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.     

A human telomerase-associated nuclease

Ciliate and yeast telomerase possess a nucleolytic activity capable of removing DNA from the 3' end of a single-stranded oligonucleotide substrate. The nuclease activity is thought to assist in enzyme proofreading and/or processivity. Herein, we report a previously uncharacterized human telomerase-associated nuclease activity that shares several properties with ciliate and yeast telomerases. Partially purified human telomerase, either from cell extracts or recombinantly produced, demonstrated an ability to remove 3' nontelomeric nucleotides from a substrate containing 5' telomeric DNA, followed by extension of the newly exposed telomeric sequence. This cleavage/extension activity was apparent at more than one position within the telomeric DNA and was influenced by sequences 5' to the telomeric/nontelomeric boundary and by substitution with a methylphosphonate moiety at the telomeric/nontelomeric DNA boundary. Our data suggest that human telomerase is associated with an evolutionarily conserved nucleolytic activity and support a model in which telomerase-substrate interactions can occur distal from the 3' primer end.     

Tracing the path of DNA substrates in active Tetrahymena telomerase holoenzyme complexes: mapping of DNA contact sites in the RNA subunit

Telomerase, the enzyme that extends single-stranded telomeric DNA, consists of an RNA subunit (TER) including a short template sequence, a catalytic protein (TERT) and accessory proteins. We used site-specific UV cross-linking to map the binding sites for DNA primers in TER within active Tetrahymena telomerase holoenzyme complexes. The mapping was performed at single-nucleotide resolution by a novel technique based on RNase H digestion of RNA-DNA hybrids made with overlapping complementary oligodeoxynucleotides. These data allowed tracing of the DNA path through the telomerase complexes from the template to the TERT binding element (TBE) region of TER. TBE is known to bind TERT and to be involved in the template 5'-boundary definition. Based on these findings, we propose that upstream sequences of each growing telomeric DNA chain are involved in regulation of its growth arrest at the 5'-end of the RNA template. The upstream DNA-TBE interaction may also function as an anchor for the subsequent realignment of the 3'-end of the DNA with the 3'-end of the template to enable initiation of synthesis of a new telomeric repeat.     

De novo telomere addition by Tetrahymena telomerase in vitro.

Previous molecular genetic studies have shown that during programmed chromosomal healing, telomerase adds telomeric repeats directly to non-telomeric sequences in Tetrahymena, forming de novo telomeres. However, the biochemical mechanism underlying this process is not well understood. Here, we show for the first time that telomerase activity is capable in vitro of efficiently elongating completely non-telomeric DNA oligonucleotide primers, consisting of natural telomere-adjacent or random sequences, at low primer concentrations. Telomerase activity isolated from mated or vegetative cells had indistinguishable specificities for nontelomeric and telomeric primers. Consistent with in vivo results, the sequence GGGGT... was the predominant initial DNA sequence added by telomerase in vitro onto the 3' end of the non-telomeric primers. The 3' and 5' sequences of the primer both influenced the efficiency and pattern of de novo telomeric DNA addition. Priming of telomerase by double-stranded primers with overhangs of various lengths showed a requirement for a minimal 3' overhang of 20 nucleotides. With fully single-stranded non-telomeric primers, primer length up to approximately 30 nucleotides strongly affected the efficiency of telomeric DNA addition. We propose a model for the primer binding site of telomerase for non-telomeric primers to account for these length and structural requirements. We also propose that programmed de novo telomere addition in vivo is achieved through a hitherto undetected intrinsic ability of telomerase to elongate completely non-telomeric sequences.     

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.     

RNA/DNA hybrid binding affinity determines telomerase template-translocation efficiency

Telomerase synthesizes telomeric DNA repeats onto chromosome termini from an intrinsic RNA template. The processive synthesis of DNA repeats relies on a unique, yet poorly understood, mechanism whereby the telomerase RNA template translocates and realigns with the DNA primer after synthesizing each repeat. Here, we provide evidence that binding of the realigned RNA/DNA hybrid by the active site is an essential step for template translocation. Employing a template-free human telomerase system, we demonstrate that the telomerase active site directly binds to RNA/DNA hybrid substrates for DNA polymerization. In telomerase processivity mutants, the template-translocation efficiency correlates with the affinity for the RNA/DNA hybrid substrate. Furthermore, the active site is unoccupied during template translocation as a 5 bp extrinsic RNA/DNA hybrid effectively reduces the processivity of the template-containing telomerase. This suggests that strand separation and template realignment occur outside the active site, preceding the binding of realigned hybrid to the active site. Our results provide new insights into the ancient RNA/DNA hybrid binding ability of telomerase and its role in template translocation.     

TRF1 inhibits telomere C-strand DNA synthesis in vitro

Human TTAGGG repeat-binding factor 1 (TRF1) is involved in the regulation of telomere length in vivo, but the mechanism of regulation remains largely undefined. We have developed an in vitro system for assessing the effect of TRF1 on DNA synthesis using purified proteins and synthetic DNA substrates. Results reveal that TRF1, when bound to telomeric duplex DNA, inhibits DNA synthesis catalyzed by DNA polymerase alpha/primase (pol alpha). Inhibition required that TRF1 be bound to duplex telomeric DNA as no effect of TRF1 was observed on nontelomeric, random DNA substrates. Inhibition was shown to be dependent on TRF1 concentration and the length of the telomeric duplex region of the DNA substrate. When bound in cis to telomeric duplex DNA, TRF1 was also capable of inhibiting pol alpha-catalyzed DNA synthesis on nontelomeric DNA sequences from positions both upstream and downstream of the extending polymerase. Inhibition of DNA synthesis was shown to be specific for TRF1 but not necessarily for the DNA polymerase used in the extension reaction. In a series of control experiments, we assessed T7 DNA polymerase-catalyzed synthesis on a DNA template containing tandem gal4 operators. In these experiments, the addition of the purified Gal4-DNA binding domain (Gal4-DBD) protein has no effect on the ability of T7 polymerase to copy the DNA template. Interestingly, TRF1 inhibition was observed on telomeric DNA substrates using T7 DNA polymerase. These results suggest that TRF1, when bound to duplex telomeric DNA, serves to block extension by DNA polymerases. These results are discussed with respect to the role of TRF1 in telomere length regulation.     

Sequence-specific DNA primer effects on telomerase polymerization activity.

The ribonucleoprotein enzyme telomerase synthesizes one strand of telomeric DNA by copying a template sequence within the RNA moiety of the enzyme. Kinetic studies of this polymerization reaction were used to analyze the mechanism and properties of the telomerase from Tetrahymena thermophila. This enzyme synthesizes TTGGGG repeats, the telomeric DNA sequence of this species, by elongating a DNA primer whose 3' end base pairs with the template-forming domain of the RNA. The enzyme was found to act nonprocessively with short (10- to 12-nucleotide) primers but to become processive as TTGGGG repeats were added. Variation of the 5' sequences of short primers with a common 3' end identified sequence-specific effects which are distinct from those involving base pairing of the 3' end of the primer with the RNA template and which can markedly induce enzyme activity by increasing the catalytic rate of the telomerase polymerization reaction. These results identify an additional mechanistic basis for telomere and DNA end recognition by telomerase in vivo.     

Structural aspects of RecA-dependent homologous strand exchange involving human telomeric DNA

Telomeric DNA sequences in human cells and those of other vertebrates consist of long d(TTAGGG) repeats. In somatic cells, telomeres shorten every cell division with shortening serving as a mitotic clock that counts cell divisions and ultimately results in cellular senescence. Telomere length is principally maintained by a ribonucleoprotein, telomerase. However, a non-negligible proportion of human cells use a recombination-based mechanism for telomere maintenance, termed alternative maintenance of telomeres (ALT). Although the molecular mechanism of ALT is not known, GT-rich sequences in prokaryotes and eukaryotes display high levels of recombination relative to those of non-GT-rich DNA. We show that human telomeric strand-exchange complexes mediated by Escherichia coli RecA protein differ from those formed with nontelomeric sequences. Moreover, telomeric strand-exchange intermediates, unlike those involving nontelomeric sequences, exhibit a tendency to form higher-order nucleoprotein structures. We propose that the strong DNA unwinding activity inherent in the assembly of the RecA strand-exchange complex promotes the formation of alternative DNA structures at human telomeric loci. Organization of these noncanonical structures into higher-order complexes involving multiple DNA duplexes could facilitate the search for homology on different DNA molecules and provide a framework for understanding recombination-dependent mechanisms of telomere maintenance.     

Healing of broken human chromosomes by the addition of telomeric repeats.

We have characterized and compared a series of naturally occurring chromosomal truncations involving the terminal region of the short arm of human chromosome 16 (16p13.3). All six broken chromosomes appear to have been stabilized by the direct addition of telomeric repeats (TTAGGG)n to nontelomeric DNA. In five of the six chromosomes, sequence analysis shows that the three of four nucleotides preceding the point of telomere addition are complementary to and in phase with the putative RNA template of human telomerase. Otherwise we have found no common structural features around the breakpoint regions. These findings, together with previously reported in vitro data, suggest that chromosome-healing events in man can be mediated by telomerase and that a small region of complementarity to the RNA template of telomerase at the end of a broken chromosome may be sufficient to prime healing in vivo.