Meiotic double-strand breaks in yeast artificial chromosomes containing human DNA.

Meiotic recombination in the yeast Saccharomyces cerevisiae is initiated by double-strand breaks (DSB) in chromosomal DNA. These DSB, which can be mapped in the rad 50S mutant yeast strain, are caused by a topoisomerase II-like enzyme, the protein Spo11. Evidence suggests that this protein is located in the axial element of the meiotic chromosome which implies that the DSB are located in these chromosomes in the vicinity of the bases of the DNA loops. We have found that in the yeast artificial chromosomes carrying human DNA, at the level of resolution obtained by pulsed field gel electrophoresis (PFGE), the meiotic DSB in the diploid yeast are co-localized with the DNase I hypersensitive sites (HS) in a haploid strain of yeast. These HS are located close to sequences which, under stress, have the potential to form secondary structures containing unpaired nucleotides. Clusters of such sequences could be a hallmark of the bases of the chromatin loops.     

The repair of double-strand breaks and S1 nuclease-sensitive sites can be monitored chromosome-specifically in Saccharomyces cerevisiae using pulsed-field gel electrophoresis

Repair under non-growth conditions of DNA double-stranded breaks (DSBs) and S1 nuclease-sensitive sites (SSSs; e.g. DNA damage which is processed by in vitro treatment with S1 nuclease to DSBs) induced by [60Co]-gamma-rays (200 Gy; anoxic conditions) was monitored in a diploid repair-competent strain of Saccharomyces cerevisiae. We used pulsed-field gel electrophoresis (PFGE), which allows the separation of chromosome-sized yeast DNA molecules, to determine the number of DSBs and SSSs in individual chromosome species of yeast. Our results indicate that SSSs which have been regarded as clusters of base damage in opposite DNA strands are repaired efficiently in a repair-proficient diploid strain of yeast. The time course of SSS repair is comparable to the one of DSB repair, indicating similarities in the molecular mechanism. Both types of repair kinetics are different for different chromosome species.     

Pulsed-field gel electrophoresis of chromosomal DNA of Saccharomyces pastorianus after exposure to x-rays (30–50 keV) and neutrons (14 MeV)

Chromosomes of budding yeast Saccharomyces pastorianus were used to determine the extent of DNA double-strand breaks (DSBs) induced by x-rays (30-50 keV) and 14 MeV neutrons. The yeast chromosomes were separated by pulsed-field gel electrophoresis (PFGE) and the proportion of unbroken molecules corresponding to the largest chromosome no. IV (1500 kbp) was used to calculate the DSB frequency assuming a random distribution of hits. To determine the protective contribution of the cell environment, chromosomes embedded in agarose plugs as well as intact yeast cells, were irradiated under conditions completely inhibiting DNA repair. Following irradiation, the intact cells were also embedded in agarose plugs and the chromosomes isolated to perform PFGE. All radiation experiments resulted in a linear dose-effect curve for DSBs. For both radiation qualities, the yield of DSBs for exposed isolated chromosomes exceeded that for intact yeast cells by a factor of 13. The relative biological effectiveness (RBE) of 14 MeV neutrons in the induction of DNA DSBs was about 2.5. This figure was found to be identical for the in vivo and in vitro exposure of yeast chromosomes (neutrons 36.7 and 2.8, x-rays 14.5 and 1.1 x 10(-8) DSB x Bp-1 Gy-1 for isolated DNA and intact cells, respectively).     

Heterochromatin is refractory to gamma-H2AX modification in yeast and mammals

Double-strand break (DSB) damage in yeast and mammalian cells induces the rapid ATM (ataxia telangiectasia mutated)/ATR (ataxia telangiectasia and Rad3 related)-dependent phosphorylation of histone H2AX (gamma-H2AX). In budding yeast, a single endonuclease-induced DSB triggers gamma-H2AX modification of 50 kb on either side of the DSB. The extent of gamma-H2AX spreading does not depend on the chromosomal sequences. DNA resection after DSB formation causes the slow, progressive loss of gamma-H2AX from single-stranded DNA and, after several hours, the Mec1 (ATR)-dependent spreading of gamma-H2AX to more distant regions. Heterochromatic sequences are only weakly modified upon insertion of a 3-kb silent HMR locus into a gamma-H2AX-covered region. The presence of heterochromatin does not stop the phosphorylation of chromatin more distant from the DSB. In mouse embryo fibroblasts, gamma-H2AX distribution shows that gamma-H2AX foci increase in size as chromatin becomes more accessible. In yeast, we see a high level of constitutive gamma-H2AX in telomere regions in the absence of any exogenous DNA damage, suggesting that yeast chromosome ends are transiently detected as DSBs.     

Chromosome integrity at a double-strand break requires exonuclease 1 and MRX

The continuity of duplex DNA is generally considered a prerequisite for chromosome continuity. However, as previously shown in yeast as well as human cells, the introduction of a double-strand break (DSB) does not generate a chromosome break (CRB) in yeast or human cells. The transition from DSB to CRB was found to be under limited control by the tethering function of the RAD50/MRE11/XRS2 (MRX) complex. Using a system for differential fluorescent marking of both sides of an endonuclease-induced DSB in single cells, we found that nearly all DSBs are converted to CRBs in cells lacking both exonuclease 1 (EXO1) activity and MRX complex. Thus, it appears that some feature of exonuclease processing or resection at a DSB is critical for maintaining broken chromosome ends in close proximity. In addition, we discovered a thermal sensitive (cold) component to CRB formation in an MRX mutant that has implications for chromosome end mobility and/or end-processing.     

Estimation of ruminal bacteriophage numbers by pulsed-field gel electrophoresis and laser densitometry.

To investigate phage activity in the rumen, a method for quantifying phage has been developed. By differential centrifugation and ultrafiltration, phage particles were separated and concentrated from ruminal fluid. Linear double-stranded DNA from this fraction containing predominantly tailed phage was isolated and separated by size, using pulsed-field gel electrophoresis (PFGE). Laser densitometry of gel photographs allowed the numbers of phages with DNA in each size region to be calculated and, therefore, the total numbers per milliliter of ruminal fluid to be estimated. Phage numbers were estimated to be between 3 x 10(9) and 1.6 x 10(10) particles ml of ruminal fluid-1. The phage population, as gauged by the appearance of DNA on PFGE gels, had two major components. A broad region of DNA between 30 and 200 kb was always present on PFGE gels. It appears this region comprises DNA from a great many different phages and would include most of the temperate phages. In addition, discrete DNA bands ranging in size from 10 to 850 kb were frequently observed. DNA from one such band, of 12 kb in size, was shown to consist primarily of a single DNA type, suggesting that it originated from a specific phage. It is postulated that the discrete bands are due to epidemics or blooms of phage activity from specific, probably lytic, phages. The method that has been developed will greatly enhance future investigations into the interactions between the ruminal phage population, the ruminal bacterial population, and animal nutrition and growth.(ABSTRACT TRUNCATED AT 250 WORDS)     

Factors That Affect the Location and Frequency of Meiosis-Induced Double-Strand Breaks in Saccharomyces Cerevisiae

Double-strand DNA breaks (DSBs) initiate meiotic recombination in Saccharomyces cerevisiae. DSBs occur at sites that are hypersensitive in nuclease digests of chromatin, suggesting a role for chromatin structure in determining DSB location. We show here that the frequency of DSBs at a site is not determined simply by DNA sequence or by features of chromatin structure. An arg4-containing plasmid was inserted at several different locations in the yeast genome. Meiosis-induced DSBs occurred at similar sites in pBR322-derived portions of the construct at all insert loci, and the frequency of these breaks varied in a manner that mirrored the frequency of meiotic recombination in the arg4 portion of the insert. However, DSBs did not occur in the insert-borne arg4 gene at a site that is frequently broken at the normal ARG4 locus, even though the insert-borne arg4 gene and the normal ARG4 locus displayed similar DNase I hypersensitivity patterns. Deletions that removed active DSB sites from an insert at HIS4 restored breaks to the insert-borne arg4 gene and to a DSB site in flanking chromosomal sequences. We conclude that the frequency of DSB at a site can be affected by sequences several thousands nucleotides away and suggest that this is because of competition between DSB sites for locally limited factors.     

DNA Dynamics during Early Double-Strand Break Processing Revealed by Non-Intrusive Imaging of Living Cells

Chromosome breakage is a major threat to genome integrity. The most accurate way to repair DNA double strand breaks (DSB) is homologous recombination (HR) with an intact copy of the broken locus. Mobility of the broken DNA has been seen to increase during the search for a donor copy. Observing chromosome dynamics during the earlier steps of HR, mainly the resection from DSB ends that generates recombinogenic single strands, requires a visualization system that does not interfere with the process, and is small relative to the few kilobases of DNA that undergo processing. Current visualization tools, based on binding of fluorescent repressor proteins to arrays of specific binding sites, have the major drawback that highly-repeated DNA and lengthy stretches of strongly bound protein can obstruct chromatin function. We have developed a new, non-intrusive method which uses protein oligomerization rather than operator multiplicity to form visible foci. By applying it to HO cleavage of the MAT locus on Saccharomyces cerevisiae chromosome III, we provide the first real-time analysis of resection in single living cells. Monitoring the dynamics of a chromatin locus next to a DSB revealed transient confinement of the damaged chromatin region during the very early steps of resection, consistent with the need to keep DNA ends in contact. Resection in a yku70 mutant began ∼10 min earlier than in wild type, defining this as the period of commitment to homology-dependent repair. Beyond the insights into the dynamics and mechanism of resection, our new DNA-labelling and -targeting method will be widely applicable to fine-scale analysis of genome organization, dynamics and function in normal and pathological contexts.     

Chromosome break-induced DNA replication leads to nonreciprocal translocations and telomere capture.

In yeast, broken chromosomes can be repaired by recombination, resulting in nonreciprocal translocations. In haploid cells suffering an HO endonuclease-induced, double-strand break (DSB), nearly 2% of the broken chromosome ends recombined with a sequence near the opposite chromosome end, which shares only 72 bp of homology with the cut sequence. This produced a repaired chromosome with the same 20-kb sequence at each end. Diploid strains were constructed in which the broken chromosome shared homology with the unbroken chromosome only on the centromere-proximal side of the DSB. More than half of these cells repaired the DSB by copying sequences distal to the break from the unbroken template chromosome. All these events were RAD52 dependent. Pedigree analysis established that DSBs occurring in G1 were repaired by a replicative mechanism, producing two identical daughter cells. We discuss the implications of these data in understanding telomerase-independent replication of telomeres, gene amplification, and the evolution of chromosomal ends.     

Use of a Ring Chromosome and Pulsed-Field Gels to Study Interhomolog Recombination, Double-Strand DNA Breaks and Sister-Chromatid Exchange in Yeast

We describe a system that uses pulsed-field gels for the physical detection of recombinant DNA molecules, double-strand DNA breaks (DSB) and sister-chromatid exchange in the yeast Saccharomyces cerevisiae. The system makes use of a circular variant of chromosome III (Chr. III). Meiotic recombination between this ring chromosome and a linear homolog produces new molecules of sizes distinguishable on gels from either parental molecule. We demonstrate that these recombinant molecules are not present either in strains with two linear Chr. III molecules or in rad50 mutants, which are defective in meiotic recombination. In conjunction with the molecular endpoints, we present data on the timing of commitment to meiotic recombination scored genetically. We have used x-rays to linearize circular Chr. III, both to develop a sensitive method for measuring frequency of DSB and as a means of detecting double-sized circles originating in part from sister-chromatid exchange, which we find to be frequent during meiosis.     

Binding of Multiple Rap1 Proteins Stimulates Chromosome Breakage Induction during DNA Replication

Telomeres, the ends of linear eukaryotic chromosomes, have a specialized chromatin structure that provides a stable chromosomal terminus. In budding yeast Rap1 protein binds to telomeric TG repeat and negatively regulates telomere length. Here we show that binding of multiple Rap1 proteins stimulates DNA double-stranded break (DSB) induction at both telomeric and non-telomeric regions. Consistent with the role of DSB induction, Rap1 stimulates nearby recombination events in a dosage-dependent manner. Rap1 recruits Rif1 and Rif2 to telomeres, but neither Rif1 nor Rif2 is required for DSB induction. Rap1-mediated DSB induction involves replication fork progression but inactivation of checkpoint kinase Mec1 does not affect DSB induction. Rap1 tethering shortens artificially elongated telomeres in parallel with telomerase inhibition, and this telomere shortening does not require homologous recombination. These results suggest that Rap1 contributes to telomere homeostasis by promoting chromosome breakage.     

RSC mobilizes nucleosomes to improve accessibility of repair machinery to the damaged chromatin

Repair of DNA double-strand breaks (DSBs) protects cells and organisms, as well as their genome integrity. Since DSB repair occurs in the context of chromatin, chromatin must be modified to prevent it from inhibiting DSB repair. Evidence supports the role of histone modifications and ATP-dependent chromatin remodeling in repair and signaling of chromosome DSBs. The key questions are, then, what the nature of chromatin altered by DSBs is and how remodeling of chromatin facilitates DSB repair. Here we report a chromatin alteration caused by a single HO endonuclease-generated DSB at the Saccharomyces cerevisiae MAT locus. The break induces rapid nucleosome migration to form histone-free DNA of a few hundred base pairs immediately adjacent to the break. The DSB-induced nucleosome repositioning appears independent of end processing, since it still occurs when the 5'-to-3' degradation of the DNA end is markedly reduced. The tetracycline-controlled depletion of Sth1, the ATPase of RSC, or deletion of RSC2 severely reduces chromatin remodeling and loading of Mre11 and Yku proteins at the DSB. Depletion of Sth1 also reduces phosphorylation of H2A, processing, and joining of DSBs. We propose that RSC-mediated chromatin remodeling at the DSB prepares chromatin to allow repair machinery to access the break and is vital for efficient DSB repair.     

Heavy ion-induced DNA double-strand breaks in yeast

Induction of DSBs in the diploid yeast, Saccharomyces cerevisiae, was measured by pulsed-field gel electrophoresis (PFGE) after the cells had been exposed on membrane filters to a variety of energetic heavy ions with values of linear energy transfer (LET) ranging from about 2 to 11,500 keV/microm, (241)Am alpha particles, and 80 keV X rays. After irradiation, the cells were lysed, and the chromosomes were separated by PFGE. The gels were stained with ethidium bromide, placed on a UV transilluminator, and analyzed using a computer-coupled camera. The fluorescence intensities of the larger bands were found to decrease exponentially with dose or particle fluence. The slope of this line corresponds to the cross section for at least one double-strand break (DSB), but closely spaced multiple breaks cannot be discriminated. Based on the known size of the native DNA molecules, breakage cross sections per base pair were calculated. They increased with LET until they reached a transient plateau value of about 6 x 10(-7) microm(2) at about 300-2000 keV/microm; they then rose for the higher LETs, probably reflecting the influence of delta electrons. The relative biological effectiveness for DNA breakage displays a maximum of about 2.5 around 100-200 keV/microm and falls below unity for LET values above 10(3) keV/microm. For these yeast cells, comparison of the derived breakage cross sections with the corresponding cross section for inactivation derived from the terminal slope of the survival curves shows a strong linear relationship between these cross sections, extending over several orders of magnitude.     

Spo11-accessory proteins link double-strand break sites to the chromosome axis in early meiotic recombination

Meiotic recombination between homologous chromosomes initiates via programmed DNA double-strand breaks (DSBs), generated by complexes comprising Spo11 transesterase plus accessory proteins. DSBs arise concomitantly with the development of axial chromosome structures, where the coalescence of axis sites produces linear arrays of chromatin loops. Recombining DNA sequences map to loops, but are ultimately tethered to the underlying axis. How and when such tethering occurs is currently unclear. Using ChIPchip in yeast, we show that Spo11-accessory proteins Rec114, Mer2, and Mei4 stably interact with chromosome axis sequences, upon phosphorylation of Mer2 by S phase Cdk. This axis tethering requires meiotic axis components (Red1/Hop1) and is modulated in?a domain-specific fashion by cohesin. Loss of Rec114, Mer2, and Mei4 binding correlates with loss of DSBs. Our results strongly suggest that hotspot sequences become tethered to axis sites by the DSB machinery prior to DSB formation.     

Correlation between premeiotic DNA replication and chromatin transition at yeast recombination initiation sites

The DNA double-strand breaks (DSBs) that initiate meiotic recombination in Saccharomyces cerevisiae are preceded first by DNA replication and then by a chromatin transition at DSB sites. This chromatin transition, detected as a quantitative increase in micrococcal nuclease (MNase) sensitivity, occurs specifically at DSB sites and not at other MNase-sensitive sites. Replication and DSB formation are directly linked: breaks do not form if replication is blocked, and delaying replication of a region also delays DSB formation in that region. We report here experiments that examine the relationship between replication, the DSB-specific chromatin transition and DSB formation. Deleting replication origins (and thus delaying replication) on the left arm of one of the two parental chromosomes III affects DSBs specifically on that replication-delayed arm and not those on the normally replicating arm. Thus, replication timing determines DSB timing in cis. Delaying replication on the left arm of chromosome III also delays the chromatin transition at DSB sites on that arm but not on the normally replicating right arm. Since the chromatin transition precedes DSB formation and requires the function of many genes necessary for DSB formation, these results suggest that initial events for DSB formation in chromatin are coupled with premeiotic DNA replication.     

The role of the repair of double-stranded DNA breaks in the radioresistance of yeast cells

The role of DNA double-strand break (DSB) repair in radioresistance of Saccharomyces cerevisiae G1 cells is discussed. The contribution of rapid and slow DNA DSB repair to radioresistance of diploid yeast has been estimated. The contribution of the DNA DSB repair involving no homologous chromosome interaction is shown to be insignificant in comparison with the recombinational repair. The rapid DNA DSB repair efficiency calculation method based on the proposed yeast radiation inactivation model is given. The calculations are in a satisfactory agreement with the experimental data. Possible mechanisms of radiation induction of lethal sectoring in yeast are discussed. This phenomenon is supposed to be due to the DNA DSB processing during vegetative division of irradiated cells. A general scheme of radiation inactivation of yeast cells is proposed.     

Cell Cycle-Dependent Regulation of Double-Strand Break Repair: A Role for the CDK

DNA Double-Strand Breaks (DSBs) are dangerous lesions that can lead to genomic instability and to cell death. Eukaryotic cells repair DSBs either by non-homologous end joining (NHEJ) or by homologous recombination (HR). Recent work has allowed to study the ability of yeast cells to repair a single, chromosomal DSB, at different stages of the cell cycle. Yeast cells repair the broken chromosome during the G1 stage only by NHEJ, whereas HR is the mechanism of choice during the rest of the cell cycle. HR does not require duplicated chromatids or passage through S-phase. Control over the fate of the broken chromosome is exerted by Clb-CDK activity, which is required to carry out the first step of HR, ssDNA resection. Similar results in other organisms suggest that this control is a conserved feature in all eukaryotes.     

Pulsed-field gel electrophoresis in the measurement of DNA double-strand break repair in xrs-6 and CHO cell lines: DNA degradation under some conditions interferes with the assessment of double-strand break rejoining.

Pulsed-field gel electrophoresis (PFGE) is a sensitive assay for DNA double-strand breaks (DSBs). The application of PFGE to the measurement of DSB rejoining requires attention to conditions after irradiation. When cells are irradiated and incubated while encapsulated in agarose, DNA DSB rejoining appears incomplete or absent due to DNA degradation artifacts. Using PFGE we have measured the DSB rejoining defect in xrs-6 cells and shown how DNA degradation can affect the results.