Selenium Source Impacts Protection of Porcine Jejunal Epithelial Cells from Cadmium-Induced DNA Damage,with Maximum Protection Exhibited with Yeast-Derived Selenium Compounds

Selenium (Se) is found in inorganic and organic forms, both of which are commonly used in animal feed supplements. The aim of this study was to determine the impact of the chemical form of Se on its associated ameliorative effects on cadmium (Cd)-induced DNA damage in a porcine model. At a cellular level, Cd mediates free oxygen radical production leading in particular to DNA damage, with consequential mutagenesis and inhibition of DNA replication. In this study, porcine jejunal epithelial cells (IPEC-J2) were pre-incubated for 48 h with one of Se-yeast (Sel-Plex), selenomethionine (Se-M), sodium selenite (Se-Ni) or sodium selenate (Se-Na). The effects of this supplementation on cell viability and DNA damage following cadmium chloride (CdCl₂) exposure were subsequently evaluated. IPEC-J2 cells were cultivated throughout in medium supplemented with porcine serum to generate a superior model that recapitulated the porcine gut epithelium. The results illustrated that Se antioxidant effects were both composition- and dose-dependent as evident from cell viability (Alamar Blue and 5-carboxyfluorescein diacetate acetoxymethyl ester) and DNA damage assays (Comet and TUNEL). Both the Se-yeast and Se-M organic species, when used at the European Food Safety Authority guideline levels, had a protective effect against Cd-induced DNA damage in the IPEC-J2 model system whereas for inorganic Se-Ni and Se-Na sources no protective effects were observed and in fact these were shown to enhance the negative effects of Cd-induced DNA damage. It can be concluded that nutritional supplementation with organoselenium may protect porcine gut integrity from damage induced by Cd.     

Patterns of unscheduled DNA synthesis in mouse embryo cells associated with in vitro aging and with spontaneous transformation to a continuous cell line

Monolayer cell cultures derived from B/C mouse embryos were examined for the ability to repair ultraviolet light-induced DNA damage (50–250 erg/mm²) during in vitro aging and subsequent alteration to a continuous cell line. Excision repair was measured by incubating the cultures with [³H]TdR and measuring DNA specific activity, and by performing quantitative autoradiography. DNA repair capacity declined during in vitro aging, and the level of repair correlated with the fraction of cells which retained the capacity to undergo scheduled DNA synthesis. This result indicates that mouse cells aged in vitro undergo a decline in their ability to repair UV-induced DNA damage comparable to that seen in cultured human fibroblasts. In cultures which spontaneously altered into continuously proliferating cell lines, DNA repair capacity increased to high levels, as did the fraction of cells capable of initiating scheduled DNA synthesis.     

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.     

Spontaneous and photosensitiser-induced DNA single-strand breaks and formamidopyrimidine-DNA glycosylase sensitive sites at nucleotide resolutionin the nuclear and mitochondrial DNA of Saccharomyces cerevisiae.

A system is described for mapping oxidative DNA damage (sites sensitive to formamidopyrimidine-DNA glycosylase and single-strand breaks) at nucleotide resolution in the nuclear and mitochondrial DNA of Saccharomyces cerevisiae. Our 3' end labelling method is sensitive and was first developed using the well-studied inducer of oxidative DNA damage, methylene blue (MB) plus light. We treated yeast DNA in vitro with this so as to maximise levels of damage for assay development. Unfortunately, MB does not remain in yeast cells and yeast DNA repair mutants sensitive to active oxygen species are not sensitive to this agent, thus for in vivo experiments we turned to a polycyclic aromatic, RO 19-8022 (RO). This resulted in oxidative DNA damage when light was applied to yeast cells in its presence. The spectra of enzyme-sensitive sites and single-strand breaks induced by MB in vitro or by RO plus light in vivo or in vitro were examined in two yeast reporter genes: the nuclear MFA2 and the mitochondrial OLI1. The experiments revealed that most of the enzyme-sensitive sites and single-strand breaks induced by MB or RO plus light are at the same positions in these sequences, and that these are guanines.     

Effect of DNA repair on the cytotoxicity and mutagenicity of polycyclic hydrocarbon derivatives in normal and xeroderma pigmentosum human fibroblasts

The cytotoxicity of the “K-region” epoxides as well as several other reactive metabolites or chemical derivatives of polycyclic hydrocarbons was compared in normally-repairing human diploid skin fibroblasts and in fibroblasts from a classical xeroderma pigmentosum (XP) patient (XP2BE) whose cells have been shown to carry out excision repair of damage induced in DNA by ultraviolet (UV) radiation at a rate approx. 20% that of normal cells. Each compound tested exhibited a 2- to 3-fold greater cytotoxicity in this XP strain than in the normal strain. To determine whether this difference in survival reflected a difference in the capacity of the strains to repair DNA damage caused by such hydrocarbon derivatives, we compared the cytotoxic effect of several “K-region” epoxides in two additional XP strains, each with a different capacity for repair of UV damage. The ration of the slopes of the survival curves for each of the XP strains to that of the normal strain, following exposure to each epoxide, was very similar to that which we had previously determined for their respective UV curves, suggesting that human cells repair damage induced in DNA by exposure to hydrocarbon derivatives with the same system used for UV-induced lesions.To determine whether the deficiency in rate of excision repair in this classical XP strain (XP2BE) causes such cells to be abnormally susceptible to mutations induced by “K-region” epoxides of polycyclic hydrocarbons, we compared them with normal cells for the frequency of induced mutations to 8-azaguanine resistance. The XP cells were two to three times more susceptible to mutations induced by the “K-region” epoxide of benzo(a)pyrene (BP), 7,12-dimethylbenz(a)anthracene (DMBA), and dibenz(a,h)anthracene (DBA). Evidence also was obtained that cells from an XP variant patient are abnormally susceptible to mutations induced by hydrocarbon epoxides and, as is the case following exposure to UV, are abnormally slow in converting low molecular weight DNA, synthesized from a template following exposure to hydrocarbon epoxides, into large-size DNA.     

DNA damage and repair in epithelial (mucous) cells and crypt cells from isolated colon

Colon epithelium is made up of two general classes of cells, surface cells which are post-mitotic and crypt cells which contain the proliferative population. Their relative vulnerability to environmental damage and ability to perform DNA repair are important issues in colon carcinogenesis. DNA damage and repair was studied by the nucleoid sedimentation method in freshly isolated crypt cells for comparison with previous studies of post-mitotic surface epithelial cells. Suspensions of crypt cells were isolated from preparations of mouse colon by a series of sequential incubations in buffer containing 1.5 mM EDTA. Treatment of crypt cells for 30 min with 1.2 X 10(-6) M methyl methane sulfonate (MMS), photoaffinity labeling with 1 X 10(-6) M ethidium monoazide, lithocholic acid (2.5 X 10(-4) M) treatment for 1 h or X-irradiation at 1500 rads resulted in single-strand breaks in the DNA, which were repaired after 2 h of additional incubation. Interestingly, X-rays at 1000 rads and lithocholic acid (LA) (2.5 X 10(-6) M) after 30 min incubation failed to produce the detectable shift in nucleoid sedimentation characteristic of single-strand breaks, perhaps due to rapid repair by these proliferative cells. UV-irradiation failed to provoke strand incision as was also observed for the superficial post-mitotic cells in the previous studies. These studies showed the feasibility of studying DNA damage and repair processes in these two classes of colon epithelial cells in response to specific carcinogenic insult.     

Changing capacity for DNA excision repair in mouse embryonic cells in vitro

Capacity for excision repair of ultraviolet radiation damage to DNA in primary cultures of mouse embryonic cells is dependent on the gestational stage and the duration of in vitro growth. Fibroblasts of mouse embryos at 13–15 days gestation excise thymine dimers and perform unscheduled DNA synthesis after ultraviolet radiation. After several successive transfers in vitro, concomitantly with a pronounced reduction in growth rate, ability for excision repair decreases. DNA repair capacity is impaired in cells obtained from embryos at late stages of development (17–19 days gestation). Experiments with epithelial kidney cells from 5-day-old mice indicate that capacity for excision repair may depend on cell type and its origin.     

The effect of aging on the DNA damage and repair capacity in 2BS cells undergoing oxidative stress

Aging is associated with a reduction in the DNA repair capacity under oxidative stress. However, whether the DNA damage and repair capacity can be a biomarker of aging remains controversial. In this study, we demonstrated two cause-and-effect relationships, the one is between the DNA damage and repair capacity and the cellular age, another is between DNA damage and repair capacity and the level of oxidative stress in human embryonic lung fibroblasts (2BS) exposed to different doses of hydrogen peroxide (H₂O₂). To clarify the mechanisms of the age-related reduction in DNA damage and repair capacity, we preliminarily evaluated the expressions of six kinds of pivotal enzymes involved in the two classical DNA repair pathways. The DNA repair capacity was observed in human fibroblasts cells using the comet assay; the age-related DNA repair enzymes were selected by RT-PCR and then verified by Western blot in vitro. Results showed that the DNA repair capacity was negatively and linearly correlated with (i) cumulative population doubling (PD) levels only in the group of low concentration of hydrogen peroxide treatment, (ii) with the level of oxidative stress only in the group of young PD cells. The mRNA expression of DNA polymerase δ1 decreased substantially in senescent cells and showed negative linear-correlation with PD levels; the protein expression level was well consistent with the mRNA level. Taken together, DNA damage and repair capacity can be a biomarker of aging. Reduced expression of DNA polymerase δ1 may be responsible for the decrease of DNA repair capacity in senescent cells.     

Complementation of the DNA repair-deficient swi10 mutant of fission yeast by the human ERCC1 gene.

In human cells DNA damage caused by UV light is mainly repaired by the nucleotide excision repair pathway. This mechanism involves dual incisions on both sides of the damage catalyzed by two nucleases. In mammalian cells XPG cleaves 3' of the DNA lesion while the ERCC1-XPF complex makes the 5' incision. The amino acid sequence of the human excision repair protein ERCC1 is homologous with the fission yeast Swi10 protein. In order to test whether these proteins are functional homologues, we overexpressed the human gene in a Schizosaccharomyces pombe swi10 mutant. A swi10 mutation has a pleiotropic effect: it reduces the frequency of mating type switching (a mitotic transposition event from a silent cassette into the expression site) and causes increased UV sensitivity. We found that the full-length ERCC1 gene only complements the transposition defect of the fission yeast mutant, while a C-terminal truncated ERCC1 protein also restores the DNA repair capacity of the yeast cells. Using the two-hybrid system of Saccharomyces cerevisiae we show that only the truncated human ERCC1 protein is able to interact with the S . pombe Rad16 protein, which is the fission yeast homologue of human XPF. This is the first example yet known that a human gene can correct a yeast mutation in nucleotide excision repair.     

Selenomethionine protects against adverse biological effects induced by space radiation

Ionizing radiation-induced adverse biological effects impose serious challenges to astronauts during extended space travel. Of particular concern is the radiation from highly energetic, heavy, charged particles known as HZE particles. The objective of the present study was to characterize HZE particle radiation-induced adverse biological effects and evaluate the effect of D-selenomethionine (SeM) on the HZE particle radiation-induced adverse biological effects. The results showed that HZE particle radiation can increase oxidative stress, cytotoxicity, and cell transformation in vitro, and decrease the total antioxidant status in irradiated Sprague-Dawley rats. These adverse biological effects were all preventable by treatment with SeM, suggesting that SeM is potentially useful as a countermeasure against space radiation-induced adverse effects. Treatment with SeM was shown to enhance ATR and CHK2 gene expression in cultured human thyroid epithelial cells. As ionizing radiation is known to result in DNA damage and both ATR and CHK2 gene products are involved in DNA damage, it is possible that SeM may prevent HZE particle radiation-induced adverse biological effects by enhancing the DNA repair machinery in irradiated cells.     

DMBA induced DNA damage and repair in mammary epithelial cells in vitro measured by a nick translation assay

A new E. coli DNA polymerase I directed nick translation assay was used for measuring 7,12-dimethylbenz[a]anthracene-induced in situ DNA damage and repair in mouse mammary epithelial cells in monolayer culture. The nick translation assay was capable of detecting a DMBA-dose dependent significant increase of DNA damage, and the same assay also allowed monitoring of the DNA repair activity provoked by DMBA treatment of the epithelial cells. This relatively simple method thus provides a rapid assay for carcinogen-induced in situ DNA damage and repair in an epithelial cell tumorigenic system.     

Developmental regulation and in vitro culture effects on expression of DNA repair and cell cycle checkpoint control genes in rhesus monkey oocytes and embryos

DNA repair is essential for maintaining genomic integrity, and may be required in the early embryo to correct damage inherited via the gametes, damage that arises during DNA replication, or damage that arises in response to exposure to genotoxic agents. The capacity of preimplantation stage mammalian embryos to repair damaged DNA has not been well characterized, particularly in primate embryos. In this study, we examined the expression of 48 mRNAs related to sensing different kinds of DNA damage, repairing that DNA damage, and controlling the cell cycle to provide an opportunity for DNA repair. The expression data reveal dynamic temporal changes, indicating a changing ability of the rhesus embryo to detect and repair different kinds of DNA damage. Low expression or overexpression of specific DNA repair genes may limit the ability of the embryo to respond to DNA damage at certain stages. Additionally, our data reveal that in vitro culture may lead to dysregulation of many such genes and a potentially impaired ability to repair DNA damage, thus affecting cellular viability and long-term embryo viability via effects on genome integrity. This effect of in vitro culture on nonhuman primate embryos may be relevant to assessing the potential advantages and disadvantages of prolonged in vitro culture of human embryos.     

Wound repair and anti-oxidative capacity is regulated by ITGB4 in airway epithelial cells

Integrin beta 4 (ITGB4) is a structural adhesion molecule which engages in maintaining the integrity of airway epithelial cells. Its specific cytomembrane structural feature strongly indicates that ITGB4 may engage in many signaling pathways and physiologic processes. However, in addition to adhesion, the specific biologic significance of ITGB4 in airway epithelial cells is almost unknown. In this article, we investigated the expression and functional properties of ITGB4 in airway epithelial cells in vivo and in vitro. Human bronchial epithelial cell line (16HBE14O-cells) and primary rat tracheal epithelial cells (RTE cells) were used to determine ITGB4 expression under ozone tress or mechanical damage, respectively. An ovalbumin (OVA)-challenged asthma model was used to investigate ITGB4 expression after antigen exposure in vivo. In addition, an ITGB4 overexpression vector and ITGB4 silence virus vector were constructed and transfected into RTE cells. Then, wound repair ability and anti-oxidation capacity was evaluated. Our results demonstrated that, on the edge of mechanically wounded cell areas, ITGB4 expression was increased after mechanical injury. After ozone stress, upregulation expression of ITGB4 was also detected. In the OVA-challenged asthma model, ITGB4 expression was decreased on airway epithelial cells accompanying with structural disruption and damage of anti-oxidation capacity. Besides, our study revealed that upregulation of ITGB4 promotes wound repair ability and anti-oxidative ability, while such abilities were blocked when ITGB4 was silenced. Taken together, these results showed that ITGB4 was a new interesting molecule involved in the regulation of wound repair and anti-oxidation processes for airway epithelial cells.     

Oxidant-induced DNA damage by quartz in alveolar epithelial cells

Respirable quartz has recently been classified as a human carcinogen. Although, studies with quartz using naked DNA as a target suggest that formation of oxyradicals by particles may play a role in the DNA-damaging properties of quartz, it is not known whether this pathway is important for DNA damage in the target cells for quartz carcinogenesis, i.e. alveolar epithelial cells. Therefore, we determined in vitro DNA damage by DQ12 quartz particles in rat and human and alveolar epithelial cells (RLE, A549) using the single cell gel electrophoresis/comet assay. The radical generation capacity of quartz was analysed by electron spin resonance (ESR) and by immunocytochemical analysis of the hydroxyl radical-specific DNA lesion 8-hydroxydeoxyguanosine (8-OHdG) in the epithelial cells. Quartz particles as well as the positive control hydrogen peroxide, caused a dose-dependent increase in DNA strand breaks in both cell lines. DNA damage by quartz was significantly reduced in the presence of the hydroxyl-radical scavengers mannitol or DMSO. The involvement of hydroxyl radicals was further established by ESR measurements and was also demonstrated by the ability of the quartz to induce formation of 8-OHdG. In conclusion, our data show that quartz elicits DNA damage in rat and human alveolar epithelial cells and indicate that these effects are driven by hydroxyl radical-generating properties of the particles.     

Polyphosphate is a key factor for cell survival after DNA damage in eukaryotic cells

Cells require extra amounts of dNTPs to repair DNA after damage. Polyphosphate (polyP) is an evolutionary conserved linear polymer of up to several hundred inorganic phosphate (Pi) residues that is involved in many functions, including Pi storage. In the present article, we report on findings demonstrating that polyP functions as a source of Pi when required to sustain the dNTP increment essential for DNA repair after damage. We show that mutant yeast cells without polyP produce less dNTPs upon DNA damage and that their survival is compromised. In contrast, when polyP levels are ectopically increased, yeast cells become more resistant to DNA damage. More importantly, we show that when polyP is reduced in HEK293 mammalian cell line cells and in human dermal primary fibroblasts (HDFa), these cells become more sensitive to DNA damage, suggesting that the protective role of polyP against DNA damage is evolutionary conserved. In conclusion, we present polyP as a molecule involved in resistance to DNA damage and suggest that polyP may be a putative target for new approaches in cancer treatment or prevention.     

DNA ligation during excision repair in yeast cell-free extracts is specifically catalyzed by the CDC9 gene product

Excision repair of DNA is an important cellular response to DNA damage induced by radiation and many chemicals. In eukaryotes, base excision repair (BER) and nucleotide excision repair (NER) are two major excision repair pathways which are completed by a DNA ligation step. Using a cell-free system, we have determined the DNA ligase requirement during BER and NER of the yeast S. cerevisiae. Under nonpermissive conditions in extracts of the cdc9-2 temperature-sensitive mutant, DNA ligation in both BER and NER pathways was defective, and the repair patches were enlarged. At the permissive temperature (23 degrees C), DNA ligation during excision repair was only partially functional in the mutant extracts. In contrast, deleting the DNA ligase IV gene did not affect DNA ligation of BER or NER. Defective DNA ligation of BER and NER in cdc9-2 mutant extracts was complemented in vitro by purified yeast Cdc9 protein, but not by DNA ligase IV even when overexpressed. These results demonstrate that the ligation step of excision repair in yeast cell-free extracts is catalyzed specifically by the Cdc9 protein, the homologue of mammalian DNA ligase I.     

Optimization of the alkaline comet assay for easy repair capacity quantification of oxidative DNA damage in PBMC from human volunteers using aphidicolin block

Assessment of DNA repair capacity (DRC) upon ex vivo challenge of peripheral blood mononuclear cells (PBMC) with oxidative damage inducing agents, as evaluated by the comet assay, is widely used as biomarker to assess the antioxidant status in human studies. Here, the alkaline comet assay was now optimized for easy and time saving detection of repair capacity upon oxidative stress-induced DNA damage using the DNA polymerase inhibitor aphidicolin (APC) to block repair of hydrogen peroxide (H₂O₂) induced DNA damage. Addition of a DMSO-containing DNA damage stop solution was found suitable to replace washing steps for H₂O₂ removal before APC block. Cell treatment with APC at 6 μM did not impact baseline DNA damage but could reliably block DNA repair after H₂O₂ challenge in both fresh and cryopreserved samples thus omitting the use of a starting time point control. Under the conditions used, frozen cells, with or without an additional 4 h rest, showed the same repair capacity as their fresh counterpart. The intra assay coefficient of variation (CV) was 3.3%. To provide proof of principle, the modified assay was applied to cryopreserved PBMC from 19 participants of a short-term Brassica diet intervention study investigating potential health promoting effects of the food intervention. Then, a 33% increase in DRC (p ≤ 0.01) could be shown in samples after intervention (mean ± SD: 5.82 ± 1) as compared to baseline (mean ± SD: 4.38 ± 1.21). Individual samples from baseline and intervention showed an inter-individual CV of 27.65% (baseline) and 17.26% (intervention). Taken together this modified comet assay protocol allows the facilitated detection of DNA repair in fresh or cryopreserved human PBMC samples with a good sensitivity and reliability and could be useful in human studies addressing the antioxidant status and repair capacity of PBMC.     

YNK1, the yeast homolog of human metastasis suppressor NM23, is required for repair of UV radiation- and etoposide-induced DNA damage

In humans, NM23-H1 is a metastasis suppressor whose expression is reduced in metastatic melanoma and breast carcinoma cells, and which possesses the ability to inhibit metastatic growth without significant impact on the transformed phenotype. NM23-H1 exhibits three enzymatic activities in vitro, each with potential to maintain genomic stability, a 3'-5' exonuclease and two kinases, nucleoside diphosphate kinase (NDPK), and protein histidine kinase. Herein we have investigated the potential contributions of NM23 proteins to DNA repair in the yeast, Saccharomyces cerevisiae, which contains a single NM23 homolog, YNK1. Ablation of YNK1 delayed repair of UV- and etoposide-induced nuclear DNA damage by 3-6h. However, YNK1 had no impact upon the kinetics of MMS-induced DNA repair. Furthermore, YNK1 was not required for repair of mitochondrial DNA damage. To determine whether the nuclear DNA repair deficit manifested as an increase in mutation frequency, the CAN1 forward assay was employed. An YNK1 deletion was associated with increased mutation rates following treatment with either UV (2.6x) or MMS (1.6 x). Mutation spectral analysis further revealed significantly increased rates of base substitution and frameshift mutations following UV treatment in the ynk1Delta strain. This study indicates a novel role for YNK1 in DNA repair in yeast, and suggests an anti-mutator function that may contribute to the metastasis suppressor function of NM23-H1 in humans.