Increased Length of Long Terminal Repeats Inhibits Ty1 Transposition and Leads to the Formation of Tandem Multimers

The Ty1 retrotransposon of Saccharomyces cerevisiae is bounded by long-terminal repeats (LTRs). We have constructed a variety of Ty1 elements in which the LTR length has been increased from the normal length of 334 bp to >2 kb. Although small insertions in the LTR have minimal effects on transposition frequency, larger insertions dramatically reduce it. Nevertheless, elements with long LTRs are incorporated into the genome at a low frequency. Most of these rare insertion events represent Ty1 tandem (head to tail) multimers.     

Intra-chromosomal gene conversion induced by a DNA double-strand break in Saccharomyces cerevisiae

We have stimulated mitotic and meiotic gene conversion between non-tandem direct repeats of ADE4 by a defined double-strand break imparted in vivo to one of two copies of the gene. The experimental design permitted us to distinguish unambiguously between reciprocal intra-chromosomal crossing over and non-reciprocal break-join events that could accompany the induced conversions. We observed that (1) less than 10% of the induced conversion events are accompanied by intra-chromosomal crossing over in both mitosis and meiosis; (2) non-reciprocal break-join is not stimulated by the double-strand breaks; (3) a double-strand break in meiosis is repaired off intra-chromosomal homology (if available) with approximately sevenfold preference over repair off the homologous chromosome. Our observations, analyzed in the light of previous investigations of spontaneous inter and intra-chromosomal crossing over and gene conversion, lead to the view that chromosomal configuration constrains intra-chromosomal crossing over accompanying conversion between closely spaced repeated genes during resolution of the conversion intermediate.     

Mechanisms for gene conversion and homologous recombination: The double-strand break repair model and the successive half crossing-over model

Two mechanisms for gene conversion and homologous recombination were discussed. (1) The double-strand break repair model. A double-strand break is expanded to a gap, which is then repaired by copying a homologous sequence. The gene conversion is often accompanied by crossing-over of the flanking sequences. We obtained evidence for this model in Red pathway of bacteriophage lambda and RecE pathway of E. coli. (2) The successive half crossing-over model. Half crossing-over leaves one recombinant duplex and one or two end(s) out of two parental duplexes. The resulting ends are, in turn, recombinogenic. Successive rounds of the half crossing-over mechanism explains why apparent plasmid gene conversion in RecF pathway of E. coli is not accompanied by crossing-over. This model can explain chromosomal gene conversion if we assume that the donor is first replicated. Gene conversion during mating-type switching in yeast, antigenic variation in unicellular microorganisms, and chromosomal gene conversion in mammalian somatic cells are explained by this model. Distinguishing between these two mechanisms is important in understanding recombination in yeast and mammalian cells and also in its application to gene targeting.     

Reduced replication: a call to ARMS

In this issue of Cell, Lemoine et al. monitor chromosome instability in yeast cells with reduced levels of an essential replicative DNA polymerase. The authors identify a hotspot for chromosome aberrations reminiscent of fragile sites in human cells. This hotspot is composed of inverted Ty elements, which lead to a double-strand break under conditions of limited replication.     

Evidence for Conservative (Two-Progeny) DNA Double-Strand Break Repair

The double-strand break repair models for homologous recombination propose that a double-strand break in a duplex DNA segment is repaired by gene conversion copying a homologous DNA segment. This is a type of conservative recombination, or two-progeny recombination, which generates two duplex DNA segments from two duplex DNA segments. Transformation with a plasmid carrying a double-strand gap and an intact homologous DNA segment resulted in products expected from such conservative (two-progeny) repair in Escherichia coli cells with active E. coli RecE pathway (recBC sbcA) or with active bacteriophage λ Red pathway. Apparently conservative double-strand break repair, however, might result from successive events of nonconservative recombination, or one-progeny recombination, which generates only one recombinant duplex DNA segment from two segments, involving multiple plasmid molecules. Contribution of such intermolecular recombination was evaluated by transformation with a mixture of two isogenic parental plasmids marked with a restriction site polymorphism. Most of the gap repair products were from intramolecular and, therefore, conservative (two-progeny) reaction under the conditions chosen. Most were conservative even in the absence of RecA protein. The double-strand gap repair reaction was not affected by inversion of the unidirectional replication origin on the plasmid. These results demonstrate the presence of the conservative (two-progeny) double-strand break repair mechanism. These experiments do not rule out the occurrence of nonconservative (one-progeny) recombination since we set up experimental conditions that should favor detection of conservative (two-progeny) recombination.     

Involvement of DNA End-Binding Protein Ku in Ty Element Retrotransposition

Saccharomyces cerevisiae Ty elements are retrotransposons whose life cycles are strikingly similar to those of retroviruses. They transpose via an RNA intermediate that is converted to linear double-stranded cDNA and then inserted into the host genome. Although Ty integration is mediated by the element-encoded integrase, it has been proposed that host factors are involved in this process. Here, we show that the DNA end-binding protein Ku, which functions in DNA double-strand break repair, potentiates retrotransposition. Specifically, by using a galactose-inducible Ty1 system, we found that in vivo, Ty1 retrotransposition rates were substantially reduced in the absence of Ku. In contrast, this phenotype was not observed with yeast strains containing mutations in other genes that are involved in DNA repair. We present evidence that Ku associates with Ty1 viruslike particles both in vitro and in vivo. These results provide an additional role for Ku and suggest that it might function in the life cycles of retroelements in other systems.     

Competitive repair by naturally dispersed repetitive DNA during non-allelic homologous recombination

Genome rearrangements often result from non-allelic homologous recombination (NAHR) between repetitive DNA elements dispersed throughout the genome. Here we systematically analyze NAHR between Ty retrotransposons using a genome-wide approach that exploits unique features of Saccharomyces cerevisiae purebred and Saccharomyces cerevisiae/Saccharomyces bayanus hybrid diploids. We find that DNA double-strand breaks (DSBs) induce NAHR-dependent rearrangements using Ty elements located 12 to 48 kilobases distal to the break site. This break-distal recombination (BDR) occurs frequently, even when allelic recombination can repair the break using the homolog. Robust BDR-dependent NAHR demonstrates that sequences very distal to DSBs can effectively compete with proximal sequences for repair of the break. In addition, our analysis of NAHR partner choice between Ty repeats shows that intrachromosomal Ty partners are preferred despite the abundance of potential interchromosomal Ty partners that share higher sequence identity. This competitive advantage of intrachromosomal Tys results from the relative efficiencies of different NAHR repair pathways. Finally, NAHR generates deleterious rearrangements more frequently when DSBs occur outside rather than within a Ty repeat. These findings yield insights into mechanisms of repeat-mediated genome rearrangements associated with evolution and cancer.     

Enzymatic restriction of mammalian cell DNA using Pvu II and Bam H1: evidence for the double-strand break origin of chromosomal aberrations

Permeabilized Chinese hamster cells were treated with the restriction enzymes Pvu II and Bam H1 which generate blunt-ended with cohesive-ended double-strand breaks in the DNA respectively. Cells were then allowed to progress to the first mitosis, where chromosomal aberrations were scored. It was found that blunt-ended double-strand breaks induced both chromosome and chromatid aberrations of exchange and deletion types, including a high frequency of tri-radials. The total aberration frequency at high enzyme concentrations was more than ten times the control background frequency. Treatment with Bam H1 on the other hand did not induce aberrations above the background rate. This may indicate that the cohesive ends generated by this enzyme may be easily repaired by the cell due to the stabilization of the hydrogen bonding at the site of the double-strand break. Measurements using the unwinding method showed that the enzymes caused strand breaks in the DNA of permeabilized cells, and an approximate X-ray dose equivalent of the restriction-enzyme-induced breaks could be calculated. This indicated that restriction-induced blunt-ended double-strand breaks are relatively inefficient in causing chromosomal aberrations. This may be because of the presence of 'clean ends' at the site of a double-strand break, which may be repaired by ligation. The method of introducing restriction enzymes into cells opens up a new model approach for the study of the conversion of double-strand breaks into chromosome aberrations.     

Conservative inheritance of newly synthesized DNA in double-strand break-induced gene conversion

To distinguish among possible mechanisms of repair of a double-strand break (DSB) by gene conversion in budding yeast, Saccharomyces cerevisiae, we employed isotope density transfer to analyze budding yeast mating type (MAT) gene switching in G2/M-arrested cells. Both of the newly synthesized DNA strands created during gene conversion are found at the repaired locus, leaving the donor unchanged. These results support suggestions that mitotic DSBs are primarily repaired by a synthesis-dependent strand-annealing mechanism. We also show that the proportion of crossing-over associated with DSB-induced ectopic recombination is not affected by the presence of nonhomologous sequences at one or both ends of the DSB or the presence of additional sequences that must be copied from the donor.     

Multimeric arrays of the yeast retrotransposon Ty.

We have identified a novel integrated form of the yeast retrotransposon Ty consisting of multiple elements joined into large arrays. These arrays were first identified among Ty-induced alpha-pheromone-resistant mutants of MATa cells of Saccharomyces cerevisiae which contain Ty insertions at HML alpha that result in the expression of that normally silent cassette. These insertions are multimeric arrays of both the induced genetically marked Ty element and unmarked Ty elements. Structural analysis of the mutations indicated that the arrays include tandem direct repeats of Ty elements separated by only a single long terminal repeat. The Ty-HML junction fragments of one mutant were cloned and shown to contain a 5-base-pair duplication of the target sequence that is characteristic of a Ty transpositional insertion. In addition, the arrays include rearranged Ty elements that do not have normal long terminal repeat junctions. We have also identified multimeric Ty insertions at other chromosomal sites and as insertions that allow expression of a promoterless his3 gene on a plasmid. The results suggest that Ty transposition includes an intermediate that can undergo recombination to produce multimers.     

cDNA of the Yeast Retrotransposon Ty5 Preferentially Recombines with Substrates in Silent Chromatin

The yeast retrotransposon Ty5 preferentially integrates into regions of silent chromatin. Ty5 cDNA also recombines with homologous sequences, generating tandem elements or elements that have exchanged markers between cDNA and substrate. In this study, we demonstrate that Ty5 integration depends upon the conserved DD(35)E domain of integrase and cis-acting sequences at the end of the long terminal repeat (LTR) implicated in integrase binding. cDNA recombination requires Rad52p, which is responsible for homologous recombination. Interestingly, Ty5 cDNA recombines at least three times more frequently with substrates in silent chromatin than with a control substrate at an internal chromosomal locus. This preference depends upon the Ty5 targeting domain that is responsible for integration specificity, suggesting that localization of cDNA to silent chromatin results in the enhanced recombination. Recombination with a telomeric substrate occasionally generates highly reiterated Ty5 arrays, and mechanisms for tandem element formation were explored by using a plasmid-based recombination assay. Point mutations were introduced into plasmid targets, and recombination products were characterized to determine recombination initiation sites. Despite our previous observation of the importance of the LTR in forming tandem elements, recombination cannot simply be explained by crossover events between the LTRs of substrate and cDNA. We propose an alternative model based on single-strand annealing, where single-stranded cDNA initiates tandem element formation and the LTR is required for strand displacement to form a looped intermediate. Retrotransposons are increasingly found associated with chromosome ends, and amplification of Ty5 by both integration and recombination exemplifies how retroelements can contribute to telomere dynamics.     

Differential usage of alternative pathways of double-strand break repair in Drosophila

Double-strand DNA breaks can be repaired by any of several alternative mechanisms that differ greatly in the nature of the final repaired products. We used a reporter construct, designated "Repair reporter 3" (Rr3), to measure the relative usage of these pathways in Drosophila germ cells. The method works by creating a double-strand break at a specific location such that expression of the red fluorescent protein, DsRed, in the next generation can be used to infer the frequency at which each pathway was used. A key feature of this approach is that most data come from phenotypic scoring, thus allowing large sample sizes and considerable precision in measurements. Specifically, we measured the proportion of breaks repaired by (1) conversion repair, (2) nonhomologous end joining (NHEJ), or (3) single-strand annealing (SSA). For conversion repair, the frequency of mitotic crossing over in the germ line indicates the relative prevalence of repair by double Holliday junction (DHJ) formation vs. the synthesis-dependent strand annealing (SDSA) pathway. We used this method to show that breaks occurring early in germ-line development were much more frequently repaired via single-strand annealing and much less likely to be repaired by end joining compared with identical breaks occurring later in development. Conversion repair was relatively rare when breaks were made either very early or very late in development, but was much more frequent in between. Significantly, the changes in relative usage occurred in a compensatory fashion, such that an increase in one pathway was accompanied by decreases in others. This negative correlation is interpreted to mean that the pathways for double-strand break repair compete with each other to handle a given breakage event.     

Homology Search and Choice of Homologous Partner during Mitotic Recombination

Homologous recombination is an important DNA repair mechanism in vegetative cells. During the repair of double-strand breaks, genetic information is transferred between the interacting DNA sequences (gene conversion). This event is often accompanied by a reciprocal exchange between the homologous molecules, resulting in crossing over. The repair of DNA damage by homologous recombination with repeated sequences dispersed throughout the genome might result in chromosomal aberrations or in the inactivation of genes. It is therefore important to understand how the suitable homologous partner for recombination is chosen. We have developed a system in the yeast Saccharomyces cerevisiae that can monitor the fate of a chromosomal double-strand break without the need to select for recombinants. The broken chromosome is efficiently repaired by recombination with one of two potential partners located elsewhere in the genome. One of the partners has homology to the broken ends of the chromosome, whereas the other is homologous to sequences distant from the break. Surprisingly, a large proportion of the repair is carried out by recombination involving the sequences distant from the broken ends. This repair is very efficient, despite the fact that it requires the processing of a large chromosomal region flanking the break. Our results imply that the homology search involves extensive regions of the broken chromosome and is not carried out exclusively by sequences adjacent to the double-strand break. We show that the mechanism that governs the choice of homologous partners is affected by the length and sequence divergence of the interacting partners, as well as by mutations in the mismatch repair genes. We present a model to explain how the suitable homologous partner is chosen during recombinational repair. The model provides a mechanism that may guard the integrity of the genome by preventing recombination between dispersed repeated sequences.     

A double-strand break in a chromosomal LINE element can be repaired by gene conversion with various endogenous LINE elements in mouse cells

A double-strand break (DSB) in the mammalian genome has been shown to be a very potent signal for the cell to activate repair processes. Two different types of repair have been identified in mammalian cells. Broken ends can be rejoined with or without loss or addition of DNA or, alternatively, a homologous template can be used to repair the break. For most genomic sequences the latter event would involve allelic sequences present on the sister chromatid or homologous chromosome. However, since more than 30% of our genome consists of repetitive sequences, these would have the option of using nonallelic sequences for homologous repair. This could have an impact on the evolution of these sequences and of the genome itself. We have designed an assay to look at the repair of DSBs in LINE-1 (L1) elements which number 10(5) copies distributed throughout the genome of all mammals. We introduced into the genome of mouse epithelial cells an L1 element with an I-SceI endonuclease site. We induced DSBs at the I-SceI site and determined their mechanism of repair. We found that in over 95% of cases, the DSBs were repaired by an end-joining process. However, in almost 1% of cases, we found strong evidence for repair involving gene conversion with various endogenous L1 elements, with some being used preferentially. In particular, the T(F) family and the L1Md-A2 subfamily, which are the most active in retrotransposition, appeared to be contributing the most in this process. The degree of homology did not seem to be a determining factor in the selection of the endogenous elements used for repair but may be based instead on accessibility. Considering their abundance and dispersion, gene conversion between repetitive elements may be occurring frequently enough to be playing a role in their evolution.     

Neutral sucrose gradient sedimentation of very large DNA from Bacillus subtilis. II. Double-strand breaks formed by gamma ray irradiation of the cells

A procedure has been developed whereby essentially all the DNA from Bacillus subtilis cells can be reproducibly extracted in a form which sediments 2.3 times faster than bacteriophage T2 DNA in a neutral sucrose gradient spun at 20,000 revs/ min. When the cells are irradiated with low (3 to 34 kilorads) gamma ray doses, some DNA moves in a slower peak, which from the previous paper (Levin &; Hutchinson, 1973) appears to be linear DNA. Some of the DNA also sediments ahead of the unirradiated DNA. On incubation of the cells at 37°C under conditions such that single-strand DNA breaks are repaired, the fast-sedimenting component is partially restored, with the DNA sedimenting ahead of it usually disappearing, and the quantity in the slower component decreasing. With 80 minutes incubation the fraction of DNA after various radiation doses in the fast-sedimenting component is the same as the fraction of cells able to form colonies, suggesting that the destruction of the component is responsible for the effect of gamma rays on the ability of a cell to replicate. Single-strand breaks introduced into the DNA within the cells do not affect the fast-sedimenting component, so radiation-induced single-strand breaks are not responsible for the effect of gamma rays on replication.The double-strand break rate for DNA in the cells is 0.010 breaks per mass the size of T2 DNA per kilorad. The fast-sedimenting component in irradiated cells which have not been incubated disappears at a rate equal to one radiationinduced double-strand break formed per genome. Since the fast-sedimenting component in solution is also destroyed by one double-strand break per genome (Levin &; Hutchinson, 1973), it is suggested that this component is the genome in the form of a circle. The correspondence between DNA in the fast-sedimenting form after incubation and the ability of cells to form colonies then indicates that a genome can replicate only if all double-strand breaks are repaired.     

Ty1 copy number dynamics in Saccharomyces

To understand long terminal repeat (LTR)-retrotransposon copy number dynamics, Ty1 elements were reintroduced into a "Ty-less" Saccharomyces strain where elements had been lost by LTR-LTR recombination. Repopulated strains exhibited alterations in chromosome size that were associated with Ty1 insertions, but did not become genetically isolated. The rates of element gain and loss under genetic and environmental conditions known to affect Ty1 retrotransposition were determined using genetically tagged reference elements. The results show that Ty1 retrotransposition varies with copy number, temperature, and cell type. In contrast to retrotransposition, Ty1 loss by LTR-LTR recombination was more constant and not markedly influenced by copy number. Endogenous Ty1 cDNA was poorly utilized for recombination when compared with LTR-LTR recombination or ectopic gene conversion. Ty1 elements also appear to be more susceptible to copy number fluctuation in haploid cells. Ty1 gain/loss ratios obtained under different conditions suggest that copy number oscillates over time by altering the rate of retrotransposition, resulting in the diverse copy numbers observed in Saccharomyces.