Activation of a system for the joining of nonhomologous DNA ends during Xenopus egg maturation.

Mature Xenopus laevis eggs provide an elementary reaction system of illegitimate recombination which efficiently joins nonhomologous DNA ends (P. Pfeiffer and W. Vielmetter, Nucleic Acids Res. 16:907-924, 1988). Here we show that stage VI oocytes, known to express a system for homologous recombination (D. Carroll, Proc. Natl. Acad. Sci. USA 80:6902-6906, 1983), are completely devoid of this joining system. Nonhomologous DNA end-to-end joining, however, attains full activity only at an extremely late stage of egg maturation. Cycloheximide inhibition patterns indicate that nonhomologous joining activity is regulated at the G2 restriction point of the cell cycle. Implications of homologous and nonhomologous recombination activities during egg maturation are discussed.     

Homologous and nonhomologous recombination in monkey cells.

Though recombinational events are important for the proper functioning of most cells, little is known about the frequency and mechanisms of recombination in mammalian cells. We have used simian virus 40 (SV40)-pBR322 hybrid plasmids constructed in vitro as substrates to detect and quantitate intramolecular homologous and nonhomologous recombination events in cultured monkey cells. Excision of wild-type or defective SV40 DNAs by recombination from these plasmids was scored by the viral plaque assay, in either the absence or the presence of DNA from a temperature-sensitive helper virus. Several independent products of homologous and nonhomologous recombination have been isolated and characterized at the DNA sequence level. We find that neither DNA replication of the recombination substrate nor SV40 large T antigen is essential for either homologous or nonhomologous recombination involving viral or pBR322 sequences.     

Common sites for recombination and cleavage mediated by bacteriophage T4 DNA topoisomerase in vitro

We have previously shown that purified T4 DNA topoisomerase promotes illegitimate recombination between two lambda DNA molecules, or between lambda and plasmid DNA in vitro (Ikeda, H. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 922-926). Since the recombinant DNA contains a duplication or deletion, it is inferred that the cross-overs take place between nonhomologous sequences of lambda DNA. In this paper, we have examined the sequences of the recombination junctions produced by the recombination between two lambda DNA molecules mediated by T4 DNA topoisomerase. We have shown that there is either no homology or there are 1-5-base pair homologies between the parental DNAs in seven combinations of lambda recombination sites, indicating that homology is not essential for the recombination. Next, we have shown an association of the recombination sites with the topoisomerase cleavage sites, indicating that a capacity of the topoisomerase to make a transient double-stranded break in DNA plays a role in the illegitimate recombination. A consensus sequence for T4 topoisomerase cleavage sites, RNAY decreases NNNNRTNY, was deduced. The cleavage experiment showed that T4 topoisomerase-mediated cleavage takes place in a 4-base pair staggered fashion and produces 5'-protruding ends.     

Covalently closed circular viral DNA formed from two types of linear DNA in woodchuck hepatitis virus-infected liver.

We found that livers from woodchucks chronically infected with woodchuck hepatitis virus (WHV) contained covalently closed circular DNA (cccDNA) molecules with deletions and insertions indicative of their formation from linear viral DNA by nonhomologous recombination, as we previously described for the duck hepatitis B virus (W. Yang and J. Summers, J. Virol. 69:4029-4036, 1995). However, evidence for two different types of linear precursors was obtained by analysis of the recombination joints in WHV cccDNA. Type 1 linear precursors possessed the structural properties that correspond to those of in situ-primed linear DNA molecules, which constitute between 7 and 20% of all viral DNA replicative intermediates synthesized in the liver. Type 2 linear precursors are hypothetical species of linear DNAs with a terminal duplication of the cohesive-end region, between DR1 and DR2. This type of linear DNA has not been previously described and was not detected among the DNA species present in nucleocapsids. A fraction of cccDNAs formed from both type 1 and type 2 linear DNAs are predicted to be functional for further DNA synthesis, and some evidence for the formation of two or more generations of cccDNA from linear DNA was observed.     

Structural analyses of DNA fragments integrated by illegitimate recombination in Schizosaccharomyces pombe

In order to elucidate the mechanisms of illegitimate recombination in eukaryotes, we have studied the structure of DNA fragments integrated by illegitimate recombination into the genome of fission yeast. Nonhomologous recombination was rarely identified when a long region of homology with the chromosomal leu1 ⁺ gene was present in the introduced leu1::ura4 ⁺ DNA fragment; but a decrease in length of homology leads to an increase in the ratio of nonhomologous to homologous recombination events. The introduced DNA fragments were integrated into different sites in the chromosomes by nonhomologous recombination. The results suggested that there are multiple modes of integration; most events simply involve both ends of the fragments, while in other cases, fragments were integrated in a more complicated manner, probably via circularization or multimerization. To analyze the mechanism of the major type of integration, DNA fragments containing the recombination junctions of three recombinants were amplified by inverted polymerase chain reaction (IPCR) and their nucleotide sequences were determined. There was no obvious homology between introduced DNA and chromosomal DNA at these recombination sites. Furthermore it was found that each terminal region of the introduced DNA was deleted, but that there were no or very small deletions in the target sites of chromosomal DNA. Two models are proposed to explain the mechanism of nonhomologous integration.     

A new type of illegitimate recombination is dependent on restriction and homologous interaction.

Illegitimate (nonhomologous) recombination requires little or no sequence homology between recombining DNAs and has been regarded as being a process distinct from homologous recombination, which requires a long stretch of homology between recombining DNAs. Under special conditions in Escherichia coli, we have found a new type of illegitimate recombination that requires an interaction between homologous DNA sequences. It was detected when a plasmid that carried 2-kb-long inverted repeats was subjected to type II restriction in vitro and type I (EcoKI) restriction in vivo within a delta rac recBC recG ruvC strain. Removal of one of the repeats or its replacement with heterologous DNA resulted in a reduction in the level of recombination. The recombining sites themselves shared, at most, a few base pairs of homology. Many of the recombination events joined a site in one of the repeats with a site in another repeat. In two of the products, one of the recombining sites was at the end of one of the repeats. Removal of one of the EcoKI sites resulted in decreased recombination. We discuss the possibility that some structure made by homologous interaction between the long repeats is used by the EcoKI restriction enzyme to promote illegitimate recombination. The possible roles and consequences of this type of homologous interaction are discussed.     

Nonhomologous DNA end joining in Schizosaccharomyces pombe efficiently eliminates DNA double-strand-breaks from haploid sequences.

Cells of higher eucaryotes are known to possess mechanisms of illegitimate recombination which promote the joining between nonhomologous ends of broken DNA and thus may serve as basic tools of double-strand-break (DSB) repair. Here we show that cells of the fission yeast Schizosaccharomyces pombe also contain activities of nonhomologous DNA end joining resembling the ones found in higher eucaryotes. Nonhomologous end joining activities were detected by transformation of linearized self-replicating plasmids in yeast cells employing a selection procedure which only propagates transformants carrying recircularized plasmid molecules. Linear plasmid substrates were generated by duplicate restriction cuts carrying either blunt ends or 3' or 5' protruding single strands (PSS) of 4 nt which were efficiently joined in any tested combination. Sequence analysis of joined products revealed that junctional sequences were shortened by 1 to 14 nt. Two mechanisms may account for junction formation (i) loss of terminal nucleotides from PSS tails to produce blunt ends which can be joined to abutting ends and (ii) interactions of DNA termini at patches of sequence homologies (1-4 bp) by formation of overlap intermediates which are subsequently processed. A general feature of the yeast joining system is that end joining can only be detected in the absence of sequence homology between the linear substrate and host genome. In the presence of homology, nonhomologous DNA end joining is efficiently competed by activities of homologous recombination.     

Illegitimate recombination in Xenopus: characterization of end-joined junctions.

When linear DNAs are injected into Xenopus laevis eggs, they are converted into several different kinds of recombination products. Some molecules undergo homologous recombination by a resection-annealing mechanism; some ends are precisely ligated; and some ends are joined by illegitimate means. The homologous and illegitimate products are also generated in nuclear extracts from stage VI Xenopus oocytes. In order to gain insight into the mechanism(s) of illegitimate end joining, we amplified, cloned and sequenced a number of junctions from eggs and from oocyte extracts. The egg junctions fell into three categories: some with no homology at the join point that may have been produced by blunt-end ligation; some based on small, but significant homologies (5-10 bp); and some with matches of only 1 or 2 nucleotides at the joint. Junctions made in oocyte extracts were largely of the latter type. In the extracts, formation of illegitimate joints required the addition of all four deoxyribonucleoside triphosphates and was inhibited by aphidicolin. This indicates that this process involves DNA synthesis, and mechanisms incorporating this feature are considered. The spectrum of recombination products formed in Xenopus eggs is very reminiscent of those produced from DNA introduced into mammalian cells.     

Cloned single- and double-stranded DNA copies of potato spindle tuber viroid (PSTV) RNA and co-inoculated subgenomic DNA fragments are infectious

A set of monomeric and oligomeric potato spindle tuber viroid (PSTV) specific DNA forms representing complete DNA copies of the circular PSTV RNA genome were constructed and cloned in plasmid pBR322 and bacteriophage M13. Both single- and double-stranded PSTV DNAs are capable of initiating viroid replication in mechanically inoculated tomato plants where it normally proceeds via the RNA-RNA pathway without DNA being involved. All dimeric and higher multimeric forms were infectious irrespective of their polarity in the case of single-stranded DNA and regardless of their orientation in the vector DNA in the case of double-stranded DNA. The vector-inserted monomeric PSTV DNA units were also found to be infectious but of low specific infectivity which was increased when these monomers had been excised. Even two subgenomic DNA fragments, representing together the 359 nucleotides of the PSTV RNA genome, initiated the synthesis of viroid RNA progeny when co-inoculated although each fragment by itself is non-infectious. These results are discussed with respect to the infectivity previously observed with certain cloned DNAs of conventional RNA and DNA viruses.     

Topoisomerase I involvement in illegitimate recombination in Saccharomyces cerevisiae.

Chromosome aberrations may cause cancer and many heritable diseases. Topoisomerase I has been suspected of causing chromosome aberrations by mediating illegitimate recombination. The effects of deletion and of overexpression of the topoisomerase I gene on illegitimate recombination in the yeast Saccharomyces cerevisiae have been studied. Yeast transformations were carried out with DNA fragments that did not have any homology to the genomic DNA. The frequency of illegitimate integration was 6- to 12-fold increased in a strain overexpressing topoisomerase I compared with that in isogenic control strains. Hot spot sequences [(G/C)(A/T)T] for illegitimate integration target sites accounted for the majority of the additional events after overexpression of topoisomerase I. These hot spot sequences correspond to sequences previously identified in vitro as topoisomerase I preferred cleavage sequences in other organisms. Furthermore, such hot spot sequences were found in 44% of the integration events present in the TOP1 wild-type strain and at a significantly lower frequency in the top1delta strain. Our results provide in vivo evidence that a general eukaryotic topoisomerase I enzyme nicks DNA and ligates nonhomologous ends, leading to illegitimate recombination.     

Efficient homologous recombination of linear DNA substrates after injection into Xenopus laevis oocytes.

When DNA molecules are injected into Xenopus oocyte nuclei, they can recombine with each other. With bacteriophage lambda DNAs, it was shown that this recombination is stimulated greatly by introduction of double-strand breaks into the substrates and is dependent on homologous overlaps in the recombination interval. With plasmid DNAs it was shown that little or no recombination occurs between circular molecules but both intra- and intermolecular events take place very efficiently with linear molecules. As with the lambda substrates, homology was required to support recombination; no simple joining of ends was observed. Blockage of DNA ends with nonhomologous sequences interfered with recombination, indicating that ends are used directly to initiate homologous interactions. These observations are combined to evaluate possible models of recombination in the oocytes. Because each oocyte is capable of recombining nanogram quantities of linear DNA, this system offers exceptional opportunities for detailed molecular analysis of the recombination process in a higher organism.     

Quantitation of a simian virus 40 nonhomologous recombination pathway.

We describe an infectious-center in situ plaque hybridization procedure which quantitates simian virus 40 (SV40) nonhomologous recombination in terms of the number of recombinant-producing cells in the DNA transfected cell population. Using this assay to measure the efficiency of recombination with SV40 DNA in permissive monkey BSC-1 cells, we found that: (i) over a range of DNA concentrations, polyomavirus DNA (which is partially homologous to SV40 DNA) cannot be distinguished from nonhomologous phi X174 RF1 DNA with respect to its ability to recombine with SV40 DNA; (ii) at defined DNA concentrations, polyomavirus and phi X174 RF1 DNA compete with each other for recombination with SV40 DNA; (iii) virtually all segments of the phi X174 genome recombine, apparently at random, with SV40 DNA; (iv) the frequency of recombinant-producing cells, among the successfully transfected (virion-producing) cells, depends upon the input SV40 DNA concentration in the transfection solution; and (v) replication-defective SV40 mutant DNAs compete with wild-type SV40 DNA for recombination with phi X174 RF1 DNA. From these observations, we conclude that the efficiency of recombination with SV40, in the system under study, is unaffected by nucleotide sequence homology and that a limiting stage in the recombination pathway occurs before SV40 DNA replication. Comparison of the dependency of recombination on initial SV40 DNA concentration with the dependency on initial phi X174 RF1 DNA concentration indicates that SV40 DNA sequences are a controlling factor in the nonhomologous recombination pathway.     

Detection of template strand switching during initiation and termination of DNA replication of porcine circovirus

Nucleotide substitution mutagenesis was conducted to investigate the importance of the inverted repeats (palindrome) at the origin of DNA replication (Ori) of porcine circovirus type 1 (PCV1). Viral genomes with engineered mutations on either arm or both arms of the palindrome were not impaired in protein synthesis and yielded infectious progeny viruses with restored or new palindromes. Thus, a flanking palindrome at the Ori was not essential for initiation of DNA replication, but one was generated inevitably at termination. Among the 26 viruses recovered, 16 showed evidence of template strand switching, from minus-strand genome DNA to palindromic strand DNA, during biosynthesis of the Ori. Here I propose a novel rolling-circle "melting-pot" model for PCV1 DNA replication. In this model, the replicator Rep protein complex binds, destabilizes, and nicks the Ori sequence to initiate leading-strand DNA synthesis. All four strands of the destabilized inverted repeats exist in a "melted" configuration, and the minus-strand viral genome and a palindromic strand are available as templates, simultaneously, during initiation or termination of DNA replication. Inherent in this model is a "gene correction" or "terminal repeat correction" mechanism that can restore mutilated inverted-repeat sequences to a palindrome at the Ori of circular DNAs or at the termini of circularized linear DNAs. Potentially, the melted state of the inverted repeats increases the rate of noncomplementary or illegitimate nucleotide incorporation into the palindrome. Thus, this melting-pot model provides insight into the mechanisms of DNA replication, gene correction, and illegitimate recombination at the Ori of PCV1, and it may be applicable to the replication of other circular DNA molecules.     

Amplification of Hot DNA segments in Escherichia coli

In Escherichia coli, a replication fork blocking event at a DNA replication terminus (Ter) enhances homologous recombination at the nearby sister chromosomal region, converting the region into a recombination hotspot, Hot, site. Using a RNaseH negative (rnhA-) mutant, we identified eight kinds of Hot DNAs (HotA-H). Among these, enhanced recombination of three kinds of Hot DNAs (HotA-C) was dependent on fork blocking events at Ter sites. In the present study, we examined whether HotA DNAs are amplified when circular DNA (HotA plus a drug-resistance DNA) is inserted into the homologous region on the chromosome of a rnhA- mutant. The resulting HotA DNA transformants were analysed using pulsed-field gel electrophoresis, fluorescence in situ hybridization and DNA microarray technique. The following results were obtained: (i) HotA DNA is amplified by about 40-fold on average; (ii) whereas 90% of the cells contain about 6-10 copies of HotA DNA, the remaining 10% of cells have as many as several hundred HotA copies; and (iii) amplification is detected in all other Hot DNAs, among which HotB and HotG DNAs are amplified to the same level as HotA. Furthermore, HotL DNA, which is activated by blocking the clockwise oriC-starting replication fork at the artificially inserted TerL site in the fork-blocked strain with a rnhA+ background, is also amplified, but is not amplified in the non-blocked strain. From these data, we propose a model that can explain production of three distinct forms of Hot DNA molecules by the following three recombination pathways: (i) unequal intersister recombination; (ii) intrasister recombination, followed by rolling-circle replication; and (iii) intrasister recombination, producing circular DNA molecules.     

Type I restriction enzyme with RecA protein promotes illegitimate recombination

Illegitimate (non-homologous) recombination requires little or no sequence homology between recombining DNAs and has been regarded as being a process distinct from homologous recombination, which requires a long stretch of homology between recombining DNAs. However, we have found a type of illegitimate recombination that requires an interaction between long homologous DNA sequences. It was detected when a plasmid that carried 2-kb-long inverted repeats was subjected to type I (EcoKI) restriction in vivo within a special mutant strain of Escherichia coli. In the present work, we analyzed genetic requirements for this type of illegitimate recombination in well-defined genetic backgrounds. Our analysis demonstrated dependence on RecA function and on the presence of two EcoKI sites on the substrate DNA. These results are in harmony with a model in which EcoKI restriction enzyme attacks an intermediate of homologous recombination to divert it to illegitimate recombination.     

A novel pathway of DNA end-to-end joining

Repair mechanisms related to illegitimate recombination can join nonhomologous DNA ends that terminate as protruding single strands (PSS). Here we analyze in Xenopus egg extracts joining reactions between 3' PSS termini and various partner termini. In junctions, 3' PSS termini are preserved by fill-in DNA synthesis, although their 5' recessed ends cannot serve as a primer. Alternative priming from a partner terminus ligated to the 3' PSS end appears unlikely, because no single strand-specific DNA ligases are detectable. We show that fill-in of 3' PSS termini precedes ligation and can even be primed in the absence of any ligation. Therefore, priming requires precise alignment of terminus pairs by a novel mechanism. We postulate that this is achieved by unique DNA binding proteins that align ends in various types of joining reactions.     

Role of DnaB helicase in UV-induced illegitimate recombination in Escherichia coli

To study the involvement of DNA replication in UV-induced illegitimate recombination, we examined the effect of temperature-sensitive dnaB mutations on illegitimate recombination and found that the frequency of illegitimate recombination was reduced by an elongation-deficient mutation, dnaB14, but not by an initiation-deficient mutation, dnaB252. This result indicates that DNA replication is required for UV-induced illegitimate recombination. In addition, the dnaB14 mutation also affected spontaneous or UV-induced illegitimate recombination enhanced by the recQ mutation. Nucleotide sequence analyses of the recombination junctions showed that DnaB-mediated illegitimate recombination is short homology dependent. Previously, Michel et al. (B. Michel, S. Ehrlich, and M. Uzest, EMBO J. 16:430--438, 1997) showed that thermal treatment of the temperature-sensitive dnaB8 mutant induces double-stranded breaks, implying that induction of illegitimate recombination occurs. To explain the discrepancy between the observations, we propose a model for DnaB function, in which the dnaB mutations may exhibit two types of responses, early and late responses, for double-stranded break formation. In the early response, replication forks stall at damaged DNA, resulting in the formation of double-stranded breaks, and the dnaB14 mutation reduces the double-stranded breaks shortly after temperature shift-up. On the other hand, in the late response, the arrested replication forks mediated by the dnaB8 mutation may induce double-stranded breaks after prolonged incubation.     

Illegitimate Recombination Induced by Overproduction of DnaB Helicase in Escherichia coli

Illegitimate recombination that usually takes place at a low frequency is greatly enhanced by treatment with DNA-damaging agents. It is thought that DNA double-strand breaks induced by this DNA damage are important for initiation of illegitimate recombination. Here we show that illegitimate recombination is enhanced by overexpression of the DnaB protein in Escherichia coli. The recombination enhanced by DnaB overexpression occurred between short regions of homology. We propose a model for the initiation of illegitimate recombination in which DnaB overexpression may excessively unwind DNA at replication forks and induce double-strand breaks, resulting in illegitimate recombination. The defect in RecQ has a synergistic effect on the increased illegitimate recombination in cells containing the overproduced DnaB protein, implying that DnaB works in the same pathway as RecQ does but that they work at different steps.     

Processing of DNA prior to illegitimate recombination in mouse cells.

In mammalian cells, the predominant pathway of chromosomal integration of exogenous DNA is random or illegitimate recombination; integration by homologous recombination is infrequent. Homologous recombination is initiated at double-strand DNA breaks which have been acted on by single-strand exonuclease. To further characterize the relationship between illegitimate and homologous recombination, we have investigated whether illegitimate recombination is also preceded by exonuclease digestion. Heteroduplex DNAs which included strand-specific restriction markers at each of four positions were generated. These DNAs were introduced into mouse embryonic stem cells, and stably transformed clones were isolated and analyzed to determine whether there was any strand bias in the retention of restriction markers with respect to their positions. Some of the mismatches appear to have been resolved by mismatch repair. Very significant strand bias was observed in the retention of restriction markers, and there was polarity of marker retention between adjacent positions. We conclude that DNA is frequently subjected to 5'-->3' exonuclease digestion prior to integration by illegitimate recombination and that the length of DNA removed by exonuclease digestion can be extensive. We also provide evidence which suggests that frequent but less extensive 3'-->5' exonuclease processing also occurs.