Erik Bivehed , Björn Hellman , Yuting Fan , Jakob Haglöf , Sonja Buratovic
{"title":"碱性条件下的DNA完整性:彗星测定影响因素的研究。","authors":"Erik Bivehed , Björn Hellman , Yuting Fan , Jakob Haglöf , Sonja Buratovic","doi":"10.1016/j.mrgentox.2023.503680","DOIUrl":null,"url":null,"abstract":"<div><p>The effect of pH on DNA integrity was assessed using a three-step approach. The comet assay was used on a whole genome level, with three different protocols: neutral (no alkaline unwinding), flash (pH 12.5 with 2.5 min unwinding), and the conventional alkaline protocol (pH>13 with 40 min unwinding). Real-time quantitative PCR (RT-qPCR) was then used to study the isolated DNA, revealing that gene amplification decreased with increasing pH, indicating DNA degradation. Specially designed molecular beacons were used to examine DNA at the molecular level, with or without alkali-labile site (ALS) insertions. At pH 12.5, fluorescence in the hairpins with ALS started to increase after 30 min, while at pH> 13, this increase was already observed after 5 min, indicating a significant increase in DNA strand breaks. Liquid chromatography analysis was also used, demonstrating that the hairpins remained intact up to pH 10, even after 1 h exposure, whereas, at pH 12.5, partial conversion into strand breaks occurred after 30 min. At pH> 13, the hairpins were almost completely degraded after 30 min. The flash protocol effectively detects DNA single- and double-strand breaks and identified these damages after 2.5 min of alkaline treatment at pH 12.5. When the hairpins were exposed to pH 12.5 for 60 min, ALS were converted to strand breaks, demonstrating the sensitivity of this approach to detect changes in DNA structure. These findings indicate that pH poses a substantial risk to DNA integrity, leading to significantly higher background levels of DNA damage compared to conditions closer to neutrality. Our study demonstrates the importance of understanding the influence of pH on DNA stability and provides insights into risks associated with alkaline environments, especially at pH> 13.</p></div>","PeriodicalId":18799,"journal":{"name":"Mutation research. Genetic toxicology and environmental mutagenesis","volume":"891 ","pages":"Article 503680"},"PeriodicalIF":2.3000,"publicationDate":"2023-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"DNA integrity under alkaline conditions: An investigation of factors affecting the comet assay\",\"authors\":\"Erik Bivehed , Björn Hellman , Yuting Fan , Jakob Haglöf , Sonja Buratovic\",\"doi\":\"10.1016/j.mrgentox.2023.503680\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>The effect of pH on DNA integrity was assessed using a three-step approach. The comet assay was used on a whole genome level, with three different protocols: neutral (no alkaline unwinding), flash (pH 12.5 with 2.5 min unwinding), and the conventional alkaline protocol (pH>13 with 40 min unwinding). Real-time quantitative PCR (RT-qPCR) was then used to study the isolated DNA, revealing that gene amplification decreased with increasing pH, indicating DNA degradation. Specially designed molecular beacons were used to examine DNA at the molecular level, with or without alkali-labile site (ALS) insertions. At pH 12.5, fluorescence in the hairpins with ALS started to increase after 30 min, while at pH> 13, this increase was already observed after 5 min, indicating a significant increase in DNA strand breaks. Liquid chromatography analysis was also used, demonstrating that the hairpins remained intact up to pH 10, even after 1 h exposure, whereas, at pH 12.5, partial conversion into strand breaks occurred after 30 min. At pH> 13, the hairpins were almost completely degraded after 30 min. The flash protocol effectively detects DNA single- and double-strand breaks and identified these damages after 2.5 min of alkaline treatment at pH 12.5. When the hairpins were exposed to pH 12.5 for 60 min, ALS were converted to strand breaks, demonstrating the sensitivity of this approach to detect changes in DNA structure. These findings indicate that pH poses a substantial risk to DNA integrity, leading to significantly higher background levels of DNA damage compared to conditions closer to neutrality. Our study demonstrates the importance of understanding the influence of pH on DNA stability and provides insights into risks associated with alkaline environments, especially at pH> 13.</p></div>\",\"PeriodicalId\":18799,\"journal\":{\"name\":\"Mutation research. 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Genetic toxicology and environmental mutagenesis","FirstCategoryId":"3","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S1383571823000980","RegionNum":4,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"BIOTECHNOLOGY & APPLIED MICROBIOLOGY","Score":null,"Total":0}
DNA integrity under alkaline conditions: An investigation of factors affecting the comet assay
The effect of pH on DNA integrity was assessed using a three-step approach. The comet assay was used on a whole genome level, with three different protocols: neutral (no alkaline unwinding), flash (pH 12.5 with 2.5 min unwinding), and the conventional alkaline protocol (pH>13 with 40 min unwinding). Real-time quantitative PCR (RT-qPCR) was then used to study the isolated DNA, revealing that gene amplification decreased with increasing pH, indicating DNA degradation. Specially designed molecular beacons were used to examine DNA at the molecular level, with or without alkali-labile site (ALS) insertions. At pH 12.5, fluorescence in the hairpins with ALS started to increase after 30 min, while at pH> 13, this increase was already observed after 5 min, indicating a significant increase in DNA strand breaks. Liquid chromatography analysis was also used, demonstrating that the hairpins remained intact up to pH 10, even after 1 h exposure, whereas, at pH 12.5, partial conversion into strand breaks occurred after 30 min. At pH> 13, the hairpins were almost completely degraded after 30 min. The flash protocol effectively detects DNA single- and double-strand breaks and identified these damages after 2.5 min of alkaline treatment at pH 12.5. When the hairpins were exposed to pH 12.5 for 60 min, ALS were converted to strand breaks, demonstrating the sensitivity of this approach to detect changes in DNA structure. These findings indicate that pH poses a substantial risk to DNA integrity, leading to significantly higher background levels of DNA damage compared to conditions closer to neutrality. Our study demonstrates the importance of understanding the influence of pH on DNA stability and provides insights into risks associated with alkaline environments, especially at pH> 13.
期刊介绍:
Mutation Research - Genetic Toxicology and Environmental Mutagenesis (MRGTEM) publishes papers advancing knowledge in the field of genetic toxicology. Papers are welcomed in the following areas:
New developments in genotoxicity testing of chemical agents (e.g. improvements in methodology of assay systems and interpretation of results).
Alternatives to and refinement of the use of animals in genotoxicity testing.
Nano-genotoxicology, the study of genotoxicity hazards and risks related to novel man-made nanomaterials.
Studies of epigenetic changes in relation to genotoxic effects.
The use of structure-activity relationships in predicting genotoxic effects.
The isolation and chemical characterization of novel environmental mutagens.
The measurement of genotoxic effects in human populations, when accompanied by quantitative measurements of environmental or occupational exposures.
The application of novel technologies for assessing the hazard and risks associated with genotoxic substances (e.g. OMICS or other high-throughput approaches to genotoxicity testing).
MRGTEM is now accepting submissions for a new section of the journal: Current Topics in Genotoxicity Testing, that will be dedicated to the discussion of current issues relating to design, interpretation and strategic use of genotoxicity tests. This section is envisaged to include discussions relating to the development of new international testing guidelines, but also to wider topics in the field. The evaluation of contrasting or opposing viewpoints is welcomed as long as the presentation is in accordance with the journal''s aims, scope, and policies.