Effects of High-Dose Ionizing Radiation in Human Gene Expression: A Meta-Analysis

Kanakoglou, Dimitrios S; Michalettou, Theodora-Dafni; Vasileiou, Christina; Gioukakis, Evangelos; Maneta, Dorothea; Kyriakidis, Konstantinos; Georgakilas, Alexandros G.; Michalopoulos, Ioannis

doi:10.3390/ijms21061938

Cited by 8 publications

(9 citation statements)

References 76 publications

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“…Accumulated knowledge over years of research on the biological effects of radiation points toward the development of holistic approaches to “big data” analysis by employing systems biology methodologies (Unger, 2014 ; Beheshti et al, 2019 ; Spratt and Speers, 2019 ; Kanakoglou et al, 2020 ). Herein, we employed a rigorous systems biology approach to unravel the molecular determinants of resistance of cancer cells to IR, based solely on HTP data.…”

Section: Introductionmentioning

confidence: 99%

Investigating Molecular Determinants of Cancer Cell Resistance to Ionizing Radiation Through an Integrative Bioinformatics Approach

Toy

Karakülah

Kontou

et al. 2021

Front. Cell Dev. Biol.

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Eradication of cancer cells through exposure to high doses of ionizing radiation (IR) is a widely used therapeutic strategy in the clinical setting. However, in many cases, cancer cells can develop remarkable resistance to radiation. Radioresistance represents a prominent obstacle in the effective treatment of cancer. Therefore, elucidation of the molecular mechanisms and pathways related to radioresistance in cancer cells is of paramount importance. In the present study, an integrative bioinformatics approach was applied to three publicly available RNA sequencing and microarray transcriptome datasets of human cancer cells of different tissue origins treated with ionizing radiation. These data were investigated in order to identify genes with a significantly altered expression between radioresistant and corresponding radiosensitive cancer cells. Through rigorous statistical and biological analyses, 36 genes were identified as potential biomarkers of radioresistance. These genes, which are primarily implicated in DNA damage repair, oxidative stress, cell pro-survival, and apoptotic pathways, could serve as potential diagnostic/prognostic markers cancer cell resistance to radiation treatment, as well as for therapy outcome and cancer patient survival. In addition, our findings could be potentially utilized in the laboratory and clinical setting for enhancing cancer cell susceptibility to radiation therapy protocols.

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Section: Introductionmentioning

confidence: 99%

Investigating Molecular Determinants of Cancer Cell Resistance to Ionizing Radiation Through an Integrative Bioinformatics Approach

Toy

Karakülah

Kontou

et al. 2021

Front. Cell Dev. Biol.

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“…The use of a reference genome in the study of medical genetics, with the help of novel tools and methods, can help the identification of novel drug-sequence variant interactions ( 46 ) and the identification of variants which may be related to mutations with a genetic base of a variety of genetic diseases, such as cancer ( 47 ) and produce further analysis ( 48 ). By studying these variants, we are able to analyse the differences and the heterogeneity of different populations in order to understand their differences ( 49 ).…”

Section: Discussionmentioning

confidence: 99%

Benchmarking of next and third generation sequencing technologies and their associated algorithms for de novo genome assembly

et al. 2021

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“…The presence of the CDKN1A gene is identified in all three networks (Figures 4-6). This gene has also been found to be overexpressed in multiple IR-exposed human cell lines, such as a series of healthy cells after exposure to high doses of X-rays and gamma-rays [68], and healthy [95] and cancerous [96] breast epithelial cells exposed to high doses of electron radiation. The p21 protein encoded by this gene, which is known to be interdependent with tumor suppressor protein TP53 [13], is also responsible for inhibiting cellular proliferation in response to DNA damage and highly correlated with DNA repair and apoptosis [76].…”

Section: Discussionmentioning

confidence: 99%

“…In order to achieve optimal results, DEG lists were sorted into 3 groups (Table 1) depending on radiation type, radiation dose and time of collection post-irradiation before being subjected to a meta-analysis. Our meta-analysis method combined unadjusted p-values of each study for every gene, using a weighted version of Stouffer's meta-analysis [66], proposed by Mosteller and Bush [67], as previously described [68]. For each gene and study, its two-tailed unadjusted p-value was converted into a one-tailed p-value, based on the sign of the corresponding Log 2 FC.…”

Section: Implementation Of Meta-analysesmentioning

confidence: 99%

A Meta-Analysis of the Effects of High-LET Ionizing Radiations in Human Gene Expression

Michalettou

Michalopoulos

Costes

et al. 2021

Life

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The use of high linear energy transfer (LET) ionizing radiation (IR) is progressively being incorporated in radiation therapy due to its precise dose localization and high relative biological effectiveness. At the same time, these benefits of particle radiation become a high risk for astronauts in the case of inevitable cosmic radiation exposure. Nonetheless, DNA Damage Response (DDR) activated via complex DNA damage in healthy tissue, occurring from such types of radiation, may be instrumental in the induction of various chronic and late effects. An approach to elucidating the possible underlying mechanisms is studying alterations in gene expression. To this end, we identified differentially expressed genes (DEGs) in high Z and high energy (HZE) particle-, γ-ray- and X-ray-exposed healthy human tissues, utilizing microarray data available in public repositories. Differential gene expression analysis (DGEA) was conducted using the R programming language. Consequently, four separate meta-analyses were conducted, after DEG lists were grouped depending on radiation type, radiation dose and time of collection post-irradiation. To highlight the biological background of each meta-analysis group, functional enrichment analysis and biological network construction were conducted. For HZE particle exposure at 8–24 h post-irradiation, the most interesting finding is the variety of DNA repair mechanisms that were downregulated, a fact that is probably correlated with complex DNA damage formation. Simultaneously, after X-ray exposure during the same hours after irradiation, DNA repair mechanisms continue to take place. Finally, in a further comparison of low- and high-LET radiation effects, the most prominent result is that autophagy mechanisms seem to persist and that adaptive immune induction seems to be present. Such bioinformatics approaches may aid in obtaining an overview of the cellular response to high-LET particles. Understanding these response mechanisms can consequently aid in the development of countermeasures for future space missions and ameliorate heavy ion treatments.

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Effects of High-Dose Ionizing Radiation in Human Gene Expression: A Meta-Analysis

Cited by 8 publications

References 76 publications

Investigating Molecular Determinants of Cancer Cell Resistance to Ionizing Radiation Through an Integrative Bioinformatics Approach

Investigating Molecular Determinants of Cancer Cell Resistance to Ionizing Radiation Through an Integrative Bioinformatics Approach

Benchmarking of next and third generation sequencing technologies and their associated algorithms for de novo genome assembly

A Meta-Analysis of the Effects of High-LET Ionizing Radiations in Human Gene Expression

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