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Sodium butyrate induces genotoxic stress in function of photoperiod variations and differentially modulates the expression of genes involved in chromatin modification and DNA repair in Petunia hybrida seedlings.
Pagano, A, L'Andolina, C, Sabatini, ME, de Sousa Araújo, S, Balestrazzi, A, Macovei, A
Planta. 2020;(5):102
Abstract
Sodium butyrate applied to Petunia hybrida seeds under a long-day photoperiod has a negative impact (reduced seedling length, decreased production of photosynthetic pigments, and accumulation of DNA damage) on early seedling development, whereas its administration under dark/light conditions (complete dark conditions for 5 days followed by exposure to long-day photoperiod for 5 days) bypasses some of the adverse effects. Genotoxic stress impairs plant development. To circumvent DNA damage, plants activate DNA repair pathways in concert with chromatin dynamics. These are essential during seed germination and seedling establishment, and may be influenced by photoperiod variations. To assess this interplay, an experimental design was developed in Petunia hybrida, a relevant horticultural crop and model species. Seeds were treated with different doses of sodium butyrate (NaB, 1 mM and 5 mM) as a stress agent applied under different light/dark conditions throughout a time period of 10 days. Phenotypic (germination percentage and speed, seedling length, and photosynthetic pigments) and molecular (DNA damage and gene expression profiles) analyses were performed to monitor the response to the imposed conditions. Seed germination was not affected by the treatments. Seedling development was hampered by increasing NaB concentrations applied under a long-day photoperiod (L) as reflected by the decreased seedling length accompanied by increased DNA damage. When seedlings were grown under dark conditions for 5 days and then exposed to long-day photoperiod for the remaining 5 days (D/L), the damaging effects of NaB were circumvented. NaB exposure under L conditions resulted in enhanced expression of HAT/HDAC (HISTONE ACETYLTRANSFERASES/HISTONE DEACTEYLASES) genes along with repression of genes involved in DNA repair. Differently, under D/L conditions, the expression of DNA repair genes was increased by NaB treatment and this was associated with lower levels of DNA damage. The observed DNA damage and gene expression profiles suggest the involvement of chromatin modification- and DNA repair-associated pathways in response to NaB and dark/light exposure during seedling development.
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2.
Use of antioxidant could ameliorate the negative impact of etoposide on human sperm DNA during chemotherapy.
Rabaça, A, Ferreira, C, Bernardino, R, Alves, M, Oliveira, P, Viana, P, Barros, A, Sousa, M, Sá, R
Reproductive biomedicine online. 2020;(6):856-866
Abstract
RESEARCH QUESTION A previous study showed that N-acetylcysteine (NAC), used after in-vitro exposure to the gonadotoxic chemotherapeutic drug etoposide, has the ability to decrease DNA damage in human spermatozoa; however, it showed no benefit when used before exposure. This study aimed to evaluate the impact of the NAC on the preservation of sperm quality during in-vitro exposure to etoposide. DESIGN Twenty semen samples were submitted to four experimental conditions: control, NAC-only incubation, etoposide-only incubation, and concomitant etoposide and NAC incubation. After in-vitro incubation, semen parameters, sperm chromatin condensation, sperm DNA fragmentation, sperm oxidative stress and sperm metabolism were used to evaluate the role of NAC in protecting human spermatozoa from etoposide. RESULTS Etoposide did not affect semen parameters, nor did it cause sperm oxidative damage or alterations in glycolytic profile. However, it induced chromatin decondensation and DNA fragmentation, which were fully prevented by NAC. CONCLUSIONS NAC was able to protect sperm DNA integrity during etoposide treatment in vitro, suggesting that NAC may be useful as an adjuvant agent in preserving male fertility during chemotherapy treatments.
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3.
Cellular pathologies and genotoxic effects arising secondary to heavy metal exposure: A review.
Kocadal, K, Alkas, FB, Battal, D, Saygi, S
Human & experimental toxicology. 2020;(1):3-13
Abstract
Environmental pollution is significant and oftentimes hazardous in the areas, where mining, foundries and smelters and other metallurgical operations are located. Systematic research on the chronic effects of metals started during the past century; nevertheless, it is evident that even today, there are large gaps in knowledge regarding the assessment of the health effects caused by environmental and occupational exposures to these metals. Heavy metals induce the production of reactive oxygen species (ROS) causing oxidative stress, make several repair-inhibiting cellular changes and alter the DNA repair processes. They favour the 'false' repairing of double-strand breaks (DSBs), propagate DNA mutations and induce carcinogenesis. A detailed literature search was performed using the MedLine/PubMed database. Depending on the mechanism of action, arsenicals can act as genotoxins, non-genotoxic agents and carcinogens. Cadmium can bind to proteins, reduce DNA repair, activate protein degradation, up-regulate cytokines and proto-oncogenes (c-fos, c-jun and c-myc), induce the expression of metallothionein, haeme-oxygenases, glutathione transferases, heat-shock proteins, acute-phase reactants and DNA polymerase β at lower concentrations. Inorganic mercury damages oxidative phosphorylation and electron transport pathways at the ubiquinone-cytochrome b5 locus and thus induces ROS production. Abandoned mining areas generate environmentally persistent waste. These specific sites urgently require maximally efficient and cheap remediation. This bears the need for methodologies employing green and sustainable remediation. Phytoremediation is important in that it is a prevalent in situ remediation technique. Its advantages include the use of solar energy, cost-effectiveness, easy operation, reduction in secondary contaminants, the use of biomass for biofuel production and low-cost adsorbents.
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4.
Dry olive leaf extract attenuates DNA damage induced by estradiol and diethylstilbestrol in human peripheral blood cells in vitro.
Topalović, D, Dekanski, D, Spremo-Potparević, B, Pirković, A, Borozan, S, Bajić, V, Stojanović, D, Giampieri, F, Gasparrini, M, Živković, L
Mutation research. Genetic toxicology and environmental mutagenesis. 2019;:402993
Abstract
Phenolic groups of steroidal or nonsteroidal estrogens can redox cycle, leading to oxidative stress, where creation of reactive oxygen species are recognized as the main mechanism of their DNA damage properties. Dry olive (Olea europaea L.) leaf extract is known to contain bioactive and antioxidative components and to have an ability to modulate the effects of various oxidants in cells. The main goal of this study was to investigate antigenotoxic potential of a standardized dry olive leaf extract on DNA damage induced by 17β-estradiol and diethylstilbestrol in human whole blood cells in vitro, using comet assay. Our results indicated that both hormones showed a genotoxic effect at a concentration of 100 μM (P < 0.05, n = 6). Dry olive leaf extract was efficient in reducing number of cells with estrogen-induced DNA damage at tested concentrations (0.125, 0.5 and 1 mg/mL) (P < 0.05, n = 6) and under two experimental protocols, pre-treatment and post-treatment, exhibiting antigenotoxic properties. Analysis of antioxidant properties of the extract revealed moderate ABTS radical scavenging properties and reducing power. Overall, our results suggested that the protective potential of dry olive leaf extract could arise from the synergistic effect of its scavenging activity and enhancement of the cells' antioxidant capacity.
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5.
Deferasirox reduces oxidative DNA damage in bone marrow cells from myelodysplastic patients and improves their differentiation capacity.
Jiménez-Solas, T, López-Cadenas, F, Aires-Mejía, I, Caballero-Berrocal, JC, Ortega, R, Redondo, AM, Sánchez-Guijo, F, Muntión, S, García-Martín, L, Albarrán, B, et al
British journal of haematology. 2019;(1):93-104
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Abstract
Patients with low-risk myelodysplastic syndromes (MDS) usually develop iron overload. This leads to a high level of oxidative stress in the bone marrow (BM) and increases haematopoietic cell dysfunction. Our objective was to analyse whether chelation with deferasirox (DFX) alleviates the consequences of oxidative stress and improves BM cell functionality. We analysed 13 iron-overloaded MDS patients' samples before and 4-10 months after treatment with DFX. Using multiparametric flow cytometry analysis, we measured intracellular reactive oxygen species (ROS), DNA oxidation and double strand breaks. Haematopoietic differentiation capacity was analysed by colony-forming unit (CFU) assays. Compared to healthy donors, MDS showed a higher level of intracellular ROS and DNA oxidative damage in BM cells. DNA oxidative damage decreased following DFX treatment. Furthermore, the clonogenic assays carried out before treatment suggest an impaired haematopoietic differentiation. DFX seems to improve this capacity, as illustrated by a decreased cluster/CFU ratio, which reached values similar to controls. We conclude that BM cells from MDS are subject to higher oxidative stress conditions and show an impaired haematopoietic differentiation. These adverse features seem to be partially rectified after DFX treatment.
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Prevention by L-carnitine of DNA damage induced by 3-hydroxy-3-methylglutaric and 3-methylglutaric acids and experimental evidence of lipid and DNA damage in patients with 3-hydroxy-3-methylglutaric aciduria.
Delgado, CA, Balbueno Guerreiro, GB, Diaz Jacques, CE, de Moura Coelho, D, Sitta, A, Manfredini, V, Wajner, M, Vargas, CR
Archives of biochemistry and biophysics. 2019;:16-22
Abstract
3-hydroxy-3-methylglutaric aciduria (HMGA) is an inherited disorder of the leucine catabolic pathway in which occurs a deficiency of the 3-hydroxy-3-methylglutaryl-CoA lyase enzyme. Therefore, the organic acids 3-hydroxy-3-methylglutaric (HMG) and 3-methylglutaric (MGA), mainly, accumulate in tissues of affected patients. Lately, much attention has been focused on free radicals as mediators of tissue damage in human diseases, causing lipid peroxidation, protein oxidation and DNA damage. The treatment of this disease is based in a restricted protein ingest and supplementation with l-carnitine (LC), an antioxidant and detoxifying agent. In the present work, we investigated the in vitro oxidative damage to DNA induced by the accumulation of organic acids and oxidative stress parameters in vivo of patients with 3-HMG, as well as the effect of the recommended therapy. The in vitro DNA damage was analyzed by the alkaline comet assay in leukocytes incubated with HMG and MGA (1 mM, 2.5 mM and 5 mM) and co-incubated with LC (90 μM and 150 μM). The in vivo urinary 15-F2t-isoprostane levels and urinary oxidized guanine species were measured by ELISA kits in patient's urine before and after the treatment with LC. HMG and MGA induced a DNA damage index (DI) significantly higher than that of the control group. The DI was significantly reduced in the presence of LC. It was also verified a significant increase of oxidized guanine species and urinary isoprostane levels, biomarker of oxidative DNA damage and lipid peroxidation respectively, in patients before treatment. After the treatment and supplementation with LC, patients presented significantly lower levels of those biomarkers. Analyzing the data together, we can conclude that HMGA patients present oxidative lipid and DNA damage, which is induced by HMG and MGA, and the antioxidant therapy with LC can prevent that kind of injuries.
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Hydrogen peroxide, a potent inducer of global genomic instability.
Qi, L, Wu, XC, Zheng, DQ
Current genetics. 2019;(4):913-917
Abstract
Oxidative stress has been implicated in a variety of human diseases. One plausible mechanism is that reactive active species can induce DNA damages and jeopardize genome integrity. To explore how oxidative stress results in global genomic instability in cells, our current study examined the genomic alterations caused by H2O2 exposure at the whole genome level in yeast. Using SNP microarrays and genome sequencing, we mapped H2O2-induced genomic alterations in the yeast genome ranging from point mutations and mitotic recombination to chromosomal aneuploidy. Our results suggested most H2O2-induced mitotic recombination events were the result of DNA double-stand breaks generated by hydroxyl radicals. Moreover, the mutagenic effect of H2O2 was shown to be largely dependent on DNA polymerase ζ. Lastly, we showed that H2O2 exposure allows rapid phenotypic evolution in yeast strains. Our findings indicate DNA lesions resulting from H2O2 may be general factors that drive genome instability and phenotypic evolution in organisms.
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8.
Periodontitis: Genomic instability implications and associated risk factors.
Borba, TT, Molz, P, Schlickmann, DS, Santos, C, Oliveira, CF, Prá, D, Neto, LK, Franke, SIR
Mutation research. Genetic toxicology and environmental mutagenesis. 2019;:20-23
Abstract
Periodontitis is a bacterial infection characterized by the presence of a dense inflammatory infiltrate, which may result in increased DNA damage and other nuclear/cellular abnormalities. Therefore, it is important to evaluate the periodontal diseases influence on DNA damage and other nuclear/cellular abnomalies formation as cancer risk markers. Thus, the aim of this study was to evaluate the periodontal diseases effect, according to its severity, on the occurrence of DNA damage and other nuclear/cellular abnormalities. This is a cross-sectional study with 77 subjects from the dentistry clinic of the University of Santa Cruz do Sul, Brazil, divided in control group (26 subjects), moderate periodontal disease group (26 subjects) and severe periodontal disease group (25 subjects). All subjects answered self-referenced questionnaires, underwent periodontal clinical examinations and allowed the collection of oral mucosa cells for the BMCyt. In relation to DNA damage biomarkers (micronuclei (MN) and/or nuclear buds (NBUD)), our results indicated no increase in MN frequencies (p > 0.05), however it indicated significant difference in NBUD frequencies between groups (p < 0.024). This result suggests that the periodontal disease status may influence DNA damage. Regarding the other nuclear/cellular abnormalities, was observed a significant difference in the binucleated (BN) frequencies between groups (p < 0.05). Moreover, the periodontitis severity was associated to an increase in the combined (summed) frequency of cells with different levels of DNA damage (MN and/or NBUD), cytokinetic defects (BN cells) and/or cell death (karyorrhexis, pyknotic and karyolytic cells) (r = 0.235; p = 0.040). Periodontal disease depending on its severity, induces nuclear anomalies in buccal cells.
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Effects of crocin in reducing DNA damage, inflammation, and oxidative stress in multiple sclerosis patients: A double-blind, randomized, and placebo-controlled trial.
Ghiasian, M, Khamisabadi, F, Kheiripour, N, Karami, M, Haddadi, R, Ghaleiha, A, Taghvaei, B, Oliaie, SS, Salehi, M, Samadi, P, et al
Journal of biochemical and molecular toxicology. 2019;(12):e22410
Abstract
Multiple sclerosis (MS) is an autoimmune disease in which the immune system attacks the nerve cells, resulting in neurological disorders. Oxidative stress, free radicals, and neuritis have important roles in MS pathogenesis. Here, we aim to evaluate the effect of crocin on inflammatory markers, oxidative damage, and deoxyribonucleic acid (DNA) damage in the blood of patients with MS. A total of 40 patients were divided into two groups, drug and placebo-treated groups, using random assignment. Participants of the intervention and control groups received two crocin capsules or placebo per day for 28 days, respectively. Findings revealed a significant decrease in the level of important pathogenic factors in MS, including lipid peroxidation, DNA damage, tumor necrosis factor-alpha, and interleukin 17 as well as a significant increase in the total antioxidant capacity in the serum of patients treated with crocin compared with the placebo group. Our results suggest the beneficial and therapeutic effects of crocin in MS.
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10.
Sub-optimal Application of a High SPF Sunscreen Prevents Epidermal DNA Damage in Vivo.
Young, AR, Greenaway, J, Harrison, GI, Lawrence, KP, Sarkany, R, Douki, T, Boyer, F, Josse, G, Questel, E, Monteil, C, et al
Acta dermato-venereologica. 2018;(9):880-887
Abstract
The cyclobutane pyrimidine dimer (CPD) is a potentially mutagenic DNA photolesion that is the basis of most skin cancers. There are no data on DNA protection by sunscreens under typical conditions of use. The study aim was to determine such protection, in phototypes I/II, with representative sunscreen-user application. A very high SPF formulation was applied at 0.75, 1.3 and 2.0 mg/cm2. Unprotected control skin was exposed to 4 standard erythema doses (SED) of solar simulated UVR, and sunscreen-treated sites to 30 SED. Holiday behaviour was also simulated by UVR exposure for 5 consecutive days. Control skin received 1 SED daily, and sunscreen-treated sites received 15 (all 3 application thicknesses) or 30 (2.0 mg/cm2) SED daily. CPD were assessed by quantitative HPLC-tandem mass spectrometry (HPLC-MS/MS) and semi-quantitative immunostaining. In comparison with unprotected control sites, sunscreen significantly (p ≤ 0.001-0.05) reduced DNA damage at 1.3 and 2.0 mg/cm2 in all cases. However, reduction with typical sunscreen use (0.75 mg/cm2) was non-significant, with the exception of HPLC-MS/MS data for the 5-day study (p <0.001). Overall, these results support sunscreen use as a strategy to reduce skin cancer, and demonstrate that public health messages must stress better sunscreen application to get maximal benefit.