Involvement of topoisomerase III in telomere-telomere recombination

Telomere maintenance is required for chromosome stability, and telomeres are typically replicated by the action of telomerase. In both mammalian tumor and yeast cells that lack telomerase, telomeres are maintained by an alternative (ALT) recombination mechanism. In yeast, Sgs1p and its associated type IA topoisomerase, Top3p, may work coordinately in removing Holliday junction intermediates from a crossover-producing recombination pathway. Previous studies have also indicated that Sgs1 helicase acts in a telomere recombination pathway. Here we show that topoisomerase III is involved in telomere-telomere recombination. The recovery of telomere recombination-dependent survivors in a telomerase-minus yeast strain was dependent on Top3p catalytic activity. Moreover, the RIF1 and RIF2 genes are required for the establishment of TOP3/SGS1-dependent telomere-telomere recombination. In human Saos-2 ALT cells, human topoisomerase IIIalpha (hTOP3alpha) also contributes to telomere recombination. Strikingly, the telomerase activity is clearly enhanced in surviving si-hTOP3alpha Saos-2 ALT cells. Altogether, the present results suggest a potential role for hTOP3alpha in dissociating telomeric structures in telomerase-deficient cells, providing therapeutic implications in human tumors.     

A role for topoisomerase III in a recombination pathway alternative to RuvABC

The physiological role of topoisomerase III is unclear for any organism. We show here that the removal of topoisomerase III in temperature sensitive topoisomerase IV mutants in Escherichia coli results in inviability at the permissive temperature. The removal of topoisomerase III has no effect on the accumulation of catenated intermediates of DNA replication, even when topoisomerase IV activity is removed. Either recQ or recA null mutations, but not helD null or lexA3, partially rescued the synthetic lethality of the double topoisomerase III/IV mutant, indicating a role for topoisomerase III in recombination. We find a bias against deleting the gene encoding topoisomerase III in ruvC53 or DeltaruvABC backgrounds compared with the isogenic wild-type strains. The topoisomerase III RuvC double mutants that can be constructed are five- to 10-fold more sensitive to UV irradiation and mitomycin C treatment and are twofold less efficient in transduction efficiency than ruvC53 mutants. The overexpression of ruvABC allows the construction of the topoisomerase III/IV double mutant. These data are consistent with a role for topoisomerase III in disentangling recombination intermediates as an alternative to RuvABC to maintain the stability of the genome.     

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 polyubiquitin gene is essential for meiosis in fission yeast

We isolated a novel sporulation-deficient mutant of Schizosaccharomyces pombe. The mutant did not have a mitotic growth defect but aborted meiosis at the first or the second division with condensed chromosomes that failed to separate, abnormal spindle(s), and disintegrated spindle pole bodies (SPBs). During the first division, the centromeres were pulled to near the spindle poles but condensed divalent chromosomes remained at the center. The failure to proceed to anaphase was also observed during a time-lapse recording of a SPB protein tagged with green fluorescent protein. The polyubiquitin gene ubi4(+), which encoded eight ubiquitins fused in tandem, complemented this mutant. The mutation, an A to G substitution, was identified within the ubi4(+) gene at the ATG initiation codon. Disruption of the ubi4(+) gene produced the same phenotypes. The ubi4(+) mRNA was strongly induced for meiosis. However, ubiquitin increases only slightly, suggesting that the role of the polyubiquitin gene is to supply ubiquitin that is consumed by unidentified mechanisms. Before the ubi4 mutant cells entered meiosis, ubiquitin was greatly decreased indicating that shortage of ubiquitin caused abortion of meiosis. This work provides insights for the role of polyubiquitin gene and importance of ubiquitination in SPB integrity at the meiotic divisions.     

Changes in chromatin structure at recombination initiation sites during yeast meiosis.

Transient double-strand breaks (DSBs) occur during Saccharomyces cerevisiae meiosis at recombination hot spots and are thought to initiate most, if not all, homologous recombination between chromosomes. To uncover the regulatory mechanisms active in DSB formation, we have monitored the change in local chromatin structure at the ARG4 and CYS3 recombination hot spots over the course of meiosis. Micrococcal nuclease (MNase) digestion of isolated meiotic chromatin followed by indirect end-labeling revealed that the DSB sites in both loci are hypersensitive to MNase and that their sensitivity increases 2- to 4-fold prior to the appearance of meiotic DSBs and recombination products. Other sensitive sites are not significantly altered. The study of hyper- and hypo-recombinogenic constructs at the ARG4 locus, also revealed that the MNase sensitivity at the DSB site correlates with both the extent of DSBs and the rate of gene conversion. These results suggest that the local chromatin structure and its modification in early meiosis play an important role in the positioning and frequency of meiotic DSBs, leading to meiotic recombination.     

The Arabidopsis homologue of Xrcc3 plays an essential role in meiosis

The eukaryotic RecA homologue Rad51 is a key factor in homologous recombination and recombinational repair. Rad51-like proteins have been identified from yeast (Rad55, Rad57 and Dmc1) to vertebrates (Rad51B, Rad51C, Rad51D, Xrcc2, Xrcc3 and Dmc1). These Rad51-like proteins are all members of the genetic recombination and DNA damage repair pathways. The sequenced genome of Arabidopsis thaliana encodes putative homologues of all six vertebrate Rad51-like proteins. We have identified and characterized an Arabidopsis mutant defective for one of these, AtXRCC3, the homologue of XRCC3. atxrcc3 plants are sterile, while they have normal vegetative development. Cytological observation shows that the atxrcc3 mutation does not affect homologous chromosome synapsis, but leads to chromosome fragmentation after pachytene, thus disrupting both male and female gametogenesis. This study shows an essential role for AtXrcc3 in meiosis in plants and possibly in other higher eukaryotes. Furthermore, atxrcc3 cells and plants are hypersensitive to DNA-damaging treatments, supporting the involvement of this Arabidopsis Rad51-like protein in recombinational repair.     

The role of OsCOM1 in homologous chromosome synapsis and recombination in rice meiosis

COM1/SAE2 is a highly conserved gene from yeast to higher eukaryotes. Its orthologs, known to cooperate with the MRX complex (Mre11/Rad50/Xrs2), are required for meiotic DNA double‐strand break (DSB) ends resection and specific mitotic DSB repair events. Here, the rice (Oryza sativa, 2n = 2x = 24) COM1/SAE2 homolog was identified through positional cloning, termed OsCOM1. Four independent mutants of OsCOM1 were isolated and characterized. In Oscom1 mutants, synaptonemal complex (SC) formation, homologous pairing and recombination were severely inhibited, whereas aberrant non‐homologous chromosome entanglements occurred constantly. Several key meiotic proteins, including ZEP1 and OsMER3, were not loaded normally onto chromosomes in Oscom1 mutants, whereas the localization of OsREC8, PAIR2 and PAIR3 seemed to be normal. Moreover, OsCOM1 was loaded normally onto meiotic chromosomes in Osrec8, zep1 and Osmer3 mutants, but could not be properly loaded in Osam1, pair2 and OsSPO11‐1^RNAi plants. These results provide direct evidence for the functions of OsCOM1 in promoting homologous synapsis and recombination in rice meiosis.     

The yeast MSH1 gene is not involved in DNA repair or recombination during meiosis

Six strong homologs of the bacterial MutS DNA mismatch repair (MMR) gene have been identified in the yeast Saccharomyces cerevisiae. With the exception of the MSH1 gene, the involvement of each homolog in DNA repair and recombination during meiosis has been determined previously. Five of the homologs have been demonstrated to act in meiotic DNA repair (MSH2, MSH3, MSH6 and MSH4) and/or meiotic recombination (MSH4 and MSH5). Unfortunately the loss of mitochondrial function that results from deletion of MSH1 disrupts meiotic progression, precluding an analysis of MSH1 function in meiotic DNA repair and recombination. However, the recent identification of two separation-of-function alleles of MSH1 that interfere with protein function but still maintain functional mitochondria allow the meiotic activities of MSH1 to be determined. We show that the G776D and F105A alleles of MSH1 exhibit no defects in meiotic recombination, repair base-base mismatches and large loop mismatches efficiently during meiosis, and have high levels of spore viability. These data indicate that the MSH1 protein, unlike other MutS homologs in yeast, plays no role in DNA repair or recombination during meiosis.     

Immediate visualization of recombination events and chromosome segregation defects in fission yeast meiosis

Chromosoma - Schizosaccharomyces pombe, also known as fission yeast, is an established model for studying chromosome biological processes. Over the years, research employing fission yeast has made...     

Effect of the DNA topoisomerase II inhibitor VP-16 on illegitimate recombination in yeast chromosomes

Etoposide and teniposide, derivatives of podophyllotoxin, are inhibitors of DNA topoisomerase II and are potent anticancer agents. An adverse effect linked to the use of these drugs is the development of acute myeloid leukemia, a disorder usually associated with chromosomal translocation. To examine podophyllotoxin-induced DNA rearrangement, we developed an assay system to measure illegitimate recombination in Saccharomyces cerevisiae chromosomes. This approach uses juxtaposed CAN1-CYH2 negative selection markers that are introduced into the LEU2 locus, which is located on chromosome III, in a yeast strain carrying the mutated can1 and cyh2 genes. Upon formation of a deletion over the active CAN1-CYH2 genes, a cell becomes resistant to both canavanine and cycloheximide. To introduce drugs into the cell, we used a yeast strain carrying an ISE2 mutation, thereby making the cell drug-permeable. Here we show that treatment of cells with etoposide (VP-16) increases the rate of illegitimate recombination in yeast, indicating that VP-16 stimulates DNA topoisomerase-mediated illegitimate recombination. Structural analysis of the resulting recombinants indicate that most are formed by deletion mutations on chromosome III, which take place between short homologous regions of DNA. We propose a model for illegitimate recombination, in which VP-16 facilitates formation of a cleavable complex between DNA topoisomerase II and DNA, thus promoting DNA double-strand breakage with the resulting DNA ends joined by a non-homologous mechanism.     

The calcineurin regulator sra plays an essential role in female meiosis in Drosophila

Modulatory calcineurin-interacting proteins (MCIPs)--also termed regulators of calcineurin (RCNs), calcipressins, or DSCR1 (Down's syndrome critical region 1)--are highly conserved regulators of calcineurin, a Ca(2+)/calmodulin-dependent protein phosphatase . Although overexpression experiments in several organisms have revealed that MCIPs inhibit calcineurin activity , their in vivo functions remain unclear. Here, we show that the Drosophila MCIP sarah (sra) is essential for meiotic progression in oocytes. Eggs from sra null mothers are arrested at anaphase of meiosis I. This phenotype was due to loss of function of sra specifically in the female germline. Sra is physically associated with the catalytic subunit of calcineurin, and its overexpression suppresses the phenotypes caused by constitutively activated calcineurin, such as rough eye or loss of wing veins. Hyperactivation of calcineurin signaling in the germline cells resulted in a meiotic-arrest phenotype, which can also be suppressed by overexpression of Sra. All these results support the hypothesis that Sra regulates female meiosis by controlling calcineurin activity in the germline. To our knowledge, this is the first unambiguous demonstration that the regulation of calcineurin signaling by MCIPs plays a critical role in a defined biological process.     

Cytokinesis in yeast meiosis depends on the regulated removal of Ssp1p from the prospore membrane

Intracellular budding is a developmentally regulated type of cell division common to many fungi and protists. In Saccaromyces cerevisiae, intracellular budding requires the de novo assembly of membranes, the prospore membranes (PSMs) and occurs during spore formation in meiosis. Ssp1p is a sporulation-specific protein that has previously been shown to localize to secretory vesicles and to recruit the leading edge protein coat (LEP coat) proteins to the opening of the PSM. Here, we show that Ssp1p is a multidomain protein with distinct domains important for PI(4,5)P(2) binding, binding to secretory vesicles and inhibition of vesicle fusion, interaction with LEP coat components and that it is subject to sumoylation and degradation. We found non-essential roles for Ssp1p on the level of vesicle transport and an essential function of Ssp1p to regulate the opening of the PSM. Together, our results indicate that Ssp1p has a domain architecture that resembles to some extent the septin class of proteins, and that the regulated removal of Ssp1p from the PSM is the major step underlying cytokinesis in yeast sporulation.     

水稻减数分裂过程中染色体重组交换行为

减数分裂在有性生物的生命周期中起着非常重要的作用,其过程高度保守。减数分裂过程中,染色体配对、联会和重组是遗传变异的源泉、有性生物进化的推动力,也是减数分裂研究的热点之一。在植物减数分裂研究中,还不可能直接观察到染色体在减数分裂过程中的交换情况,往往是通过交换后群体的遗传分析来推测。文章通过图示基因型方法分析了来自花药培养的32个水稻双单倍体(DH)株系,发现少数株系某些染色体部分区段为杂合状态,并利用STS分子标记对杂合状态的真实性进行了验证,推测杂合区段的出现可能与染色体的修复不完全或修复错误有关。研究结果为解释植物减数分裂的机理提供了直接证据。     

Interaction between yeast sgs1 helicase and DNA topoisomerase III

The Saccharomyces cerevisiae Sgs1 protein is a member of the RecQ family of DNA helicases that includes the human Bloom's syndrome and Werner's syndrome proteins. In this work, we report studies on the interaction between Sgs1 and DNA topoisomerase III in vitro and in vivo. Affinity chromatography experiments with various fragments of Sgs1, a 1447-amino acid polypeptide, suggested that its N-terminal one-fifth was sufficient for interaction with DNA topoisomerase III. Gel electrophoretic mobility shift assays also indicated that a fragment Sgs1(1-283), containing residues 1-283, inhibited the binding of DNA topoisomerase III to single-stranded DNA. A shorter protein fragment containing residues 1-107 also showed partial inhibition in these assays. Studies of a sgs1 top1 double mutant lacking both Sgs1 and DNA topoisomerase I showed that the slow growth phenotype of this double mutant is suppressed by expressing full-length Sgs1, but not Sgs1 without the N-terminal 107 amino acid residues. In sgs1 top3 cells devoid of DNA topoisomerase III, however, expression of full-length Sgs1 or Sgs1 lacking the N-terminal 107 amino acid residues has the same effect of reducing the growth rate of the double mutant. These in vitro and in vivo data indicate that Sgs1 and DNA topoisomerase III physically interact and that this interaction is physiologically significant.     

The double-stranded DNA helix in recombination at meiosis.

The nature of meiotic genetic recombination was resolved at the DNA level by the 1953 Watson and Crick model. What remains to be determined are the roles of the various recombination proteins and the distribution and localization of recombination events in the meiotic prophase nucleus.     

Induction of meiosis in yeast

Summary Meiosis is induced in yeast by a sequence of events starting with the disappearance of glucose from the growth medium. Preparation for meiosis during the period of the premeiotic mitoses involves: (1) Development of the ability to metabolize acetate; and (2) establishment and maintenance of sufficiently high concentrations of RNA and protein in the cell to support an extensive biosynthetic activity. A new regulation model is proposed on the basis of the results obtained.     

The novel male meiosis recombination regulator coordinates the progression of meiosis prophase I

Meiosis is a specialized cell division for producing haploid gametes in sexually reproducing organisms. In this study, we have independently identified a novel meiosis protein male meiosis recombination regulator (MAMERR)/4930432K21Rik and showed that it is indispensable for meiosis prophase I progression in male mice. Using super-resolution structured illumination microscopy, we found that MAMERR functions at the same double-strand breaks as the replication protein A and meiosis-specific with OB domains/spermatogenesis associated 22 complex. We generated a Mamerr-deficient mouse model by deleting exons 3–6 and found that most of Mamerr^−/− spermatocytes were arrested at pachynema and failed to progress to diplonema, although they exhibited almost intact synapsis and progression to the pachytene stage along with XY body formation. Further mechanistic studies revealed that the recruitment of DMC1/RAD51 and heat shock factor 2–binding protein in Mamerr^−/− spermatocytes was only mildly impaired with a partial reduction in double-strand break repair, whereas a substantial reduction in ubiquitination on the autosomal axes and on the XY body appeared as a major phenotype in Mamerr^−/− spermatocytes. We propose that MAMERR may participate in meiotic prophase I progression by regulating the ubiquitination of key meiotic proteins on autosomes and XY chromosomes, and in the absence of MAMERR, the repressed ubiquitination of key meiotic proteins leads to pachytene arrest and cell death.     

A role for topoisomerase III in Escherichia coli chromosome segregation

The cellular function of Escherichia coli topoisomerase III remains elusive. We show that rescue of temperature‐sensitive mutants in parE and parC (encoding the subunits of the chromosomal decatenase topoisomerase IV) at restrictive temperatures by high‐copy suppressors is strictly dependent on topB (encoding topoisomerase III). Double mutants of parEΔtopB and parCΔtopB were barely viable, grew slowly, and were defective in chromosome segregation at permissive temperatures. The topB mutant phenotype did not result from accumulation of toxic recombination intermediates, because it was not relieved by mutations in either recQ or recA. In addition, in an otherwise wild‐type genetic background, ΔtopB cells treated with the type II topoisomerase inhibitor novobiocin displayed aberrant chromosome segregation. This novobiocin sensitivity was attributable to an increased demand for topoisomerase IV and is unlikely to define a new role for topoisomerase III; therefore, these results suggest that topoisomerase III participates in orderly and efficient chromosome segregation in E. coli.