Inhibition of upper small intestinal mTOR lowers plasma glucose levels by inhibiting glucose production

T. M.Zaved Waise; Mozhgan Rasti; Frank A. Duca; Song Yang Zhang; Paige V. Bauer; Christopher J. Rhodes; Tony K.T. Lam

doi:10.1038/s41467-019-08582-7

Inhibition of upper small intestinal mTOR lowers plasma glucose levels by inhibiting glucose production

T. M.Zaved Waise, Mozhgan Rasti, Frank A. Duca, Song Yang Zhang, Paige V. Bauer, Christopher J. Rhodes, Tony K.T. Lam

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19 Scopus citations

Abstract

Glucose homeostasis is partly controlled by the energy sensor mechanistic target of rapamycin (mTOR) in the muscle and liver. However, whether mTOR in the small intestine affects glucose homeostasis in vivo remains unknown. Here, we first report that delivery of rapamycin or an adenovirus encoding the dominant negative acting mTOR-mutated protein into the upper small intestine is sufficient to inhibit small intestinal mTOR signaling and lower glucose production in rodents with high fat diet-induced insulin resistance. Second, we found that molecular activation of small intestinal mTOR blunts the glucose-lowering effect of the oral anti-diabetic agent metformin, while inhibiting small intestinal mTOR alone lowers plasma glucose levels by inhibiting glucose production in rodents with diabetes as well. Thus, these findings illustrate that inhibiting upper small intestinal mTOR is sufficient and necessary to lower glucose production and enhance glucose homeostasis, and thereby unveil a previously unappreciated glucose-lowering effect of small intestinal mTOR.

Original language	English (US)
Article number	714
Journal	Nature communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-08582-7
State	Published - Dec 1 2019

ASJC Scopus subject areas

Chemistry(all)
Biochemistry, Genetics and Molecular Biology(all)
Physics and Astronomy(all)

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title = "Inhibition of upper small intestinal mTOR lowers plasma glucose levels by inhibiting glucose production",

abstract = "Glucose homeostasis is partly controlled by the energy sensor mechanistic target of rapamycin (mTOR) in the muscle and liver. However, whether mTOR in the small intestine affects glucose homeostasis in vivo remains unknown. Here, we first report that delivery of rapamycin or an adenovirus encoding the dominant negative acting mTOR-mutated protein into the upper small intestine is sufficient to inhibit small intestinal mTOR signaling and lower glucose production in rodents with high fat diet-induced insulin resistance. Second, we found that molecular activation of small intestinal mTOR blunts the glucose-lowering effect of the oral anti-diabetic agent metformin, while inhibiting small intestinal mTOR alone lowers plasma glucose levels by inhibiting glucose production in rodents with diabetes as well. Thus, these findings illustrate that inhibiting upper small intestinal mTOR is sufficient and necessary to lower glucose production and enhance glucose homeostasis, and thereby unveil a previously unappreciated glucose-lowering effect of small intestinal mTOR.",

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note = "Funding Information: This work was supported by a Canadian Institutes of Health Research (CIHR) Foundation Grant to T.K.T.L. (FDN-143204). T.M.Z.W. is supported by a Diabetes Canada post-doctoral fellowships. F.A.D. was a Banting Fellow. S.Y.Z. is supported by a Banting and Best Diabetes Centre post-doctoral fellowship. P.V.B. was supported by an Ontario Graduate Scholarship and a BBDC graduate studentship. T.K.T.L. holds the Canada Research Chair (Tier 1) in Diabetes and Obesity & the John Kitson McIvor (1915–1942) Endowed Chair in Diabetes Research at the Toronto General Hospital Research Institute and the University of Toronto. Publisher Copyright: {\textcopyright} 2019, The Author(s).",

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AU - Rhodes, Christopher J.

AU - Lam, Tony K.T.

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N2 - Glucose homeostasis is partly controlled by the energy sensor mechanistic target of rapamycin (mTOR) in the muscle and liver. However, whether mTOR in the small intestine affects glucose homeostasis in vivo remains unknown. Here, we first report that delivery of rapamycin or an adenovirus encoding the dominant negative acting mTOR-mutated protein into the upper small intestine is sufficient to inhibit small intestinal mTOR signaling and lower glucose production in rodents with high fat diet-induced insulin resistance. Second, we found that molecular activation of small intestinal mTOR blunts the glucose-lowering effect of the oral anti-diabetic agent metformin, while inhibiting small intestinal mTOR alone lowers plasma glucose levels by inhibiting glucose production in rodents with diabetes as well. Thus, these findings illustrate that inhibiting upper small intestinal mTOR is sufficient and necessary to lower glucose production and enhance glucose homeostasis, and thereby unveil a previously unappreciated glucose-lowering effect of small intestinal mTOR.

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Inhibition of upper small intestinal mTOR lowers plasma glucose levels by inhibiting glucose production

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