Nervous system expression of PPARγ and mutant PPARγ has profound effects on metabolic regulation and brain development

M Stump, DF Guo, KT Lu, M Mukohda… - …, 2016 - academic.oup.com
Endocrinology, 2016academic.oup.com
Peroxisome proliferator activated receptor (PPARγ) is a nuclear receptor transcription factor
that regulates adipogenesis and energy homeostasis. Recent studies suggest PPARγ may
mediate some of its metabolic effects through actions in the brain. We used a Cre-
recombinase-dependent (using NestinCre) conditionally activatable transgene expressing
either wild-type (WT) or dominant-negative (P467L) PPARγ to examine mechanisms by
which PPARγ in the nervous system controls energy balance. Inducible expression of …
Peroxisome proliferator activated receptor (PPARγ) is a nuclear receptor transcription factor that regulates adipogenesis and energy homeostasis. Recent studies suggest PPARγ may mediate some of its metabolic effects through actions in the brain. We used a Cre-recombinase-dependent (using NestinCre) conditionally activatable transgene expressing either wild-type (WT) or dominant-negative (P467L) PPARγ to examine mechanisms by which PPARγ in the nervous system controls energy balance. Inducible expression of PPARγ was evident throughout the brain. Expression of 2 PPARγ target genes, aP2 and CD36, was induced by WT but not P467L PPARγ in the brain. Surprisingly, NesCre/PPARγ-WT mice exhibited severe microcephaly and brain malformation, suggesting that PPARγ can modulate brain development. On the contrary, NesCre/PPARγ-P467L mice exhibited blunted weight gain to high-fat diet, which correlated with a decrease in lean mass and tissue masses, accompanied by elevated plasma GH, and depressed plasma IGF-1, indicative of GH resistance. There was no expression of the transgene in the pancreas but both fasting plasma glucose, and fed and fasted plasma insulin levels were markedly decreased. NesCre/PPARγ-P467L mice fed either control diet or high-fat diet displayed impaired glucose tolerance yet exhibited increased sensitivity to exogenous insulin and increased insulin receptor signaling in white adipose tissue, liver, and skeletal muscle. These observations support the concept that alterations in PPARγ-driven mechanisms in the nervous system play a role in the regulation of growth and glucose metabolic homeostasis.
Oxford University Press