DNA-bound proteins contribute much more than soluble intracellular compounds to the intrinsic protection against radiation-induced DNA strand breaks in human cells

To assess the role of soluble intracellular compounds and DNA-bound proteins in the intrinsic protection against radiation-induced DNA strand breaks, the alkaline unwinding technique was applied to cellular, nuclear, and nucleoid monolayers. It was found that, when the soluble intracellular compounds were removed from human fibroblasts by permeabilization (nuclear monolayers) and irradiated in a phosphate buffer containing 150 mM monovalent cations (Na+ and K+) and 0.8 mM MgCl2, the frequency of radiation-induced DNA strand breaks increased twofold. Removal of both soluble intracellular compounds and DNA-bound proteins from the cells by a pretreatment with 2 M NaCl (nucleoid monolayers) resulted in a 100-fold increase in the frequency of strand-break induction by gamma radiation. Expressed as percentage of total intrinsic protection against radiation-induced DNA strand breaks, DNA-bound protein contributed 99% compared to 1% by soluble intracellular compounds. Using a different experimental approach it was found that the radioprotective capacity of soluble intracellular compounds was equivalent to about 5 mM dimethyl sulfoxide (DMSO) and DNA-bound proteins to about 70 mM DMSO. It is concluded that DNA-bound proteins play a much greater role than soluble intracellular compounds in the intrinsic protection against radiation-induced DNA strand breaks in cultured human cells.     

The influence of chromatin structure on the frequency of radiation-induced DNA strand breaks: a study using nuclear and nucleoid monolayers

To assess the influence of chromatin structure on the frequency of radiation-induced DNA strand breaks, the alkaline unwinding technique was applied to nuclear and nucleoid monolayers. These chromatin substrates were prepared by treating human fibroblasts grown as monolayers with the nonionic detergent Triton X-100 and varying concentrations of cations. The chromatin structure was modified either by a stepwise removal of DNA-bound proteins by extraction in increasing concentrations of monovalent salt, or by the addition or deletion of mono- and divalent cations to condense or decondense the chromatin, respectively. It was found that the stepwise removal of DNA-bound proteins from the chromatin dramatically increased the frequency of radiation-induced DNA strand breaks. The DNA-bound proteins showed a qualitative difference in their ability to protect the DNA where proteins removed by salt concentrations above 1.0 M exerted the greatest protection. Furthermore, the frequency of radiation-induced DNA strand breaks was found to be 6 times lower in condensed chromatin than in decondensed chromatin and about 80 times lower than in protein-depleted chromatin. It is concluded that the presence of DNA-bound proteins and the folding of the chromatin into higher-order structures protect the DNA against radiation-induced strand breaks.     

Poly(ADP-ribose) polymerases PARP1 and PARP2 modulate topoisomerase II beta (TOP2B) function during chromatin condensation in mouse spermiogenesis

To achieve the specialized nuclear structure in sperm necessary for fertilization, dramatic chromatin reorganization steps in developing spermatids are required where histones are largely replaced first by transition proteins and then by protamines. This entails the transient formation of DNA strand breaks to allow for, first, DNA relaxation and then chromatin compaction. However, the nature and origin of these breaks are not well understood. We previously reported that these DNA strand breaks trigger the activation of poly(ADP-ribose) (PAR) polymerases PARP1 and PARP2 and that interference with PARP activation causes poor chromatin integrity with abnormal retention of histones in mature sperm and impaired embryonic survival. Here we show that the activity of topoisomerase II beta (TOP2B), an enzyme involved in DNA strand break formation in elongating spermatids, is strongly inhibited by the activity of PARP1 and PARP2 in vitro, and this is in turn counteracted by the PAR-degrading activity of PAR glycohydrolase. Moreover, genetic and pharmacological PARP inhibition both lead to increased TOP2B activity in murine spermatids in vivo as measured by covalent binding of TOP2B to the DNA. In summary, the available data suggest a functional relationship between the DNA strand break-generating activity of TOP2B and the DNA strand break-dependent activation of PARP enzymes that in turn inhibit TOP2B. Because PARP activity also facilitates histone H1 linker removal and local chromatin decondensation, cycles of PAR formation and degradation may be necessary to coordinate TOP2B-dependent DNA relaxation with histone-to-protamine exchange necessary for spermatid chromatin remodeling.     

Nucleosome rearrangement in human cells following short patch repair of DNA damaged by bleomycin.

We have examined the structure of newly repaired regions of chromatin in intact and permeabilized human cells following exposure to bleomycin (BLM). The average repair patch size (in permeabilized cells) was six to nine bases, following doses of 1-25 micrograms/mL BLM, and greater than 80% of the total repair synthesis was resistant to aphidicolin. In both intact and permeabilized cells, nascent repair patches were initially very sensitive to staphylococcal nuclease, analogous to repair induced by "long patch" agents, and are nearly absent from isolated nucleosome core DNA. Unlike long patch repair, however, the loss of nuclease sensitivity during subsequent chase periods was very slow in intact cells, or in permeabilized cells treated with a low dose of BLM (1 microgram/mL), and was abolished by treatment with hydroxyurea (HU) or aphidicolin (APC). The rate of repair patch ligation did not correlate with this slow rate of chromatin rearrangement since greater than 95% of the patches were ligated within 6 h after incorporation (even in the presence of HU or APC). In permeabilized cells, repair patches induced by either 5 or 25 micrograms/mL BLM, where significant levels of strand breaks occur in compact regions of chromatin, lost the enhanced nuclease sensitivity at a rate similar to that observed following long patch repair. This rapid rate of rearrangement was not affected by APC. These results indicate that short patch repair in linker regions of nucleosomes, and/or "open" regions of chromatin, involves much less nucleosome rearrangement than long patch repair or short patch repair in condensed chromatin domains.     

Chromatin condensation and differential sensitivity of mammalian and insect cells to DNA strand breaks induced by bleomycin

Bleomycin (BLM) induces DNA damage in living cells. In this report we analyzed the role of chromatin compactness in the differential response of mosquito (ATC-15) and mammalian (CHO) cells to DNA strand breaks induced by BLM. We used cells unexposed and exposed to sodium butyrate (NaB), which induces chromatin decondensation. By nucleoid sedimentation assay and digestions of nuclei with DNAse I, untreated mosquito cells (no BLM; no NaB) were shown to have more chromatin condensation than untreated CHO cells. By alkaline unwinding ATC-15 cells treated with NaB showed more BLM-induced DNA strand breaks than NaB-untreated CHO cells. The time-course of BLM-induced DNA damage to nuclear DNA was similar for NaB-untreated mammalian and insect cells, but with mosquito cells showing less DNA strand breaks, both at physiological temperatures and at 4 °C. However, when DNA repair was inhibited by low temperatures and chromatin was decondensed by NaB treatments, differences in BLM-induced DNA damage between these cells lines were no longer observed. In both cell lines, NaB did not affect BLM action on cell growth and viability. On the other hand, the low sensitivity of ATC-15 cells to BLM was reflected in their better growth efficiency. These cells exhibited a satisfactory growth at BLM doses that produced a permanent arrest of growth in CHO cells. The data suggest that mosquito cells might have linker DNAs shorter than those of mammalian cells, which would result in the observed both greater chromatin condensation and greater resistance to DNA damage induced by BLM as compared to CHO cells.     

Poly(ADP-ribosylated) histones in chromatin replication

Poly(ADP-ribosylation) of histones and several other nuclear proteins seem to participate in nuclear processes involving DNA strand breaks like repair, replication, or recombination. This is suggested from the fact that the enzyme poly(ADP-ribose) polymerase responsible for this modification is activated by DNA strand breaks produced in these nuclear processes. In this article I provide three lines of evidence supporting the idea that histone poly(ADP-ribosylation) is involved in chromatin replication. First, cellular lysates from rapidly dividing mouse or human cells in culture synthesize a significant number of oligo- in addition to mono(ADP-ribosylated) histones. Blocking the cells by treatment of cultures with 5 mM butyrate for 24 h or by serum or nutrient depletion results in the synthesis of only mono- but not of oligo(ADP-ribosylated) histones under the same conditions. Thus, the presence of oligo(ADP-ribosylated) histones is related to cell proliferation. Second, cellular lysates or nuclei isolated under mild conditions in the presence of spermine and spermidine and devoid of DNA strand breaks mainly synthesize mono(ADP-ribosylated) histones; introduction of a small number of cuts by DNase I or micrococcal nuclease results in a dramatic increase in the length of poly(ADP-ribose) attached to histones presumably by activation of poly(ADP-ribose) polymerase. Free ends of DNA that could stimulate poly(ADP-ribosylation) of histones are present at the replication fork. Third, putatively acetylated species of histone H4 are more frequently ADP-ribosylated than nonacetylated H4; the number of ADP-ribose groups on histone H4 was found to be equal or exceed by one the number of acetyl groups on this molecule. Since one recognized role of tetraacetylated H4 is its participation in the assembly of new nucleosomes, oligo(ADP-ribosylation) of H4 (and by extension of other histones) may function in new nucleosome formation. Based on these results I propose that poly(ADP-ribosylated) histones are employed for the assembly of histone complexes and their deposition on DNA during replication. Modified histones arise at the replication fork by activation of poly(ADP-ribose) polymerase by unligated Okazaki fragments.     

Direct stimulation of poly(ADP ribose) polymerase in permeabilized cells by double-stranded DNA oligomers

Poly(ADP ribosyl)ation, a post-translational modification of nuclear proteins catalyzed by poly (ADP ribose) polymerase, is an immediate response of most eukaryotic cells to DNA strand breaks and has been implicated in DNA repair and other cellular phenomena associated with DNA strand breakage. Poly(ADP ribose) polymerase activity levels have been frequently assayed by incubating permeabilized cells with radioactively labeled NAD+ as substrate. In such assays enzyme activation has routinely been achieved indirectly by prior exposure of living cells to carcinogens or by adding DNase I to permeabilized cells, thereby introducing strand breaks in chromosomal DNA. Here we show that, as an alternative method, the direct activation of purified poly(ADP ribose) polymerase by double-stranded oligonucleotides (N. A. Berger and S. I. Petzold, 1985, Biochemistry 24, 4352-4355) can be adopted for permeabilized cell systems. The inclusion of a palindromic decameric deoxynucleotide in the reaction buffer stimulated the enzyme activity in permeabilized Molt-3 human lymphoma cells up to 30-fold (at 50 micrograms/ml [corrected] oligonucleotide concentration) in a concentration-dependent manner. The activating effect of oligonucleotides was also evident when ethanol-fixed HeLa cells were postincubated with NAD+ to allow poly(ADP ribose) synthesis to occur in situ, which was detected as specific anti-poly (ADP ribose) immunofluorescence. We conclude that double-stranded oligonucleotides can be conveniently used as chemically and stoichiometrically well-defined poly (ADP ribose) polymerase activators in permeabilized or ethanol-fixed mammalian cells.     

Histone H1 and chromatin interactions in human fibroblast nuclei after H1 depletion and reconstitution with H1 subfractions.

BACKGROUND: Linker histones constitute a family of lysine-rich proteins associated with nucleosome core particles and linker DNA in eukaryotic chromatin. In permeabilized cells, they can be extracted from nuclei by using salt concentration in the range of 0.3 to 0.7 M. Although other nuclear proteins are also extracted at 0.7 M salt, the remaining nucleus represents a template that is relatively intact. METHODS: A cytochemical method was used to study the affinity of reconstituted linker histones for chromatin in situ in cultured human fibroblasts. We also investigated their ability to condense chromatin by using DNA-specific osmium ammine staining for electron microscopy. RESULTS: Permeabilized and H1-depleted fibroblast nuclei were suitable for the study of linker histone-chromatin interactions after reconstitution with purified linker histone subfractions. Our results showed that exogenous linker histones bind to chromatin with lower affinity than the native ones. We detected no significant differences between the main H1 and H1 degrees histone fractions with respect to their affinity for chromatin or in their ability to condense chromatin. CONCLUSIONS: Linker histone interactions with chromatin are controlled also by mechanisms independent of linker histone subtype composition.     

Mitochondrial GPx1 decreases induced but not basal oxidative damage to mtDNA in T47D cells

The production of oxyradicals by mitochondria (mt) is a source of oxidative damage to mtDNA such as 8-oxo-dG lesions that may lead to mutations and mitochondrial dysfunction. The potential protection of mtDNA by glutathione peroxidase-1 (GPx1) was investigated in GPx1-proficient (GPx-2) and GPx1-deficient (Hygro-3) human breast T47D cell transfectants. GPx activity and GPx1-like antigen concentration in mitochondria were respectively at least 100-fold and 20- to 25-fold higher in GPx2 than Hygro-3 cells. In spite of this large difference in peroxide-scavenging capacity, the basal 8-oxo-dG frequency in mtDNA, assessed by carefully controlled postlabeling assay, was strikingly similar in both cell lines. In contrast, in response to menadione-mediated oxidative stress, induction of 8-oxo-dG and DNA strand breaks was much lower in the GPx1-proficient mitochondria (e.g., +14% 8-oxo-dG versus +54% in Hygro-3 after 1-h exposure to 25 microM menadione, P < 0.05). Our data indicate that the mitochondrial glutathione/GPx1 system protected mtDNA against damage induced by oxidative stress, but did not prevent basal oxidative damage to mtDNA, which, surprisingly, appeared independent of GPx1 status in the T47D model.     

Poly(ADP-ribosyl)ation during chromatin remodeling steps in rat spermiogenesis

In spermiogenesis, spermatid differentiation is marked by dramatic changes in chromatin density and composition. The extreme condensation of the spermatid nucleus is characterized by an exchange of histones to transition proteins and then to protamines as the major nuclear proteins. Alterations in DNA topology that occur in this process have been shown to require the controlled formation of DNA strand breaks. Poly(ADP-ribosyl)ation is a posttranslational modification of proteins mediated by a family of poly(ADP-ribose) polymerase (PARP) proteins, and two family members, PARP-1 and PARP-2, are activated by DNA strand breaks that are directly detected by the DNA-binding domains of these enzymes. Here, we show for the first time that poly(ADP-ribose) formation, mediated by poly(ADP-ribose) polymerases (PARP-1 and presumably PARP-2), occurs in spermatids of steps 11–14, steps that immediately precede the most pronounced phase of chromatin condensation in spermiogenesis. High levels of ADP-ribose polymer were observed in spermatid steps 12–13 in which the highest rates of chromatin nucleoprotein exchanges take place. We also detected -H2AX, indicating the presence of DNA double-strand breaks during the same steps. Thus, we hypothesize that transient ADP-ribose polymer formation may facilitate DNA strand break management during the chromatin remodeling steps of sperm cell maturation.M.L. Meyer-Ficca and H. Scherthan contributed equally to this work     

Radioprotection of human cell nuclear DNA by polyamines: radiosensitivity of chromatin is influenced by tightly bound spermine

The polyamines putrescine (PUT) and spermine (SPM) were examined for their ability to protect human cell DNA against the formation of radiation-induced double-strand breaks (DSBs). As observed previously, under conditions where polyamines were shown to be almost completely absent, association with nuclear matrix protein into a nucleoid, and organization into chromatin structure, protected DNA from induction of DSBs by factors of 4.5 and 95, respectively. At concentrations below 1 mM, PUT or SPM provided equivalent levels of protection to deproteinized nuclear DNA, consistent with their capacity to scavenge radiation-induced radicals. At constant ionic strength, 5 mM SPM protected deproteinized DNA and nucleoid DNA and DNA in nuclear chromatin by factors of 100 and 26, respectively. At 5 mM, SPM provided 15 times greater protection of deproteinized DNA than did PUT. Under physiologically relevant conditions, 5 mM SPM protected DNA in the intact nucleus from the induction of DSBs by a factor of 2 relative to DNA in the absence of SPM. Studies of SPM binding during cellular fractionation revealed that a significant fraction of the cellular SPM is tightly bound in the nucleus but can be removed by extended washing. Thus the association of SPM with nuclear chromatin appears to be a significant contributor to the resistance of the cell's DNA to the induction of DSBs.     

Alterations in the nuclear matrix protein mass correlate with heat-induced inhibition of DNA single-strand-break repair

The total protein mass co-isolating with the nuclear matrix or nucleoid from Chinese hamster ovary (CHO) cells was observed to increase in heated cells as a function of increasing exposure temperature between 43 degrees C and 45 degrees C or of exposure time at any temperature. The sedimentation distance of the CHO cell nucleoid in sucrose gradients increased with increasing exposure time at 45 degrees C. Both these nuclear alterations correlated in a log-linear manner with heat-induced inhibition of DNA strand break repair. A two-fold threshold increase in nuclear matrix protein mass preceded any substantial inhibition of repair of DNA single-strand breaks. When preheated cells (45 degrees C for 15 min) were incubated at 37 degrees C the nuclear matrix protein mass and nucleoid sedimentation recovered with a half-time of about 5 h, while DNA single-strand-break repair recovered with a half-time of about 2 h. When preheated cells were placed at 41 degrees C (step-down heating; SDH) a further increase was observed in the nuclear matrix protein mass and the half-time of DNA strand break repair, while nucleoid sedimentation recovered toward control values. These results implicate alterations in the protein mass of the nuclear matrix in heat-induced inhibition of repair of DNA single-strand breaks.     

Proteins associated with mitochondrial DNA protect it against the action of X-rays and hydrogen peroxide

It has been suggested in a number of investigations that the high vulnerability of mitochondrial DNA to reactive oxygen species and other damaging agents is due to the absence in mitochondria of histones complexed with DNA. In the present study it was shown that DNA-binding proteins of mitochondrial nucleoids were able to shield mitochondrial DNA from X-ray radiation and hydrogen peroxide, as nuclear histones did. Mitochondria, mitochondrial nucleoid proteins, and histones were isolated from mouse liver cells. The degree of damage to or protection of mitochondrial DNA was assessed from the yield of its PCR amplification product. The in vitro experiments demonstrated that mouse mitochondrial DNA, when in complex with mitochondrial nucleoids or nuclear histones, was damaged much less by radiation and/or hydrogen peroxide than in the absence of these proteins and histones. No significant difference between mitochondrial nucleoid proteins and nuclear histones was revealed in their efficiency to protect mitochondrial DNA from the damaging effect of radiation and hydrogen peroxide. It is likely that the nucleoid proteins in the mitochondria shield mitochondrial DNA against the attack of reactive oxygen species, thus significantly decreasing the level of the oxidative damage to mitochondrial DNA.     

Analysis of metal-induced DNA lesions and DNA-repair replication in mammalian cells

The potency of several metal compounds in causing lesions in DNA either directly or by exposure of intact cultured cells has been examined using the neutral conditions of nucleoid gradient sedimentation. HgCl2 was clearly the most potent inducer of single-strand breakage when added to isolated nucleoids or when nucleoids were prepared from cells treated with this compound. CaCrO4 , however, caused DNA-strand breaks in nucleoids isolated from cells treated with this agent but did not induce DNA strand breaks when added directly to nucleoids. Although less potent than HgCl2, NiCl2 also caused significant single strand breakage in isolated nucleoids or in nucleoids prepared from cells treated with this metal. Since strand breakage of DNA in intact cells may occur secondary to activation of DNA-dependent nucleases during repair replication, CsCl gradient density sedimentation was utilized to examine whether repair processes were induced by exposure of cells to NiCl2, HgCl2 and CaCrO4 . CaCrO4 and NiCl2 induced substantial DNA-repair activity at concentrations and exposure times where DNA lesions could not be detected whereas HgCl2 induced a 10-fold lower level of DNA-repair activity compared to CaCrO4 at optimal concentrations which again were below the concentrations of this metal that produced measurable DNA lesions. Both the induction of DNA-repair activity and DNA-strand breakage by these metals was concentration- and time-dependent. These results demonstrate some unique aspects of the interaction of HgCl2, NiCl2 and CaCrO4 with the DNA of intact cells and point to the possible important correlation of induction of DNA repair to carcinogenesis since nickel and chromate have clearly been implicated as carcinogens and induce considerable repair whereas HgCl2 is not considered a carcinogen and induces the least DNA repair despite its potency in producing DNA lesions.     

Proteins associated with mitochondrial DNA protect it against X-rays and hydrogen peroxide

The high susceptibility of mitochondrial DNA to reactive oxygen species and other damaging agents has been supposed to result from the absence of histones. Here we show that DNA-binding proteins of mitochondrial nucleoids can shield mtDNA from X-ray radiation and hydrogen peroxide just as nuclear histones do. Mitochondria, mitochondrial nucleoid proteins, and histones were isolated from mouse liver and assessed for mtDNA protection by the yield of PCR products. In vitro, mtDNA in complex either with nucleoid proteins or with nuclear histones proved to be much less damaged than naked mtDNA, with little difference in protective efficacy. Most probably, in mitochondria the nucleoid proteins also protect mtDNA against reactive oxygen species and thus attenuate the oxidative damage.     

DNA fragmentation in permeabilized cells and nuclei. The role of (Ca2+ + Mg2+)-dependent endodeoxyribonuclease.

Permeabilized mammalian cells and isolated nuclei were used to study various aspects of DNA replication and repair. The present paper describes a progressive fragmentation of parental DNA in human lymphoblastoid cells that were permeabilized with L-alpha-lysophosphatidylcholine or with saponin and incubated at 37 degrees C in a DNA-synthesis mixture. The formation of DNA single-strand breaks (measured by alkaline elution) was linear with the time of incubation and was temperature-dependent. It was prevented by deleting Mg2+ or both Mg2+ and Ca2+ from the incubation mixture, or by the addition of EDTA. It was increased by deleting the components necessary for DNA synthesis, and by substituting Mn2+ for Mg2+ and Ca2+. DNA strand breaks also accumulated in isolated nuclei incubated in a DNA synthesis mixture, but not when Mg2+ was omitted. These results suggest that DNA fragmentation in permeabilized cells and nuclei was due to an activation of (Ca2+ + Mg2+)-dependent endodeoxyribonucleases. The integrity of template DNA needs to be ascertained when the conditions for measuring DNA synthesis in permeabilized cells or in nuclei are formulated.     

Variation in radiation-induced formation of DNA double-strand breaks as a function of chromatin structure.

The influence of chromatin structure on induction of DNA double-strand breaks (DSBs) by X radiation was studied in DNA from CHO cells. Whole cells, nuclei with condensed or relaxed chromatin, and deproteinized DNA in agarose plugs were irradiated and DSB formation was measured as a decrease in the length of DNA by nondenaturing, pulsed-field, agarose gel electrophoresis. The yield of DSBs in deproteinized DNA (2.3 x 10(-10) DSBs Da-1 Gy-1) was observed to be 70 times greater than the yield of DSBs (3.1 x 10(-12) DSBs Da-1 Gy-1) observed in DNA in the intact cell nucleus. Organization of DNA into the basic nucleosome repeat structure and condensation of the chromatin fiber into higher-order structure protected DNA from DSB induction by factors of 8.3 and 4.5, respectively. An additional twofold protection of DNA in fully condensed chromatin occurred in the intact cell nucleus. Since this protection did not appear to involve chromatin structure, we speculate that this additional protection may result from the association of soluble protein and nonprotein sulfhydryls with DNA in the intact cell nucleus. The results are consistent with the organization of nuclear DNA into both basic nucleosome repeat structure and higher-order chromatin structure providing significant protection against DSB induction.     

Poly(ADP-ribose) polymerase-1 as a regulator of protein-nucleic acid interactions in the processes responding to genotoxic action

Poly(ADP-ribose) polymerase-1 (PARP-1), nuclear protein of higher eukaryotes, specifically detects strand breaks in DNA. When bound to DNA strand breaks, PARP-1 is activated and catalyzes synthesis of poly(ADP-ribose) covalently attached to the row of nuclear proteins, with the main acceptor being PARP-1 itself. This protein participates in a majority of DNA dependent processes: repair, recombination; replication: cell death: apoptosis and necrosis. Poly(ADP-ribosyl)ation of proteins is considered as mechanism, which signals about DNA damage and modulate protein functioning in response to genotoxic impact. The main emphasis is made on the roles of PARP-1 and poly(ADP-ribosyl)ation in base excision repair (BER), the process, which provides repair of DNA breaks. The main proposed functions of PARP-1 in this process are: factor initiating assemblage of protein complex of BER; temporary protection of DNA ends; modulation of chromatin structure via poly(ADP-ribosyl)ation of histones; signaling function in detection of the levels of DNA damage in cell.     

The SUMO-targeted ubiquitin ligase subunit Slx5 resides in nuclear foci and at sites of DNA breaks

The Slx5/Slx8 protein complex, a heterodimeric SUMO-targeted ubiquitin ligase, plays an important role in genomic integrity. Slx5/Slx8 is believed to interact with sumoylated proteins that reside in the nuclei of budding yeast cells. In this complex, Slx5, owing to at least two SUMO interacting motifs (SIMs), has been proposed to be the targeting subunit of the Slx8 ubiquitin ligase. However, little is known about the exact subnuclear localization and targets of Slx5/Slx8. In this study we show that Slx5, but not Slx8, forms prominent nuclear foci. The formation of these foci depends on SUMO and a SIM in Slx5. Therefore, we investigated the subnuclear localization and potential chromatin association of Slx5. Using co-localization studies in live cells and fixed chromatin, we were able to localize Slx5 to DNA damage induced foci of Rad52 and Rad9, two proteins involved in the cellular response to DNA damage. Subsequent chromatin immunoprecipitation (ChIP) studies revealed that Slx5 is associated with HO endonuclease induced chromosome breaks. Surprisingly, real-time PCR analysis of Slx5 ChIPs revealed that the level of Slx5 at HO breaks in an slx8 deletion background is reduced about 4-fold. These results indicate that the DNA-damage targeting of Slx5/Slx8 depends on formation of the heterodimer and that this occurs at a subset of nuclear foci also containing DNA damage repair and checkpoint factors.