Abstract
Skeletal muscle constitutes the major site of glucose uptake leading to increased removal of glucose from the circulation in response to insulin. Type 2 diabetes and obesity are often associated with insulin resistance that can be counteracted by exercise or the use of drugs increasing the relative proportion of oxidative fibers. RIP140 is a transcriptional coregulator with a central role in metabolic tissues and we tested the effect of modulating its level of expression on muscle glucose and lipid metabolism in two mice models. Here, we show that although RIP140 protein is expressed at the same level in both oxidative and glycolytic muscles, it inhibits both fatty acid and glucose utilization in a fiber-type dependent manner. In RIP140-null mice, fatty acid utilization increases in the extensor digitorum longus and this is associated with elevated expression of genes implicated in fatty acid binding and transport. In the RIP140-null soleus, depletion of RIP140 leads to increased GLUT4 trafficking and glucose uptake with no change in Akt activity. AMPK phosphorylation/activity is inhibited in the soleus of RIP140 transgenic mice and increased in RIP140-null soleus. This is associated with increased UCP1 expression and mitochondrial uncoupling revealing the existence of a signaling pathway controlling insulin-independent glucose uptake in the soleus of RIP140-null mice. In conclusion, our findings reinforce the participation of RIP140 in the maintenance of energy homeostasis by acting as an inhibitor of energy production and particularly point to RIP140 as a promising therapeutic target in the treatment of insulin resistance.
Highlights
Skeletal muscle constitutes the major site of glucose uptake leading to increased removal of glucose from the circulation in response to insulin
Analysis of mRNA levels of key metabolic genes implicated in fatty acid handling showed that FABP3, CD36, MCAD, CPT1b, CPT2, CIDEA and ACC2 were increased in the absence of Receptor-interacting protein 140 (RIP140) in the extensor digitorum longus (EDL) while unaffected in the soleus, except for FABP3 (Figure 2B)
We show that depletion of RIP140 unmasks a signaling pathway upregulating insulin-independent glucose uptake in oxidative muscle through increased expression of UCP1, activation of AMPK, and, increased trafficking of GLUT4 (Figure 9)
Summary
Skeletal muscle constitutes the major site of glucose uptake leading to increased removal of glucose from the circulation in response to insulin. Insulin resistance is a key feature of type 2 diabetes and obesity where it is often associated with accumulation of intramyocellular lipids and decreased oxidative capacities in skeletal muscle. Fiber type composition can be modulated by different factors such as exercise, aging, and hormonal changes [4], [5]. Endurance training leads to an increase in the proportion of type I fibers while resistance training promotes increased type II fibers. It has been shown that increasing the proportion of the most oxidative fibers helps in counteracting diet-induced obesity [6], increasing type II/
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