Induction of oxidative DNA damage in the peri-infarct region after permanent focal cerebral ischemia

To address the role of oxidative DNA damage in focal cerebral ischemia lacking reperfusion, we investigated DNA base and strand damage in a rat model of permanent middle cerebral artery occlusion (MCAO). Contents of 8-hydroxyl-2'-deoxyguanosine (8-OHdG) and apurinic/apyrimidinic abasic sites (AP sites), hallmarks of oxidative DNA damage, were quantitatively measured in nuclear DNA extracts from brains obtained 4-72 h after MCAO. DNA single- and double-strand breaks were detected on coronal brain sections using in situ DNA polymerase I-mediated biotin-dATP nick-translation (PANT) and terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling (TUNEL), respectively. Levels of 8-OHdG and AP sites were markedly elevated 16-72 h following MCAO in the frontal cortex, representing the peri-infarct region, but levels did not significantly change within the ischemic core regions of the caudateputamen and parietal cortex. PANT- and TUNEL-positive cells began to be detectable 4-8 h following MCAO in the caudate-putamen and parietal cortex and reached maximal levels at 72 h. PANT- and TUNEL-positive cells were also detected 16-72 h after MCAO in the lateral frontal cortex within the infarct border, where many cells also showed colocalization of DNA single-strand breaks and DNA fragmentation. In contrast, levels of PANT-positive cells alone were transiently increased (16 h after MCAO) in the medial frontal cortex, an area distant from the infarct zone. These data suggest that within peri-infarct brain regions, oxidative injury to nuclear DNA in the form of base and strand damage may be a significant and contributory cause of secondary expansion of brain damage following permanent focal ischemia.     

In situ detection of neuronal DNA strand breaks using the Klenow fragment of DNA polymerase I reveals different mechanisms of neuron death after global cerebral ischemia

Ischemic cell injury in the brain may involve a cascade of programmed cell death. DNA damage may be either a catalyst or a consequence of this cascade. Therefore, the induction of DNA strand breaks in the rat brain following transient global ischemia was examined using (a) the Klenow labeling assay, identifying DNA single-strand breaks (SSBs) or double-strand breaks (DSBs) with protruding 5' termini, and (b) terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling (TUNEL), detecting DNA DSBs with protruding 3' termini or blunt ends. Klenow-positive staining occurred within 2 h of reperfusion and increased with increasing durations of reperfusion. DNA damage detected with the Klenow labeling assay preceded that of TUNEL expression in the caudate putamen, reticular thalamus, thalamus, and cortex. However, in CA1, DNA SSBs were not detected until 72 h of reperfusion and occurred simultaneously with DSBs. Thus, the time course and fragmentation characteristics of DNA damage differ between the hippocampal CA1 and other selectively vulnerable brain regions. This distinct pattern suggests that the delayed neuronal death in CA1 following transient global ischemia may occur via an apoptotic mechanism different from that of other brain regions.     

In vitro assembly of semi-artificial molecular machine and its use for detection of DNA damage

Naturally occurring bio-molecular machines work in every living cell and display a variety of designs. Yet the development of artificial molecular machines centers on devices capable of directional motion, i.e. molecular motors, and on their scaled-down mechanical parts (wheels, axels, pendants etc). This imitates the macro-machines, even though the physical properties essential for these devices, such as inertia and momentum conservation, are not usable in the nanoworld environments. Alternative designs, which do not follow the mechanical macromachines schemes and use mechanisms developed in the evolution of biological molecules, can take advantage of the specific conditions of the nanoworld. Besides, adapting actual biological molecules for the purposes of nano-design reduces potential dangers the nanotechnology products may pose. Here we demonstrate the assembly and application of one such bio-enabled construct, a semi-artificial molecular device which combines a naturally-occurring molecular machine with artificial components. From the enzymology point of view, our construct is a designer fluorescent enzyme-substrate complex put together to perform a specific useful function. This assembly is by definition a molecular machine, as it contains one. Yet, its integration with the engineered part - fluorescent dual hairpin - re-directs it to a new task of labeling DNA damage. Our construct assembles out of a 32-mer DNA and an enzyme vaccinia topoisomerase I (VACC TOPO). The machine then uses its own material to fabricate two fluorescently labeled detector units (Figure 1). One of the units (green fluorescence) carries VACC TOPO covalently attached to its 3'end and another unit (red fluorescence) is a free hairpin with a terminal 3'OH. The units are short-lived and quickly reassemble back into the original construct, which subsequently recleaves. In the absence of DNA breaks these two units continuously separate and religate in a cyclic manner. In tissue sections with DNA damage, the topoisomerase-carrying detector unit selectively attaches to blunt-ended DNA breaks with 5'OH (DNase II-type breaks), fluorescently labeling them. The second, enzyme-free hairpin formed after oligonucleotide cleavage, will ligate to a 5'PO(4) blunt-ended break (DNase I-type breaks), if T4 DNA ligase is present in the solution. When T4 DNA ligase is added to a tissue section or a solution containing DNA with 5'PO(4) blunt-ended breaks, the ligase reacts with 5'PO(4) DNA ends, forming semi-stable enzyme-DNA complexes. The blunt ended hairpins will interact with these complexes releasing ligase and covalently linking hairpins to DNA, thus labeling 5'PO(4) blunt-ended DNA breaks. This development exemplifies a new practical approach to the design of molecular machines and provides a useful sensor for detection of apoptosis and DNA damage in fixed cells and tissues.     

Non-homologous DNA end joining repair in normal and leukemic cells depends on the substrate ends

Double-strand breaks (DSBs) are the most serious DNA damage which, if unrepaired or misrepaired, may lead to cell death, genomic instability or cancer transformation. In human cells they can be repaired mainly by non-homologous DNA end joining (NHEJ). The efficacy of NHEJ pathway was examined in normal human lymphocytes and K562 myeloid leukemic cells expressing the BCR/ABL oncogenic tyrosine kinase activity and lacking p53 tumor suppressor protein. In our studies we employed a simple and rapid in vitro DSB end joining assay based on fluorescent detection of repair products. Normal and cancer cells were able to repair DNA damage caused by restriction endonucleases, but the efficiency of the end joining was dependent on the type of cells and the structure of DNA ends. K562 cells displayed decreased NHEJ activity in comparison to normal cells for 5' complementary DNA overhang. For blunt-ended DNA there was no significant difference in end joining activity. Both kinds of cells were found about 10-fold more efficient for joining DNA substrates with compatible 5' overhangs than those with blunt ends. Our recent findings have shown that stimulation of DNA repair could be involved in the drug resistance of BCR/ABL-positive cells in anticancer therapy. For the first time the role of STI571 was investigated, a specific inhibitor of BCR/ABL oncogenic protein approved for leukemia treatment in the NHEJ pathway. Surprisingly, STI571 did not change the response of BCR/ABL-positive K562 cells in terms of NHEJ for both complementary and blunt ends. Our results suggest that the various responses of the cells to DNA damage via NHEJ can be correlated with the differences in the genetic constitution of human normal and cancer cells. However, the role of NHEJ in anticancer drug resistance in BCR/ABL-positive cells is questionable.     

The Saccharomyces cerevisiae Sae2 protein negatively regulates DNA damage checkpoint signalling

Double-strand breaks (DSBs) elicit a DNA damage response, resulting in checkpoint-mediated cell-cycle delay and DNA repair. The Saccharomyces cerevisiae Sae2 protein is known to act together with the MRX complex in meiotic DSB processing, as well as in DNA damage response during the mitotic cell cycle. Here, we report that cells lacking Sae2 fail to turn off both Mec1- and Tel1-dependent checkpoints activated by a single irreparable DSB, and delay Mre11 foci disassembly at DNA breaks, indicating that Sae2 may negatively regulate checkpoint signalling by modulating MRX association at damaged DNA. Consistently, high levels of Sae2 prevent checkpoint activation and impair MRX foci formation in response to unrepaired DSBs. Mec1- and Tel1-dependent Sae2 phosphorylation is necessary for these Sae2 functions, suggesting that the two kinases, once activated, may regulate checkpoint switch off through Sae2-mediated inhibition of MRX signalling.     

Assessing Phagocytic Clearance of Cell Death in Experimental Stroke by Ligatable Fluorescent Probes

We describe a new histochemical approach for visualization of phagocytic clearance in focal brain ischemia. The approach permits the study of elimination of dead cells in stroke by waste-management phagocytes of any cellular lineage. Although numerous cells of different origins that are capable of phagocytosis are present in ischemic brain, only part of them actively engulf and digest cell corpses. The selective visualization, quantification and analysis of such active phagocytic waste-management are helpful in assessing brain response to ischemia. Efficient cell death clearance is important for brain recovery from ischemic injury, as it opens the way for the subsequent regenerative processes. The failure to clean the corpses would result in a toxic reaction caused by non-degraded DNA and proteins. The described procedure uses fluorescent probes selectively ligated by a viral topoisomerase to characteristic DNA breaks produced in all phagocytes during engulfment and digestion of cells irreversibly damaged by ischemia. The method is a new tool for the investigation of brain reaction to ischemic injury.     

Enzymatic restriction of mammalian cell DNA using Pvu II and Bam H1: evidence for the double-strand break origin of chromosomal aberrations

Permeabilized Chinese hamster cells were treated with the restriction enzymes Pvu II and Bam H1 which generate blunt-ended with cohesive-ended double-strand breaks in the DNA respectively. Cells were then allowed to progress to the first mitosis, where chromosomal aberrations were scored. It was found that blunt-ended double-strand breaks induced both chromosome and chromatid aberrations of exchange and deletion types, including a high frequency of tri-radials. The total aberration frequency at high enzyme concentrations was more than ten times the control background frequency. Treatment with Bam H1 on the other hand did not induce aberrations above the background rate. This may indicate that the cohesive ends generated by this enzyme may be easily repaired by the cell due to the stabilization of the hydrogen bonding at the site of the double-strand break. Measurements using the unwinding method showed that the enzymes caused strand breaks in the DNA of permeabilized cells, and an approximate X-ray dose equivalent of the restriction-enzyme-induced breaks could be calculated. This indicated that restriction-induced blunt-ended double-strand breaks are relatively inefficient in causing chromosomal aberrations. This may be because of the presence of 'clean ends' at the site of a double-strand break, which may be repaired by ligation. The method of introducing restriction enzymes into cells opens up a new model approach for the study of the conversion of double-strand breaks into chromosome aberrations.     

Rapid Communication: Regional Variability in DNA Fragmentation After Global Ischemia Evidenced by Combined Histological and Gel Electrophoresis Observations in the Rat Brain

Abstract: We have studied whether the delayed cell death induced by transient forebrain ischemia is associated with an inter-nucleosomal cleavage of DNA into oligonucleosome-sized fragments. The integrity of genomic DNA in various brain regions after a 20-min four-vessel ischemia was examined using gel elec-trophoresis. We found typical ladders of oligonucleosomal DNA fragments in the striatum and in the Ammon's horn. In the latter we also often found a random DNA degradation as a smear pattern. These findings were reinforced by a specific in situ labeling of DNA breaks in tissue sections. A dark staining of nuclei was observed in the cell bodies of neurons—in particular in the head of the caudate and in the vulnerable CAl hippocampal area. With biochemical and histological approaches, there was no evidence of DNA degradation in regions that are resistant to the injury. We conclude that the association of multiple mechanisms of cell damage may occur after a global ischemia. The regional variability in DNA fragmentation stresses the importance of using histological approaches in parallel with gel electrophoresis.     

Early Detection of DNA Strand Breaks in the Brain After Transient Focal Ischemia: Implications for the Role of DNA Damage in Apoptosis and Neuronal Cell Death

Abstract: Using in situ DNA polymerase I-mediated biotin-dATP nick-translation (PANT) and terminal deoxynucleotidyl-transferase-mediated dUTP nick end-labeling (TUNEL), we investigated the evolution of DNA strand breaks, a marker of DNA damage, in rat brain after 1 h of middle cerebral artery occlusion and various durations of reperfusion. DNA single-strand breaks (SSBs) detected by PANT were present in neurons after as little as 1 min of reperfusion. Numbers of neurons containing an SSB increased progressively in the ischemic core but decreased in the ischemic penumbra after 1 h of reperfusion. DNA double-strand breaks (DSBs) detected by TUNEL were first seen in neurons after 1 h of reperfusion, and their numbers then increased progressively in the ischemic core, with a regional distribution similar to that of SSBs. However, the number of SSB-containing cells was greater than that of DSB-containing cells at all time points tested. SSB-containing cells detected within the first hour of reperfusion were exclusively neuronal and exhibited normal nuclear morphology. At 16–72 h of reperfusion, many SSB- and DSB-containing cells, including both neurons and astrocytes, showed morphological changes consistent with apoptosis. Gel electrophoresis of DNA isolated from the ischemic core showed DNA fragmentation at 24 h, when both SSBs and DSBs were present, but not at 1 h, when few DSBs were detected. These results suggest that damage to nuclear DNA is an early event after neuronal ischemia and that the accumulation of unrepaired DNA SSBs may contribute to delayed ischemic neuronal death, perhaps by triggering apoptosis.     

Presence of double-strand breaks with single-base 3' overhangs in cells undergoing apoptosis but not necrosis

Apoptotic cells in rat thymus were labeled in situ in paraffin-embedded and frozen tissue sections by ligation of double-stranded DNA fragments containing digoxigenin or Texas red. Two forms of double-stranded DNA fragments were prepared using the polymerase chain reaction: one was synthesized using Taq polymerase, which yields products with single- base 3' overhangs, and one using Pfu polymerase, which produces blunt- ended products. Both types of fragment could be ligated to apoptotic nuclei in thymus, indicating the presence in such nuclei of DNA double- strand breaks with single-base 3' overhangs as well as blunt ends. However, in nuclei with DNA damage resulting from a variety of nonapoptotic processes (necrosis, in vitro autolysis, peroxide damage, and heating) single-base 3' overhangs were either nondetectable or present at much lower concentrations than in apoptotic cells. Blunt DNA ends were present in such tissues, but at lower concentrations than in apoptotic cells. In contrast, in all of these forms of DNA damage, nuclei contained abundant 3'-hydroxyls accessible to labeling with terminal deoxynucleotidyl transferase. Thus, although single-base 3' overhangs and blunt ends are present in apoptotic nuclei, the specificity of the in situ ligation of 3'-overhang fragments to apoptotic nuclei indicates that apoptotic cells labeled in this way can readily be distinguished from cells with nonapoptotic DNA damage. These data are consistent with the involvement of an endonuclease similar to DNase I in apoptosis, which is predicted to leave short 3' overhangs as well as blunt ends in digestion of chromatin.     

Induction of chromosomal aberrations by restriction endonucleases encapsulated in liposomes

We used liposomes to deliver the restriction endonucleases BamHI and SmaI into human heteroploid HEp-2 cells. With this method very low concentrations of enzymes (2 units/ml) were active in the production of chromosomal aberrations. SmaI, which produces blunt-ended double-strand breaks in the DNA molecule, induces chromosomal aberrations more effectively than BamHI, which produces cohesive ends. Our results indicate that liposomes are suitable vectors for introducing restriction endonucleases into cultured human cells.     

Asymmetric somatic cell hybridization in plants

As part of an investigation into whether it would be possible to use UV radiation as a suitable pretreatment of the donor cells in asymmetric hybridization experiments, the effects of this treatment on sugarbeet (Beta vulgaris L.) protoplast DNA have been determined and compared with those of gamma radiation. Both nuclear and mitochondrial DNAs have been examined. The dose ranges chosen had previously been determined to be potentially applicable for fusion experiments. Pulsed field gel electrophoresis and standard agarose gel electrophoresis have been used in combination with laser scanning densitometry to gain an insight into the precise nature and degree of DNA damage resulting from irradiation. It was observed that UV radiation introduced substantial modifications to sugarbeet DNA. Double-strand breaks were detected, the number of which was found to be directly proportional to the dose applied. Such breaks indicate that UV radiation results in substantial chromosome/chromatid fragmentation in these cells. Chemical modifications to the DNA structure could be revealed by a significant reduction in DNA hybridization to specific mitochondrial and nuclear DNA probes. Following gamma irradiation at equivalent biological doses (i.e. those just sufficient to prevent colony formation) much less damage was detected. Fewer DNA fragments were produced indicating the presence of fewer double-strand breaks in the DNA structure. In comparison to UV treatments, DNA hybridization to specific probes following gamma radiation was inhibited less. For both treatments, mitochondrial DNA appeared more sensitive to damage than nuclear DNA. The possibility that DNA repair processes might account for these differences has also been investigated. Results indicate either that repair processes are not involved in the effects observed or that DNA repair occurs so fast that it was not possible to demonstrate such involvement with the experimental system used. The general relevance of such processes to asymmetric cell hybridization is discussed.     

DNA strand breakage after kidney storage

Ischemia and storage cause single-stranded DNA breaks. The breaks become evident after 30 min of warm storage or after only 4 hr of cold storage. The number of breaks increases with increasing ischemia time. The DNA damage was detected by alkaline sucrose gradient analysis of the DNA.     

The mechanism of human nonhomologous DNA end joining

Double-strand breaks are common in all living cells, and there are two major pathways for their repair. In eukaryotes, homologous recombination is restricted to late S or G(2), whereas nonhomologous DNA end joining (NHEJ) can occur throughout the cell cycle and is the major pathway for the repair of double-strand breaks in multicellular eukaryotes. NHEJ is distinctive for the flexibility of the nuclease, polymerase, and ligase activities that are used. This flexibility permits NHEJ to function on the wide range of possible substrate configurations that can arise when double-strand breaks occur, particularly at sites of oxidative damage or ionizing radiation. NHEJ does not return the local DNA to its original sequence, thus accounting for the wide range of end results. Part of this heterogeneity arises from the diversity of the DNA ends, but much of it arises from the many alternative ways in which the nuclease, polymerases, and ligase can act during NHEJ. Physiologic double-strand break processes make use of the imprecision of NHEJ in generating antigen receptor diversity. Pathologically, the imprecision of NHEJ contributes to genome mutations that arise over time.     

Cell cycle-regulated centers of DNA double-strand break repair

In eukaryotes, homologous recombination is an important pathway for the repair of DNA double-strand breaks. We have studied this process in living cells in the yeast Saccharomyces cerevisiae using Rad52 as a cell biological marker. In response to DNA damage, Rad52 redistributes itself and forms foci specifically during S phase. We have shown previously that Rad52 foci are centers of DNA repair where multiple DNA double-strand breaks colocalize. Here we report a correlation between the timing of Rad52 focus formation and modification of the Rad52 protein. In addition, we show that the two ends of a double-strand break are held tightly together in the majority of cells. Interestingly, in a small but significant fraction of the S phase cells, the two ends of a break separate suggesting that mechanisms exist to reassociate and align these ends for proper DNA repair.     

Cell Cycle-Regulated Centers of DNA Double-Strand Break Repair

In eukaryotes, homologous recombination is an important pathway for the repair of DNA double-strand breaks. We have studied this process in living cells in the yeast Saccharomyces cerevisiae using Rad52 as a cell biological marker. In response to DNA damage, Rad52 redistributes itself and forms foci specifically during S phase. We have shown previously that Rad52 foci are centers of DNA repair where multiple DNA double-strand breaks colocalize. Here we report a correlation between the timing of Rad52 focus formation and modification of the Rad52 protein. In addition, we show that the two ends of a double-strand break are held tightly together in the majority of cells. Interestingly, in a small but significant fraction of the S phase cells, the two ends of a break separate suggesting that mechanisms exist to reassociate and align these ends for proper DNA repair.     

Gamma-irradiation and doxorubicin treatment of normal human cells cause cell cycle arrest via different pathways

Ionizing radiation and doxorubicin both produce oxidative damage and double-strand breaks in DNA. Double-strand breaks and oxidative damage are highly toxic and cause cell cycle arrest, provoking DNA repair and apoptosis in cancer cell lines. To investigate the response of normal human cells to agents causing oxidative damage, we monitored alterations in gene expression in F65 normal human fibroblasts. Treatment with g-irradiation and doxorubicin altered the expression of 23 and 68 known genes, respectively, with no genes in common. Both agents altered the expression of genes involved in cell cycle arrest, and arrested the treated cells in G2/M phase 12 h after treatment. 24 h after g-irradiation, the percentage of G1 cells increased, whereas after doxorubicin treatment the percentage of G2/M cells remained constant for 24 h. Our results suggest that F65 cells respond differently to g-irradiation- and doxorubicin-induced DNA damage, probably using entirely different biochemical pathways.     

Epileptogenesis after Experimental Focal Cerebral Ischemia

Cerebrovascular diseases are one of the most common causes of epilepsy in adults, and the incidence of stroke-induced epileptogenesis is increasing as the population ages. The mechanisms that lead to stroke-induced epileptogenesis in a subpopulation of patients, however, are still poorly understood. Recent advances in inducing epileptogenesis in rodent focal ischemia models have provided tools that can be used to identify the risk factors and neurobiologic changes leading to development of epilepsy after stroke. Here we summarize data from models in which epileptogenesis has been studied after focal ischemia; photothrombosis, middle cerebral artery (MCA) occlusion with filament, and endothelin-1-induced MCA occlusion. Analysis of the data indicates that neurobiologic changes occurring during stroke-induced epileptogenesis share some similarities to those induced by status epilepticus or traumatic brain injury. Special issue dedicated to Dr. Simo S. Oja     

Histochemical Demonstration of DNA Double Strand Breaks by in Situ 3'-tailing Reaction in Apoptotic Endometrium

A new histochemical technique, called in situ 3'-tailing reaction (ISTR), to detect DNA double strand breaks (DSB) was developed and applied to tissue sections of apoptotic endometrium. To demonstrate DSB, biotin-labeled and unlabeled dATPs with terminal deoxynucleotidyl transferase (TdT) were added to the many 3-hydroxyl termini of DNA fragments generated in the apoptotic cells. For an efficient 3'-end labeling, it was necessary to treat the sections with λ-exonuclease (λEx) prior to the TdT reaction to generate 3'-protruding ends. The λEx-TdT reaction specifically labeled nuclear fragments in the apoptotic cells in paraformaldehyde fixed frozen sections. In paraffin sections, pretreatment with proteinase K was effective for 3'-tailing reaction. ISTR should be a useful tool for detecting dying cells in both physiological and pathological states.     

Potentiation of sulphur mustard or cisplatin-induced toxicity by caffeine in Chinese hamster cells correlates with formation of DNA double-strand breaks during replication on a damaged template

Caffeine inhibited the elongation of nascent DNA and induced breaks in the template DNA of sulphur mustard-treated Chinese hamster cells. The sizes of template and nascent DNAs, as indicated by alkaline sucrose gradient sedimentation, were similar suggesting that incision of template DNA occurred opposite gaps formed in nascent DNA by the action of caffeine, forming, effectively, double-strand breaks in DNA. Double-strand break formation was demonstrated, by means of elution of labelled DNA through polycarbonate filters at neutral pH, in both sulphur mustard- and cisplatin-treated cells when they were incubated in the presence of caffeine for 24 h. Double-strand breaks were only formed in that DNA which had been replicated in the presence of caffeine after treatment with sulphur mustard or cisplatin. Non-toxic concentrations of cycloheximide abolished the potentiation by caffeine of sulphur mustard-induced toxicity to Chinese hamster cells and at the same time abolished the formation of the low molecular weight nascent DNA, and as a consequence of its inhibitory effect on DNA synthesis, and the formation of double-strand breaks in DNA. Potentiation of the lethal and clastogenic effects of genotoxic agents by caffeine is therefore due to effects on the rate and mode of DNA synthesis which lead finally to double-strand breaks in DNA.