Seung-Yon Lee scite author profile

Much of the mammalian skeleton originates from a cartilage template eventually replaced by bone via endochondral ossification. Despite much knowledge about growth factors and nuclear proteins in skeletal development, little is understood about the role of metabolic regulation. Here we report that genetic deletion of the glucose transporter Glut1 (Slc2a1), either before or after the onset of chondrogenesis in the limb, severely impairs chondrocyte proliferation and hypertrophy, resulting in dramatic shortening of the limbs. The cartilage defects are reminiscent to those caused by deficiency in Bmp signaling. Importantly, deletion of Bmpr1a in chondrocytes markedly reduces Glut1 levels in vivo, whereas recombinant BMP2 increases Glut1 mRNA and protein levels, boosting glucose metabolism in primary chondrocytes. Biochemical studies identify a Bmp-mTORC1-Hif1a signaling cascade resulting in upregulation of Glut1 in chondrocytes. The results therefore uncover a hitherto unknown connection between Bmp signaling and glucose metabolism in the regulation of cartilage development.

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PTH Promotes Bone Anabolism by Stimulating Aerobic Glycolysis via IGF Signaling

Esen

Lee

Wice

et al. 2015

129

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Teriparatide, a recombinant peptide corresponding to amino acids 1-34 of human parathyroid hormone (PTH), has been an effective bone anabolic drug for over a decade. However, the mechanism whereby PTH stimulates bone formation remains poorly understood. Here we report that in cultures of osteoblast-lineage cells, PTH stimulates glucose consumption and lactate production in the presence of oxygen, a hallmark of aerobic glycolysis, also known as Warburg effect. Experiments with radioactively labeled glucose demonstrate that PTH suppresses glucose entry into the tricarboxylic acid cycle (TCA cycle). Mechanistically, the increase in aerobic glycolysis is secondary to insulin-like growth factor (Igf) signaling induced by PTH, whereas the metabolic effect of Igf is dependent on activation of mammalian target of rapamycin complex 2 (mTORC2). Importantly, pharmacological perturbation of glycolysis suppresses the bone anabolic effect of intermittent PTH in the mouse. Thus, stimulation of aerobic glycolysis via Igf signaling contributes to bone anabolism in response to PTH.

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Notch signaling suppresses glucose metabolism in mesenchymal progenitors to restrict osteoblast differentiation

Lee¹,

Long

2018

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ROS inhibit the expression of testicular steroidogenic enzyme genes via the suppression of Nur77 transactivation

Lee

Gong

Hong

et al. 2009

Free Radical Biology and Medicine

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PTH Promotes Bone Anabolism by Stimulating Aerobic Glycolysis via IGF Signaling

Esen¹,

Lee²,

Wice³

et al. 2015

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Seung-Yon Lee

Glucose metabolism induced by Bmp signaling is essential for murine skeletal development

PTH Promotes Bone Anabolism by Stimulating Aerobic Glycolysis via IGF Signaling

Notch signaling suppresses glucose metabolism in mesenchymal progenitors to restrict osteoblast differentiation

ROS inhibit the expression of testicular steroidogenic enzyme genes via the suppression of Nur77 transactivation

PTH Promotes Bone Anabolism by Stimulating Aerobic Glycolysis via IGF Signaling

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