Leptin receptor co-expression gene network moderates the effect of early life adversity on eating behavior in children.

Leptin influences eating behavior. Exposure to early adversity is associated with eating behaviour disorders and metabolic syndrome, but the role of the leptin receptor on this relationship is poorly explored. We investigated whether individual differences in brain region specific leptin receptor (LepR) gene networks could moderate the effects of early adversity on eating behavior and metabolism. We created an expression-based polygenic risk score (ePRS) reflecting variations in the function of LepR gene network in prefrontal cortex and hypothalamus to investigate the interactions between a cumulative index of postnatal adversity on eating behavior in two independent birth cohorts (MAVAN and GUSTO). To explore whether variations in the prefrontal cortex or hypothalamic genetic scores could be associated with metabolic measurements, we also assessed the relationship between LepR-ePRS and fasting blood glucose and leptin levels in a third independent cohort (ALSPAC). We identified significant interaction effects between postnatal adversity and prefrontal-based LepR-ePRS on the Child Eating Behavior Questionnaire scores. In MAVAN, we observed a significant interaction effect on food enjoyment at 48 months (ß = 61.58, p = 0.015) and 72 months (ß = 97.78, p = 0.001); food responsiveness at 48 months (ß = 83.79, p = 0.009) satiety at 48 months (ß = -43.63, p = 0.047). Similar results were observed in the GUSTO cohort, with a significant interaction effect on food enjoyment (ß = 30.48, p = 0.006) food fussiness score (ß = -24.07, p = 0.02) and satiety score at 60 months (ß = -17.00, p = 0.037). No effects were found when focusing on the hypothalamus-based LepR-ePRS on eating behavior in MAVAN and GUSTO cohorts, and there was no effect of hypothalamus and prefrontal cortex based ePRSs on metabolic measures in ALSPAC. Our study indicated that exposure to postnatal adversity interacts with prefrontal cortex LepR-ePRS to moderate eating behavior, suggesting a neurobiological mechanism associated with the development of eating behavior problems in response to early adversity. The knowledge of these mechanisms may guide the understanding of eating patterns associated with risk for obesity in response to fluctuations in stress exposure early in life.

Early life stress and the programming of eating behavior and anxiety: Sex-specific relationships with serotonergic activity and hypothalamic neuropeptides.

Early life experiences have strong influences on brain programming and can affect eating behavior control and body weight later in life. However, there is no consensus about the relationship between neonatal stress and feeding behavior. We evaluated whether maternal deprivation (MD) and maternal separation (MS) alter body weight and appetite using standard rat chow consumption and palatable food. Also, we evaluated anxiety and the expression of the leptin receptor, neuropeptides POMC, CART, NPY in the hypothalamus, as well as the serotoninergic system in the amygdala and hypothalamus as possible modulators of these behaviors. We found a decrease in standard rat chow consumption in MD. However, both neonatal stress protocols increased the consumption of palatable food and led to anxiogenic behavior in male animals. MD led to decreased hypothalamic POMC levels in adult males. Serotonin in the hypothalamus was decreased by both stress models in males and females. In the amygdala, MS decreased serotonin levels while MD increased its metabolite levels. We observed that males are more vulnerable and females are more resilient to the effects of neonatal stress on anxiety-like behavior, as well as on food consumption and on the central changes observed. These data together add support to the concept that the early environment contributes to the development of eating disorders later in life.