Sgs1 helicase activity is required for mitotic but apparently not for meiotic functions

RMI1 is essential for maintaining rice genome stability at high temperature

Heat is a critical environmental stress for plant survival. One of its harmful effects on the cells is the disruption of genome integrity. However, the mechanisms by which plants cope with heat-induced DNA damage remain largely unknown. RMI1, a component of the RTR (RECQ4-TOP3α-RMI1) complex, plays a pivotal role in maintaining genome stability. In this study, we identified the target gene RMI1 by characterizing a high-temperature-sensitive mutant. The growth and development of rmi1-1 seedlings carrying a non-frameshift mutation in RMI1 were hindered at 38°C. Abnormal mitotic chromosome behaviours ultimately led to the cell death of root tips. Additionally, the presence of chromosome fragments during anaphase I caused pollen abortion and sterility in rmi1-1 plants. Yeast two-hybrid assays revealed that the interactions between RMI1-1 and RECQ4 or TOP3α were weakened with increasing temperature and entirely ceased at 36°C. In contrast, the functional RMI1 maintained its interactions with RECQ4 or TOP3α under the same conditions. These results indicate that the non-frameshift mutation in RMI1 disrupts the formation of the RTR complex at high temperatures, leading to defects in DNA repair and increased sensitivity of rmi1-1 under heat stress. However, embryos of the rmi1-cr2 mutant with a frameshift mutation in RMI1 exhibited complete lethality. In addition, the overexpression of RMI1 enhanced the heat tolerance in rice. These findings provide insights into the molecular mechanisms that RMI1 responds to high temperatures by maintaining genome stability in rice.

Structural Aspects of DNA Repair and Recombination in Crop Improvement

The adverse effects of global climate change combined with an exponentially increasing human population have put substantial constraints on agriculture, accelerating efforts towards ensuring food security for a sustainable future. Conventional plant breeding and modern technologies have led to the creation of plants with better traits and higher productivity. Most crop improvement approaches (conventional breeding, genome modification, and gene editing) primarily rely on DNA repair and recombination (DRR). Studying plant DRR can provide insights into designing new strategies or improvising the present techniques for crop improvement. Even though plants have evolved specialized DRR mechanisms compared to other eukaryotes, most of our insights about plant-DRRs remain rooted in studies conducted in animals. DRR mechanisms in plants include direct repair, nucleotide excision repair (NER), base excision repair (BER), mismatch repair (MMR), non-homologous end joining (NHEJ) and homologous recombination (HR). Although each DRR pathway acts on specific DNA damage, there is crosstalk between these. Considering the importance of DRR pathways as a tool in crop improvement, this review focuses on a general description of each DRR pathway, emphasizing on the structural aspects of key DRR proteins. The review highlights the gaps in our understanding and the importance of studying plant DRR in the context of crop improvement.

Maintenance of Yeast Genome Integrity by RecQ Family DNA Helicases

With roles in DNA repair, recombination, replication and transcription, members of the RecQ DNA helicase family maintain genome integrity from bacteria to mammals. Mutations in human RecQ helicases BLM, WRN and RecQL4 cause incurable disorders characterized by genome instability, increased cancer predisposition and premature adult-onset aging. Yeast cells lacking the RecQ helicase Sgs1 share many of the cellular defects of human cells lacking BLM, including hypersensitivity to DNA damaging agents and replication stress, shortened lifespan, genome instability and mitotic hyper-recombination, making them invaluable model systems for elucidating eukaryotic RecQ helicase function. Yeast and human RecQ helicases have common DNA substrates and domain structures and share similar physical interaction partners. Here, we review the major cellular functions of the yeast RecQ helicases Sgs1 of Saccharomyces cerevisiae and Rqh1 of Schizosaccharomyces pombe and provide an outlook on some of the outstanding questions in the field.

The contribution of the S-phase checkpoint genes MEC1 and SGS1 to genome stability maintenance in Candida albicans

Genome rearrangements, a common feature of Candida albicans isolates, are often associated with the acquisition of antifungal drug resistance. In Saccharomyces cerevisiae, perturbations in the S-phase checkpoints result in the same sort of Gross Chromosomal Rearrangements (GCRs) observed in C. albicans. Several proteins are involved in the S. cerevisiae cell cycle checkpoints, including Mec1p, a protein kinase of the PIKK (phosphatidyl inositol 3-kinase-like kinase) family and the central player in the DNA damage checkpoint. Sgs1p, the ortholog of BLM, the Bloom's syndrome gene, is a RecQ-related DNA helicase; cells from BLM patients are characterized by an increase in genome instability. Yeast strains bearing deletions in MEC1 or SGS1 are viable (in contrast to the inviability seen with loss of MEC1 in S. cerevisiae) but the different deletion mutants have significantly different phenotypes. The mec1Δ/Δ colonies have a wild-type colony morphology, while the sgs1Δ/Δ mutants are slow-growing, producing wrinkled colonies with pseudohyphal-like cells. The mec1Δ/Δ mutants are only sensitive to ethylmethane sulfonate (EMS), methylmethane sulfonate (MMS), and hydroxyurea (HU) but the sgs1Δ/Δ mutants exhibit a high sensitivity to all DNA-damaging agents tested. In an assay for chromosome 1 integrity, the mec1Δ/Δ mutants exhibit an increase in genome instability; no change was observed in the sgs1Δ/Δ mutants. Finally, loss of MEC1 does not affect sensitivity to the antifungal drug fluconazole, while loss of SGS1 leads to an increased susceptibility to fluconazole. Neither deletion elevated the level of antifungal drug resistance acquisition.

The RecQ DNA helicases in DNA repair

The RecQ helicases are conserved from bacteria to humans and play a critical role in genome stability. In humans, loss of RecQ gene function is associated with cancer predisposition and/or premature aging. Recent experiments have shown that the RecQ helicases function during distinct steps during DNA repair; DNA end resection, displacement-loop (D-loop) processing, branch migration, and resolution of double Holliday junctions (dHJs). RecQ function in these different processing steps has important implications for its role in repair of double-strand breaks (DSBs) that occur during DNA replication and meiosis, as well as at specific genomic loci such as telomeres.

Sgs1 truncations induce genome rearrangements but suppress detrimental effects of BLM overexpression in Saccharomyces cerevisiae

RecQ-like DNA helicases are conserved from bacteria to humans. They perform functions in the maintenance of genome stability, and their mutation is associated with cancer predisposition and premature aging syndromes in humans. Here, a series of C-terminal deletions and point mutations of Sgs1, the only RecQ-like helicase in yeast, show that the Helicase/RNase D C-terminal domain and the Rad51 interaction domain are dispensable for Sgs1's role in suppressing genome instability, whereas the zinc-binding domain and the helicase domain are required. BLM expression from the native SGS1 promoter had no adverse effects on cell growth and was unable to complement any sgs1Δ defects. BLM overexpression, however, significantly increased the rate of accumulating gross-chromosomal rearrangements in a dosage-dependent manner and greatly exacerbated sensitivity to DNA-damaging agents. Co-expressing sgs1 truncations of up to 900 residues, lacking all known functional domains of Sgs1, suppressed the hydroxyurea sensitivity of BLM-overexpressing cells, suggesting a functional relationship between Sgs1 and BLM. Protein disorder prediction analysis of Sgs1 and BLM was used to produce a functional Sgs1-BLM chimera by replacing the N-terminus of BLM with the disordered N-terminus of Sgs1. The functionality of this chimera suggests that it is the disordered N-terminus, a site of protein binding and posttranslational modification, that confers species specificity to these two RecQ-like proteins.

The roles of the Saccharomyces cerevisiae RecQ helicase SGS1 in meiotic genome surveillance

Background

The Saccharomyces cerevisiae RecQ helicase Sgs1 is essential for mitotic and meiotic genome stability. The stage at which Sgs1 acts during meiosis is subject to debate. Cytological experiments showed that a deletion of SGS1 leads to an increase in synapsis initiation complexes and axial associations leading to the proposal that it has an early role in unwinding surplus strand invasion events. Physical studies of recombination intermediates implicate it in the dissolution of double Holliday junctions between sister chromatids.

Methodology/Principal Findings

In this work, we observed an increase in meiotic recombination between diverged sequences (homeologous recombination) and an increase in unequal sister chromatid events when SGS1 is deleted. The first of these observations is most consistent with an early role of Sgs1 in unwinding inappropriate strand invasion events while the second is consistent with unwinding or dissolution of recombination intermediates in an Mlh1- and Top3-dependent manner. We also provide data that suggest that Sgs1 is involved in the rejection of ‘second strand capture’ when sequence divergence is present. Finally, we have identified a novel class of tetrads where non-sister spores (pairs of spores where each contains a centromere marker from a different parent) are inviable. We propose a model for this unusual pattern of viability based on the inability of sgs1 mutants to untangle intertwined chromosomes. Our data suggest that this role of Sgs1 is not dependent on its interaction with Top3. We propose that in the absence of SGS1 chromosomes may sometimes remain entangled at the end of pre-meiotic replication. This, combined with reciprocal crossing over, could lead to physical destruction of the recombined and entangled chromosomes. We hypothesise that Sgs1, acting in concert with the topoisomerase Top2, resolves these structures.

Conclusions

This work provides evidence that Sgs1 interacts with various partner proteins to maintain genome stability throughout meiosis.

Role of Blm and collaborating factors in recombination and survival following replication stress in Ustilago maydis

Inactivation of the structural gene for the RecQ family member, BLM in human, Sgs1 in budding yeast, or Rqh1 in fission yeast leads to inappropriate recombination, chromosome abnormalities, and disturbed replication fork progression. Studies with yeasts have demonstrated that auxiliary gene functions can contribute in overlapping ways with Sgs1 or Rqh1 to circumvent or overcome lesions in DNA caused by certain genotoxic agents. In the combined absence of these functions, recombination-mediated processes lead to severe loss of fitness. Here we performed a genetic study to determine the role of the Ustilago maydis Blm homolog in DNA repair and in alleviating replication stress. We characterized the single mutant as well as double mutants additionally deleted of genes encoding Srs2, Fbh1, Mus81, or Exo1. Unlike yeasts, neither the blm srs2, blm exo1, nor blm mus81 double mutant exhibited extreme loss of fitness. Inactivation of Brh2, the BRCA2 homolog, suppressed toxicity to hydroxyurea caused by loss of Blm function. However, differential suppression by Brh2 derivatives lacking the canonical DNA-binding region suggests that the particular domain structure comprising this DNA-binding region may be instrumental in promoting the observed hydroxyurea toxicity.

Sgs1 function in the repair of DNA replication intermediates is separable from its role in homologous recombinational repair

Mutations in human homologues of the bacterial RecQ helicase cause diseases leading to cancer predisposition and/or shortened lifespan (Werner, Bloom, and Rothmund-Thomson syndromes). The budding yeast Saccharomyces cerevisiae has one RecQ helicase, Sgs1, which functions with Top3 and Rmi1 in DNA repair. Here, we report separation-of-function alleles of SGS1 that suppress the slow growth of top3Delta and rmi1Delta cells similar to an SGS1 deletion, but are resistant to DNA damage similar to wild-type SGS1. In one allele, the second acidic region is deleted, and in the other, only a single aspartic acid residue 664 is deleted. sgs1-D664Delta, unlike sgs1Delta, neither disrupts DNA recombination nor has synthetic growth defects when combined with DNA repair mutants. However, during S phase, it accumulates replication-associated X-shaped structures at damaged replication forks. Furthermore, fluorescent microscopy reveals that the sgs1-D664Delta allele exhibits increased spontaneous RPA foci, suggesting that the persistent X-structures may contain single-stranded DNA. Taken together, these results suggest that the Sgs1 function in repair of DNA replication intermediates can be uncoupled from its role in homologous recombinational repair.

The Arabidopsis BLAP75/Rmi1 homologue plays crucial roles in meiotic double-strand break repair

In human cells and in Saccharomyces cerevisiae, BLAP75/Rmi1 acts together with BLM/Sgs1 and TopoIIIalpha/Top3 to maintain genome stability by limiting crossover (CO) formation in favour of NCO events, probably through the dissolution of double Holliday junction intermediates (dHJ). So far, very limited data is available on the involvement of these complexes in meiotic DNA repair. In this paper, we present the first meiotic study of a member of the BLAP75 family through characterisation of the Arabidopsis thaliana homologue. In A. thaliana blap75 mutants, meiotic recombination is initiated, and recombination progresses until the formation of bivalent-like structures, even in the absence of ZMM proteins. However, chromosome fragmentation can be detected as soon as metaphase I and is drastic at anaphase I, while no second meiotic division is observed. Using genetic and imunolocalisation studies, we showed that these defects reflect a role of A. thaliana BLAP75 in meiotic double-strand break (DSB) repair -- that it acts after the invasion step mediated by RAD51 and associated proteins and that it is necessary to repair meiotic DSBs onto sister chromatids as well as onto the homologous chromosome. In conclusion, our results show for the first time that BLAP75/Rmi1 is a key protein of the meiotic homologous recombination machinery. In A. thaliana, we found that this protein is dispensable for homologous chromosome recognition and synapsis but necessary for the repair of meiotic DSBs. Furthermore, in the absence of BLAP75, bivalent formation can happen even in the absence of ZMM proteins, showing that in blap75 mutants, recombination intermediates exist that are stable enough to form bivalent structures, even when ZMM are absent.

Longevity mutation in SCH9 prevents recombination errors and premature genomic instability in a Werner/Bloom model system

Werner and Bloom syndromes are human diseases characterized by premature age-related defects including elevated cancer incidence. Using a novel Saccharomyces cerevisiae model system for aging and cancer, we show that cells lacking the RecQ helicase SGS1 (WRN and BLM homologue) undergo premature age-related changes, including reduced life span under stress and calorie restriction (CR), G1 arrest defects, dedifferentiation, elevated recombination errors, and age-dependent increase in DNA mutations. Lack of SGS1 results in a 110-fold increase in gross chromosomal rearrangement frequency during aging of nondividing cells compared with that generated during the initial population expansion. This underscores the central role of aging in genomic instability. The deletion of SCH9 (homologous to AKT and S6K), but not CR, protects against the age-dependent defects in sgs1Δ by inhibiting error-prone recombination and preventing DNA damage and dedifferentiation. The conserved function of Akt/S6k homologues in lifespan regulation raises the possibility that modulation of the IGF-I–Akt–56K pathway can protect against premature aging syndromes in mammals.

Holliday junction processing activity of the BLM-Topo IIIalpha-BLAP75 complex

BLM, the protein mutated in Bloom's syndrome, possesses a helicase activity that can dissociate DNA structures, including the Holliday junction, expected to arise during homologous recombination. BLM is stably associated with topoisomerase IIIalpha (Topo IIIalpha) and the BLAP75 protein. The BLM-Topo IIIalpha-BLAP75 (BTB) complex can efficiently resolve a DNA substrate that harbors two Holliday junctions (the double Holliday junction) in a non-crossover manner. Here we show that the Holliday junction unwinding activity of BLM is greatly enhanced as a result of its association with Topo IIIalpha and BLAP75. Enhancement of this BLM activity requires both Topo IIIalpha and BLAP75. Importantly, Topo IIIalpha cannot be substituted by Escherichia coli Top3, and the Holliday junction unwinding activity of BLM-related helicases WRN and RecQ is likewise impervious to Topo IIIalpha and BLAP75. However, the topoisomerase activity of Topo IIIalpha is dispensable for the enhancement of the DNA unwinding reaction. We have also ascertained the requirement for the BLM ATPase activity in double Holliday junction dissolution and DNA unwinding by constructing, purifying, and characterizing specific mutant variants that lack this activity. These results provide valuable information concerning how the functional integrity of the BTB complex is governed by specific protein-protein interactions among the components of this complex and the enzymatic activities of BLM and Topo IIIalpha.

Multiple functions of Drosophila BLM helicase in maintenance of genome stability

Bloom Syndrome, a rare human disorder characterized by genomic instability and predisposition to cancer, is caused by mutation of BLM, which encodes a RecQ-family DNA helicase. The Drosophila melanogaster ortholog of BLM, DmBlm, is encoded by mus309. Mutations in mus309 cause hypersensitivity to DNA-damaging agents, female sterility, and defects in repairing double-strand breaks (DSBs). To better understand these phenotypes, we isolated novel mus309 alleles. Mutations that delete the N terminus of DmBlm, but not the helicase domain, have DSB repair defects as severe as those caused by null mutations. We found that female sterility is due to a requirement for DmBlm in early embryonic cell cycles; embryos lacking maternally derived DmBlm have anaphase bridges and other mitotic defects. These defects were less severe for the N-terminal deletion alleles, so we used one of these mutations to assay meiotic recombination. Crossovers were decreased to about half the normal rate, and the remaining crossovers were evenly distributed along the chromosome. We also found that spontaneous mitotic crossovers are increased by several orders of magnitude in mus309 mutants. These results demonstrate that DmBlm functions in multiple cellular contexts to promote genome stability.

The INO80 complex is required for damage-induced recombination

The budding yeast INO80 complex has a role in remodeling chromatin structure, and the SWR1 complex replaces a H2A/H2B dimer with a variant dimer, H2A.Z (Htz1)/H2B. It has been reported that these chromatin remodeling complexes contain Arp4 (actin-related protein) and actin in common and are recruited to HO endonuclease-induced DNA double-strand break (DSB) site. Reportedly, Ino80 can evict nucleosomes surrounding a HO-induced DSB; however, it has no apparent role to play in the repair of HO-induced DSB. Here we show that an essential factor for INO80 chromatin remodeling activity, Arp8, is involved in damage-induced sister chromatid recombination and interchromosomal recombination between heteroalleles. In contrast, arp6 mutants are proficient for recombination, indicating that the SWR1 complex does not promote recombination. Our data suggest that the remodeling of chromatin by the INO80 complex facilitates efficient homologous recombination upon DNA damages.

A positive involvement of RecQL4 in UV-induced S-phase arrest

RecQL4 belongs to a family of conserved RECQ helicases that are important in maintaining chromosomal integrity. Human patients lacking RecQL4 showed extreme sensitivity to UV and oxidation damage, suggesting that RecQL4 is involved in the damage signaling and/or repair. Here we show that human mutant cells lacking RecQL4 were defective in UV-induced S-phase arrest, whereas cells defective in bloom syndrome protein (BLM), another member of RecQ family exhibited a normal S-phase arrest following UV irradiation. In keeping with this, a targeted inhibition of RecQL4 expression in human 293 cells showed a defect in inducing S-phase (replication) arrest following UV treatment. Human mutant cells lacking RecQL4 protein were also defective in inducing S-phase arrest following hydroxyurea treatment. Together, our results suggest that RecQL4 may have a unique role in replication fork arrest, which may not be shared with other members of RecQ family such as BLM.

Sgs1 regulates gene conversion tract lengths and crossovers independently of its helicase activity

RecQ helicases maintain genome stability and suppress tumors in higher eukaryotes through roles in replication and DNA repair. The yeast RecQ homolog Sgs1 interacts with Top3 topoisomerase and Rmi1. In vitro, Sgs1 binds to and branch migrates Holliday junctions (HJs) and the human RecQ homolog BLM, with Top3alpha, resolves synthetic double HJs in a noncrossover sense. Sgs1 suppresses crossovers during the homologous recombination (HR) repair of DNA double-strand breaks (DSBs). Crossovers are associated with long gene conversion tracts, suggesting a model in which Sgs1 helicase catalyzes reverse branch migration and convergence of double HJs for noncrossover resolution by Top3. Consistent with this model, we show that allelic crossovers and gene conversion tract lengths are increased in sgs1Delta. However, crossover and tract length suppression was independent of Sgs1 helicase activity, which argues against helicase-dependent HJ convergence. HJs may converge passively by a "random walk," and Sgs1 may play a structural role in stimulating Top3-dependent resolution. In addition to the new helicase-independent functions for Sgs1 in crossover and tract length control, we define three new helicase-dependent functions, including the suppression of chromosome loss, chromosome missegregation, and synthetic lethality in srs2Delta. We propose that Sgs1 has helicase-dependent functions in replication and helicase-independent functions in DSB repair by HR.

Mrc1 and Srs2 are major actors in the regulation of spontaneous crossover

In vegetative cells, most recombination intermediates are metabolized without an association with a crossover (CO). The avoidance of COs allows for repair and prevents genomic rearrangements, potentially deleterious if the sequences involved are at ectopic locations. We have designed a system that permits to screen spontaneous intragenic recombination events in Saccharomyces cerevisiae and to investigate the CO outcome in different genetic contexts. We have analyzed the CO outcome in the absence of the Srs2 and Sgs1 helicases, DNA damage checkpoint proteins as well as in a mutant proliferating cell nuclear antigen (PCNA) and found that they all contribute to genome stability. Remarkably high effects on COs are mediated by srs2Delta, mrc1Delta and a pol30-RR mutation in PCNA. Our results support the view that Mrc1 plays a specific role in DNA replication, promoting the Srs2 recruitment to PCNA independently of checkpoint signaling. Srs2 would prevent formation of double Holliday junctions (dHJs) and thus CO formation. Sgs1 also negatively regulates CO formation but through a different process that resolves dHJs to yield non-CO products.

Overexpression of Rad51 inhibits double-strand break-induced homologous recombination but does not affect gene conversion tract lengths

DNA double-strand breaks (DSBs) in yeast are repaired by homologous recombination (HR) and non-homologous end-joining (NHEJ). Rad51 forms nucleoprotein filaments at processed broken ends that effect strand exchange, forming heteroduplex DNA (hDNA) that gives rise to a gene conversion tract. We hypothesized that excess Rad51 would increase gene conversion tract lengths. We found that excess Rad51 reduced DSB-induced HR but did not alter tract lengths or other outcomes including rates of crossovers, break-induced replication, or chromosome loss. Thus, excess Rad51 appears to influence DSB-induced HR at an early stage. MAT heterozygosity largely mitigated the inhibitory effect of excess Rad51 on allelic HR, but not direct repeat HR. Excess Rad52 had no effect on DSB-induced HR efficiency or outcome, nor did it mitigate the dominant negative effects of excess Rad51. Excess Rad51 had little effect on DSB-induced lethality in wild-type cells, but it did enhance lethality in yku70Delta mutants. Interestingly, dnl4Delta showed marked DSB-induced lethality but this was not further enhanced by excess Rad51. The differential effects of yku70Delta and dnl4Delta indicate that the enhanced killing with excess Rad51 in yku70Delta is not due to its NHEJ defect, but may reflect its defect in end-protection and/or its inability to escape from checkpoint arrest. Srs2 displaces Rad51 from nucleoprotein filaments in vitro, suggesting that excess Rad51 might antagonize Srs2. We show that excess Rad51 does not reduce survival of wild-type cells treated with methylmethane sulfonate (MMS), or cells suffering a single DSB. In contrast, excess Rad51 sensitized srs2Delta cells to both MMS and a single DSB. These results support the idea that excess Rad51 antagonizes Srs2, and underscores the importance of displacing Rad51 from nucleoprotein filaments to achieve optimum repair efficiency.

Yeast Rmi1/Nce4 controls genome stability as a subunit of the Sgs1-Top3 complex

Genome stability requires a set of RecQ-Top3 DNA helicase-topoisomerase complexes whose sole budding yeast homolog is encoded by SGS1-TOP3. RMI1/NCE4 was identified as a potential intermediate in the SGS1-TOP3 pathway, based on the observation that strains lacking any one of these genes require MUS81 and MMS4 for viability. This idea was tested by confirming that sgs1 and rmi1 mutants display the same spectrum of synthetic lethal interactions, including the requirements for SLX1, SLX4, SLX5, and SLX8, and by demonstrating that rmi1 mus81 synthetic lethality is dependent on homologous recombination. On their own, mutations in RMI1 result in phenotypes that mimic those of sgs1 or top3 strains including slow growth, hyperrecombination, DNA damage sensitivity, and reduced sporulation. And like top3 strains, most rmi1 phenotypes are suppressed by mutations in SGS1. We show that Rmi1 forms a heteromeric complex with Sgs1-Top3 in yeast and that these proteins interact directly in a recombinant system. The Rmi1-Top3 complex is stable in the absence of the Sgs1 helicase, but the loss of either Rmi1 or Top3 in yeast compromises its partner's interaction with Sgs1. Biochemical studies demonstrate that recombinant Rmi1 is a structure-specific DNA binding protein with a preference for cruciform structures. We propose that the DNA binding specificity of Rmi1 plays a role in targeting Sgs1-Top3 to appropriate substrates.

The ability of Sgs1 to interact with DNA topoisomerase III is essential for damage-induced recombination

SGS1 encodes a protein having DNA helicase activity, and a mutant allele of SGS1 was identified as a suppressor of the slow growth phenotype of top3 mutants. In this study, we examined whether Sgs1 prevents formation of DNA double strand breaks (DSBs) or is involved in DSB repair following exposure to methyl methanesulfonate (MMS). An analysis by pulsed-field gel electrophoresis and epistasis analyses indicated that Sgs1 is required for DSB repair that involves Rad52. In addition, analyses on the relationship between Sgs1 and proteins involved in DSB repair suggested that Sgs1 and Mre11 function via independent pathways both of which require Rad52. In sgs1 mutants, interchromosomal heteroallelic recombination and sister chromatid recombination (SCR) were not induced upon exposure to MMS, though both were induced in wild type cells, indicating the involvement of Sgs1 in heteroallelic recombination and SCR. Surprisingly, the ability of Sgs1 to bind to DNA topoisomerase III (Top3) was absolutely required for the induction of heteroallelic recombination and SCR and suppression of MMS sensitivity but its helicase activity was not, suggesting that Top3 plays a more important role in both recombinations than the DNA helicase activity of Sgs1.

The hyper unequal sister chromatid recombination in an sgs1 mutant of budding yeast requires MSH2

Budding yeast SGS1 and the human Bloom's syndrome (BS) gene, BLM, are homologues of the Escherichia coli recQ. Cells derived from BS patients are characterized by a dramatic increase in sister chromatid exchange (SCE). We previously reported that budding yeast cells deficient in SGS1 showed an increase in the frequency of recombination between unequal sister chromatids recombination (USCR). In this study, we examined the factors influencing the elevated SCR frequency in sgs1 disruptants. The increase in SCR frequency in sgs1 mutants was greatly reduced by disrupting the RAD52 or MSH2 gene, which is involved in mismatch repair. However, a plasmid carrying MSH2, having a missense mutation defective in mismatch repair complemented the reduced USCR in msh2 sgs1 mutants, suggesting that the function of Msh2 in mismatch repair is dispensable for USCR.

The possible roles of the DNA helicase and C-terminal domains in RECQ5/QE: complementation study in yeast

DmRECQ5/QE is a member of the RECQ5 subfamily, which shares homology with the Escherichia coli RecQ DNA helicase. Although the DNA helicase activity of RECQ5/QE has been characterized in vitro, the in vivo function of RECQ5/QE was essentially unknown. To investigate the cellular role of RECQ5, the potential of RECQ5/QE was evaluated by substitution of the only RecQ-like helicase, Sgs1, in budding yeast. RECQ5/QE can complement several phenotypes of sgs1, including the synthetic growth defect with srs2, the hypersensitivity to hydroxyurea and methyl methanesulfonate, and the elevated frequency of homologous recombination and sister chromatid exchange (SCE), but poorly complemented the suppression of slow growth in top3. These data suggested that RECQ5/QE exhibits an evolutionarily conserved RecQ function in vivo. The RECQ5/QE domain necessary for the yeast complementation was determined. The helicase domain and helicase activity were required to complement both the sgs1srs2 and sgs1top3 phenotypes. In contrast, the C-terminal domain was dispensable for complementing the sgs1srs2 phenotype, but was required for the sgs1top3 phenotype. These results suggested that the RECQ5/QE helicase activity is important for cellular function and that the C-terminal domain has a specific function in the absence of Top3.

The Sgs1 helicase regulates chromosome synapsis and meiotic crossing over

BACKGROUND

In budding yeast, Sgs1 is the sole member of the RecQ family of DNA helicases. Like the human Bloom syndrome helicase (BLM), Sgs1 functions during both vegetative growth and meiosis. The sgs1 null mutant sporulates poorly and displays reduced spore viability.

RESULTS

We have identified novel functions for Sgs1 in meiosis. Loss of Sgs1 increases the number of axial associations, which are connections between homologous chromosomes that serve as initiation sites for synaptonemal complex formation. In addition, mutation of SGS1 increases the number of synapsis initiation complexes and increases the rate of chromosome synapsis. Loss of Sgs1 also increases the number of meiotic crossovers without changing the frequency of gene conversion. The sgs1 defect in sporulation is due to checkpoint-induced arrest/delay at the pachytene stage of meiotic prophase. A non-null allele of SGS1 that specifically deletes the helicase domain is defective in the newly described meiotic functions of Sgs1, but wild-type for most vegetative functions and for spore formation.

CONCLUSIONS

We have shown that the helicase domain of Sgs1 serves as a negative regulator of meiotic interchromosomal interactions. The activity of the wild-type Sgs1 protein reduces the numbers of axial associations, synapsis initiation complexes, and crossovers, and decreases the rate of chromosome synapsis. Our data argue strongly that axial associations marked by synapsis initiation complexes correspond to sites of reciprocal exchange. We propose that the Sgs1 helicase prevents a subset of recombination intermediates from becoming crossovers, and this distinction is made at an early stage in meiotic prophase.

Deficiency of Caenorhabditis elegans RecQ5 homologue reduces life span and increases sensitivity to ionizing radiation

Gene expression and RNA interference phenotypes were investigated for a Caenorhabditis elegans homologue (Ce-RCQ-5) of human RecQ5 protein. Expression of the mRNA was observed by in situ hybridization from earliest embryogenesis and gradually decreased during late embryogenesis. Ce-RCQ-5 was immuno-localized in the nuclei of embryos, germ cells, and oocytes and also in the nuclei of various somatic cells of larvae and adults. Despite ubiquitous expression in postembryonic cells, RCQ-5 protein expression was highest in intestinal cells, which was confirmed by tagging the gene expression with green fluorescence protein. When endogenous Ce-rcq-5 gene expression was inhibited by RNA interference, no clear phenotypes were observed during development. However, C. elegans life span was reduced by 37% due to RNA interference of rcq-5 gene, suggesting its possible role in maintenance of genomic stability, as has been ascribed to other RecQ family DNA helicases. In addition, C. elegans became significantly more sensitive to ionizing radiation after inhibition of rcq-5 gene expression, indicating an involvement of C. elegans RCQ-5 in a cellular response to DNA damage, possibly in DNA repair.

RecQ helicases: suppressors of tumorigenesis and premature aging

The RecQ helicases represent a subfamily of DNA helicases that are highly conserved in evolution. Loss of RecQ helicase function leads to a breakdown in the maintenance of genome integrity, in particular hyper-recombination. Germ-line defects in three of the five known human RecQ helicases give rise to defined genetic disorders associated with cancer predisposition and/or premature aging. These are Bloom's syndrome, Werner's syndrome and Rothmund-Thomson syndrome, which are caused by defects in the genes BLM, WRN and RECQ4 respectively. Here we review the properties of RecQ helicases in organisms from bacteria to humans, with an emphasis on the biochemical functions of these enzymes and the range of protein partners that they operate with. We will discuss models in which RecQ helicases are required to protect against replication fork demise, either through prevention of fork breakdown or restoration of productive DNA synthesis.

Arabidopsis RecQsim, a plant-specific member of the RecQ helicase family, can suppress the MMS hypersensitivity of the yeast sgs1 mutant

The Arabidopsis genome contains seven genes that belong to the RecQ family of ATP-dependent DNA helicases. RecQ members in Saccharomyces cerevisiae (SGS1) and man (WRN, BLM and RecQL4) are involved in DNA recombination, repair and genome stability maintenance, but little is known about the function of their plant counterparts. The Arabidopsis thaliana RecQsim gene is remarkably different from the other RecQ-like genes due to an insertion in its helicase domain. We isolated the AtRecQsim orthologues from rice and rape and established the presence of a similar insertion in their helicase domain, which suggests a plant specific function for the insert. The expression pattern of the AtRecQsim gene was compared with the other Arabidopsis RecQ-like members in different tissues and in response to stress. The transcripts of the AtRecQsim gene were found in all plant organs and its accumulation was higher in roots and seedlings, as compared to the other AtRecQ-like members. In contrast to most AtRecQ-like genes, the examined environmental cues did not have a detectable effect on the accumulation of the AtRecQsim transcripts. The budding yeast sgs1 mutant, which is known to be hypersensitive to the DNA-damaging drug MMS, was transformed with the AtRecQsim cDNA. The AtRecQsim gene suppressed the MMS hypersensitivity phenotype of the sgs1 cells. We propose that the Arabidopsis RecQsim gene, despite its unusual structure, exhibits an evolutionary conserved function.

Functional relation among RecQ family helicases RecQL1, RecQL5, and BLM in cell growth and sister chromatid exchange formation

Human RECQL1 and RECQL5 belong to the RecQ family that includes Bloom syndrome, Werner syndrome, and Rothmund-Thomson syndrome causative genes. Cells derived from individuals suffering from these syndromes show significant levels of genomic instability. However, neither RECQL1 nor RECQL5 has been related to a disease, and nothing is known about the functions of RecQL1 and RecQL5. We generated here RECQL1(-/-), RECQL5(-/-), RECQL1(-/-)/RECQL5(-/-), RECQL1(-/-)/BLM(-/-), and RECQL5(-/-)/BLM(-/-) cells from chicken B-lymphocyte line DT40 cells. Although BLM(-/-) DT40 cells showed a slow-growth phenotype, a higher sensitivity to methyl methanesulfonate than the wild type, and an approximately 10-fold increase in the frequency of sister chromatid exchange (SCE) compared to wild-type cells, RECQL1(-/-), RECQL5(-/-), and RECQL1(-/-)/RECQL5(-/-) cells showed no significant difference from the wild-type cells in growth, sensitivity to DNA-damaging agents, and the frequency of SCE. However, both RECQL1(-/-)/BLM(-/-) and RECQL5(-/-)/BLM(-/-) cells grew more slowly than BLM(-/-) cells because of the increase in the population of dead cells, indicating that RecQL1 and RecQL5 are somehow involved in cell viability under the BLM function-impaired condition. Surprisingly, RECQL5(-/-)/BLM(-/-) cells showed a higher frequency of SCE than BLM(-/-) cells, indicating that RecQL5 suppresses SCE under the BLM function-impaired condition.

Budding yeast mms4 is epistatic with rad52 and the function of Mms4 can be replaced by a bacterial Holliday junction resolvase

MMS4 of Saccharomyces cerevisiae was originally identified as the gene responsible for one of the collection of methyl methanesulfonate (MMS)-sensitive mutants, mms4. Recently it was identified as a synthetic lethal gene with an SGS1 mutation. Epistatic analyses revealed that MMS4 is involved in a pathway leading to homologous recombination requiring Rad52 or in the recombination itself, in which SGS1 is also involved. MMS sensitivity of mms4 but not sgs1, was suppressed by introducing a bacterial Holliday junction (HJ) resolvase, RusA. The frequencies of spontaneously occurring unequal sister chromatid recombination (SCR) and loss of marker in the rDNA in haploid mms4 cells and interchromosomal recombination between heteroalleles in diploid mms4 cells were essentially the same as those of wild-type cells. Although UV- and MMS-induced interchromosomal recombination was defective in sgs1 diploid cells, hyper-induction of interchromosomal recombination was observed in diploid mms4 cells, indicating that the function of Mms4 is dispensable for this type of recombination.

Helicase activity is only partially required for Schizosaccharomyces pombe Rqh1p function

The RecQ-related family of DNA helicases is required for the maintenance of genomic stability in organisms ranging from bacteria to humans. In humans, mutation of three RecQ-related helicases, BLM, WRN and RecQL4, cause the cancer-prone and premature ageing diseases of Bloom syndrome, Werner's syndrome and Rothmund-Thompson syndrome, respectively. In the fission yeast Schizosaccharomyces pombe, disruption of the rqh1(+) gene, which encodes the single Sz. pombe RecQ-related helicase, causes cells to display reduced viability and elevated levels of chromosome loss. After S-phase arrest or DNA damage, cells lacking rqh1(+) function display elevated levels of homologous recombination and defective chromosome segregation. Here we show that, like other RecQ family members, the Rqh1p protein displays 3' to 5' DNA helicase activity. Interestingly, however, unlike other RecQ family members, the helicase activity of Rqh1p is only partially required for its function in recovery from S-phase arrest or DNA damage. We also report that high cellular levels of Rqh1p result in lethal chromosome segregation defects, while more moderate levels of Rqh1p cause significantly elevated rates of chromosome loss. This suggests that careful regulation of RecQ-like protein levels in eukaryotic cells is vital for maintaining genome stability.

Supercomplex formation between Mlh1-Mlh3 and Sgs1-Top3 heterocomplexes in meiotic yeast cells

The genome of Saccharomyces cerevisia encodes four mismatch repair MutL proteins and these proteins form three heterocomplexes: Mlh1-Mlh2, Mlh1-Mlh3, and Mlh1-Pms1. Only, the Mlh1-Mlh3 heterocomplex has been implicated specifically in promotion of meiotic crossing-over. In this report, we show that yeast Mlh3 co-immunoprecipitates with Sgs1 helicase in sporulating cells at late stage of meiotic prophase I. Sgs1, a member of the RecQ DNA helicase family, appears to form a stable complex with topoisomerase III (Top3) during meiosis. We suggest that Mlh1-Mlh3 heterocomplex may act as a molecular matchmaker to coordinate Sgs1-Top3 complex in the resolution of meiotic recombination intermediates.

Defending genome integrity during S-phase: putative roles for RecQ helicases and topoisomerase III

The maintenance of genome stability is important not only for cell viability, but also for the suppression of neoplastic transformation in higher eukaryotes. It has long been recognised that a common feature of cancer cells is genomic instability. Although the so-called three 'Rs' of genome maintenance, DNA replication, recombination and repair, have historically been studied in isolation, a wealth of recent evidence indicates that these processes are intimately interrelated and interdependent. In this article, we will focus on challenges to the maintenance of genome integrity that arise during the S-phase of the cell cycle, and the possible roles that RecQ helicases and topoisomerase III play in the maintenance of genome integrity during the process of DNA replication.

SGS1 is a multicopy suppressor of srs2: functional overlap between DNA helicases

Sgs1 is a member of the RecQ family of DNA helicases, which have been implicated in genomic stability, cancer and ageing. Srs2 is another DNA helicase that shares several phenotypic features with Sgs1 and double sgs1srs2 mutants have a severe synthetic growth phenotype. This suggests that there may be functional overlap between these two DNA helicases. Consistent with this idea, we found the srs2Delta mutant to have a similar genotoxin sensitivity profile and replicative lifespan to the sgs1Delta mutant. In order to directly test if Sgs1 and Srs2 are functionally interchangeable, the ability of high-copy SGS1 and SRS2 plasmids to complement the srs2Delta and sgs1Delta mutants was assessed. We report here that SGS1 is a multicopy suppressor of the methyl methanesulphonate (MMS) and hydroxyurea sensitivity of the srs2Delta mutant, whereas SRS2 overexpression had no complementing ability in the sgs1Delta mutant. Domains of Sgs1 directly required for processing MMS-induced DNA damage, most notably the helicase domain, are also required for complementation of the srs2Delta mutant. Although SGS1 overexpression was unable to rescue the shortened mean replicative lifespan of the srs2Delta mutant, maximum lifespan was significantly increased by multicopy SGS1. We conclude that Sgs1 is able to partially compensate for the loss of Srs2.

Functional and physical interaction between Sgs1 and Top3 and Sgs1-independent function of Top3 in DNA recombination repair

A mutant allele of SGS1 of Saccharomyces cerevisiae was identified as a suppressor of the slow-growth phenotype of top3 mutants. We previously reported the involvement of Top3 via the interaction with the N-terminal region of Sgs1 in the complementation of methylmethanesulfonate (MMS) sensitivity and the suppression of hyper recombination of a sgs1 mutant. In this study, we found that several amino acids residues in the N-terminal region of Sgs1 between residues 4 and 33 were responsible for binding to Top3 and essential for complementing the sensitivity to MMS of sgsl cells. Two-hybrid assays suggested that the region of Top3 responsible for the binding to Sgs1 was bipartite, with portion in the N- and C-terminal domains. Although disruption of the SGS1 gene suppressed the semi-lethality of the top3 mutant of strain MR, the sgsl-top3 double mutant grew more slowly and was more sensitive to MMS than the sgsl single mutant, indicating that Top3 plays some role independently of Sgs1. The DNA topoisomerase activity of Top3 was required for the Top3 function to repair DNA damages induced by MMS, as shown by the fact that the TOP3 gene carrying a mutation (Phe for Tyr) at the amino acid residue essential for its activity (residue 356) failed to restore the MMS sensitivity of sgs1-top3 to the level of that of the sgs1 single mutant. Epistatic analysis using the sgs1-top3 double mutant, rad52 mutant and sgs1-top3-rad52 triple mutant indicated that TOP3 belongs to the RAD52 recombinational repair pathway.

Coaction of DNA topoisomerase IIIalpha and a RecQ homologue during the germ-line mitosis in Caenorhabditis elegans

BACKGROUND

Among the four RecQ homologues predicted from the Caenorhabditis elegans genomic DNA sequence, T04A11.6 is most similar to Bloom syndrome's protein in humans. To investigate a possible interaction of the protein with topoisomerase IIIalpha (TOP3alpha), as observed between TOP3 and RecQ homologues in yeast and human, the top3alpha gene expression was suppressed by RNA interference (RNAi) in the him-6(e1104) C. elegans strain which is mutated in T04A11.6 (F. Mueller & C. Wicky, personal communication).

RESULTS

Germ cells in the gonads of the progeny him-6(e1104);top3alpha(RNAi) showed severe chromosomal abnormalities and were arrested during mitosis with a subsequent failure in meiotic entry. Most of the aberrant chromosomes were stained by the TUNEL assay but not by the SYTO12 dye, suggesting extensive DNA breaks not associated with apoptosis. The phenotypes in the germ cells of him-6(e1104);top3alpha(RNAi) were also observed in the progeny produced by double RNA interference of the top3alpha and him-6 gene expression, though at a reduced level. The over-expressed TOP3alpha and Him-6 proteins showed specific physical interaction in vitro, in agreement with the genetic interaction in C. elegans.

CONCLUSION

In C. elegans, TOP3alpha and the RecQ homologue (T04A11.6) contribute to genome stability during germ-line mitosis, probably by acting in a complex.

Topoisomerase III acts upstream of Rad53p in the S-phase DNA damage checkpoint

Deletion of the Saccharomyces cerevisiae TOP3 gene, encoding Top3p, leads to a slow-growth phenotype characterized by an accumulation of cells with a late S/G2 content of DNA (S. Gangloff, J. P. McDonald, C. Bendixen, L. Arthur, and R. Rothstein, Mol. Cell. Biol. 14:8391-8398, 1994). We have investigated the function of TOP3 during cell cycle progression and the molecular basis for the cell cycle delay seen in top3Delta strains. We show that top3Delta mutants exhibit a RAD24-dependent delay in the G2 phase, suggesting a possible role for Top3p in the resolution of abnormal DNA structures or DNA damage arising during S phase. Consistent with this notion, top3Delta strains are sensitive to killing by a variety of DNA-damaging agents, including UV light and the alkylating agent methyl methanesulfonate, and are partially defective in the intra-S-phase checkpoint that slows the rate of S-phase progression following exposure to DNA-damaging agents. This S-phase checkpoint defect is associated with a defect in phosphorylation of Rad53p, indicating that, in the absence of Top3p, the efficiency of sensing the existence of DNA damage or signaling to the Rad53 kinase is impaired. Consistent with a role for Top3p specifically during S phase, top3Delta mutants are sensitive to the replication inhibitor hydroxyurea, expression of the TOP3 mRNA is activated in late G1 phase, and DNA damage checkpoints operating outside of S phase are unaffected by deletion of TOP3. All of these phenotypic consequences of loss of Top3p function are at least partially suppressed by deletion of SGS1, the yeast homologue of the human Bloom's and Werner's syndrome genes. These data implicate Top3p and, by inference, Sgs1p in an S-phase-specific role in the cellular response to DNA damage. A model proposing a role for these proteins in S phase is presented.

The DNA helicase activity of yeast Sgs1p is essential for normal lifespan but not for resistance to topoisomerase inhibitors

The Saccharomyces cerevisiae SGS1 gene is a member of the RecQ family of ATP-dependent DNA helicases, which includes the human WRN, BLM and RECQ4 genes. Mutations in the WRN gene cause the human premature ageing disorder, Werner's syndrome. Deletion of the SGS1 gene also causes premature ageing in yeast, suggesting that the molecular mechanisms of cellular ageing may be evolutionarily conserved. To investigate the role of the RecQ helicase domain in ageing, a point mutation (SGS1 K(706)-->A) known to eliminate the DNA helicase activity of Sgs1p was constructed. This mutant allele failed to rescue the premature ageing of the sgs1Delta strain, demonstrating that Sgs1p DNA helicase activity is required for a normal lifespan. In contrast, the SGS1 K(706)-->A allele was sufficient to rescue the hypersensitivity of the sgs1Delta strain to topoisomerase inhibitors, but not other genotoxic agents. These findings support the idea that Sgs1p fulfils multiple cellular functions, and that DNA helicase activity is dispensable for some of these (e.g. functional interaction with topoisomerases), but essential for others (e.g. longevity).

A yeast gene, MGS1, encoding a DNA-dependent AAA(+) ATPase is required to maintain genome stability

Changes in DNA superhelicity during DNA replication are mediated primarily by the activities of DNA helicases and topoisomerases. If these activities are defective, the progression of the replication fork can be hindered or blocked, which can lead to double-strand breaks, elevated recombination in regions of repeated DNA, and genome instability. Hereditary diseases like Werner's and Bloom's Syndromes are caused by defects in DNA helicases, and these diseases are associated with genome instability and carcinogenesis in humans. Here we report a Saccharomyces cerevisiae gene, MGS1 (Maintenance of Genome Stability 1), which encodes a protein belonging to the AAA(+) class of ATPases, and whose central region is similar to Escherichia coli RuvB, a Holliday junction branch migration motor protein. The Mgs1 orthologues are highly conserved in prokaryotes and eukaryotes. The Mgs1 protein possesses DNA-dependent ATPase and single-strand DNA annealing activities. An mgs1 deletion mutant has an elevated rate of mitotic recombination, which causes genome instability. The mgs1 mutation is synergistic with a mutation in top3 (encoding topoisomerase III), and the double mutant exhibits severe growth defects and markedly increased genome instability. In contrast to the mgs1 mutation, a mutation in the sgs1 gene encoding a DNA helicase homologous to the Werner and Bloom helicases suppresses both the growth defect and the increased genome instability of the top3 mutant. Therefore, evolutionarily conserved Mgs1 may play a role together with RecQ family helicases and DNA topoisomerases in maintaining proper DNA topology, which is essential for genome stability.

A novel protein interacts with the Werner's syndrome gene product physically and functionally

Werner's syndrome (WS) is a rare autosomal recessive disorder characterized by premature aging. The gene responsible for WS encodes a protein homologous to Escherichia coli RecQ. Here we describe a novel Werner helicase interacting protein (WHIP), which interacts with the N-terminal portion of Werner protein (WRN), containing the exonuclease domain. WHIP, which shows homology to replication factor C family proteins, is conserved from E. coli to human. Ectopically expressed WHIP and WRN co-localized in granular structures in the nucleus. The functional relationship between WHIP and WRN was indicated by genetic analysis of yeast cells. Disruptants of the SGS1 gene of Saccharomyces cerevisiae, which is the WRN homologue in yeast, show an accelerated aging phenotype and high sensitivity to methyl methanesulfonate as compared with wild-type cells. Disruption of the yeast WHIP (yWHIP) gene in wild-type cells and sgs1 disruptants resulted in slightly accelerated aging and enhancement of the premature aging phenotype of sgs1 disruptants, respectively. In contrast, disruption of the yWHIP gene partially alleviated the sensitivity to methyl methanesulfonate of sgs1 disruptants.

Different domains of Sgs1 are required for mitotic and meiotic functions

The SGS1 of Saccharomyces cerevisiae is a homologue for human Bloom's syndrome, Werner's syndrome, and Rothmund-Thomson's syndrome causative genes. Disruptants of SGS1 show high sensitivity to methyl methanesulfonate (MMS) and hydroxyurea, and hyper recombination phenotypes including interchromosomal homologous recombination in mitotic growth. In addition, sgs1 disruptants show poor sporulation and a reduced level of meiotic recombination as assayed by return-to-growth. We examined domains of Sgs1 required for mitotic and meiotic functions of Sgs1 by transfecting variously mutated SGS1 into sgs1 disruptants. The N-terminal 1-401 amino acid region was required for complementation of MMS sensitivity and suppression of hyper heteroallelic recombinations of sgs1 disruptants in mitotic growth and for complementation of poor sporulation and of reduced meiotic recombination. Although the N-terminal 1-125 amino acid region was absolutely required for the complementation of MMS sensitivity and suppression of hyper heteroallelic recombinations in mitotic growth, it was dispensable for the meiotic functions. In contrast, the highly acidic region (400-596 amino acid) was dispensable for the mitotic functions but a deletion of this region affected the meiotic functions. The C-terminal 1271-1350 amino acid region containing a HRDC (helicase and RNaseD C-terminal) domain was dispensable for the mitotic and meiotic functions. Although DNA helicase activity of Sgs1 was not required for Sgs1 to complement the meiotic functions, a deletion of helicase motifs III-IV (842-1046 amino acid) abolished the complementing activity of Sgs1, indicating that a structurally intact helicase domain is necessary for Sgs1 to fulfill its meiotic functions.