Proofreading activity of DNA polymerase Pol2 mediates 3'-end processing during nonhomologous end joining in yeast.

Genotoxic agents that cause double-strand breaks (DSBs) often generate damage at the break termini. Processing enzymes, including nucleases and polymerases, must remove damaged bases and/or add new bases before completion of repair. Artemis is a nuclease involved in mammalian nonhomologous end joining (NHEJ), but in Saccharomyces cerevisiae the nucleases and polymerases involved in NHEJ pathways are poorly understood. Only Pol4 has been shown to fill the gap that may form by imprecise pairing of overhanging 3' DNA ends. We previously developed a chromosomal DSB assay in yeast to study factors involved in NHEJ. Here, we use this system to examine DNA polymerases required for NHEJ in yeast. We demonstrate that Pol2 is another major DNA polymerase involved in imprecise end joining. Pol1 modulates both imprecise end joining and more complex chromosomal rearrangements, and Pol3 is primarily involved in NHEJ-mediated chromosomal rearrangements. While Pol4 is the major polymerase to fill the gap that may form by imprecise pairing of overhanging 3' DNA ends, Pol2 is important for the recession of 3' flaps that can form during imprecise pairing. Indeed, a mutation in the 3'-5' exonuclease domain of Pol2 dramatically reduces the frequency of end joins formed with initial 3' flaps. Thus, Pol2 performs a key 3' end-processing step in NHEJ.

Kinetic pathway of pyrophosphorolysis by a retrotransposon reverse transcriptase.

DNA and RNA polymerases use a common phosphoryl transfer mechanism for base addition that requires two or three acidic amino acid residues at their active sites. We previously showed, for the reverse transcriptase (RT) encoded by the yeast retrotransposon Ty1, that one of the three conserved active site aspartates (D(211)) can be substituted by asparagine and still retain in vitro polymerase activity, although in vivo transposition is lost. Transposition is partially restored by second site suppressor mutations in the RNAse H domain. The novel properties of this amino acid substitution led us to express the WT and D(211)N mutant enzymes, and study their pre-steady state kinetic parameters. We found that the k(pol) was reduced by a factor of 223 in the mutant, although the K(d) for nucleotide binding was unaltered. Further, the mutant enzyme had a marked preference for Mn(2+) over Mg(2+). To better understand the functions of this residue within the Ty1 RT active site, we have now examined the in vitro properties of WT and D(211)N mutant Ty1 RTs in carrying out pyrophosphorolysis, the reverse reaction to polymerization, where pyrophosphate is the substrate and dNTPs are the product. We find that pyrophosphorolysis is efficient only when the base-paired primer template region is >14 bases, and that activity increases when the primer end is blunt-ended or recessed by only a few bases. Using pre-steady state kinetic analysis, we find that the rate of pyrophosphorolysis (k(pyro)) in the D(211)N mutant is nearly 320 fold lower than the WT enzyme, and that the mutant enzyme has an approximately 170 fold lower apparent K(d) for pyrophosphate. These findings indicate that subtle substrate differences can strongly affect the enzyme's ability to properly position the primer-end to carry out pyrophosphorolysis. Further the kinetic data suggests that the D(211) residue has a role in pyrophosphate binding and release, which could affect polymerase translocation, and help explain the D(211)N mutant's transposition defect.

Capture of linear fragments at a double-strand break in yeast.

Double-strand breaks (DSBs) are dangerous chromosomal lesions that must be efficiently repaired in order to avoid loss of genetic information or cell death. In all organisms studied to date, two different mechanisms are used to repair DSBs: homologous recombination (HR) and non-homologous end joining (NHEJ). Previous studies have shown that during DSB repair, non-homologous exogenous DNA (also termed 'filler DNA') can be incorporated at the site of a DSB. We have created a genetic system in the yeast Saccharomyces cerevisiae to study the mechanism of fragment capture. Our yeast strains carry recognition sites for the HO endonuclease at a unique chromosomal site, and plasmids in which a LEU2 gene is flanked by HO cut sites. Upon induction of the HO endonuclease, a linear extrachromosomal fragment is generated in each cell and its incorporation at the chromosomal DSB site can be genetically monitored. Our results show that linear fragments are captured at the repaired DSB site at frequencies of 10(-6) to 10(-4) per plated cell depending on strain background and specific end sequences. The mechanism of fragment capture depends on the NHEJ machinery, but only partially on the homologous recombination proteins. More than one fragment can be used during repair, by a mechanism that relies on the annealing of small complementary sequences. We present a model to explain the basis for fragment capture.

Global mapping of transposon location.

Transposable genetic elements are ubiquitous, yet their presence or absence at any given position within a genome can vary between individual cells, tissues, or strains. Transposable elements have profound impacts on host genomes by altering gene expression, assisting in genomic rearrangements, causing insertional mutations, and serving as sources of phenotypic variation. Characterizing a genome's full complement of transposons requires whole genome sequencing, precluding simple studies of the impact of transposition on interindividual variation. Here, we describe a global mapping approach for identifying transposon locations in any genome, using a combination of transposon-specific DNA extraction and microarray-based comparative hybridization analysis. We use this approach to map the repertoire of endogenous transposons in different laboratory strains of Saccharomyces cerevisiae and demonstrate that transposons are a source of extensive genomic variation. We also apply this method to mapping bacterial transposon insertion sites in a yeast genomic library. This unique whole genome view of transposon location will facilitate our exploration of transposon dynamics, as well as defining bases for individual differences and adaptive potential.

Widespread RNA editing of embedded alu elements in the human transcriptome.

More than one million copies of the approximately 300-bp Alu element are interspersed throughout the human genome, with up to 75% of all known genes having Alu insertions within their introns and/or UTRs. Transcribed Alu sequences can alter splicing patterns by generating new exons, but other impacts of intragenic Alu elements on their host RNA are largely unexplored. Recently, repeat elements present in the introns or 3'-UTRs of 15 human brain RNAs have been shown to be targets for multiple adenosine to inosine (A-to-I) editing. Using a statistical approach, we find that editing of transcripts with embedded Alu sequences is a global phenomenon in the human transcriptome, observed in 2674 ( approximately 2%) of all publicly available full-length human cDNAs (n = 128,406), from >250 libraries and >30 tissue sources. In the vast majority of edited RNAs, A-to-I substitutions are clustered within transcribed sense or antisense Alu sequences. Edited bases are primarily associated with retained introns, extended UTRs, or with transcripts that have no corresponding known gene. Therefore, Alu-associated RNA editing may be a mechanism for marking nonstandard transcripts, not destined for translation.

Insights into the role of an active site aspartate in Ty1 reverse transcriptase polymerization.

Long terminal repeat-containing retrotransposons encode reverse transcriptases (RTs) that replicate their RNA into integratable, double-stranded DNA. A mutant version of the RT from Saccharomyces cerevisiae retrotransposon Ty1, in which one of the three active site aspartates has been changed to asparagine (D211N), is still capable of in vitro polymerization, although it is blocked for in vivo transposition. We generated recombinant WT and D211N Ty1 RTs to study RT function and determine specific roles for the Asp(211) residue. Presteady-state kinetic analysis of the two enzymes shows that the D211N mutation has minimal effect on nucleotide binding but reduces the k(pol) by approximately 230-fold. The mutation reduces binding affinity for both Mn(2+) and Mg(2+), indicating that the Asp(211) side chain helps create a tight metal binding pocket. Although both enzymes are highly processive and tend to remain bound to their initial substrate, each shows distinctive patterns of pausing, attributable to interactions between metal ions and the active site residue. These results provide insights to specific roles for the Asp(211) residue during polymerization and indicate unusual enzymatic properties that bear on the Ty1 replication pathway.

Reciprocal translocations in Saccharomyces cerevisiae formed by nonhomologous end joining.

Reciprocal translocations are common in cancer cells, but their creation is poorly understood. We have developed an assay system in Saccharomyces cerevisiae to study reciprocal translocation formation in the absence of homology. We induce two specific double-strand breaks (DSBs) simultaneously on separate chromosomes with HO endonuclease and analyze the subsequent chromosomal rearrangements among surviving cells. Under these conditions, reciprocal translocations via nonhomologous end joining (NHEJ) occur at frequencies of approximately 2-7 x 10(-5)/cell exposed to the DSBs. Yku80p is a component of the cell's NHEJ machinery. In its absence, reciprocal translocations still occur, but the junctions are associated with deletions and extended overlapping sequences. After induction of a single DSB, translocations and inversions are recovered in wild-type and rad52 strains. In these rearrangements, a nonrandom assortment of sites have fused to the DSB, and their junctions show typical signs of NHEJ. The sites tend to be between open reading frames or within Ty1 LTRs. In some cases the translocation partner is formed by a break at a cryptic HO recognition site. Our results demonstrate that NHEJ-mediated reciprocal translocations can form in S. cerevisiae as a consequence of DSB repair.

Extension and cleavage of the polypurine tract plus-strand primer by Ty1 reverse transcriptase.

Using hybrid RNA/DNA substrates containing the polypurine tract (PPT) plus-strand primer, we have examined the interaction between the Ty1 reverse transcriptase (RT) and the plus-strand initiation complex. We show here that, although the PPT sequence is relatively resistant to RNase H cleavage, it can be cleaved internally by the polymerase-independent RNase H activity of Ty1 RT. Alternatively, this PPT can be used to initiate plus-strand DNA synthesis. We demonstrate that cleavage at the PPT/DNA junction occurs only after at least 9 nucleotides are extended. Cleavage leaves a nick between the RNA primer and the nascent plus-strand DNA. We show that Ty1 RT has a strand displacement activity beyond a gap but that the PPT is not efficiently re-utilized in vitro for another round of DNA synthesis after a first plus-strand DNA has been synthesized and cleaved at the PPT/U3 junction.

Ku-dependent and Ku-independent end-joining pathways lead to chromosomal rearrangements during double-strand break repair in Saccharomyces cerevisiae.

Chromosomal double-strand breaks (DSBs) can be repaired by either homology-dependent or homology-independent pathways. Nonhomologous repair mechanisms have been relatively less well studied, despite their potential importance in generating chromosomal rearrangements. We have developed a Saccharomyces cerevisiae-based assay to identify and characterize homology-independent chromosomal rearrangements associated with repair of a unique DSB generated within an engineered URA3 gene. Approximately 1% of successfully repaired cells have accompanying chromosomal rearrangements consisting of large insertions, deletions, aberrant gene conversions, or other more complex changes. We have analyzed rearrangements in isogenic wild-type, rad52, yku80, and rad52 yku80 strains, to determine the types of events that occur in the presence or absence of these key repair proteins. Deletions were found in all strain backgrounds, but insertions were dependent upon the presence of Yku80p. A rare RAD52- and YKU80-independent form of deletion was present in all strains. These events were characterized by long one-sided deletions (up to 13 kb) and extensive imperfect overlapping sequences (7-22 bp) at the junctions. Our results demonstrate that the frequency and types of repair events depend on the specific genetic context. This approach can be applied to a number of problems associated with chromosome stability.