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Characterising nitric oxide-mediated metabolic benefits of low-dose ultraviolet radiation in the mouse: a focus on brown adipose tissue

Characterising nitric oxide-mediated metabolic benefits of low-dose ultraviolet radiation in the mouse: a focus on brown adipose tissue
Characterising nitric oxide-mediated metabolic benefits of low-dose ultraviolet radiation in the mouse: a focus on brown adipose tissue

AIMS/HYPOTHESIS: Exposure to sunlight has the potential to suppress metabolic dysfunction and obesity. We previously demonstrated that regular exposure to low-doses of ultraviolet radiation (UVR) reduced weight gain and signs of diabetes in male mice fed a high-fat diet, in part via release of nitric oxide from skin. Here, we explore further mechanistic pathways through which low-dose UVR exerts these beneficial effects.

METHODS: We fed mice with a luciferase-tagged Ucp1 gene (which encodes uncoupling protein-1 [UCP-1]), referred to here as the Ucp1 luciferase transgenic mouse ('Thermomouse') a high-fat diet and examined the effects of repeated exposure to low-dose UVR on weight gain and development of metabolic dysfunction as well as UCP-1-dependent thermogenesis in interscapular brown adipose tissue (iBAT).

RESULTS: Repeated exposure to low-dose UVR suppressed the development of glucose intolerance and hepatic lipid accumulation via dermal release of nitric oxide while also reducing circulating IL-6 (compared with mice fed a high-fat diet only). Dietary nitrate supplementation did not mimic the effects of low-dose UVR. A single low dose of UVR increased UCP-1 expression (by more than twofold) in iBAT of mice fed a low-fat diet, 24 h after exposure. However, in mice fed a high-fat diet, there was no effect of UVR on UCP-1 expression in iBAT (compared with mock-treated mice) when measured at regular intervals over 12 weeks. More extensive circadian studies did not identify any substantial shifts in UCP-1 expression in mice exposed to low-dose UVR, although skin temperature at the interscapular site was reduced in UVR-exposed mice. The appearance of cells with a white adipocyte phenotype ('whitening') in iBAT induced by consuming the high-fat diet was suppressed by exposure to low-dose UVR in a nitric oxide-dependent fashion. Significant shifts in the expression of important core gene regulators of BAT function (Dio2, increased more than twofold), fatty acid transport (increased Fatp2 [also known as Slc27a2]), lipolysis (decreased Atgl [also known as Pnpla2]), lipogenesis (decreased Fasn) and inflammation (decreased Tnf), and proportions of macrophages (increased twofold) were observed in iBAT of mice exposed to low-dose UVR. These effects were independent of nitric oxide released from skin.

CONCLUSIONS/INTERPRETATION: Our results suggest that non-burning (low-dose) UVR suppresses the BAT 'whitening', steatotic and pro-diabetic effects of consuming a high-fat diet through skin release of nitric oxide, with some metabolic and immune pathways in iBAT regulated by UVR independently of nitric oxide.

Brown adipose tissue, Circadian rhythm, Hepatic steatosis, High-fat diet, Metabolic dysfunction, Mice, Nitric oxide, Ultraviolet radiation, Uncoupling protein-1, Whitening
0012-186X
179-193
Dhamrait, Gursimran K.
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Panchal, Kunjal
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Fleury, Naomi J.
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Abel, Tamara N.
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Ancliffe, Mathew K.
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Crew, Rachael C.
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Croft, Kevin
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Fernandez, Bernadette O.
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Minnion, Magdalena
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Hart, Prue H.
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Lucas, Robyn M.
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Mark, Peter J.
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Feelisch, Martin
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Weller, Richard B.
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Matthews, Vance
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Gorman, Shelley
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Dhamrait, Gursimran K.
98b2b474-6a73-431a-9eb0-ebd2cd6cf12c
Panchal, Kunjal
07a69101-302c-412d-88c4-742c9956eda0
Fleury, Naomi J.
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Abel, Tamara N.
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Ancliffe, Mathew K.
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Crew, Rachael C.
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Croft, Kevin
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Fernandez, Bernadette O.
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Minnion, Magdalena
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Hart, Prue H.
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Lucas, Robyn M.
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Mark, Peter J.
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Feelisch, Martin
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Weller, Richard B.
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Matthews, Vance
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Gorman, Shelley
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Dhamrait, Gursimran K., Panchal, Kunjal, Fleury, Naomi J., Abel, Tamara N., Ancliffe, Mathew K., Crew, Rachael C., Croft, Kevin, Fernandez, Bernadette O., Minnion, Magdalena, Hart, Prue H., Lucas, Robyn M., Mark, Peter J., Feelisch, Martin, Weller, Richard B., Matthews, Vance and Gorman, Shelley (2020) Characterising nitric oxide-mediated metabolic benefits of low-dose ultraviolet radiation in the mouse: a focus on brown adipose tissue. Diabetologia, 63 (1), 179-193. (doi:10.1007/s00125-019-05022-5).

Record type: Article

Abstract

AIMS/HYPOTHESIS: Exposure to sunlight has the potential to suppress metabolic dysfunction and obesity. We previously demonstrated that regular exposure to low-doses of ultraviolet radiation (UVR) reduced weight gain and signs of diabetes in male mice fed a high-fat diet, in part via release of nitric oxide from skin. Here, we explore further mechanistic pathways through which low-dose UVR exerts these beneficial effects.

METHODS: We fed mice with a luciferase-tagged Ucp1 gene (which encodes uncoupling protein-1 [UCP-1]), referred to here as the Ucp1 luciferase transgenic mouse ('Thermomouse') a high-fat diet and examined the effects of repeated exposure to low-dose UVR on weight gain and development of metabolic dysfunction as well as UCP-1-dependent thermogenesis in interscapular brown adipose tissue (iBAT).

RESULTS: Repeated exposure to low-dose UVR suppressed the development of glucose intolerance and hepatic lipid accumulation via dermal release of nitric oxide while also reducing circulating IL-6 (compared with mice fed a high-fat diet only). Dietary nitrate supplementation did not mimic the effects of low-dose UVR. A single low dose of UVR increased UCP-1 expression (by more than twofold) in iBAT of mice fed a low-fat diet, 24 h after exposure. However, in mice fed a high-fat diet, there was no effect of UVR on UCP-1 expression in iBAT (compared with mock-treated mice) when measured at regular intervals over 12 weeks. More extensive circadian studies did not identify any substantial shifts in UCP-1 expression in mice exposed to low-dose UVR, although skin temperature at the interscapular site was reduced in UVR-exposed mice. The appearance of cells with a white adipocyte phenotype ('whitening') in iBAT induced by consuming the high-fat diet was suppressed by exposure to low-dose UVR in a nitric oxide-dependent fashion. Significant shifts in the expression of important core gene regulators of BAT function (Dio2, increased more than twofold), fatty acid transport (increased Fatp2 [also known as Slc27a2]), lipolysis (decreased Atgl [also known as Pnpla2]), lipogenesis (decreased Fasn) and inflammation (decreased Tnf), and proportions of macrophages (increased twofold) were observed in iBAT of mice exposed to low-dose UVR. These effects were independent of nitric oxide released from skin.

CONCLUSIONS/INTERPRETATION: Our results suggest that non-burning (low-dose) UVR suppresses the BAT 'whitening', steatotic and pro-diabetic effects of consuming a high-fat diet through skin release of nitric oxide, with some metabolic and immune pathways in iBAT regulated by UVR independently of nitric oxide.

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Accepted/In Press date: 29 August 2019
e-pub ahead of print date: 11 November 2019
Published date: 1 January 2020
Keywords: Brown adipose tissue, Circadian rhythm, Hepatic steatosis, High-fat diet, Metabolic dysfunction, Mice, Nitric oxide, Ultraviolet radiation, Uncoupling protein-1, Whitening

Identifiers

Local EPrints ID: 436477
URI: http://eprints.soton.ac.uk/id/eprint/436477
ISSN: 0012-186X
PURE UUID: 81dfb224-2d15-4bba-9754-393c37440b27
ORCID for Bernadette O. Fernandez: ORCID iD orcid.org/0000-0001-6337-0381
ORCID for Martin Feelisch: ORCID iD orcid.org/0000-0003-2320-1158

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Date deposited: 11 Dec 2019 17:30
Last modified: 17 Mar 2024 05:07

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Contributors

Author: Gursimran K. Dhamrait
Author: Kunjal Panchal
Author: Naomi J. Fleury
Author: Tamara N. Abel
Author: Mathew K. Ancliffe
Author: Rachael C. Crew
Author: Kevin Croft
Author: Bernadette O. Fernandez ORCID iD
Author: Magdalena Minnion
Author: Prue H. Hart
Author: Robyn M. Lucas
Author: Peter J. Mark
Author: Martin Feelisch ORCID iD
Author: Richard B. Weller
Author: Vance Matthews
Author: Shelley Gorman

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