. We describe a method to reversibly bypass replicative senescence and generate mass cultures that have different average telomere lengths. A retrovirus carrying hTERT flanked by excision sites for Cre recombinase rendered normal human fibroblasts telomerase-positive and replicatively immortal. Superinfection with retroviruses carrying wild-type or mutant forms of TIN2, a negative regulator of telomere length, created telomerase-positive, immortal populations with varying average telomere lengths. Subsequent infection with a Cre-expressing retrovirus abolished telomerase activity, creating mortal cells with varying telomere lengths. Using these cell populations, we show that, after hTERT excision, cells senesce with shorter telomeres than parental cells. Moreover, long telomeres, but not telomerase, protected cells from the loss of division potential caused by ionizing radiation. Finally, although telomerase-negative cells with short telomeres senesced after fewer doublings than those with long telomeres, telomere length per se did not correlate with senescence. Our results support a role for telomere structure, rather than length, in replicative senescence.     

Telomere biology in mammalian germ cells and during development

The development of an organism is a strictly regulated program in which controlled gene expression guarantees the establishment of a specific phenotype. The chromosome termini or so-called telomeres preserve the integrity of the genome within developing cells. In the germline, during early development, and in highly proliferative organs, human telomeres are balanced between shortening processes with each cell division and elongation by telomerase, but once terminally differentiated or mature the equilibrium is shifted to gradual shortening by repression of the telomerase enzyme. Telomere length is to a large extent genetically determined and the neonatal telomere length equilibrium is, in fact, a matter of evolution. Gradual telomere shortening in normal human somatic cells during consecutive rounds of replication eventually leads to critically short telomeres that induce replicative senescence in vitro and probably in vivo. Hence, a molecular clock is set during development, which determines the replicative potential of cells during extrauterine life. Telomeres might be directly or indirectly implicated in longevity determination in vivo, and information on telomere length setting in utero and beyond should help elucidate presumed causal connections between early growth and aging disorders later in life. Only limited information exists concerning the mechanisms underlying overall telomere length regulation in the germline and during early development, especially in humans. The intent of this review is to focus on recent advances in our understanding of telomere biology in germline cells as well as during development (pre- and postimplantation periods) in an attempt to summarize our knowledge about telomere length determination and its importance for normal development in utero and the occurrence of the aging and abnormal phenotype later on.     

Telomere dynamics and genome stability in the human pancreatic tumor cell line MIAPaCa-2

Telomeres are specialized structures found at the ends of eukaryotic chromosomes serving as guardians of genome stability. In normal cells telomeres shorten with each cell division, but immortal cells undergoing multiple divisions constantly have to maintain telomere lengths above a critical level. This is accomplished either through expression of telomerase or the alternative recombination pathway (ALT). In the present study, we analyzed telomere dynamics of the telomerase positive human pancreatic tumor cell line MIAPaCa-2. The cells demonstrated genomic instability with a high frequency of chromosomal aberrations resulting in differences between individual karyotypes within the same cell population. The telomeres were short when compared with normal human fibroblasts, and about 39% of the chromosome ends did not have detectable telomere repeats as demonstrated by PNA-FISH. In many cases telomere signals were missing even when sister chromatids were strongly labeled. In addition, we used an internal PNA probe specific for the X chromosome, present in a single copy in these cells, in order to follow telomere dynamics on individual chromatids. High heterogeneity in telomere signals among individual X chromosomes as well as between their sister chromatids suggested sudden and stochastic loss or gain of telomere repeats. Such constant genomic instability often results in apoptosis and death of a fraction of cells present in the culture at all times. We discuss possible molecular mechanisms that may explain this observed telomere heterogeneity and possible adaptive repair mechanisms by which these cells maintain their chromosomes in order to survive such extreme and permanent genomic instability.