DNA repeat rearrangements mediated by DnaK-dependent replication fork repair

Microarray-based STR genotyping using RecA-mediated ligation

We describe a novel assay capable of accurately determining the length of short tandem repeat (STR) alleles. STR genotyping is achieved utilizing RecA-mediated ligation (RML), which combines the high fidelity of RecA-mediated homology searching with allele-specific ligation. RecA catalyzes the pairing of synthetic oligonucleotides with one strand of a double-stranded DNA target, in this case a PCR amplicon. Ligation occurs only when two adjacent oligonucleotides are base paired to the STR region without any overlap or gap. RecA activity is required to overcome the inherent difficulty of annealing repeated sequences in register. This assay is capable of determining STR genotypes of human samples, is easily adapted to high throughput or automated systems and can have widespread utility in diagnostic and forensic applications.

Homologous recombination restarts blocked replication forks at the expense of genome rearrangements by template exchange

Template switching induced by stalled replication forks has recently been proposed to underlie complex genomic rearrangements. However, the resulting models are not supported by robust physical evidence. Here, we analyzed replication and recombination intermediates in a well-defined fission yeast system that blocks replication forks. We show that, in response to fork arrest, chromosomal rearrangements result from Rad52-dependent nascent strand template exchange occurring during fork restart. This template exchange occurs by both Rad51-dependent and -independent mechanisms. We demonstrate that Rqh1, the BLM homolog, limits Rad51-dependent template exchange without affecting fork restart. In contrast, we report that the Srs2 helicase promotes both fork restart and template exchange. Our data demonstrate that template exchange occurs during recombination-dependent fork restart at the expense of genome rearrangements.

Post-replication repair suppresses duplication-mediated genome instability

RAD6 is known to suppress duplication-mediated gross chromosomal rearrangements (GCRs) but not single-copy sequence mediated GCRs. Here, we found that the RAD6- and RAD18-dependent post-replication repair (PRR) and the RAD5-, MMS2-, UBC13-dependent error-free PRR branch acted in concert with the replication stress checkpoint to suppress duplication-mediated GCRs formed by homologous recombination (HR). The Rad5 helicase activity, but not its RING finger, was required to prevent duplication-mediated GCRs, although the function of Rad5 remained dependent upon modification of PCNA at Lys164. The SRS2, SGS1, and HCS1 encoded helicases appeared to interact with Rad5, and epistasis analysis suggested that Srs2 and Hcs1 act upstream of Rad5. In contrast, Sgs1 likely functions downstream of Rad5, potentially by resolving DNA structures formed by Rad5. Our analysis is consistent with models in which PRR prevents replication damage from becoming double strand breaks (DSBs) and/or regulates the activity of HR on DSBs.

Genome instability is a hallmark of many cancers and underlies many inherited disorders that cause a predisposition to cancer. The human genome has many different types of duplicated sequences that can lead to genome instability by recombination-mediated pathways. We previously discovered that duplication-mediated chromosomal rearrangements are suppressed by a number of pathways. Some of these pathways were specific to rearrangements between genomic duplications. Here, we have performed a detailed analysis of pathways dependent upon RAD6, and have discovered that the error-free branch of post-replication repair (PRR) either is as an alternative to homologous recombination or prevents the generation of homologous recombination intermediates. Both of these functions could lead to genomic instability in the context of genomes containing substantial amounts of duplications. The extreme sensitivity of our assay to post-replication repair defects reveals substantial complexity in the interaction of PRR defects, suggesting the presence of many alternative PRR pathways. Together, the results emphasize the importance for appropriately balancing different repair pathways to maintain global genomic stability and highlight a number of defects that could underlie genome instabilities in some cancers.

The importance of XRCC2 in RAD51-related DNA damage repair

The repair of DNA damage by homologous recombination (HR) is a key pathway for the maintenance of genetic stability in mammalian cells, especially during and following DNA replication. The central HR protein is RAD51, which ensures high fidelity DNA repair by facilitating strand exchange between damaged and undamaged homologous DNA segments. Several RAD51-like proteins, including XRCC2, appear to help with this process, but their roles are not well understood. Here we show that XRCC2 is highly conserved and that most substantial truncations of the protein destroy its ability to function. XRCC2 and its partner protein RAD51L3 are found to interact with RAD51 in the 2-hybrid system, and XRCC2 is shown to be important but not essential for the accumulation of RAD51 at the sites of DNA damage. We visualize the localization of XRCC2 protein at the same sites of DNA damage for the first time using specialized irradiation conditions. Our data indicate that an important function of XRCC2 is to enhance the activity of RAD51, so that the loss of XRCC2 results in a severe delay in the early response of RAD51 to DNA damage.

Maintaining genome stability at the replication fork

Aberrant DNA replication is a major source of the mutations and chromosome rearrangements that are associated with pathological disorders. When replication is compromised, DNA becomes more prone to breakage. Secondary structures, highly transcribed DNA sequences and damaged DNA stall replication forks, which then require checkpoint factors and specialized enzymatic activities for their stabilization and subsequent advance. These mechanisms ensure that the local DNA damage response, which enables replication fork progression and DNA repair in S phase, is coupled with cell cycle transitions. The mechanisms that operate in eukaryotic cells to promote replication fork integrity and coordinate replication with other aspects of chromosome maintenance are becoming clear.

The FANCM family of DNA helicases/translocases

FANCM and its relatives, Hef, Mph1 and Fml1, are DNA junction-specific helicases/translocases that target and process perturbed replication forks and intermediates of homologous recombination. They have variously been implicated in promoting the activation of the S-phase checkpoint, recruitment of the Fanconi Anemia Core Complex to sites of DNA damage, crossover avoidance during DNA double-strand break repair by homologous recombination, and the replicative bypass of DNA lesions by template switching. This review summarises our current understanding of the biochemical activities and biological functions of the FANCM family.

Fusion of nearby inverted repeats by a replication-based mechanism leads to formation of dicentric and acentric chromosomes that cause genome instability in budding yeast

Large-scale changes (gross chromosomal rearrangements [GCRs]) are common in genomes, and are often associated with pathological disorders. We report here that a specific pair of nearby inverted repeats in budding yeast fuse to form a dicentric chromosome intermediate, which then rearranges to form a translocation and other GCRs. We next show that fusion of nearby inverted repeats is general; we found that many nearby inverted repeats that are present in the yeast genome also fuse, as does a pair of synthetically constructed inverted repeats. Fusion occurs between inverted repeats that are separated by several kilobases of DNA and share >20 base pairs of homology. Finally, we show that fusion of inverted repeats, surprisingly, does not require genes involved in double-strand break (DSB) repair or genes involved in other repeat recombination events. We therefore propose that fusion may occur by a DSB-independent, DNA replication-based mechanism (which we term "faulty template switching"). Fusion of nearby inverted repeats to form dicentrics may be a major cause of instability in yeast and in other organisms.

Large-scale expansions of Friedreich's ataxia GAA repeats in yeast

Large-scale expansions of DNA repeats are implicated in numerous hereditary disorders in humans. We describe a yeast experimental system to analyze large-scale expansions of triplet GAA repeats responsible for the human disease Friedreich's ataxia. When GAA repeats were placed into an intron of the chimeric URA3 gene, their expansions caused gene inactivation, which was detected on the selective media. We found that the rates of expansions of GAA repeats increased exponentially with their lengths. These rates were only mildly dependent on the repeat's orientation within the replicon, whereas the repeat-mediated replication fork stalling was exquisitely orientation dependent. Expansion rates were significantly elevated upon inactivation of the replication fork stabilizers, Tof1 and Csm3, but decreased in the knockouts of postreplication DNA repair proteins, Rad6 and Rad5, and the DNA helicase Sgs1. We propose a model for large-scale repeat expansions based on template switching during replication fork progression through repetitive DNA.

The Saccharomyces cerevisiae Esc2 and Smc5-6 proteins promote sister chromatid junction-mediated intra-S repair

Recombination is important for DNA repair, but it can also contribute to genome rearrangements. RecQ helicases, including yeast Sgs1 and human BLM, safeguard genome integrity through their functions in DNA recombination. Sgs1 prevents the accumulation of Rad51-dependent sister chromatid junctions at damaged replication forks, and its functionality seems to be regulated by Ubc9- and Mms21-dependent sumoylation. We show that mutations in Smc5-6 and Esc2 also lead to an accumulation of recombinogenic structures at damaged replication forks. Because Smc5-6 is sumoylated in an Mms21-dependent manner, this finding suggests that Smc5-6 may be a crucial target of Mms21 implicated in this process. Our data reveal that Smc5-6 and Esc2 are required to tolerate DNA damage and that their functionality is critical in genotoxic conditions in the absence of Sgs1. As reported previously for Sgs1 and Smc5-6, we find that Esc2 physically interacts with Ubc9 and SUMO. This interaction is correlated with the ability of Esc2 to promote DNA damage tolerance. Collectively, these data suggest that Esc2 and Smc5-6 act in concert with Sgs1 to prevent the accumulation of recombinogenic structures at damaged replication forks, likely by integrating sumoylation activities to regulate the repair pathways in response to damaged DNA.

SRS2 and SGS1 prevent chromosomal breaks and stabilize triplet repeats by restraining recombination

Several molecular mechanisms have been proposed to explain trinucleotide repeat expansions. Here we show that in yeast srs2Delta cells, CTG repeats undergo both expansions and contractions, and they show increased chromosomal fragility. Deletion of RAD52 or RAD51 suppresses these phenotypes, suggesting that recombination triggers trinucleotide repeat instability in srs2Delta cells. In sgs1Delta cells, CTG repeats undergo contractions and increased fragility by a mechanism partially dependent on RAD52 and RAD51. Analysis of replication intermediates revealed abundant joint molecules at the CTG repeats during S phase. These molecules migrate similarly to reversed replication forks, and their presence is dependent on SRS2 and SGS1 but not RAD51. Our results suggest that Srs2 promotes fork reversal in repetitive sequences, preventing repeat instability and fragility. In the absence of Srs2 or Sgs1, DNA damage accumulates and is processed by homologous recombination, triggering repeat rearrangements.

A DNA damage response in Escherichia coli involving the alternative sigma factor, RpoS

We isolated an Escherichia coli mutant in the iraD gene, sensitive to various forms of DNA damage. Our data are consistent with the function of IraD to promote accumulation of the alternative transcription sigma factor, RpoS, by binding to the adaptor RssB protein that targets RpoS for degradation. Our results demonstrate the physiological importance of this mode of regulation for DNA damage tolerance. Although RpoS is best known for its regulation of genes induced in stationary phase, our work underscores the importance of the RpoS regulon in a DNA damage response in actively growing cells. We show that iraD transcription is induced by DNA damage by a mechanism independent of the SOS response. The IraD and SOS regulatory pathways appear to act synergistically to ensure survival of cells faced with oxidative or DNA damaging stress during cellular growth.

SUMOylation regulates Rad18-mediated template switch

Replication by template switch is thought to mediate DNA damage-bypass and fillings of gaps. Gap-filling repair requires homologous recombination as well as Rad18- and Rad5-mediated proliferating cell nuclear antigen (PCNA) polyubiquitylation. However, it is unclear whether these processes are coordinated, and the physical evidence for Rad18-Rad5-dependent template switch at replication forks is still elusive. Here we show, using genetic and physical approaches, that in budding yeast (Saccharomyces cerevisiae) Rad18 is required for the formation of X-shaped sister chromatid junctions (SCJs) at damaged replication forks through a process involving PCNA polyubiquitylation and the ubiquitin-conjugating enzymes Mms2 and Ubc13. The Rad18-Mms2-mediated damage-bypass through SCJs requires the small ubiquitin-like modifier (SUMO)-conjugating enzyme Ubc9 and SUMOylated PCNA, and is coordinated with Rad51-dependent recombination events. We propose that the Rad18-Rad5-Mms2-dependent SCJs represent template switch events. Altogether, our results unmask a role for PCNA ubiquitylation and SUMOylation pathways in promoting transient damage-induced replication-coupled recombination events involving sister chromatids at replication forks.

Chaperones in control of protein disaggregation

The chaperone protein network controls both initial protein folding and subsequent maintenance of proteins in the cell. Although the native structure of a protein is principally encoded in its amino-acid sequence, the process of folding in vivo very often requires the assistance of molecular chaperones. Chaperones also play a role in a post-translational quality control system and thus are required to maintain the proper conformation of proteins under changing environmental conditions. Many factors leading to unfolding and misfolding of proteins eventually result in protein aggregation. Stress imposed by high temperature was one of the first aggregation-inducing factors studied and remains one of the main models in this field. With massive protein aggregation occurring in response to heat exposure, the cell needs chaperones to control and counteract the aggregation process. Elimination of aggregates can be achieved by solubilization of aggregates and either refolding of the liberated polypeptides or their proteolysis. Here, we focus on the molecular mechanisms by which heat-shock protein 70 (Hsp70), Hsp100 and small Hsp chaperones liberate and refold polypeptides trapped in protein aggregates.

The SOS Regulatory Network

All organisms possess a diverse set of genetic programs that are used to alter cellular physiology in response to environmental cues. The gram-negative bacterium, Escherichia coli, mounts what is known as the "SOS response" following DNA damage, replication fork arrest, and a myriad of other environmental stresses. For over 50 years, E. coli has served as the paradigm for our understanding of the transcriptional, and physiological changes that occur following DNA damage (400). In this chapter, we summarize the current view of the SOS response and discuss how this genetic circuit is regulated. In addition to examining the E. coli SOS response, we also include a discussion of the SOS regulatory networks in other bacteria to provide a broader perspective on how prokaryotes respond to DNA damage.

Template switching: from replication fork repair to genome rearrangements

Genome rearrangements are a hallmark of human genomic disorders and occur largely through recombination mechanisms. In this issue, Lee et al. (2007) show that the complex nonrecurrent rearrangements observed in the dysmyelinating disorder Pelizaeus-Merzbacher disease (PMD) are likely to be caused by a replication mechanism involving template switching.

The Hsp70 chaperone machines of Escherichia coli: a paradigm for the repartition of chaperone functions

Molecular chaperones are highly conserved in all free-living organisms. There are many types of chaperones, and most are conveniently grouped into families. Genome sequencing has revealed that many organisms contain multiple members of both the DnaK (Hsp70) family and their partner J-domain protein (JDP) cochaperone, belonging to the DnaJ (Hsp40) family. Escherichia coli K-12 encodes three Hsp70 genes and six JDP genes. The coexistence of these chaperones in the same cytosol suggests that certain chaperone-cochaperone interactions are permitted, and that chaperone tasks and their regulation have become specialized over the course of evolution. Extensive genetic and biochemical analyses have greatly expanded knowledge of chaperone tasking in this organism. In particular, recent advances in structure determination have led to significant insights of the underlying complexities and functional elegance of the Hsp70 chaperone machine.

Polymerase switching in DNA replication

Our view of DNA replication has been of two coupled DNA polymerases anchored to the replication fork helicase in a "replisome" complex, synthesizing leading and lagging strands simultaneously. New evidence suggests that three DNA polymerases can be accommodated into the replisome and that polymerases and repair factors are dynamically recruited and engaged without dismantling of the replisome.

Microarray analysis of Mu transposition in Salmonella enterica, serovar Typhimurium: transposon exclusion by high-density DNA binding proteins

All organisms contain transposons with the potential to disrupt and rearrange genes. Despite the presence of these destabilizing sequences, some genomes show remarkable stability over evolutionary time. Do bacteria defend the genome against disruption by transposons? Phage Mu replicates by transposition and virtually all genes are potential insertion targets. To test whether bacteria limit Mu transposition to specific parts of the chromosome, DNA arrays of Salmonella enterica were used to quantitatively measure target site preference and compare the data with Escherichia coli. Essential genes were as susceptible to transposon disruption as non-essential ones in both organisms, but the correlation of transposition hot spots among homologous genes was poor. Genes in highly transcribed operons were insulated from transposon mutagenesis in both organisms. A 10 kb cold spot on the pSLT plasmid was near parS, a site to which the ParB protein binds and spreads along DNA. Deleting ParB erased the plasmid cold spot, and an ectopic parS site placed in the Salmonella chromosome created a new cold spot in the presence of ParB. Our data show that competition between cellular proteins and transposition proteins on plasmids and the chromosome is a dominant factor controlling the genetic footprint of transposons in living cells.

Replication fork stalling at natural impediments

Accurate and complete replication of the genome in every cell division is a prerequisite of genomic stability. Thus, both prokaryotic and eukaryotic replication forks are extremely precise and robust molecular machines that have evolved to be up to the task. However, it has recently become clear that the replication fork is more of a hurdler than a runner: it must overcome various obstacles present on its way. Such obstacles can be called natural impediments to DNA replication, as opposed to external and genetic factors. Natural impediments to DNA replication are particular DNA binding proteins, unusual secondary structures in DNA, and transcription complexes that occasionally (in eukaryotes) or constantly (in prokaryotes) operate on replicating templates. This review describes the mechanisms and consequences of replication stalling at various natural impediments, with an emphasis on the role of replication stalling in genomic instability.

Chromosome segregation control by Escherichia coli ObgE GTPase

Escherichia coli cells depleted of the conserved GTPase, ObgE, show early chromosome-partitioning defects and accumulate replicated chromosomes in which the terminus regions are colocalized. Cells lacking ObgE continue to initiate replication, with a normal ratio of the origin to terminus. Localization of the SeqA DNA binding protein, normally seen as punctate foci, however, was disturbed. Depletion of ObgE also results in cell filamentation, with polyploid DNA content. Depletion of ObgE did not cause lethality, and cells recovered fully after expression of ObgE was restored. We propose a model in which ObgE is required to license chromosome segregation and subsequent cell cycle events.

Sister chromatid junctions in the hyperthermophilic archaeon Sulfolobus solfataricus

Although the Archaea exhibit an intriguing combination of bacterial- and eukaryotic-like features, it is not known how these prokaryotic cells segregate their chromosomes before the process of cell division. In the course of our analysis of the third replication origin in the archaeon Sulfolobus solfataricus, we identify and characterise sister chromatid junctions in this prokaryote. This pairing appears to be mediated by hemicatenane-like structures, and we provide evidence that these junctions persist in both replicating and postreplicative cells. These data, in conjunction with fluorescent in situ hybridisation analyses, suggest that Sulfolobus chromosomes have a significant period of postreplicative sister chromatid synapsis, a situation that is more reminiscent of eukaryotic than bacterial chromosome segregation mechanisms.

RecA-independent recombination is efficient but limited by exonucleases

Genetic recombination in bacteria is facilitated by the RecA strand transfer protein and strongly depends on the homology between interacting sequences. RecA-independent recombination is detectable but occurs at extremely low frequencies and is less responsive to the extent of homology. In this article, we show that RecA-independent recombination in Escherichia coli is depressed by the redundant action of single-strand exonucleases. In the absence of multiple single-strand exonucleases, the efficiency of RecA-independent recombination events, involving either gene conversion or crossing-over, is markedly increased to levels rivaling RecA-dependent events. This finding suggests that RecA-independent recombination is not intrinsically inefficient but is limited by single-strand DNA substrate availability. Crossing-over is inhibited by exonucleases ExoI, ExoVII, ExoX, and RecJ, whereas only ExoI and RecJ abort gene-conversion events. In ExoI(-) RecJ(-) strains, gene conversion can be accomplished by transformation of short single-strand DNA oligonucleotides and is more efficient when the oligonucleotide is complementary to the lagging-strand replication template. We propose that E. coli encodes an unknown mechanism for RecA-independent recombination (independent of prophage recombination systems) that is targeted to replication forks. The potential of RecA-independent recombination to mediate exchange at short homologies suggests that it may contribute significantly to genomic change in bacteria, especially in species with reduced cellular exonuclease activity or those that encode DNA protection factors.

Replisome assembly and the direct restart of stalled replication forks

Failure to reactivate either stalled or collapsed replication forks is a source of genomic instability in both prokaryotes and eukaryotes. In prokaryotes, dedicated fork repair systems that involve both recombination and replication proteins have been identified genetically and characterized biochemically. Replication conflicts are solved through several pathways, some of which require recombination and some of which operate directly at the stalled fork. Some recent biochemical observations support models of direct fork repair in which the removal of the blocking template lesion is not always required for replication restart.

Postreplication repair inhibits CAG.CTG repeat expansions in Saccharomyces cerevisiae

Trinucleotide repeats (TNRs) are unique DNA microsatellites that can expand to cause human disease. Recently, Srs2 was identified as a protein that inhibits TNR expansions in Saccharomyces cerevisiae. Here, we demonstrate that Srs2 inhibits CAG . CTG expansions in conjunction with the error-free branch of postreplication repair (PRR). Like srs2 mutants, expansions are elevated in rad18 and rad5 mutants, as well as the PRR-specific PCNA alleles pol30-K164R and pol30-K127/164R. Epistasis analysis indicates that Srs2 acts upstream of these PRR proteins. Also, like srs2 mutants, the pol30-K127/164R phenotype is specific for expansions, as this allele does not alter mutation rates at dinucleotide repeats, at nonrepeating sequences, or for CAG . CTG repeat contractions. Our results suggest that Srs2 action and PRR processing inhibit TNR expansions. We also investigated the relationship between PRR and Rad27 (Fen1), a well-established inhibitor of TNR expansions that acts at 5' flaps. Our results indicate that PRR protects against expansions arising from the 3' terminus, presumably replication slippage events. This work provides the first evidence that CAG . CTG expansions can occur by 3' slippage, and our results help define PRR as a key cellular mechanism that protects against expansions.

Replication arrest-stimulated recombination: Dependence on the RecA paralog, RadA/Sms and translesion polymerase, DinB

Difficulties in replication can lead to breakage of the fork. Recombinational reactions restore the integrity of the fork through strand-invasion of the broken chromosome with its sister. If this occurs in the context of repeated DNA sequences, genetic rearrangements can result. We have proposed that this process accounts for stimulation of chromosomal rearrangements by mutations in Escherichia coli's replicative DNA helicase, DnaB. At its permissive temperature for growth, a dnaB107 mutant is a 1000-fold more likely to experience a deletion of a 787bp tandem repeated segment inserted in the E. coli chromosome than is a wild-type strain. We have previously shown that enhanced deletion in a dnaB107 strain is reduced in recA, recB and recG102 (formerly known as radC102) derivatives. Here I show that this enhanced recombination is dependent on other factors: the RuvA Holliday junction helicase, the RecJ single-strand DNA exonuclease, the RadA/Sms RecA-paralog protein of unknown function and, surprisingly, the DinB translesion polymerase. The requirement for these factors in DnaB-stimulated rearrangements is much greater than that observed for recombinational events such as P1 transduction. This may be because strand invasion into the repeats limits the extent of heteroduplex DNA that can be formed in the initial stage of recombination. I propose that RadA, RecG and RuvAB are critically required to stabilize the strand-invasion intermediate and that DinB polymerase extends the invading 3' strand to aid in re-initiation. The role of DinB in bacteria may be analogous to translesion DNA polymerase eta in eukaryotes, recently shown to aid recombination.

One-step purification of bacterially expressed recombinant transducin alpha-subunit and isotopically labeled PDE6 gamma-subunit for NMR analysis

Interactions between the transducin alpha-subunit (Galpha(t)) and the cGMP phosphodiesterase gamma-subunit (PDEgamma) are critical not only for turn-on but also turn-off of vertebrate visual signal transduction. Elucidation of the signaling mechanisms dominated by these interactions has been restrained by the lack of atomic structures for full-length Galpha(t)/PDEgamma complexes, in particular, the signaling-state complex represented by Galpha(t).GTPgammaS/PDEgamma. As a preliminary step in our effort for NMR structural analysis of Galpha(t)/PDEgamma interactions, we have developed efficient protocols for the large-scale production of recombinant Galpha(t) (rGalpha(t)) and homogeneous and functional isotopically labeled PDEgamma from Escherichia coli cells. One-step purification of rGalpha(t) was achieved through cobalt affinity chromatography in the presence of glycerol, which effectively removed the molecular chaperone DnaK that otherwise persistently co-purified with rGalpha(t). The purified rGalpha(t) was found to be functional in GTPgammaS/GDP exchange upon activation of rhodopsin and was used to form a signaling-state complex with labeled PDEgamma, rGalpha(t). GTPgammaS/[U-13C,15N]PDEgamma. The labeled PDEgamma sample yielded a well-resolved 1H-15N HSQC spectrum. The methods described here for large-scale production of homogeneous and functional rGalpha(t) and isotope-labeled PDEgamma should support further NMR structural analysis of the rGalpha(t)/PDEgamma complexes. In addition, our protocol for removing the co-purifying DnaK contaminant may be of general utility in purifying E. coli-expressed recombinant proteins.