Y. Iztleuov, M. Iztleuov, A. Elubaeva, A. Tulyaeyva, N. Abenova
{"title":"电离辐射的致癌性:文献综述","authors":"Y. Iztleuov, M. Iztleuov, A. Elubaeva, A. Tulyaeyva, N. Abenova","doi":"10.52532/2521-6414-2023-4-70-39-45","DOIUrl":null,"url":null,"abstract":"Relevance: According to WHO, malignant neoplasms rank second in population mortality structure due to a constantly increasing influence of technogenic factors that have a direct carcinogenic effect on the body and suppress defense mechanisms. Ionizing radiation plays a special role in the development of cancer. It is used in industry, agriculture, medicine, and scientific research as a diagnostic tool in modern healthcare and radiation therapy for cancer treatment. The consequences of radiation influence are not only the result of a direct effect on the body but also a delayed one through generations of parents and grandparents. According to the radiobiological hypothesis, any level of radiation, no matter how small, ОБЗОРЫ ЛИТЕРАТУРЫ Онкология и Радиология Казахстана, №4 (70) 2023 45 poses a risk of long-term consequences, including cancer, in exposed people and their descendants of the first two generations. That is, cancerous tumors are likely consequences of the influence of radiation. Despite various theories of the biological effect of low doses of ionizing radiation, most authors attach primary importance to DNA damage in the manifestation of genetic effects (the concept of non-threshold mutational action). The study aimed to highlight the role of ionizing radiation in tumorigenesis. Methods: Data from MEDLINE, Embase, Scopus, PubMed, Cochrane Central Register of Controlled Trials was analyzed to select and analyze relevant information over the past 10 years using the keywords: gamma irradiation, spontaneous oncogenesis, prevention of oncogenesis, Results: Radiation exposure may increase the risk of cancer development due to epigenetic changes leading to increased genomic instability (GI) and/or specific suppression of tumor suppressor genes. Changes in the TP53 gene network expression occur; the most significant genes as predictors of carcinogenesis are ST13, IER3, BRCAI, LRDD, and MRAS. Epigenetic changes also influence individual susceptibility to radiation-induced cancer. In addition to the mutagenic effects of ROS and AFN, there is also evidence that oxidative stress plays a fundamental role in epigenetic modifications. Conclusion: As a result of radiation exposure, damage occurs that causes genetic and epigenetic changes, leading to changes in the level of protein expression due to changes in the methylation of cytosine residues in DNA, modification of histones, and regulation of microRNA expression.","PeriodicalId":19480,"journal":{"name":"Oncologia i radiologia Kazakhstana","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2023-12-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"CARCINOGENICITY OF IONIZING RADIATION: A LITERATURE REVIEW\",\"authors\":\"Y. Iztleuov, M. Iztleuov, A. Elubaeva, A. Tulyaeyva, N. Abenova\",\"doi\":\"10.52532/2521-6414-2023-4-70-39-45\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Relevance: According to WHO, malignant neoplasms rank second in population mortality structure due to a constantly increasing influence of technogenic factors that have a direct carcinogenic effect on the body and suppress defense mechanisms. Ionizing radiation plays a special role in the development of cancer. It is used in industry, agriculture, medicine, and scientific research as a diagnostic tool in modern healthcare and radiation therapy for cancer treatment. The consequences of radiation influence are not only the result of a direct effect on the body but also a delayed one through generations of parents and grandparents. According to the radiobiological hypothesis, any level of radiation, no matter how small, ОБЗОРЫ ЛИТЕРАТУРЫ Онкология и Радиология Казахстана, №4 (70) 2023 45 poses a risk of long-term consequences, including cancer, in exposed people and their descendants of the first two generations. That is, cancerous tumors are likely consequences of the influence of radiation. Despite various theories of the biological effect of low doses of ionizing radiation, most authors attach primary importance to DNA damage in the manifestation of genetic effects (the concept of non-threshold mutational action). The study aimed to highlight the role of ionizing radiation in tumorigenesis. Methods: Data from MEDLINE, Embase, Scopus, PubMed, Cochrane Central Register of Controlled Trials was analyzed to select and analyze relevant information over the past 10 years using the keywords: gamma irradiation, spontaneous oncogenesis, prevention of oncogenesis, Results: Radiation exposure may increase the risk of cancer development due to epigenetic changes leading to increased genomic instability (GI) and/or specific suppression of tumor suppressor genes. Changes in the TP53 gene network expression occur; the most significant genes as predictors of carcinogenesis are ST13, IER3, BRCAI, LRDD, and MRAS. Epigenetic changes also influence individual susceptibility to radiation-induced cancer. In addition to the mutagenic effects of ROS and AFN, there is also evidence that oxidative stress plays a fundamental role in epigenetic modifications. 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引用次数: 0
摘要
相关性:世卫组织称,恶性肿瘤在人口死亡率结构中位居第二,这是因为技术因素的影响不断增加,对人体产生直接致癌作用并抑制防御机制。电离辐射在癌症的发展中起着特殊作用。在工业、农业、医学和科学研究中,电离辐射被用作现代医疗的诊断工具和治疗癌症的放射疗法。辐射影响的后果不仅是对人体的直接影响,而且是通过父母和祖父母世代相传的延迟影响。根据放射生物学假说,任何程度的辐射,无论多么微小,都会对人体产生影响、№4 (70) 2023 45 有可能对接触者及其前两代的后代造成包括癌症在内的长期后果。也就是说,癌症肿瘤很可能是辐射影响的后果。尽管关于低剂量电离辐射生物效应的理论多种多样,但大多数作者都将 DNA 损伤作为遗传效应表现的首要因素(非阈值突变作用概念)。 本研究旨在强调电离辐射在肿瘤发生中的作用。 研究方法分析了来自 MEDLINE、Embase、Scopus、PubMed 和 Cochrane Central Register of Controlled Trials 的数据,以伽马辐照、自发肿瘤发生、预防肿瘤发生为关键词,筛选并分析了过去 10 年的相关信息:由于表观遗传学变化导致基因组不稳定性(GI)增加和/或肿瘤抑制基因的特异性抑制,辐照可能会增加癌症发生的风险。TP53 基因网络的表达发生了变化;预测癌症发生的最重要基因是 ST13、IER3、BRCAI、LRDD 和 MRAS。表观遗传变化也会影响个人对辐射诱发癌症的易感性。除了 ROS 和 AFN 的诱变作用外,还有证据表明氧化应激在表观遗传修饰中起着根本性的作用。 结论辐照造成的损伤会引起基因和表观遗传学的变化,导致 DNA 中胞嘧啶残基的甲基化、组蛋白的修饰和 microRNA 表达的调控引起蛋白质表达水平的变化。
CARCINOGENICITY OF IONIZING RADIATION: A LITERATURE REVIEW
Relevance: According to WHO, malignant neoplasms rank second in population mortality structure due to a constantly increasing influence of technogenic factors that have a direct carcinogenic effect on the body and suppress defense mechanisms. Ionizing radiation plays a special role in the development of cancer. It is used in industry, agriculture, medicine, and scientific research as a diagnostic tool in modern healthcare and radiation therapy for cancer treatment. The consequences of radiation influence are not only the result of a direct effect on the body but also a delayed one through generations of parents and grandparents. According to the radiobiological hypothesis, any level of radiation, no matter how small, ОБЗОРЫ ЛИТЕРАТУРЫ Онкология и Радиология Казахстана, №4 (70) 2023 45 poses a risk of long-term consequences, including cancer, in exposed people and their descendants of the first two generations. That is, cancerous tumors are likely consequences of the influence of radiation. Despite various theories of the biological effect of low doses of ionizing radiation, most authors attach primary importance to DNA damage in the manifestation of genetic effects (the concept of non-threshold mutational action). The study aimed to highlight the role of ionizing radiation in tumorigenesis. Methods: Data from MEDLINE, Embase, Scopus, PubMed, Cochrane Central Register of Controlled Trials was analyzed to select and analyze relevant information over the past 10 years using the keywords: gamma irradiation, spontaneous oncogenesis, prevention of oncogenesis, Results: Radiation exposure may increase the risk of cancer development due to epigenetic changes leading to increased genomic instability (GI) and/or specific suppression of tumor suppressor genes. Changes in the TP53 gene network expression occur; the most significant genes as predictors of carcinogenesis are ST13, IER3, BRCAI, LRDD, and MRAS. Epigenetic changes also influence individual susceptibility to radiation-induced cancer. In addition to the mutagenic effects of ROS and AFN, there is also evidence that oxidative stress plays a fundamental role in epigenetic modifications. Conclusion: As a result of radiation exposure, damage occurs that causes genetic and epigenetic changes, leading to changes in the level of protein expression due to changes in the methylation of cytosine residues in DNA, modification of histones, and regulation of microRNA expression.