Bone-specific insulin resistance disrupts whole-body glucose homeostasis via decreased osteocalcin activation
Jianwen Wei, … , William S. Blaner, Gerard Karsenty
Jianwen Wei, … , William S. Blaner, Gerard Karsenty
Published March 18, 2014
Citation Information: J Clin Invest. 2014;124(4):1781-1793. https://doi.org/10.1172/JCI72323.
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Research Article

Bone-specific insulin resistance disrupts whole-body glucose homeostasis via decreased osteocalcin activation

Abstract

Insulin signaling in osteoblasts has been shown recently to contribute to whole-body glucose homeostasis in animals fed a normal diet; however, it is unknown whether bone contributes to the insulin resistance that develops in animals challenged by a high-fat diet (HFD). Here, we evaluated the consequences of osteoblast-specific overexpression of or loss of insulin receptor in HFD-fed mice. We determined that the severity of glucose intolerance and insulin resistance that mice develop when fed a HFD is in part a consequence of osteoblast-dependent insulin resistance. Insulin resistance in osteoblasts led to a decrease in circulating levels of the active form of osteocalcin, thereby decreasing insulin sensitivity in skeletal muscle. Insulin resistance developed in osteoblasts as the result of increased levels of free saturated fatty acids, which promote insulin receptor ubiquitination and subsequent degradation. Together, these results underscore the involvement of bone, among other tissues, in the disruption of whole-body glucose homeostasis resulting from a HFD and the involvement of insulin and osteocalcin cross-talk in glucose intolerance. Furthermore, our data indicate that insulin resistance develops in bone as the result of lipotoxicity-associated loss of insulin receptors.

Authors

Jianwen Wei, Mathieu Ferron, Christopher J. Clarke, Yusuf A. Hannun, Hongfeng Jiang, William S. Blaner, Gerard Karsenty

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Figure 4

HFD decreases bone resorption in an insulin-dependent manner.

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HFD decreases bone resorption in an insulin-dependent manner. (A) qPCR a...
(A) qPCR analysis of the expression of Opg, Rankl, Ctsk, and Tcirg1 in bones of WT mice fed a normal diet or a HFD (n = 4); (B) Insrfl/+ and Col1a1-Insr+/– mice fed a HFD (n = 7); and (C) WT and Col1a1-INSRTg mice fed a HFD (n = 6). (D) Serum Ctx levels in WT mice fed a normal diet or a HFD (n = 8). (E) Serum Ctx levels in Insrfl/+ and Col1a1-Insr+/– mice fed a normal diet or a HFD (n = 8). (F) Serum Ctx levels in WT and Col1a1-INSRTg mice fed a normal diet or a HFD (n = 8). (G) Histomorphometric analysis of vertebrae of WT mice fed a normal diet or HFD (n = 8), (H) Col1a1-Insr+/– mice fed a normal diet or HFD (n = 8), and (I) Col1a1-INSRTg mice fed a normal diet or HFD (n = 8). Mineralized bone volume over the total tissue volume (BV/TV), osteoclast surface per bone surface (Oc.S./BS), and bone formation rate per bone surface (BFR/BS) were measured. (J) Serum PINP levels in WT (n = 6), (K) Col1a1-INSRTg (n = 6), and (L) Col1a1-Insr+/– (n = 6) mice fed a normal diet or a HFD. qPCR analysis of the expression of Ocn, Col1a1, Osterix, and Runx2 in bones of (M) WT (n = 4), (N) Col1a1-Insr+/– (n = 5), and (O) Col1a1-INSRTg (n = 5) mice fed a normal diet or a HFD. *P < 0.05.