Topoisomerase I‐mediated cleavage at unrepaired ribonucleotides generates DNA double‐strand breaks

Ribonuclease activity of topoisomerase I (Top1) causes DNA nicks bearing 2′,3′‐cyclic phosphates at ribonucleotide sites. Here, we provide genetic and biochemical evidence that DNA double‐strand breaks (DSBs) can be directly generated by Top1 at sites of genomic ribonucleotides. We show that RNase H2‐deficient yeast cells displayed elevated frequency of Rad52 foci, inactivation of RNase H2 and RAD52 led to synthetic lethality, and combined loss of RNase H2 and RAD51 induced slow growth and replication stress. Importantly, these phenotypes were rescued upon additional deletion of TOP1, implicating homologous recombination for the repair of Top1‐induced damage at ribonuclelotide sites. We demonstrate biochemically that irreversible DSBs are generated by subsequent Top1 cleavage on the opposite strand from the Top1‐induced DNA nicks at ribonucleotide sites. Analysis of Top1‐linked DNA from pull‐down experiments revealed that Top1 is covalently linked to the end of DNA in RNase H2‐deficient yeast cells, supporting this model. Taken together, these results define Top1 as a source of DSBs and genome instability when ribonucleotides incorporated by the replicative polymerases are not removed by RNase H2.     

Error‐free and mutagenic processing of topoisomerase 1‐provoked damage at genomic ribonucleotides

Genomic ribonucleotides incorporated during DNA replication are commonly repaired by RNase H2‐dependent ribonucleotide excision repair (RER). When RNase H2 is compromised, such as in Aicardi‐Goutières patients, genomic ribonucleotides either persist or are processed by DNA topoisomerase 1 (Top1) by either error‐free or mutagenic repair. Here, we present a biochemical analysis of these pathways. Top1 cleavage at genomic ribonucleotides can produce ribonucleoside‐2′,3′‐cyclic phosphate‐terminated nicks. Remarkably, this nick is rapidly reverted by Top1, thereby providing another opportunity for repair by RER. However, the 2′,3′‐cyclic phosphate‐terminated nick is also processed by Top1 incision, generally 2 nucleotides upstream of the nick, which produces a covalent Top1–DNA complex with a 2‐nucleotide gap. We show that these covalent complexes can be processed by proteolysis, followed by removal of the phospho‐peptide by Tdp1 and the 3′‐phosphate by Tpp1 to mediate error‐free repair. However, when the 2‐nucleotide gap is associated with a dinucleotide repeat sequence, sequence slippage re‐alignment followed by Top1‐mediated religation can occur which results in 2‐nucleotide deletion. The efficiency of deletion formation shows strong sequence‐context dependence.     

Topoisomerase I Alone Is Sufficient to Produce Short DNA Deletions and Can Also Reverse Nicks at Ribonucleotide Sites

Ribonucleotide monophosphates (rNMPs) are among the most frequent form of DNA aberration, as high ratios of ribonucleotide triphosphate:deoxyribonucleotide triphosphate pools result in approximately two misincorporated rNMPs/kb of DNA. The main pathway for the removal of rNMPs is by RNase H2. However, in a RNase H2 knock-out yeast strain, a topoisomerase I (Top1)-dependent mutator effect develops with accumulation of short deletions within tandem repeats. Proposed models for these deletions implicated processing of Top1-generated nicks at rNMP sites and/or sequential Top1 binding, but experimental support has been lacking thus far. Here, we investigated the biochemical mechanism of the Top1-induced short deletions at the rNMP sites by generating nicked DNA substrates bearing 2′,3′-cyclic phosphates at the nick sites, mimicking the Top1-induced nicks. We demonstrate that a second Top1 cleavage complex adjacent to the nick and subsequent faulty Top1 religation led to the short deletions. Moreover, when acting on the nicked DNA substrates containing 2′,3′-cyclic phosphates, Top1 generated not only the short deletion, but also a full-length religated DNA product. A catalytically inactive Top1 mutant (Top1-Y723F) also induced the full-length products, indicating that Top1 binding independent of its enzymatic activity promotes the sealing of DNA backbones via nucleophilic attacks by the 5′-hydroxyl on the 2′,3′-cyclic phosphate. The resealed DNA would allow renewed attempt for repair by the error-free RNase H2-dependent pathway in vivo. Our results provide direct evidence for the generation of short deletions by sequential Top1 cleavage events and for the promotion of nick religation at rNMP sites by Top1.     

Trapping of human DNA topoisomerase I by DNA structures mimicking intermediates of DNA repair

In this report we show that human DNA Topoisomerase I (Top1) forms DNA-protein adducts with nicked and gapped DNA structures lacking a conventional Top1 cleavage site. The radioactively labeled crosslinking products were identified by SDS-gel electrophoresis. The chemical structure of the groups at 5' or 3' end of the nick does not have an effect on the formation of these covalent adducts. Therefore, all kinds of nicks, either directly induced by ionizing radiation or reactive oxygen species or indirectly induced in the course of base excision repair (BER) are targets for Top1 that competes with BER proteins and other nick-sensors. Top1-DNA covalent adducts formed in cells exposed to DNA damaging agents can promote genetic instability.     

DNA sequencing by partial ribosubstitution

A new rapid method for DNA sequence analysis has been devised. In this method, base-specific cleavage is achieved at partially substituted ribonucleotides which are introduced by DNA polymerase extension in the presence of Mn2⁺. Access to a target sequence and label incorporation are achieved by extending a restriction fragment primer with DNA polymerase I. After a short initial incorporation with [α-³²P]deoxynucleotide triphosphates to label the 5′ region of the target sequence, the triphosphates are removed and the reaction mixture is divided four ways for a second primed extension. The second extension is a cold chase in the presence of Mn²⁺, all four deoxynucleotides and one of the four ribonucleotides under conditions that result in about 2% ribonucleotides substitution at each position. After cleavage at the restriction site and alkali cleavage at the positions of partial ribosubstitution, each reaction mixture is analysed by electrophoresis on a high-resolution denaturing acrylamide gel. As in the other rapid DNA sequencing methods the extent of DNA sequence that can be determined from a single experiment is limited only by the resolution of the analysing gels. At present some 100 nucleotides of sequence can be determined from a single priming reaction.     

Tyrosyl-DNA phosphodiesterase 1 (TDP1) repairs DNA damage induced by topoisomerases I and II and base alkylation in vertebrate cells

Tyrosyl-DNA phosphodiesterase 1 (Tdp1) repairs topoisomerase I cleavage complexes (Top1cc) by hydrolyzing their 3'-phosphotyrosyl DNA bonds and repairs bleomycin-induced DNA damage by hydrolyzing 3'-phosphoglycolates. Yeast Tdp1 has also been implicated in the repair of topoisomerase II-DNA cleavage complexes (Top2cc). To determine whether vertebrate Tdp1 is involved in the repair of various DNA end-blocking lesions, we generated Tdp1 knock-out cells in chicken DT40 cells (Tdp1-/-) and Tdp1-complemented DT40 cells with human TDP1. We found that Tdp1-/- cells were not only hypersensitive to camptothecin and bleomycin but also to etoposide, methyl methanesulfonate (MMS), H(2)O(2), and ionizing radiation. We also show they were deficient in mitochondrial Tdp1 activity. In biochemical assays, recombinant human TDP1 was found to process 5'-phosphotyrosyl DNA ends when they mimic the 5'-overhangs of Top2cc. Tdp1 also processes 3'-deoxyribose phosphates generated from hydrolysis of abasic sites, which is consistent with the hypersensitivity of Tdp1-/- cells to MMS and H(2)O(2). Because recent studies established that CtIP together with BRCA1 also repairs topoisomerase-mediated DNA damage, we generated dual Tdp1-CtIP-deficient DT40 cells. Our results show that Tdp1 and CtIP act in parallel pathways for the repair of Top1cc and MMS-induced lesions but are epistatic for Top2cc. Together, our findings reveal a broad involvement of Tdp1 in DNA repair and clarify the role of human TDP1 in the repair of Top2-induced DNA damage.     

Loss of nonhomologous end joining confers camptothecin resistance in DT40 cells. Implications for the repair of topoisomerase I-mediated DNA damage

DNA topoisomerase I (Top1) generates transient DNA single-strand breaks via the formation of cleavage complexes in which the enzyme is linked to the 3'-phosphate of the cleavage strand. The anticancer drug camptothecin (CPT) poisons Top1 by trapping cleavage complexes, thereby inducing Top1-linked single-strand breaks. Such DNA lesions are converted into DNA double-strand breaks (DSBs) upon collision with replication forks, implying that DSB repair pathways could be involved in the processing/repair of Top1-mediated DNA damage. Here we report that Top1-mediated DNA damage is repaired primarily by homologous recombination, a major pathway of DSB repair. Unexpectedly, however, we found that nonhomologous end joining (NHEJ), another DSB repair pathway, has no positive role in the relevant repair; notably, DT40 cell mutants lacking either of the NHEJ factors (namely, Ku70, DNA-dependent protein kinase catalytic subunit, and DNA ligase IV) were resistant to killing by CPT. In addition, we showed that the absence of NHEJ alleviates the requirement of homologous recombination in the repair of CPT-induced DNA damage. Our results indicate that NHEJ can be a cytotoxic pathway in the presence of CPT, shedding new light on the molecular mechanisms for the formation and repair of Top1-mediated DNA damage in vertebrates. Thus, our data have significant implications for cancer chemotherapy involving Top1 inhibitors.     

Proofreading of ribonucleotides inserted into DNA by yeast DNA polymerase ɛ

We have investigated the ability of the 3′ exonuclease activity of Saccharomyces cerevisiae DNA polymerase ? (Pol ?) to proofread newly inserted ribonucleotides (rNMPs). During DNA synthesis in vitro, Pol ? proofreads ribonucleotides with apparent efficiencies that vary from none at some locations to more than 90% at others, with rA and rU being more efficiently proofread than rC and rG. Previous studies show that failure to repair ribonucleotides in the genome of rnh201Δ strains that lack RNase H2 activity elevates the rate of short deletions in tandem repeat sequences. Here we show that this rate is increased by 2–4-fold in pol2-4 rnh201Δ strains that are also defective in Pol ? proofreading. In comparison, defective proofreading in these same strains increases the rate of base substitutions by more than 100-fold. Collectively, the results indicate that although proofreading of an ‘incorrect’ sugar is less efficient than is proofreading of an incorrect base, Pol ? does proofread newly inserted rNMPs to enhance genome stability.     

Position- and orientation-specific enhancement of topoisomerase I cleavage complexes by triplex DNA structures

Topoisomerase I (Top1) activities are sensitive to various endogenous base modifications, and anticancer drugs including the natural alkaloid camptothecin. Here, we show that triple helix-forming oligonucleotides (TFOs) can enhance Top1-mediated DNA cleavage by affecting either or both the nicking and the closing activities of Top1 depending on the position and the orientation of the triplex DNA structure relative to the Top1 site. TFO binding 1 bp downstream from the Top1 site enhances cleavage by inhibiting religation and to a lesser extent DNA nicking. In contrast, TFO binding 4 bp downstream from the Top1 site enhances DNA nicking especially when the 3′ end of the TFO is proximal to the Top1 site. However, when the orientation of the triplex is inverted, with its 5′ terminus 4 bp downstream from the Top1 site, religation is also inhibited. These position- and orientation-dependent effects of triplex structures on the Top1-mediated DNA cleavage and religation are discussed in the context of molecular modeling and effects of TFO on DNA twist and mobility at the duplex/triplex junction.     

Ribonucleotide-deoxyribonucleotide linkages at the origin of DNA replication of colicin E1 plasmid

We have shown by nearest-neighbor analysis that ribonucleotide-DNA linkages exist on 6 S L-strand² fragments, the first DNA fragments made on Colicin E1 plasmid, at the origin of replication. The linkages rApdA and rApdC predominate. This is in agreement with the previous finding that located the 5′ end of the 6 S L-fragments on the plasmid DNA sequence (Tomizawa et al., 1977). Most of the molecules that contain ribonucleotides have a single rA residue and a large fraction of this residue is phosphorylated at the 5′ end. A total of 20 to 40% of the 6 S L-fragments contain at least one ribonucleotide.     

Association of XRCC1 and tyrosyl DNA phosphodiesterase (Tdp1) for the repair of topoisomerase I-mediated DNA lesions

DNA topoisomerase I (Top1) is converted into a cellular poison by camptothecin (CPT) and various endogenous and exogenous DNA lesions. In this study, we used X-ray repair complementation group 1 (XRCC1)-deficient and XRCC1-complemented EM9 cells to investigate the mechanism by which XRCC1 affects the cellular responses to Top1 cleavage complexes induced by CPT. XRCC1 complementation enhanced survival to CPT-induced DNA lesions produced independently of DNA replication. CPT-induced comparable levels of Top1 cleavage complexes (single-strand break (SSB) and DNA-protein cross-links (DPC)) in both XRCC1-deficient and XRCC1-complemented cells. However, XRCC1-complemented cells repaired Top1-induced DNA breaks faster than XRCC1-deficient cells, and exhibited enhanced tyrosyl DNA phosphodiesterase (Tdp1) and polynucleotide kinase phosphatase (PNKP) activities. XRCC1 immunoprecipitates contained Tdp1 polypeptide, and both Tdp1 and PNKP activities, indicating a functional connection between the XRCC1 single-strand break repair pathway and the repair of Top1 covalent complexes by Tdp1 and PNKP.     

The yeast type I topoisomerase Top3 interacts with Sgs1, a DNA helicase homolog: a potential eukaryotic reverse gyrase.

We have previously shown that cells mutant for TOP3, a gene encoding a prokaryotic-like type I topoisomerase in Saccharomyces cerevisiae, display a pleiotropic phenotype including slow growth and genome instability. We identified a mutation, sgs1 (slow growth suppressor), that suppresses both the growth defect and the increased genomic instability of top3 mutants. Here we report the independent isolation of the SGS1 gene in a screen for proteins that interact with Top3. DNA sequence analysis reveals that the putative Sgs1 protein is highly homologous to the helicase encoded by the Escherichia coli recQ gene. These results imply that Sgs1 creates a deleterious topological substrate that Top3 preferentially resolves. The interaction of the Sgs1 helicase homolog and the Top3 topoisomerase is reminiscent of the recently described structure of reverse gyrase from Sulfolobus acidocaldarius, in which a type I DNA topoisomerase and a helicase-like domain are fused in a single polypeptide.     

The absence of Top3 reveals an interaction between the Sgs1 and Pif1 DNA helicases in Saccharomyces cerevisiae

RecQ DNA helicases and Topo III topoisomerases have conserved genetic, physical, and functional interactions that are consistent with a model in which RecQ creates a recombination-dependent substrate that is resolved by Topo III. The phenotype associated with Topo III loss suggests that accumulation of a RecQ-created substrate is detrimental. In yeast, mutation of the TOP3 gene encoding Topo III causes pleiotropic defects that are suppressed by deletion of the RecQ homolog Sgs1. We searched for gene dosage suppressors of top3 and identified Pif1, a DNA helicase that acts with polarity opposite to that of Sgs1. Pif1 overexpression suppresses multiple top3 defects, but exacerbates sgs1 and sgs1 top3 defects. Furthermore, Pif1 helicase activity is essential in the absence of Top3 in an Sgs1-dependent manner. These data clearly demonstrate that Pif1 helicase activity is required to counteract Sgs1 helicase activity that has become uncoupled from Top3. Pif1 genetic interactions with the Sgs1-Top3 pathway are dependent upon homologous recombination. We also find that Pif1 is recruited to DNA repair foci and that the frequency of these foci is significantly increased in top3 mutants. Our results support a model in which Pif1 has a direct role in the prevention or repair of Sgs1-induced DNA damage that accumulates in top3 mutants.