Profiling of energy metabolism in olanzapine-induced weight gain in rats and its prevention by the CB1-antagonist AVE1625.

This is the first study to examine the effect of subchronic olanzapine (OLZ) on energy homeostasis in rats, covering all aspects of energy balance, including energy intake as metabolizable energy, storage, and expenditure. We further analyzed whether, and by which mechanism, the CB1-antagonist AVE1625 might attenuate OLZ-induced body weight gain. For this purpose, we selected juvenile female Hanover Wistar rats that robustly and reproducibly demonstrated weight gain on OLZ treatment, accepting limitations to model the aberrations on lipid and carbohydrate metabolism. Rats received 2 mg/kg OLZ orally twice daily for 12 days. Body weight and body composition were analyzed. Moreover daily food intake, energy expenditure, and substrate oxidation were determined in parallel to motility and body core temperature. OLZ treatment resulted in substantial body weight gain, in which lean and fat mass increased significantly. OLZ-treated rats showed hyperphagia that manifested in increased carbohydrate oxidation and lowered fat oxidation (FO). Energy expenditure was increased, motility decreased, but there was no indication for hypothermia in OLZ-treated rats. Coadministration of OLZ and AVE1625 (10 mg/kg orally once daily) attenuated body weight gain, diminishing the enhanced food intake while maintaining increased energy expenditure and decreased motility. Our data reveal that energy expenditure was enhanced in OLZ-treated rats, an effect not critically influenced by motility. Energy uptake, however, exceeded energy expenditure and led to a positive energy balance, confirming hyperphagia as the major driving factor for OLZ-induced weight gain. Combination of OLZ treatment with the CB1-antagonist AVE1625 attenuated body weight gain in rats.

Neonatal screening for very long-chain acyl-coA dehydrogenase deficiency: enzymatic and molecular evaluation of neonates with elevated C14:1-carnitine levels.

OBJECTIVE: Neonatal screening programs for very long-chain acyl-coenzyme A dehydrogenase deficiency have been implemented recently in various countries. Mildly elevated C14:1-carnitine on day 3 of life strongly suggests very long-chain acyl-coenzyme A dehydrogenase deficiency. DESIGN: We characterized 11 neonates with elevated C14:1-carnitine by enzyme and molecular analyses. Palmitoyl-coenzyme A oxidation was measured in lymphocytes. Sequencing of all 20 exons of the VLCAD gene was performed from genomic DNA. RESULTS: Palmitoyl-coenzyme A oxidation revealed significantly decreased residual activities consistent with very long-chain acyl-coenzyme A dehydrogenase deficiency in 7 neonates. In 2 individuals, residual activities of 48% and 44%, respectively, suggested heterozygosity. Two disease-causing mutations were detected in 6 of 7 neonates with very long-chain acyl-coenzyme A dehydrogenase deficiency; in the remaining 1 patient, only 1 mutation was identified. Of 2 individuals with residual activities consistent with heterozygosity, 1 was heterozygous for a VLCAD mutation. The other child and both individuals with normal palmitoyl-coenzyme A oxidation had normal genotypes. CONCLUSIONS: In 4 of 11 neonates identified with elevated C14:1-carnitine, very long-chain acyl-coenzyme A dehydrogenase deficiency was excluded. A C14:1-carnitine level > 1 micromol/L strongly suggests very long-chain acyl-coenzyme A dehydrogenase deficiency, whereas concentrations < or = 1 micromol/L do not allow a clear discrimination among affected patients, carriers, and healthy individuals. Further diagnostic evaluation, including enzyme and molecular analyses, is essential to identify very long-chain acyl-coenzyme A dehydrogenase deficiency correctly.

Pitfalls of neonatal screening for very-long-chain acyl-CoA dehydrogenase deficiency using tandem mass spectrometry.

Neonatal screening programs for very-long-chain acyl-CoA dehydrogenase deficiency (VLCADD) have recently been implemented. We report 2 newborns with elevated C14:1-carnitine levels on day 3 of life and normal levels on days 5 to 7. Enzyme and molecular analyses confirmed VLCADD in the first patient and heterozygosity in the second patient. We conclude that the diagnosis of VLCADD can be missed by acylcarnitine analysis during anabolic conditions. An increased C14:1-carnitine level can also occur in heterozygous individuals. Elevated C14:1-carnitine level on neonatal screening warrants further diagnostic workup even if a repeat sample demonstrates normal acylcarnitine levels.

Absence of UCP3 in brown adipose tissue does not impair nonshivering thermogenesis.

We report on a novel Djungarian hamster mutant lineage that exhibits a loss of uncoupling protein (UCP) 3 mRNA and protein in brown adipose tissue (BAT), whereas UCP3 expression in skeletal muscle is only mildly diminished. In response to 2 d of cold exposure, UCP3 mRNA was 4.5-fold elevated in BAT of wild-type hamsters but remained undetectable in mutant hamsters. Notably, in BAT of warm- and cold-exposed mutant hamsters, UCP1 and UCP2 mRNA levels were increased. The tissue specificity of UCP3 deficiency suggests that the underlying unknown mutation impairs a factor controlling UCP3 gene expression selectively in brown adipocytes. In wild-type but not mutant primary brown adipocytes, UCP3 gene expression was stimulated by treatment with peroxisome proliferator activated receptor (PPAR) ligands. This implies that the underlying mutation causing UCP3 deficiency is expressed within brown adipocytes and disrupts PPAR-dependent transactivation of the UCP3 gene. On the functional level, we found no direct phenotypic consequences of altered UCP expression in BAT. The absence of UCP3 in BAT of cold-acclimated mutant hamsters affected neither maximal nonshivering thermogenesis elicited by noradrenaline nor the uncoupled respiration of isolated mitochondria in the presence of oligomycin and in response to palmitate.