Cell Cycle Modulation through Subcellular Spatially Resolved Production of Singlet Oxygen via Direct 765 nm Irradiation: Manipulating the Onset of Mitosis.

Alfonso Blazquez-Castro; Thomas Breitenbach; Peter Remsen Ogilby

doi:10.1039/c8pp00338f

Cell Cycle Modulation through Subcellular Spatially Resolved Production of Singlet Oxygen via Direct 765 nm Irradiation: Manipulating the Onset of Mitosis.

Alfonso Blazquez-Castro, Thomas Breitenbach, Peter Remsen Ogilby

Department of Chemistry

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

13 Citations (Scopus)

Abstract

Reactive oxygen species, ROS, are acknowledged signaling molecules in cellular processes. Singlet molecular oxygen, O ₂(a ¹Δ _g), is one ROS that can initiate cell responses that range from death to proliferation. To better understand the mechanisms involved, it is necessary to further investigate cell response to the “dose” of O ₂(a ¹Δ _g) that has been selectively produced at the expense of other ROS. In this context, dose refers not just to the amount of O ₂(a ¹Δ _g) produced, but also to the subcellular spatial domain in which it is produced. In this study, we selectively produced small and non-toxic amounts of O ₂(a ¹Δ _g) in sensitizer-free experiments by irradiating oxygen at 765 nm using a laser focused either into the nucleus or cytoplasm of HeLa cells. We find that O ₂(a ¹Δ _g)-mediated cell proliferation depends appreciably on the site of O ₂(a ¹Δ _g) production. At the same incident laser power, irradiation into the cytoplasm elicits moderate enhancement of proliferation, whereas irradiation into the nucleus leads to an appreciable delay in the onset and completion of mitosis. We discuss these results in light of what is known about the intracellular photophysics of O ₂(a ¹Δ _g) and the redox state of different cell domains.

Original language	English
Journal	Photochemical & Photobiological Sciences
Volume	17
Issue	10
Pages (from-to)	1310-1318
Number of pages	9
ISSN	1474-905X
DOIs	https://doi.org/10.1039/c8pp00338f
Publication status	Published - 2018

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title = "Cell Cycle Modulation through Subcellular Spatially Resolved Production of Singlet Oxygen via Direct 765 nm Irradiation: Manipulating the Onset of Mitosis.",

abstract = "Reactive oxygen species, ROS, are acknowledged signaling molecules in cellular processes. Singlet molecular oxygen, O 2(a 1Δ g), is one ROS that can initiate cell responses that range from death to proliferation. To better understand the mechanisms involved, it is necessary to further investigate cell response to the “dose” of O 2(a 1Δ g) that has been selectively produced at the expense of other ROS. In this context, dose refers not just to the amount of O 2(a 1Δ g) produced, but also to the subcellular spatial domain in which it is produced. In this study, we selectively produced small and non-toxic amounts of O 2(a 1Δ g) in sensitizer-free experiments by irradiating oxygen at 765 nm using a laser focused either into the nucleus or cytoplasm of HeLa cells. We find that O 2(a 1Δ g)-mediated cell proliferation depends appreciably on the site of O 2(a 1Δ g) production. At the same incident laser power, irradiation into the cytoplasm elicits moderate enhancement of proliferation, whereas irradiation into the nucleus leads to an appreciable delay in the onset and completion of mitosis. We discuss these results in light of what is known about the intracellular photophysics of O 2(a 1Δ g) and the redox state of different cell domains.",

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Cell Cycle Modulation through Subcellular Spatially Resolved Production of Singlet Oxygen via Direct 765 nm Irradiation: Manipulating the Onset of Mitosis. / Blazquez-Castro, Alfonso; Breitenbach, Thomas ; Ogilby, Peter Remsen.
In: Photochemical & Photobiological Sciences, Vol. 17, No. 10, 2018, p. 1310-1318.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

TY - JOUR

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AU - Ogilby, Peter Remsen

PY - 2018

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AB - Reactive oxygen species, ROS, are acknowledged signaling molecules in cellular processes. Singlet molecular oxygen, O 2(a 1Δ g), is one ROS that can initiate cell responses that range from death to proliferation. To better understand the mechanisms involved, it is necessary to further investigate cell response to the “dose” of O 2(a 1Δ g) that has been selectively produced at the expense of other ROS. In this context, dose refers not just to the amount of O 2(a 1Δ g) produced, but also to the subcellular spatial domain in which it is produced. In this study, we selectively produced small and non-toxic amounts of O 2(a 1Δ g) in sensitizer-free experiments by irradiating oxygen at 765 nm using a laser focused either into the nucleus or cytoplasm of HeLa cells. We find that O 2(a 1Δ g)-mediated cell proliferation depends appreciably on the site of O 2(a 1Δ g) production. At the same incident laser power, irradiation into the cytoplasm elicits moderate enhancement of proliferation, whereas irradiation into the nucleus leads to an appreciable delay in the onset and completion of mitosis. We discuss these results in light of what is known about the intracellular photophysics of O 2(a 1Δ g) and the redox state of different cell domains.

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Cell Cycle Modulation through Subcellular Spatially Resolved Production of Singlet Oxygen via Direct 765 nm Irradiation: Manipulating the Onset of Mitosis.

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