Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor

Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor

Rapid growth of brain tumors such as glioblastoma often results in oxygen deprivation and the emergence of hypoxic zones. In consequence, the enrichment of reactive oxygen species occurs, harming nonmalignant cells and leading them toward apoptotic cell death. However, cancer cells survive such expo...

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Main Authors: Kamil Krawczynski, Jakub Godlewski, Agnieszka Bronisz
Format: Article
Language:English
Published: MDPI AG 2020-08-01
Series:Antioxidants
Subjects:
glioblastoma
hypoxia
oxidative stress
cancer niche
tumor microenvironment
Online Access:https://www.mdpi.com/2076-3921/9/8/747
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spelling doaj-4bb491844afa403bb0b5893126a16f4b2020-11-25T03:38:38ZengMDPI AGAntioxidants2076-39212020-08-01974774710.3390/antiox9080747Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain TumorKamil Krawczynski0Jakub Godlewski1Agnieszka Bronisz2Department of Neurochemistry, Mossakowski Medical Research Centre, Polish Academy of Sciences, 02-106 Warsaw, PolandDepartment of Neurochemistry, Mossakowski Medical Research Centre, Polish Academy of Sciences, 02-106 Warsaw, PolandDepartment of Neurochemistry, Mossakowski Medical Research Centre, Polish Academy of Sciences, 02-106 Warsaw, PolandRapid growth of brain tumors such as glioblastoma often results in oxygen deprivation and the emergence of hypoxic zones. In consequence, the enrichment of reactive oxygen species occurs, harming nonmalignant cells and leading them toward apoptotic cell death. However, cancer cells survive such exposure and thrive in a hypoxic environment. As the mechanisms responsible for such starkly different outcomes are not sufficiently explained, we aimed to explore what transcriptome rearrangements are used by glioblastoma cells in hypoxic areas. Using metadata analysis of transcriptome in different subregions of the glioblastoma retrieved from the Ivy Glioblastoma Atlas Project, we created the reactive oxygen species-dependent map of the transcriptome. This map was then used for the analysis of differential gene expression in the histologically determined cellular tumors and hypoxic zones. The gene ontology analysis cross-referenced with the clinical data from The Cancer Genome Atlas revealed that the metabolic shift is one of the major prosurvival strategies applied by cancer cells to overcome hypoxia-related cytotoxicity.https://www.mdpi.com/2076-3921/9/8/747glioblastomahypoxiaoxidative stresscancer nichetumor microenvironment
collection DOAJ
language English
format Article
sources DOAJ
author Kamil Krawczynski
Jakub Godlewski
Agnieszka Bronisz
spellingShingle Kamil Krawczynski
Jakub Godlewski
Agnieszka Bronisz
Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor
Antioxidants
glioblastoma
hypoxia
oxidative stress
cancer niche
tumor microenvironment
author_facet Kamil Krawczynski
Jakub Godlewski
Agnieszka Bronisz
author_sort Kamil Krawczynski
title Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor
title_short Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor
title_full Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor
title_fullStr Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor
title_full_unstemmed Oxidative Stress—Part of the Solution or Part of the Problem in the Hypoxic Environment of a Brain Tumor
title_sort oxidative stress—part of the solution or part of the problem in the hypoxic environment of a brain tumor
publisher MDPI AG
series Antioxidants
issn 2076-3921
publishDate 2020-08-01
description Rapid growth of brain tumors such as glioblastoma often results in oxygen deprivation and the emergence of hypoxic zones. In consequence, the enrichment of reactive oxygen species occurs, harming nonmalignant cells and leading them toward apoptotic cell death. However, cancer cells survive such exposure and thrive in a hypoxic environment. As the mechanisms responsible for such starkly different outcomes are not sufficiently explained, we aimed to explore what transcriptome rearrangements are used by glioblastoma cells in hypoxic areas. Using metadata analysis of transcriptome in different subregions of the glioblastoma retrieved from the Ivy Glioblastoma Atlas Project, we created the reactive oxygen species-dependent map of the transcriptome. This map was then used for the analysis of differential gene expression in the histologically determined cellular tumors and hypoxic zones. The gene ontology analysis cross-referenced with the clinical data from The Cancer Genome Atlas revealed that the metabolic shift is one of the major prosurvival strategies applied by cancer cells to overcome hypoxia-related cytotoxicity.
topic glioblastoma
hypoxia
oxidative stress
cancer niche
tumor microenvironment
url https://www.mdpi.com/2076-3921/9/8/747
work_keys_str_mv AT kamilkrawczynski oxidativestresspartofthesolutionorpartoftheprobleminthehypoxicenvironmentofabraintumor
AT jakubgodlewski oxidativestresspartofthesolutionorpartoftheprobleminthehypoxicenvironmentofabraintumor
AT agnieszkabronisz oxidativestresspartofthesolutionorpartoftheprobleminthehypoxicenvironmentofabraintumor
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