Chromosome healing: spontaneous and programmed de novo telomere formation by telomerase

Developmentally regulated telomerase activity is correlated with chromosomal healing during chromatin diminution in Ascaris suum

Telomerase is the ribonucleoprotein complex responsible for the maintenance of the physical ends, or telomeres, of most eukaryotic chromosomes. In this study, telomerase activity has been identified in cell extracts from the nematode Ascaris suum. This parasitic nematode is particularly suited as a model system for the study of telomerase, because it shows the phenomenon of chromatin diminution, consisting of developmentally programmed chromosomal breakage, DNA elimination, and new telomere formation. In vitro, the A. suum telomerase is capable of efficiently recognizing and elongating nontelomeric primers with nematode-specific telomere repeats by using limited homology at the 3' end of the DNA to anneal with the putative telomerase RNA template. The activity of this enzyme is developmentally regulated, and it correlates temporally with the phenomenon of chromatin diminution. It is up-regulated during the first two rounds of embryonic cell divisions, to reach a peak in 4-cell-stage embryos, when three presomatic blastomeres prepare for chromatin diminution. The activity remains high until the beginning of gastrulation, when the last of the presomatic cells undergoes chromatin diminution, and then constantly decreases during further development. In summary, our data strongly argue for a role of this enzyme in chromosome healing during the process of chromatin diminution.

De novo inverted duplication 9p21pter involving telomeric repeated sequences

We report on clinical and cytogenetic findings in a boy with partial 9p duplication, dup(9)(p21pter). Clinical manifestations included facial and hand anomalies and mental retardation. Fluorescence in situ hybridization (FISH) and comparative genomic hybridization (CGH) were used to characterize further and confirm the conventional banding data. Investigation by FISH using whole chromosome 9 paint probe showed that the additional material was derived from chromosome 9. Using CGH, a region of gain was found in the chromosome segment 9p21pter. YACs and telomeric probes confirmed the duplicated region. Using the all-human telomeric sequences probe, intrachromosomal telomeric signal was noted on the short arm of the abnormal chromosome 9. Mechanism of formation of the duplication, including intrachromosomal telomeric sequences, is discussed.

Construction of mammalian artificial chromosomes: prospects for defining an optimal centromere

Two reports have shown that mammalian artificial chromosomes (MAC) can be constructed from cloned human centromere DNA and telomere repeats, proving the principle that chromosomes can form from naked DNA molecules transfected into human cells. The MACs were mitotically stable, low copy number and bound antibodies associated with active centromeres. As a step toward second-generation MACs, yeast and bacterial cloning systems will have to be adapted to achieve large MAC constructs having a centromere, two telomeres, and genomic copies of mammalian genes. Available construction techniques are discussed along with a new P1 artificial chromosome (PAC)-derived telomere vector (pTAT) that can be joined to other PACs in vitro, avoiding a cloning step during which large repetitive arrays often rearrange. The PAC system can be used as a route to further define the optimal DNA elements required for efficient MAC formation, to investigate the expression of genes on MACs, and possibly to develop efficient MAC-delivery protocols.

Chromosome break-induced DNA replication leads to nonreciprocal translocations and telomere capture

In yeast, broken chromosomes can be repaired by recombination, resulting in nonreciprocal translocations. In haploid cells suffering an HO endonuclease-induced, double-strand break (DSB), nearly 2% of the broken chromosome ends recombined with a sequence near the opposite chromosome end, which shares only 72 bp of homology with the cut sequence. This produced a repaired chromosome with the same 20-kb sequence at each end. Diploid strains were constructed in which the broken chromosome shared homology with the unbroken chromosome only on the centromere-proximal side of the DSB. More than half of these cells repaired the DSB by copying sequences distal to the break from the unbroken template chromosome. All these events were RAD52 dependent. Pedigree analysis established that DSBs occurring in G1 were repaired by a replicative mechanism, producing two identical daughter cells. We discuss the implications of these data in understanding telomerase-independent replication of telomeres, gene amplification, and the evolution of chromosomal ends.

Developmentally programmed assembly of higher order telomerase complexes with distinct biochemical and structural properties

In Euplotes crassus, telomerase is responsible for telomere maintenance during vegetative growth and de novo telomere synthesis during macronuclear development. Here we show that telomerase in the vegetative stage of the life cycle exists as a 280-kD complex that can add telomeric repeats only onto telomeric DNA primers. Following the initiation of macronuclear development, telomerase assembles into larger complexes of 550 kD, 1600 kD, and 5 MD. In the 1600-kDa and 5-MDa complexes, telomerase is more processive than in the two smaller complexes and can add telomeres de novo onto nontelomeric 3' ends. Assembly of higher order telomerase complexes is accompanied by an extended region of RNase V1 and RNase T1 protection in the telomerase RNA subunit that is not observed with telomerase from vegetatively growing cells. The protected residues encompass a highly conserved region previously proposed to serve as a platform for formation of higher order structures. These findings provide the first direct demonstration of developmentally regulated higher order telomerase complexes with unique biochemical and structural properties.

Involvement of telomeric sequences in chromosomal aberrations

The genomes of higher eukaryotes are not homogeneous in terms of structure or function. Many examples of chromosomal regions particularly prone to involvement in aberrations have been reported. The molecular structures of some of these regions have now been determined, most notably the folate-sensitive fragile sites and FRA16B-a distamycin A-sensitive fragile site. In addition, a number of cytological studies suggest that telomeric sequences can in some circumstances be involved in chromosomal aberrations more frequently than expected. Here, the roles of telomeric DNA sequences, both terminal and interstitial, and telomerase in chromosomal aberration formation are reviewed.

Induction of telomerase activity by in vivo X-irradiation of mouse splenocytes and its possible role in chromosome healing

Telomeres serve as protective caps for the chromosome ends. They are one of the functional elements required for the stable transmission of eukaryotic chromosomes. Telomerase, a ribonucleoprotein, stabilises the telomere length by adding telomere repeats on to chromosome ends. Telomeres and telomerase can play a role in the formation of chromosome aberrations and especially in healing of the chromosome or chromatid breaks produced by radiation-induced DNA damage. Telomerase-independent processes also appear to be capable of capping broken chromosome ends. We have studied the expression of telomerase, telomere status and chromosome rearrangements in mouse splenocytes following different doses (0.5, 1.0, 2.0 or 3.0 Gy) of X-irradiation in vivo up to 224 days post-exposure. A dose-dependent increase in telomerase activity up to 2 Gy X-ray exposure was observed immediately after irradiation. The increased enzyme activity was detected even up to day 224 post-irradiation, the last time point studied, especially at higher doses (2 Gy and 3 Gy). A significant difference in average telomere length, measured by quantitative fluorescence in situ hybridisation (Q-FISH) on metaphase chromosomes, noticed immediately after irradiation indicates terminal deletion or altered telomere chromatin. However, telomere length was not statistically significant from the control at the later time points studied. Presence of telomere repeats at the chromosomal breakage sites revealed by FISH with peptide nucleic acid (PNA) telomeric probe indicates a possible role of telomerase-dependent or independent processes in chromosome healing and telomere capture in mammalian cells. We found that approximately 25 to 50% of the newly formed telomeres at the breakage sites are in the range of 200 bp to 1 kb, which might suggest that these repeats could have been added by telomerase which showed a corresponding increase following irradiation.

In vivo addition of telomeric repeats to foreign DNA generates extrachromosomal DNAs in the taxol-producing fungus Pestalotiopsis microspora

Transformation of the taxol-producing filamentous fungus Pestalotiopsis microspora with a plasmid containing the bacterial hygromycin resistance gene fused to Aspergillus regulatory sequences resulted in the in vivo formation of extrachromosomal DNAs with telomeric repeats in the majority of transformants. Repeats of the telomeric sequence 5'-TTAGGG-3' were appended to nontelomeric transforming DNA termini. No fungal sequences other than telomeric repeats were detected in extrachromosomal DNAs. Transformants contained three to six different sizes or conformational forms of extrachromosomal DNAs. The DNAs showed no change in size or internal structure during 6 months of growth with selection, but were lost after 20 days of growth without selection. Transformation of wild-type P. microspora with a PCR-amplified extrachromosomal DNA having terminal telomeric repeats produced up to 50-fold more transformants than the original transformation vector. The addition of telomeric repeats to foreign DNA is unusual among fungi and may have important adaptive or developmental implications.

Flexible positioning of the telomerase-associated nuclease leads to preferential elimination of nontelomeric DNA

In addition to a reverse transcriptase activity, telomerase is associated with a DNA endonuclease that removes nucleotides from a primer 3' terminus prior to telomere repeat addition. Here we examine the DNA specificity of the primer cleavage-elongation reaction carried out by the Euplotes crassus telomerase. We show that the primer cleavage activity copurified with the E. crassus telomerase polymerase, indicating that it either is an intrinsic property of telomerase or is catalyzed by a tightly associated factor. Using chimeric primers containing stretches of telomeric DNA that could be precisely positioned on the RNA template, we found that the cleavage site is more flexible than originally proposed. Primers harboring mismatches in dT tracts that aligned opposite nucleotides 37 to 40 in the RNA template were cleaved to eliminate the mismatched residues along with the adjacent 3' sequence. The cleaved product was then elongated to generate perfect telomeric repeats. Mismatches in dG tracts were not removed, implying that the nuclease does not track coordinately with the polymerase active site. Our data indicate that the telomerase-associated nuclease could provide a rudimentary proofreading function in telomere synthesis by eliminating mismatches between the DNA primer and the 5' region of the telomerase RNA template.

A novel specificity for the primer-template pairing requirement in Tetrahymena telomerase

Telomerase is a specialized reverse transcriptase with a built-in RNA template. Base pairing between the templating domain of telomerase RNA and a telomeric DNA primer is normally a characteristic of elongation of telomeric DNA. Here we demonstrate the mechanism by which Tetrahymena telomerase bypasses a requirement for template-primer pairing in order to add telomeric DNA de novo to completely non-telomeric DNA primers. We show that this reaction initiates by copying the template residue at the 3' boundary of the telomerase RNA template sequence. Unexpectedly, as the RNA template moves through the telomerase catalytic center, the number of required potential Watson-Crick base pairs between RNA template and DNA primer increases from zero to five. We propose that this unprecedented position specificity of a base pairing potential requirement in a polymerase underlies the chromosome healing mechanism of telomerase, and reflects constraints inherent in an internal template.

Developmentally regulated initiation of DNA synthesis by telomerase: evidence for factor-assisted de novo telomere formation

Telomerase serves a dual role at telomeres, maintaining tracts of telomere repeats and forming telomeres de novo on broken chromosomes in a process called chromosome healing. In ciliates, both mechanisms are readily observed. Vegetatively growing cells maintain pre-existing telomeres, while cells undergoing macronuclear development fragment their chromosomes and form telomeres de novo. Here we provide the first evidence for developmentally regulated initiation of DNA synthesis by telomerase. In vitro assays were conducted with telomerase from vegetative and developing Euplotes macronuclei using chimeric primers that contained non-telomeric 3' ends and an upstream stretch of telomeric DNA. In developing macronuclei, chimeric primers had two fates: nucleotides were either polymerized directly onto the 3' terminus or residues were removed from the 3' end by endonucleolytic cleavage before polymerization began. In contrast, telomerase from vegetative macronuclei used only the cleavage pathway. Telomere repeat addition onto non-telomeric 3' ends was lost when developing macronuclei were lysed and the contents purified on glycerol gradients. However, when fractions from the glycerol gradient were added back to partially purified telomerase, telomere synthesis was restored. The data indicate that a dissociable chromosome healing factor (CHF) collaborates with telomerase to initiate developmentally programmed de novo telomere formation.

Processing of nontelomeric 3' ends by telomerase: default template alignment and endonucleolytic cleavage

Telomerase is a specialized reverse transcriptase that maintains telomeres at chromosome ends by extending preexisting tracts of telomeric DNA and forming telomeres de novo on broken chromosomes. Whereas the interaction of telomerase with telomeric DNA has been studied in some detail, relatively little is known about how this enzyme processes nontelomeric DNA. In this study we recruited the Euplotes telomerase to nontelomeric 3' termini in vitro using chimeric DNA primers that carried one repeat of a telomeric sequence at various positions upstream of a nontelomeric 3' end. Such primers were processed in two distinct pathways. First, nontelomeric 3' ends could be elongated directly by positioning a primer terminus at a specific site on the RNA template. Delivery to this default site was precise, always resulting in the addition of 4 dG residues to the non-telomeric 3' ends. These same residues initiate new telomeres formed in vivo. Alternatively, 3' nontelomeric nucleotides were removed from primers prior to initiating the first elongation cycle. As with default positioning of nontelomeric 3' ends, the cleavage event was extremely precise and was followed by the addition of dG residues to the primer 3' ends. The specificity of the cleavage reaction was mediated by primer interaction with the RNA template and, remarkably, proceeded by an endonucleolytic mechanism. These observations suggest a mechanism for the precision of developmentally regulated de novo telomere formation and expand our understanding of the enzymatic properties of telomerase.