Hypoxia-induced disruption of neural vascular barrier is mediated by the intracellular induction of Fe(II) ion

Neural vascular barrier maintains the optimal tissue microenvironment of central nervous system in which neural cells can function normally. In various neural diseases, the decrease in oxygen concentration, hypoxia, of affected tissues is known to accelerate the disease progression through disruptio...

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Published inExperimental cell research Vol. 379; no. 2; pp. 166 - 171
Main Authors Cui, Dan, Arima, Mitsuru, Hirayama, Tasuku, Ikeda, Eiji
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 15.06.2019
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Summary:Neural vascular barrier maintains the optimal tissue microenvironment of central nervous system in which neural cells can function normally. In various neural diseases, the decrease in oxygen concentration, hypoxia, of affected tissues is known to accelerate the disease progression through disruption of neural vascular barrier. Therefore, the clarification of mechanisms underlying hypoxia-induced disruption of neural vascular barrier would definitely lead to the establishment of new effective therapies for intractable neural diseases. In the present study, we first found that hypoxia disrupts neural vascular barrier through pathways independent of HIF-1α and HIF-2α. Then, with a specific fluorescence probe for ferrous, Fe(II) ion, we have obtained the interesting data showing that hypoxia increased the intracellular level of Fe(II) ion in endothelial cells of our in vitro model for neural vascular barrier, and that hypoxia-induced disruption of neural vascular barrier could be inhibited by chelating Fe(II) ion in endothelial cells. Furthermore, in the presence of a reducing reagent for reactive oxygen species (ROS), hypoxia could not disrupt the neural vascular barrier despite that the hypoxic increase in intracellular level of Fe(II) ion was confirmed in endothelial cells. These results indicate that hypoxia-triggered increase in the level of intracellular Fe(II) ion and subsequent production of ROS, probably through Fenton reaction, are the essential pathway mediating the disruption of neural vascular barrier under hypoxia.
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ISSN:0014-4827
1090-2422
DOI:10.1016/j.yexcr.2019.04.003