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This Article Full Text Full Text (PDF) All Versions of this Article: 582/2/801    most recent jphysiol.2007.132902v1 Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Fueger, P. T. Articles by Wasserman, D. H. Search for Related Content PubMed PubMed Citation Articles by Fueger, P. T. Articles by Wasserman, D. H. Related Collections Skeletal Muscle and Exercise

¹ Department of Molecular Physiology and Biophysics
² Department of Internal Medicine
³ Mouse Metabolic Phenotyping Center, Vanderbilt University School of Medicine, Nashville, TN 37232, USA
⁴ Department of Biochemistry, Albert Einstein College of Medicine, Bronx, NY 10461, USA

The absence of GLUT4 severely impairs basal glucose uptake in vivo, but does not alter glucose homeostasis or circulating insulin. Glucose uptake in isolated contracting skeletal muscle (MGU) is also impaired by the absence of GLUT4, and onset of muscle fatigue is hastened. Whether the body can compensate and preserve glucose homeostasis during exercise, as it does in the basal state, is unknown. One aim was to test the effectiveness of glucoregulatory compensation for the absence of GLUT4 in vivo. The absence of GLUT4 was also used to further define the role of hexokinase (HK) II, which catalyses glucose phosphorylation after it is transported in the cell. HK II increases MGU during exercise, as well as exercise endurance. In the absence of GLUT4, HK II expression will not affect MGU. A second aim was to test whether, in the absence of GLUT4, HK II retains its ability to increase exercise endurance. Wild-type (WT), GLUT4 null (GLUT4^–/–), and GLUT4 null overexpressing HK II (GLUT4^–/–HK^Tg) mice were studied using a catheterized mouse model that allows blood sampling and isotope infusions during treadmill exercise. The impaired capacity of working muscle to take up glucose in GLUT4^–/– is partially offset by an exaggerated increase in the glucagon: insulin ratio, increased liver glucose production, hyperglycaemia, and a greater capillary density in order to increase the delivery of glucose to the exercising muscle of GLUT4^–/–. Hearts of GLUT4^–/– also exhibited a compensatory increase in HK II expression and a paradoxical increase in glucose uptake. Exercise tolerance was reduced in GLUT4^–/– compared to WT. As expected, MGU in GLUT4^–/–HK^Tg was the same as in GLUT4^–/–. However, HK II overexpression retained its ability to increase exercise endurance. In conclusion, unlike the basal state where glucose homeostasis is preserved, hyperglycaemia results during exercise in GLUT4^–/– due to a robust stimulation of liver glucose release in the face of severe impairments in MGU. Finally, studies in GLUT4^–/–HK^Tg show that HK II improves exercise tolerance, independent of its effects on MGU.

(Received 20 March 2007; accepted after revision 9 May 2007; first published online 10 May 2007)
Corresponding author P. T. Fueger: Duke University Medical Center, Department of Pharmacology and Cancer Biology, 4321 Medical Park Drive, Suite 200, Durham, NC 27704, USA. Email: patrick.fueger{at}duke.edu