Determination of the physiological range of oxygen tension in bone marrow monocytes using two-photon phosphorescence lifetime imaging microscopy

Oxygen is a key regulator of both development and homeostasis. To study the role of oxygen, a variety of in vitro and ex vivo cell and tissue models have been used in biomedical research. However, because of ambiguity surrounding the level of oxygen that cells experience in vivo, the cellular pathwa...

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Published inScientific reports Vol. 12; no. 1; p. 3497
Main Authors Narazaki, Ayako, Shimizu, Reito, Yoshihara, Toshitada, Kikuta, Junichi, Sakaguchi, Reiko, Tobita, Seiji, Mori, Yasuo, Ishii, Masaru, Nishikawa, Keizo
Format Journal Article
LanguageEnglish
Published England Nature Publishing Group 10.03.2022
Nature Publishing Group UK
Nature Portfolio
Subjects
Animals
Bone imaging
Bone marrow
Bone Marrow - metabolism
Cell culture
Homeostasis
Hypoxia
Hypoxia - metabolism
Macrophages
Medical research
Mice
Microscopy
Monocytes
Monocytes - metabolism
Oxygen
Oxygen - metabolism
Oxygen tension
Oxygenation
Phenotypes
Phosphorescence
Photons
Physiology
Spatial discrimination
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Summary:Oxygen is a key regulator of both development and homeostasis. To study the role of oxygen, a variety of in vitro and ex vivo cell and tissue models have been used in biomedical research. However, because of ambiguity surrounding the level of oxygen that cells experience in vivo, the cellular pathway related to oxygenation state and hypoxia have been inadequately studied in many of these models. Here, we devised a method to determine the oxygen tension in bone marrow monocytes using two-photon phosphorescence lifetime imaging microscopy with the cell-penetrating phosphorescent probe, BTPDM1. Phosphorescence lifetime imaging revealed the physiological level of oxygen tension in monocytes to be 5.3% in live mice exposed to normal air. When the mice inhaled hypoxic air, the level of oxygen tension in bone marrow monocytes decreased to 2.4%. By performing in vitro cell culture experiment within the physiological range of oxygen tension, hypoxia changed the molecular phenotype of monocytes, leading to enhanced the expression of CD169 and CD206, which are markers of a unique subset of macrophages in bone marrow, osteal macrophages. This current study enables the determination of the physiological range of oxygen tension in bone marrow with spatial resolution at a cellular level and application of this information on oxygen tension in vivo to in vitro assays. Quantifying oxygen tension in tissues can provide invaluable information on metabolism under physiological and pathophyisological conditions. This method will open new avenues for research on oxygen biology.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-07521-9