A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance

Cholsoon Jang; Sungwhan F. Oh; Shogo Wada; Glenn C. Rowe; Laura Liu; Mun Chun Chan; James Rhee; Atsushi Hoshino; Boa Kim; Ayon Ibrahim; Luisa G. Baca; Esl Kim; Chandra C. Ghosh; Samir M. Parikh; Aihua Jiang; Qingwei Chu; Daniel E. Forman; Stewart H. Lecker; Saikumari Krishnaiah; Joshua D. Rabinowitz; Aalim M. Weljie; Joseph A. Baur; Dennis L. Kasper; Zoltan Arany

doi:10.1038/nm.4057

A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance

Cholsoon Jang, Sungwhan F. Oh, Shogo Wada, Glenn C. Rowe, Laura Liu, Mun Chun Chan, James Rhee, Atsushi Hoshino, Boa Kim, Ayon Ibrahim, Luisa G. Baca, Esl Kim, Chandra C. Ghosh, Samir M. Parikh, Aihua Jiang, Qingwei Chu, Daniel E. Forman, Stewart H. Lecker, Saikumari Krishnaiah, Joshua D. RabinowitzAalim M. Weljie, Joseph A. Baur, Dennis L. Kasper, Zoltan Arany

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

387 Scopus citations

Abstract

Epidemiological and experimental data implicate branched-chain amino acids (BCAAs) in the development of insulin resistance, but the mechanisms that underlie this link remain unclear. Insulin resistance in skeletal muscle stems from the excess accumulation of lipid species, a process that requires blood-borne lipids to initially traverse the blood vessel wall. How this trans-endothelial transport occurs and how it is regulated are not well understood. Here we leveraged PPARGC1a (also known as PGC-1α; encoded by Ppargc1a), a transcriptional coactivator that regulates broad programs of fatty acid consumption, to identify 3-hydroxyisobutyrate (3-HIB), a catabolic intermediate of the BCAA valine, as a new paracrine regulator of trans-endothelial fatty acid transport. We found that 3-HIB is secreted from muscle cells, activates endothelial fatty acid transport, stimulates muscle fatty acid uptake in vivo and promotes lipid accumulation in muscle, leading to insulin resistance in mice. Conversely, inhibiting the synthesis of 3-HIB in muscle cells blocks the ability of PGC-1α to promote endothelial fatty acid uptake. 3-HIB levels are elevated in muscle from db/db mice with diabetes and from human subjects with diabetes, as compared to those without diabetes. These data unveil a mechanism in which the metabolite 3-HIB, by regulating the trans-endothelial flux of fatty acids, links the regulation of fatty acid flux to BCAA catabolism, providing a mechanistic explanation for how increased BCAA catabolic flux can cause diabetes.

Original language	English (US)
Pages (from-to)	421-426
Number of pages	6
Journal	Nature medicine
Volume	22
Issue number	4
DOIs	https://doi.org/10.1038/nm.4057
State	Published - Apr 1 2016
Externally published	Yes

ASJC Scopus subject areas

General Biochemistry, Genetics and Molecular Biology

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10.1038/nm.4057

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Jang, C., Oh, S. F., Wada, S., Rowe, G. C., Liu, L., Chan, M. C., Rhee, J., Hoshino, A., Kim, B., Ibrahim, A., Baca, L. G., Kim, E., Ghosh, C. C., Parikh, S. M., Jiang, A., Chu, Q., Forman, D. E., Lecker, S. H., Krishnaiah, S., ... Arany, Z. (2016). A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance. Nature medicine, 22(4), 421-426. https://doi.org/10.1038/nm.4057

Jang, C, Oh, SF, Wada, S, Rowe, GC, Liu, L, Chan, MC, Rhee, J, Hoshino, A, Kim, B, Ibrahim, A, Baca, LG, Kim, E, Ghosh, CC, Parikh, SM, Jiang, A, Chu, Q, Forman, DE, Lecker, SH, Krishnaiah, S, Rabinowitz, JD, Weljie, AM, Baur, JA, Kasper, DL & Arany, Z 2016, 'A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance', Nature medicine, vol. 22, no. 4, pp. 421-426. https://doi.org/10.1038/nm.4057

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title = "A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance",

abstract = "Epidemiological and experimental data implicate branched-chain amino acids (BCAAs) in the development of insulin resistance, but the mechanisms that underlie this link remain unclear. Insulin resistance in skeletal muscle stems from the excess accumulation of lipid species, a process that requires blood-borne lipids to initially traverse the blood vessel wall. How this trans-endothelial transport occurs and how it is regulated are not well understood. Here we leveraged PPARGC1a (also known as PGC-1α; encoded by Ppargc1a), a transcriptional coactivator that regulates broad programs of fatty acid consumption, to identify 3-hydroxyisobutyrate (3-HIB), a catabolic intermediate of the BCAA valine, as a new paracrine regulator of trans-endothelial fatty acid transport. We found that 3-HIB is secreted from muscle cells, activates endothelial fatty acid transport, stimulates muscle fatty acid uptake in vivo and promotes lipid accumulation in muscle, leading to insulin resistance in mice. Conversely, inhibiting the synthesis of 3-HIB in muscle cells blocks the ability of PGC-1α to promote endothelial fatty acid uptake. 3-HIB levels are elevated in muscle from db/db mice with diabetes and from human subjects with diabetes, as compared to those without diabetes. These data unveil a mechanism in which the metabolite 3-HIB, by regulating the trans-endothelial flux of fatty acids, links the regulation of fatty acid flux to BCAA catabolism, providing a mechanistic explanation for how increased BCAA catabolic flux can cause diabetes.",

author = "Cholsoon Jang and Oh, {Sungwhan F.} and Shogo Wada and Rowe, {Glenn C.} and Laura Liu and Chan, {Mun Chun} and James Rhee and Atsushi Hoshino and Boa Kim and Ayon Ibrahim and Baca, {Luisa G.} and Esl Kim and Ghosh, {Chandra C.} and Parikh, {Samir M.} and Aihua Jiang and Qingwei Chu and Forman, {Daniel E.} and Lecker, {Stewart H.} and Saikumari Krishnaiah and Rabinowitz, {Joshua D.} and Weljie, {Aalim M.} and Baur, {Joseph A.} and Kasper, {Dennis L.} and Zoltan Arany",

note = "Funding Information: Acknowledgments Human endothelial colony forming cells (ECFCs) were kindly provided by J. Bischoff (Boston Children's Hospital). Fatp4-/- and Cd36-/- mice were kindly provided by J. Miner (Washington University School of Medicine) and J. Lawler (Harvard Medical School), respectively. Flt1flox/flox and Kdrflox/flox mice were kindly provided by Genentech. C.J. is supported by the Lotte Scholarship and American Heart Association (AHA). S.F.O. is supported by the Crohn's and Colitis Foundation of America (Research Fellowship Award). S.W. is supported by the Toyobo Biotechnology Foundation. G.C.R. is supported by the US National Institute of Arthritis and Musculoskeletal and Skin Diseases (AR062128). J.R. is supported by the US National Institutes of Health (5 T32 GM7592-35). S.M.P. is supported by the US National Heart, Lung, and Blood Institute (NHLBI) (HL093234; HL125275) and the US National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) (DK095072). Q.C. and J.A.B. are supported by the NIDDK (DK098656; DK049210). Z.A. is supported by the NHLBI (HL094499), the AHA and the Geis Realty Group Emerging Initiatives Fund and Dean and Ann Geis.",

year = "2016",

month = apr,

day = "1",

doi = "10.1038/nm.4057",

language = "English (US)",

volume = "22",

pages = "421--426",

journal = "Nature medicine",

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T1 - A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance

AU - Jang, Cholsoon

AU - Oh, Sungwhan F.

AU - Wada, Shogo

AU - Rowe, Glenn C.

AU - Liu, Laura

AU - Chan, Mun Chun

AU - Rhee, James

AU - Hoshino, Atsushi

AU - Kim, Boa

AU - Ibrahim, Ayon

AU - Baca, Luisa G.

AU - Kim, Esl

AU - Ghosh, Chandra C.

AU - Parikh, Samir M.

AU - Jiang, Aihua

AU - Chu, Qingwei

AU - Forman, Daniel E.

AU - Lecker, Stewart H.

AU - Krishnaiah, Saikumari

AU - Rabinowitz, Joshua D.

AU - Weljie, Aalim M.

AU - Baur, Joseph A.

AU - Kasper, Dennis L.

AU - Arany, Zoltan

N1 - Funding Information: Acknowledgments Human endothelial colony forming cells (ECFCs) were kindly provided by J. Bischoff (Boston Children's Hospital). Fatp4-/- and Cd36-/- mice were kindly provided by J. Miner (Washington University School of Medicine) and J. Lawler (Harvard Medical School), respectively. Flt1flox/flox and Kdrflox/flox mice were kindly provided by Genentech. C.J. is supported by the Lotte Scholarship and American Heart Association (AHA). S.F.O. is supported by the Crohn's and Colitis Foundation of America (Research Fellowship Award). S.W. is supported by the Toyobo Biotechnology Foundation. G.C.R. is supported by the US National Institute of Arthritis and Musculoskeletal and Skin Diseases (AR062128). J.R. is supported by the US National Institutes of Health (5 T32 GM7592-35). S.M.P. is supported by the US National Heart, Lung, and Blood Institute (NHLBI) (HL093234; HL125275) and the US National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) (DK095072). Q.C. and J.A.B. are supported by the NIDDK (DK098656; DK049210). Z.A. is supported by the NHLBI (HL094499), the AHA and the Geis Realty Group Emerging Initiatives Fund and Dean and Ann Geis.

PY - 2016/4/1

Y1 - 2016/4/1

N2 - Epidemiological and experimental data implicate branched-chain amino acids (BCAAs) in the development of insulin resistance, but the mechanisms that underlie this link remain unclear. Insulin resistance in skeletal muscle stems from the excess accumulation of lipid species, a process that requires blood-borne lipids to initially traverse the blood vessel wall. How this trans-endothelial transport occurs and how it is regulated are not well understood. Here we leveraged PPARGC1a (also known as PGC-1α; encoded by Ppargc1a), a transcriptional coactivator that regulates broad programs of fatty acid consumption, to identify 3-hydroxyisobutyrate (3-HIB), a catabolic intermediate of the BCAA valine, as a new paracrine regulator of trans-endothelial fatty acid transport. We found that 3-HIB is secreted from muscle cells, activates endothelial fatty acid transport, stimulates muscle fatty acid uptake in vivo and promotes lipid accumulation in muscle, leading to insulin resistance in mice. Conversely, inhibiting the synthesis of 3-HIB in muscle cells blocks the ability of PGC-1α to promote endothelial fatty acid uptake. 3-HIB levels are elevated in muscle from db/db mice with diabetes and from human subjects with diabetes, as compared to those without diabetes. These data unveil a mechanism in which the metabolite 3-HIB, by regulating the trans-endothelial flux of fatty acids, links the regulation of fatty acid flux to BCAA catabolism, providing a mechanistic explanation for how increased BCAA catabolic flux can cause diabetes.

AB - Epidemiological and experimental data implicate branched-chain amino acids (BCAAs) in the development of insulin resistance, but the mechanisms that underlie this link remain unclear. Insulin resistance in skeletal muscle stems from the excess accumulation of lipid species, a process that requires blood-borne lipids to initially traverse the blood vessel wall. How this trans-endothelial transport occurs and how it is regulated are not well understood. Here we leveraged PPARGC1a (also known as PGC-1α; encoded by Ppargc1a), a transcriptional coactivator that regulates broad programs of fatty acid consumption, to identify 3-hydroxyisobutyrate (3-HIB), a catabolic intermediate of the BCAA valine, as a new paracrine regulator of trans-endothelial fatty acid transport. We found that 3-HIB is secreted from muscle cells, activates endothelial fatty acid transport, stimulates muscle fatty acid uptake in vivo and promotes lipid accumulation in muscle, leading to insulin resistance in mice. Conversely, inhibiting the synthesis of 3-HIB in muscle cells blocks the ability of PGC-1α to promote endothelial fatty acid uptake. 3-HIB levels are elevated in muscle from db/db mice with diabetes and from human subjects with diabetes, as compared to those without diabetes. These data unveil a mechanism in which the metabolite 3-HIB, by regulating the trans-endothelial flux of fatty acids, links the regulation of fatty acid flux to BCAA catabolism, providing a mechanistic explanation for how increased BCAA catabolic flux can cause diabetes.

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JO - Nature medicine

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ER -

A branched-chain amino acid metabolite drives vascular fatty acid transport and causes insulin resistance

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