Vascular endothelial cell function is important for regulating vascular perfusion, which is increased in the skeletal muscle during exercise. Our previous research identified endothelial selective PPARD, a transcription factor, which is critical for endothelial cell function and homeostasis. Loss of PPARD in endothelium enhances vascular inflammation and disrupts endothelial integrity. In the present study, we aims to investigate whether endothelial PPARD is involved in nutrient transport in the muscle endothelial cells and whether it is involved in exercise endurance and training effcacy. The Cdh5-Cre driven deletion of the floxed Ppard allele was used for making the endothelium selective Ppard knockout (PpardEC-KO) mice and wild type littermates (PpardEC-WT). Human endothelial cells were used to examine glucose and fatty acid uptake and its transport to myocytes. Treadmill exercise with incremental speed and inclination was used. Both PpardEC-WT and PpardEC-KO mice were viable and did not show abnormalities at baseline. Both PpardEC-WT and PpardEC-KO mice were put on treadmill to test their running endurance. Deletion of Ppard in endothelium resulted in early exhaustion, shortened distance, and less speed. Running exercise for 4 weeks partially improved endurance in the PpardEC-KO mice. PpardEC-KO mice had less oxidative muscle fibers both at baseline and after training. Higher blood lactate level and less glucose preservation were found in PpardEC-KO mice after running the same distance as PpardEC-WT mice. In human endothelial cells, PPARD knockdown resulted in less glucose and fatty acid uptake. Glucose transport to myocyte from endothelial cells was also attenuated with PPARD knockdown. PPARD may act through SGK1 responsible for GLUT1 expression and glucose uptake. Our study showed an important role of endothelial cell in regulating nutrient transport into skeletal muscle during physical exercise. Impaired endothelial transport of glucose and fatty acid reduces exercise endurance. This study is funded by the General Research Funds 14107822 and 14105321 from the Hong Kong University Grant Council. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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