Reiterative dG addition by Euplotes crassus telomerase during extension of non-telomeric DNA.

Telomerase from the ciliate Euplotes crassus incorporates G4T4telomeric repeats onto both telomeric and non-telomeric single-stranded DNA 3'-ends via reverse transcription of a templating domain in its RNA subunit. Here we describe an unusual mode of template copying that is characteristic of DNA synthesis onto non-telomeric 3'-ends in vitro . When dTTP was eliminated from telomerase reactions, telomeric primers or DNA products generated from the telomerase endonuclease were extended by precise copying of the RNA template. In contrast, telomerase catalyzed the addition of up to 13 dG residues onto primers with non-telomeric 3'-ends under the same reaction conditions. Introducing mismatches in the 3'-terminus of telomeric primers that reduced primer complementarity to the RNA template induced reiterative dG incorporation, indicating that the reaction is influenced by Watson-Crick base pair formation between the primer and the RNA template. Unexpectedly, the reiterative dG addition mode was confined to telomerase derived from developing cells that undergo new telomere formation. This reaction was not observed in vegetatively growing cells. We postulate that indiscriminate dG addition by telomerase occurs by reiterative copying of C residues in the telomerase RNA templating domain and reflects lateral instability of the primer-template interaction during de novo telomere formation.

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.

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.