Leptin increases skeletal muscle lipoprotein lipase and postprandial lipid metabolism in mice

WT Donahoo, NR Stob, S Ammon, N Levin, RH Eckel - Metabolism, 2011 - Elsevier
WT Donahoo, NR Stob, S Ammon, N Levin, RH Eckel
Metabolism, 2011Elsevier
The ability of leptin to preserve lean tissue during weight loss may be in part due to
differences in nutrient partitioning. Because lipoprotein lipase (LPL) plays a key role in
partitioning lipid nutrients, this study was conducted to test the hypothesis that leptin would
modify the tissue-specific regulation of LPL and result in increased lipid oxidation and
decreased storage. The effects of daily intraperitoneal leptin injections (2 mg/kg body
weight) over 2 weeks on LPL activity and postprandial lipid metabolism were tested in both …
The ability of leptin to preserve lean tissue during weight loss may be in part due to differences in nutrient partitioning. Because lipoprotein lipase (LPL) plays a key role in partitioning lipid nutrients, this study was conducted to test the hypothesis that leptin would modify the tissue-specific regulation of LPL and result in increased lipid oxidation and decreased storage. The effects of daily intraperitoneal leptin injections (2 mg/kg body weight) over 2 weeks on LPL activity and postprandial lipid metabolism were tested in both wild-type (WT), leptin-deficient ob/ob obese mice and mice pair fed to the leptin-treated mice. On the experimental day, mice were given food by gavage, blood was drawn periodically, and adipose tissue and skeletal muscle were harvested for measurements of LPL activity at 240 minutes. After 2 weeks of leptin administration, skeletal muscle LPL (SMLPL) activity was increased in leptin-treated compared with pair-fed (P = .012) and WT (P = .002) mice. There was no effect of leptin or pair feeding on postprandial adipose tissue LPL activity. In ob/ob mice, leptin treatment normalized the decrease in postprandial free fatty acid concentration (P = .066). Leptin had no effect on either the area under the triglyceride (TG) excursion or the integrated area under the TG excursion in WT mice. In ob/ob mice, however, the TG excursion was lower in the leptin-treated than the pair-fed mice by area under the TG excursion (P = .012) and was lower than in the WT mice by integrated area under the TG excursion (P = .027). As expected, 2 weeks of leptin treatment decreased body weight in both the WT and ob/ob mice (−2.6% and −10.4%, respectively). Leptin treatment increased SMLPL, an effect that may have contributed to the leptin-induced weight loss. The leptin-induced decreased postprandial TG excursion in ob/ob mice suggests that leptin acts to augment clearance of postprandial TG-rich lipoprotein lipid and that this increase may in part be secondary to the increased activity of SMLPL. The trend for decreased postprandial free fatty acid may indicate that leptin decreases adipose tissue lipid stores without increasing lipolysis.
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