Adropin: An endocrine link between the biological clock and cholesterol homeostasis

Sarbani Ghoshal; Joseph R. Stevens; Cyrielle Billon; Clemence Girardet; Sadichha Sitaula; Arthur S. Leon; D. C. Rao; James S. Skinner; Tuomo Rankinen; Claude Bouchard; Marinelle V. Nuñez; Kimber L. Stanhope; Deborah A. Howatt; Alan Daugherty; Jinsong Zhang; Matthew Schuelke; Edward P. Weiss; Alisha R. Coffey; Brian J. Bennett; Praveen Sethupathy; Thomas P. Burris; Peter J. Havel; Andrew A. Butler

doi:10.1016/j.molmet.2017.12.002

Adropin: An endocrine link between the biological clock and cholesterol homeostasis

Sarbani Ghoshal, Joseph R. Stevens, Cyrielle Billon, Clemence Girardet, Sadichha Sitaula, Arthur S. Leon, D. C. Rao, James S. Skinner, Tuomo Rankinen, Claude Bouchard, Marinelle V. Nuñez, Kimber L. Stanhope, Deborah A. Howatt, Alan Daugherty, Jinsong Zhang, Matthew Schuelke, Edward P. Weiss, Alisha R. Coffey, Brian J. Bennett, Praveen SethupathyThomas P. Burris, Peter J. Havel, Andrew A. Butler

Research output: Contribution to journal › Article › peer-review

57 Scopus citations

Abstract

Objective: Identify determinants of plasma adropin concentrations, a secreted peptide translated from the Energy Homeostasis Associated (ENHO) gene linked to metabolic control and vascular function. Methods: Associations between plasma adropin concentrations, demographics (sex, age, BMI) and circulating biomarkers of lipid and glucose metabolism were assessed in plasma obtained after an overnight fast in humans. The regulation of adropin expression was then assessed in silico, in cultured human cells, and in animal models. Results: In humans, plasma adropin concentrations are inversely related to atherogenic LDL-cholesterol (LDL-C) levels in men (n = 349), but not in women (n = 401). Analysis of hepatic Enho expression in male mice suggests control by the biological clock. Expression is rhythmic, peaking during maximal food consumption in the dark correlating with transcriptional activation by RORα/γ. The nadir in the light phase coincides with the rest phase and repression by Rev-erb. Plasma adropin concentrations in nonhuman primates (rhesus monkeys) also exhibit peaks coinciding with feeding times (07:00 h, 15:00 h). The ROR inverse agonists SR1001 and the 7-oxygenated sterols 7-β-hydroxysterol and 7-ketocholesterol, or the Rev-erb agonist SR9009, suppress ENHO expression in cultured human HepG2 cells. Consumption of high-cholesterol diets suppress expression of the adropin transcript in mouse liver. However, adropin over expression does not prevent hypercholesterolemia resulting from a high cholesterol diet and/or LDL receptor mutations. Conclusions: In humans, associations between plasma adropin concentrations and LDL-C suggest a link with hepatic lipid metabolism. Mouse studies suggest that the relationship between adropin and cholesterol metabolism is unidirectional, and predominantly involves suppression of adropin expression by cholesterol and 7-oxygenated sterols. Sensing of fatty acids, cholesterol and oxysterols by the RORα/γ ligand-binding domain suggests a plausible functional link between adropin expression and cellular lipid metabolism. Furthermore, the nuclear receptors RORα/γ and Rev-erb may couple adropin synthesis with circadian rhythms in carbohydrate and lipid metabolism.

Original language	English
Pages (from-to)	51-64
Number of pages	14
Journal	Molecular Metabolism
Volume	8
DOIs	https://doi.org/10.1016/j.molmet.2017.12.002
State	Published - Feb 2018

Bibliographical note

Funding Information:
AAB acknowledges support from the Lottie Caroline Hardy Charitable Trust. The CREG study was supported by K01-DK-080886 and DK-56341 (Nutrition and Obesity Research Center) and UL1-RR-024992 (Clinical Translational Science Award). Dr. Havel's and Dr. Stanhope's laboratory received funding from R01-HL-075675, R01-HL-091333. R01-HL-107256, R01-HL-121324, 1R01-HL-121324-02S1 and a multi-campus Award from the University of California, Office of the President. The HERITAGE Family Study was funded by HL-45670, HL-47323, HL-47317, HL-47327, and HL-47321 (CB, TR, DR, AL, JSS). C. Bouchard is also partially funded by the John W. Barton Sr. Chair in Genetics and Nutrition. AC, BB, DP and PS acknowledge support from 5R01HL128572 (BJB), P30DK056350 (BJB, DP), R01DK105965 (PS), a pilot grant from the Nutrition Research Institute (BJB, PS), and an NSF Graduate Research Fellowship Program DGE-1144081 (ARC). TB acknowledges the support of 5R01MH092769 and 5R01MH093429.

Funding Information:
AAB acknowledges support from the Lottie Caroline Hardy Charitable Trust . The CREG study was supported by K01-DK-080886 and DK-56341 ( Nutrition and Obesity Research Center ) and UL1-RR-024992 ( Clinical Translational Science Award ). Dr. Havel's and Dr. Stanhope's laboratory received funding from R01-HL-075675, R01-HL-091333. R01-HL-107256, R01-HL-121324, 1R01-HL-121324-02S1 and a multi-campus Award from the University of California, Office of the President. The HERITAGE Family Study was funded by HL-45670, HL-47323, HL-47317, HL-47327, and HL-47321 (CB, TR, DR, AL, JSS). C. Bouchard is also partially funded by the John W. Barton Sr. Chair in Genetics and Nutrition. AC, BB, DP and PS acknowledge support from 5R01HL128572 (BJB), P30DK056350 (BJB, DP), R01DK105965 (PS), a pilot grant from the Nutrition Research Institute (BJB, PS), and an NSF Graduate Research Fellowship Program DGE-1144081 (ARC). TB acknowledges the support of 5R01MH092769 and 5R01MH093429.

Publisher Copyright:
© 2018 The Authors

Keywords

Adropin
Cardiovascular disease
Cholesterol
LDL
Obesity
Sex

ASJC Scopus subject areas

Molecular Biology
Cell Biology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.molmet.2017.12.002

Cite this

Ghoshal, S., Stevens, J. R., Billon, C., Girardet, C., Sitaula, S., Leon, A. S., Rao, D. C., Skinner, J. S., Rankinen, T., Bouchard, C., Nuñez, M. V., Stanhope, K. L., Howatt, D. A., Daugherty, A., Zhang, J., Schuelke, M., Weiss, E. P., Coffey, A. R., Bennett, B. J., ... Butler, A. A. (2018). Adropin: An endocrine link between the biological clock and cholesterol homeostasis. Molecular Metabolism, 8, 51-64. https://doi.org/10.1016/j.molmet.2017.12.002

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title = "Adropin: An endocrine link between the biological clock and cholesterol homeostasis",

abstract = "Objective: Identify determinants of plasma adropin concentrations, a secreted peptide translated from the Energy Homeostasis Associated (ENHO) gene linked to metabolic control and vascular function. Methods: Associations between plasma adropin concentrations, demographics (sex, age, BMI) and circulating biomarkers of lipid and glucose metabolism were assessed in plasma obtained after an overnight fast in humans. The regulation of adropin expression was then assessed in silico, in cultured human cells, and in animal models. Results: In humans, plasma adropin concentrations are inversely related to atherogenic LDL-cholesterol (LDL-C) levels in men (n = 349), but not in women (n = 401). Analysis of hepatic Enho expression in male mice suggests control by the biological clock. Expression is rhythmic, peaking during maximal food consumption in the dark correlating with transcriptional activation by RORα/γ. The nadir in the light phase coincides with the rest phase and repression by Rev-erb. Plasma adropin concentrations in nonhuman primates (rhesus monkeys) also exhibit peaks coinciding with feeding times (07:00 h, 15:00 h). The ROR inverse agonists SR1001 and the 7-oxygenated sterols 7-β-hydroxysterol and 7-ketocholesterol, or the Rev-erb agonist SR9009, suppress ENHO expression in cultured human HepG2 cells. Consumption of high-cholesterol diets suppress expression of the adropin transcript in mouse liver. However, adropin over expression does not prevent hypercholesterolemia resulting from a high cholesterol diet and/or LDL receptor mutations. Conclusions: In humans, associations between plasma adropin concentrations and LDL-C suggest a link with hepatic lipid metabolism. Mouse studies suggest that the relationship between adropin and cholesterol metabolism is unidirectional, and predominantly involves suppression of adropin expression by cholesterol and 7-oxygenated sterols. Sensing of fatty acids, cholesterol and oxysterols by the RORα/γ ligand-binding domain suggests a plausible functional link between adropin expression and cellular lipid metabolism. Furthermore, the nuclear receptors RORα/γ and Rev-erb may couple adropin synthesis with circadian rhythms in carbohydrate and lipid metabolism.",

keywords = "Adropin, Cardiovascular disease, Cholesterol, LDL, Obesity, Sex",

author = "Sarbani Ghoshal and Stevens, {Joseph R.} and Cyrielle Billon and Clemence Girardet and Sadichha Sitaula and Leon, {Arthur S.} and Rao, {D. C.} and Skinner, {James S.} and Tuomo Rankinen and Claude Bouchard and Nu{\~n}ez, {Marinelle V.} and Stanhope, {Kimber L.} and Howatt, {Deborah A.} and Alan Daugherty and Jinsong Zhang and Matthew Schuelke and Weiss, {Edward P.} and Coffey, {Alisha R.} and Bennett, {Brian J.} and Praveen Sethupathy and Burris, {Thomas P.} and Havel, {Peter J.} and Butler, {Andrew A.}",

note = "Funding Information: AAB acknowledges support from the Lottie Caroline Hardy Charitable Trust. The CREG study was supported by K01-DK-080886 and DK-56341 (Nutrition and Obesity Research Center) and UL1-RR-024992 (Clinical Translational Science Award). Dr. Havel's and Dr. Stanhope's laboratory received funding from R01-HL-075675, R01-HL-091333. R01-HL-107256, R01-HL-121324, 1R01-HL-121324-02S1 and a multi-campus Award from the University of California, Office of the President. The HERITAGE Family Study was funded by HL-45670, HL-47323, HL-47317, HL-47327, and HL-47321 (CB, TR, DR, AL, JSS). C. Bouchard is also partially funded by the John W. Barton Sr. Chair in Genetics and Nutrition. AC, BB, DP and PS acknowledge support from 5R01HL128572 (BJB), P30DK056350 (BJB, DP), R01DK105965 (PS), a pilot grant from the Nutrition Research Institute (BJB, PS), and an NSF Graduate Research Fellowship Program DGE-1144081 (ARC). TB acknowledges the support of 5R01MH092769 and 5R01MH093429. Funding Information: AAB acknowledges support from the Lottie Caroline Hardy Charitable Trust . The CREG study was supported by K01-DK-080886 and DK-56341 ( Nutrition and Obesity Research Center ) and UL1-RR-024992 ( Clinical Translational Science Award ). Dr. Havel's and Dr. Stanhope's laboratory received funding from R01-HL-075675, R01-HL-091333. R01-HL-107256, R01-HL-121324, 1R01-HL-121324-02S1 and a multi-campus Award from the University of California, Office of the President. The HERITAGE Family Study was funded by HL-45670, HL-47323, HL-47317, HL-47327, and HL-47321 (CB, TR, DR, AL, JSS). C. Bouchard is also partially funded by the John W. Barton Sr. Chair in Genetics and Nutrition. AC, BB, DP and PS acknowledge support from 5R01HL128572 (BJB), P30DK056350 (BJB, DP), R01DK105965 (PS), a pilot grant from the Nutrition Research Institute (BJB, PS), and an NSF Graduate Research Fellowship Program DGE-1144081 (ARC). TB acknowledges the support of 5R01MH092769 and 5R01MH093429. Publisher Copyright: {\textcopyright} 2018 The Authors",

year = "2018",

month = feb,

doi = "10.1016/j.molmet.2017.12.002",

language = "English",

volume = "8",

pages = "51--64",

}

Ghoshal, S, Stevens, JR, Billon, C, Girardet, C, Sitaula, S, Leon, AS, Rao, DC, Skinner, JS, Rankinen, T, Bouchard, C, Nuñez, MV, Stanhope, KL, Howatt, DA, Daugherty, A, Zhang, J, Schuelke, M, Weiss, EP, Coffey, AR, Bennett, BJ, Sethupathy, P, Burris, TP, Havel, PJ & Butler, AA 2018, 'Adropin: An endocrine link between the biological clock and cholesterol homeostasis', Molecular Metabolism, vol. 8, pp. 51-64. https://doi.org/10.1016/j.molmet.2017.12.002

TY - JOUR

T1 - Adropin

T2 - An endocrine link between the biological clock and cholesterol homeostasis

AU - Ghoshal, Sarbani

AU - Stevens, Joseph R.

AU - Billon, Cyrielle

AU - Girardet, Clemence

AU - Sitaula, Sadichha

AU - Leon, Arthur S.

AU - Rao, D. C.

AU - Skinner, James S.

AU - Rankinen, Tuomo

AU - Bouchard, Claude

AU - Nuñez, Marinelle V.

AU - Stanhope, Kimber L.

AU - Howatt, Deborah A.

AU - Daugherty, Alan

AU - Zhang, Jinsong

AU - Schuelke, Matthew

AU - Weiss, Edward P.

AU - Coffey, Alisha R.

AU - Bennett, Brian J.

AU - Sethupathy, Praveen

AU - Burris, Thomas P.

AU - Havel, Peter J.

AU - Butler, Andrew A.

N1 - Funding Information: AAB acknowledges support from the Lottie Caroline Hardy Charitable Trust. The CREG study was supported by K01-DK-080886 and DK-56341 (Nutrition and Obesity Research Center) and UL1-RR-024992 (Clinical Translational Science Award). Dr. Havel's and Dr. Stanhope's laboratory received funding from R01-HL-075675, R01-HL-091333. R01-HL-107256, R01-HL-121324, 1R01-HL-121324-02S1 and a multi-campus Award from the University of California, Office of the President. The HERITAGE Family Study was funded by HL-45670, HL-47323, HL-47317, HL-47327, and HL-47321 (CB, TR, DR, AL, JSS). C. Bouchard is also partially funded by the John W. Barton Sr. Chair in Genetics and Nutrition. AC, BB, DP and PS acknowledge support from 5R01HL128572 (BJB), P30DK056350 (BJB, DP), R01DK105965 (PS), a pilot grant from the Nutrition Research Institute (BJB, PS), and an NSF Graduate Research Fellowship Program DGE-1144081 (ARC). TB acknowledges the support of 5R01MH092769 and 5R01MH093429. Funding Information: AAB acknowledges support from the Lottie Caroline Hardy Charitable Trust . The CREG study was supported by K01-DK-080886 and DK-56341 ( Nutrition and Obesity Research Center ) and UL1-RR-024992 ( Clinical Translational Science Award ). Dr. Havel's and Dr. Stanhope's laboratory received funding from R01-HL-075675, R01-HL-091333. R01-HL-107256, R01-HL-121324, 1R01-HL-121324-02S1 and a multi-campus Award from the University of California, Office of the President. The HERITAGE Family Study was funded by HL-45670, HL-47323, HL-47317, HL-47327, and HL-47321 (CB, TR, DR, AL, JSS). C. Bouchard is also partially funded by the John W. Barton Sr. Chair in Genetics and Nutrition. AC, BB, DP and PS acknowledge support from 5R01HL128572 (BJB), P30DK056350 (BJB, DP), R01DK105965 (PS), a pilot grant from the Nutrition Research Institute (BJB, PS), and an NSF Graduate Research Fellowship Program DGE-1144081 (ARC). TB acknowledges the support of 5R01MH092769 and 5R01MH093429. Publisher Copyright: © 2018 The Authors

PY - 2018/2

Y1 - 2018/2

N2 - Objective: Identify determinants of plasma adropin concentrations, a secreted peptide translated from the Energy Homeostasis Associated (ENHO) gene linked to metabolic control and vascular function. Methods: Associations between plasma adropin concentrations, demographics (sex, age, BMI) and circulating biomarkers of lipid and glucose metabolism were assessed in plasma obtained after an overnight fast in humans. The regulation of adropin expression was then assessed in silico, in cultured human cells, and in animal models. Results: In humans, plasma adropin concentrations are inversely related to atherogenic LDL-cholesterol (LDL-C) levels in men (n = 349), but not in women (n = 401). Analysis of hepatic Enho expression in male mice suggests control by the biological clock. Expression is rhythmic, peaking during maximal food consumption in the dark correlating with transcriptional activation by RORα/γ. The nadir in the light phase coincides with the rest phase and repression by Rev-erb. Plasma adropin concentrations in nonhuman primates (rhesus monkeys) also exhibit peaks coinciding with feeding times (07:00 h, 15:00 h). The ROR inverse agonists SR1001 and the 7-oxygenated sterols 7-β-hydroxysterol and 7-ketocholesterol, or the Rev-erb agonist SR9009, suppress ENHO expression in cultured human HepG2 cells. Consumption of high-cholesterol diets suppress expression of the adropin transcript in mouse liver. However, adropin over expression does not prevent hypercholesterolemia resulting from a high cholesterol diet and/or LDL receptor mutations. Conclusions: In humans, associations between plasma adropin concentrations and LDL-C suggest a link with hepatic lipid metabolism. Mouse studies suggest that the relationship between adropin and cholesterol metabolism is unidirectional, and predominantly involves suppression of adropin expression by cholesterol and 7-oxygenated sterols. Sensing of fatty acids, cholesterol and oxysterols by the RORα/γ ligand-binding domain suggests a plausible functional link between adropin expression and cellular lipid metabolism. Furthermore, the nuclear receptors RORα/γ and Rev-erb may couple adropin synthesis with circadian rhythms in carbohydrate and lipid metabolism.

AB - Objective: Identify determinants of plasma adropin concentrations, a secreted peptide translated from the Energy Homeostasis Associated (ENHO) gene linked to metabolic control and vascular function. Methods: Associations between plasma adropin concentrations, demographics (sex, age, BMI) and circulating biomarkers of lipid and glucose metabolism were assessed in plasma obtained after an overnight fast in humans. The regulation of adropin expression was then assessed in silico, in cultured human cells, and in animal models. Results: In humans, plasma adropin concentrations are inversely related to atherogenic LDL-cholesterol (LDL-C) levels in men (n = 349), but not in women (n = 401). Analysis of hepatic Enho expression in male mice suggests control by the biological clock. Expression is rhythmic, peaking during maximal food consumption in the dark correlating with transcriptional activation by RORα/γ. The nadir in the light phase coincides with the rest phase and repression by Rev-erb. Plasma adropin concentrations in nonhuman primates (rhesus monkeys) also exhibit peaks coinciding with feeding times (07:00 h, 15:00 h). The ROR inverse agonists SR1001 and the 7-oxygenated sterols 7-β-hydroxysterol and 7-ketocholesterol, or the Rev-erb agonist SR9009, suppress ENHO expression in cultured human HepG2 cells. Consumption of high-cholesterol diets suppress expression of the adropin transcript in mouse liver. However, adropin over expression does not prevent hypercholesterolemia resulting from a high cholesterol diet and/or LDL receptor mutations. Conclusions: In humans, associations between plasma adropin concentrations and LDL-C suggest a link with hepatic lipid metabolism. Mouse studies suggest that the relationship between adropin and cholesterol metabolism is unidirectional, and predominantly involves suppression of adropin expression by cholesterol and 7-oxygenated sterols. Sensing of fatty acids, cholesterol and oxysterols by the RORα/γ ligand-binding domain suggests a plausible functional link between adropin expression and cellular lipid metabolism. Furthermore, the nuclear receptors RORα/γ and Rev-erb may couple adropin synthesis with circadian rhythms in carbohydrate and lipid metabolism.

KW - Adropin

KW - Cardiovascular disease

KW - Cholesterol

KW - LDL

KW - Obesity

KW - Sex

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Adropin: An endocrine link between the biological clock and cholesterol homeostasis

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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