Environmental enrichment accentuates glucose-induced feeding suppression and glial cell line-derived neurotrophic factor gene expression in the hypothalamus of mice.

The hypothalamus controls food intake by integrating nutrient signals, of which one of the most important is glucose. Consequently, impairments in hypothalamic glucose-sensing mechanisms are associated with hyperphagia and obesity. Environmental enrichment (EE) is an animal housing protocol that provides complex sensory, motor, and social stimulations and has been proven to reduce adiposity in laboratory mice. However, the mechanism by which EE promotes adiposity-suppressing effect remains incompletely understood. Neurotrophic factors play an important role in the development and maintenance of the nervous system, but they are also involved in the hypothalamic regulation of feeding. Brain-derived neurotrophic factor (BDNF) and glial cell line-derived neurotrophic factor (GDNF) are expressed in the hypothalamus and their expression is stimulated by glucose. EE is associated with increased expression of Bdnf mRNA in the hypothalamus. Therefore, we hypothesized that EE potentiates the anorectic action of glucose by altering the expression of neurotrophic factor genes in the hypothalamus. Male C57BL/6 mice were maintained under standard or EE conditions to investigate the feeding response to glucose and the associated expression of feeding-related neurotrophic factor genes in the hypothalamus. Intraperitoneal glucose injection reduced food intake in both control and EE mice with a significantly greater reduction in the EE group compared to the control group. EE caused a significantly enhanced response of Gdnf mRNA expression to glucose without altering basal Gdnf mRNA expression and Bdnf mRNA response to glucose. These findings suggest that EE enhances glucose-induced feeding suppression, at least partly, by enhancing hypothalamic glucose-sensing ability that involves GDNF.

Glucose and fructose directly stimulate brain-derived neurotrophic factor gene expression in microglia.

Brain-derived neurotrophic factor (BDNF) is expressed in both hypothalamic neurons and microglia, and plays a critical role in the regulation of metabolism. Although hypothalamic expression of BDNF is regulated by metabolic signals such as nutrients and hormones, it remains unknown whether these signals differentially regulate BDNF expression in different cell types. The present study aimed to determine whether glucose and fructose regulate BDNF expression in microglia via the specific glucose transporter. To determine the effect of glucose and fructose on Bdnf mRNA and protein expression, murine microglial cell line SIM-A9 cells were exposed to the maintenance concentration of glucose (17.5 mmol/l), high glucose (25 mmol/l), or fructose (7.5 mmol/l) for 40 min to 24 h. To determine whether the blockade of glucose transporter 5 (GLUT5) negates the effect of glucose on Bdnf mRNA expression, cells were exposed to 25 mmol/l glucose in the presence or absence of the GLUT5 inhibitor for 4 h. Levels of Bdnf mRNA and protein were measured by real-time PCR and ELISA, respectively. High glucose caused a significant increase in both pan-Bdnf and long-form Bdnf (L-Bdnf) mRNA as well as protein levels when compared with the maintenance of concentration of glucose in a time-dependent manner. Fructose treatment also increased L-Bdnf mRNA expression. Pharmacological blockade of GLUT5 did not affect glucose-induced Bdnf mRNA expression. These findings suggest that glucose and fructose directly stimulate Bdnf mRNA expression in microglia and these responses may mediate the metabolic actions of glucose and fructose.

Glucose Stimulates Glial Cell Line-Derived Neurotrophic Factor Gene Expression in Microglia through a GLUT5-Independent Mechanism.

Feeding-regulating neurotrophic factors are expressed in both neurons and glial cells. However, nutritional regulation of anorexigenic glial cell line-derived neurotrophic factor (GDNF) and orexigenic mesencephalic astrocyte-derived neurotrophic factor (MANF) expression in specific cell types remains poorly understood. Hypothalamic glucose sensing plays a critical role in the regulation of food intake. It has been theorized that local glucose concentration modulates microglial activity partially via glucose transporter 5 (GLUT5). We hypothesized that an increased local glucose concentration stimulates GDNF expression while inhibiting MANF expression in the hypothalamus and microglia via GLUT5. The present study investigated the effect of glucose on Gdnf and Manf mRNA expression in the mouse hypothalamus and murine microglial cell line SIM-A9. Intracerebroventricular glucose treatment significantly increased Gdnf mRNA levels in the hypothalamus without altering Manf mRNA levels. Exposure to high glucose caused a significant increase in Gdnf mRNA expression and a time-dependent change in Manf mRNA expression in SIM-A9 cells. GLUT5 inhibitor treatment did not block glucose-induced Gdnf mRNA expression in these cells. These findings suggest that microglia are responsive to changes in the local glucose concentration and increased local glucose availability stimulates the expression of microglial GNDF through a GLUT5-independent mechanism, contributing to glucose-induced feeding suppression.

Effect of environmental enrichment on aggression and the expression of brain-derived neurotrophic factor transcript variants in group-housed male mice.

Social and environmental factors influence behavior via modulation of brain physiological functions. Environmental enrichment (EE) is an animal housing technique that provides complex sensory, motor, and social stimulation, leading to modifications in the innate aggressiveness in group-housed laboratory mice. Brain-derived neurotrophic factor (BDNF) is encoded by multiple splice variants and plays a critical role in controlling aggressive behavior in a transcript variant-specific manner. BDNF mediates the beneficial effects of EE on a variety of pathophysiological conditions. These findings led to the hypothesis that EE reduces aggressive behavior by altering the expression of Bdnf mRNA in a transcript variant-specific manner. To test this hypothesis, 3-4-week-old male C57BL/6 mice were randomly group-housed (5 mice per cage) under standard or EE conditions for 6-8 weeks. Aggressive behavior was monitored and levels of Bdnf mRNA variants in aggression-related brain regions were measured. Mice housed in EE cages displayed a significantly lower frequency of aggressive interactions compared to control mice. EE increased levels of Bdnf mRNA variant I (Bdnf I) in the amygdala while it reduced levels of Bdnf I in the hypothalamus, hippocampus, prefrontal cortex, parietal cortex, and brainstem. Meanwhile, EE did not significantly alter levels of Bdnf mRNA variants IIc, IV, and VI in all brain regions examined. These findings support the hypothesis that EE diminishes inter-male aggression by altering Bdnf mRNA expression in a transcript variant-specific and brain region-specific manner. Specifically, brain region-specific alterations in Bdnf I expression may partly mediate EE-induced suppression of inter-male aggression.