Project description:Dnmt1/3a deletion in prefrontal cortical neurons reduces palatable food intake

Project description:We studied the global genomic response in the hypothalamus during heat acclimation, with and without combined hypohydration stress. Rats were acclimated for 2 days or for 30 days at 34°C. Hypohydration (10% decrease in body weight) was attained by water deprivation. Functional analyses demonstrated a bi-phasic acclimatory profile with a transient upregulation of genes encoding ion channels, transporters, and transmitter signaling upon 2 days acclimation, suggesting enhanced neuronal excitability at that acclimation phase. Following long acclimation most genes returned to their pre-acclimation expression levels. In both acclimation phases, genes encoding hormones and neuropeptides, linked with metabolic rate and food intake, were downregulated. The response to hypohydration was characterized by an upregulation of a large number of genes primarily associated with the regulation of ion channels and cell-volume and neuronal excitability. During 2 days acclimation, the response was transiently desensitized, recovering upon LTHA. The results suggest that hypohydration overrides the heat acclimatory status. Keywords: other

Project description:The function of the central nervous system to regulate food intake can be disrupted by sustained metabolic challenges such as high-fat diet (HFD), which may contribute to the development of various metabolic disorders. In the present study, we found that HFD specifically enhanced food-seeking behavior in fruit flies without altering flies’ baseline metabolism and food consumption. Mechanistically, HFD increased the excitability of a small group of octopaminergic (OA) neurons to a hunger hormone named adipokinetic hormone (AKH), via increasing the accumulation of AKH receptor (AKHR) in these neurons. Upon HFD, excess dietary lipids are transported by a lipoprotein LTP to enter these OA+AKHR+ neurons via the cognate receptor LpR1, which in turn activated AMPK-TOR signaling and suppressed autophagy-dependent degradation of AKHR. Taken together, we uncovered a mechanism that linked HFD, AMPK-TOR signaling, neuronal autophagy, and food-seeking behavior, providing insight in the reshaping of neural circuitry under metabolic challenges and the progression of metabolic diseases.

Project description:The function of the central nervous system to regulate food intake can be disrupted by sustained metabolic challenges such as high-fat diet (HFD), which may contribute to the development of various metabolic disorders. In the present study, we found that HFD specifically enhanced food-seeking behavior in fruit flies without altering flies’ baseline metabolism and food consumption. Mechanistically, HFD increased the excitability of a small group of octopaminergic (OA) neurons to a hunger hormone named adipokinetic hormone (AKH), via increasing the accumulation of AKH receptor (AKHR) in these neurons. Upon HFD, excess dietary lipids are transported by a lipoprotein LTP to enter these OA+AKHR+ neurons via the cognate receptor LpR1, which in turn activated AMPK-TOR signaling and suppressed autophagy-dependent degradation of AKHR. Taken together, we uncovered a mechanism that linked HFD, AMPK-TOR signaling, neuronal autophagy, and food-seeking behavior, providing insight in the reshaping of neural circuitry under metabolic challenges and the progression of metabolic diseases.

Project description:To study the molecular mediators of naturally rewarding effects of palatable food we used a model of palatable “snacking” (Ulrich-Lai et al., 2007) in which rats are given chronic, brief access to a limited amount of sucrose solution (30%). Single housed, male Long-Evans rats (250g) (n=12 per group) from Harlan Labs (Indianapolis, IN) received normal rat chow (Harlan Teklad) and water ad libitum for the duration of the experiment. After a one-week period of acclimation, rats were randomly assigned to drink treatment groups of either 30% sucrose solution or water. Rats received a 14-day regimen of twice daily (9:30 and 15:30) brief (maximum of 30 minutes) limited (up to 4 mL) access of their assigned drink solution. Drink solutions were delivered via a graduated sipper placed onto the cage top in addition to the existing water bottle and sippers were immediately removed when the animal had consumed 4mL or after the 30-minute access period, whichever occurred first. Drink intake, food intake, and body weight were monitored throughout the experiment to verify that the rats learned to drink sucrose, that they adjusted chow intake for calories consumed from sucrose (~10%), and that there was no effect on body weight gain as is normally seen with this model (Ulrich-Lai et al., 2007). Drink treatment terminated on day 14 and at 8:00 on the morning of day 15, the rats were sacrificed by rapid decapitation. BLA tissue was dissected, RNA extracted, and gene expression changes between water and sucrose groups were accessed by microarray.

Project description:To study the molecular mediators of naturally rewarding effects of palatable food we used a model of palatable “snacking” (Ulrich-Lai et al., 2007) in which rats are given chronic, brief access to a limited amount of sucrose solution (30%). Single housed, male Long-Evans rats (250g) (n=12 per group) from Harlan Labs (Indianapolis, IN) received normal rat chow (Harlan Teklad) and water ad libitum for the duration of the experiment. After a one-week period of acclimation, rats were randomly assigned to drink treatment groups of either 30% sucrose solution or water. Rats received a 14-day regimen of twice daily (9:30 and 15:30) brief (maximum of 30 minutes) limited (up to 4 mL) access of their assigned drink solution. Drink solutions were delivered via a graduated sipper placed onto the cage top in addition to the existing water bottle and sippers were immediately removed when the animal had consumed 4mL or after the 30-minute access period, whichever occurred first. Drink intake, food intake, and body weight were monitored throughout the experiment to verify that the rats learned to drink sucrose, that they adjusted chow intake for calories consumed from sucrose (~10%), and that there was no effect on body weight gain as is normally seen with this model (Ulrich-Lai et al., 2007). Drink treatment terminated on day 14 and at 8:00 on the morning of day 15, the rats were sacrificed by rapid decapitation. BLA tissue was dissected, RNA extracted, and gene expression changes between water and sucrose groups were accessed by microarray. We used microarray to assess the changes in gene expression in the BLA of rats that have had a history of sucrose snacks (n=12) vs control (n=12). Rats received access (up to 4 mL) to extra bottles containing water (control) or 30% sucrose twice daily for 14 days. Rats had ab lib access to chow and water for the duration of the experiment. Rats were sacrificed the morning of day 15 and the BLA was removed for microarray analysis. Functional cluster analysis was performed on the list of 145 significantly upregulated genes using Ingenuity Pathway Analysis (Ingenuity Systems, Redwood City, CA). See supplementary file at the foot of this record.

Project description:Background: Anorexia is a common symptom among cancer patients and contributes to malnutrition and strongly impinges on quality of life. Cancer-induced anorexia is thought to be caused by an inability of food intake-regulating systems in the hypothalamus to respond adequately to negative energy balance during tumour growth. Here, we show that this impaired response of food-intake control is likely to be mediated by altered serotonin signalling and by failure in post-transcriptional neuropeptide Y (NPY) regulation. Methods: Two tumour cachectic mouse models with different food intake behaviours were used: a C26-colon adenocarcinoma model with increased food intake and a Lewis lung carcinoma model with decreased food intake. This contrast in food intake behaviour between tumour-bearing (TB) mice in response to growth of the two different tumours was used to distinguish between processes involved in cachexia and mechanisms that might be important in food intake regulation. The hypothalamus was used for transcriptomics (affymetrix chips). Results: In both models, hypothalamic expression of orexigenic NPY was significantly higher compared with controls, suggesting that this change does not directly reflect food intake status but might be linked to negative energy balance in cachexia. Expression of genes involved in serotonin signalling showed to be different between C26-TB mice and Lewis lung carcinoma-TB mice and was inversely associated with food intake. In vitro, using hypothalamic cell lines, serotonin repressed neuronal hypothalamic NPY secretion while not affecting messenger NPY expression, suggesting that serotonin signalling can interfere with NPY synthesis, transport, or secretion. Conclusions: Altered serotonin signalling is associated with changes in food intake behaviour in cachectic TB mice. Serotonins' inhibitory effect on food intake under cancer cachectic conditions is probably via affecting the NPY system. Therefore, serotonin regulation might be a therapeutic target to prevent the development of cancer-induced eating disorders.

Project description:Background: Anorexia is a common symptom among cancer patients and contributes to malnutrition and strongly impinges on quality of life. Cancer-induced anorexia is thought to be caused by an inability of food intake-regulating systems in the hypothalamus to respond adequately to negative energy balance during tumour growth. Here, we show that this impaired response of food-intake control is likely to be mediated by altered serotonin signalling and by failure in post-transcriptional neuropeptide Y (NPY) regulation. Methods: Two tumour cachectic mouse models with different food intake behaviours were used: a C26-colon adenocarcinoma model with increased food intake and a Lewis lung carcinoma model with decreased food intake. This contrast in food intake behaviour between tumour-bearing (TB) mice in response to growth of the two different tumours was used to distinguish between processes involved in cachexia and mechanisms that might be important in food intake regulation. The hypothalamus was used for transcriptomics (affymetrix chips). Results: In both models, hypothalamic expression of orexigenic NPY was significantly higher compared with controls, suggesting that this change does not directly reflect food intake status but might be linked to negative energy balance in cachexia. Expression of genes involved in serotonin signalling showed to be different between C26-TB mice and Lewis lung carcinoma-TB mice and was inversely associated with food intake. In vitro, using hypothalamic cell lines, serotonin repressed neuronal hypothalamic NPY secretion while not affecting messenger NPY expression, suggesting that serotonin signalling can interfere with NPY synthesis, transport, or secretion. Conclusions: Altered serotonin signalling is associated with changes in food intake behaviour in cachectic TB mice. Serotonins' inhibitory effect on food intake under cancer cachectic conditions is probably via affecting the NPY system. Therefore, serotonin regulation might be a therapeutic target to prevent the development of cancer-induced eating disorders.

Project description:Sensory inputs activate sparse ensembles of neurons in the dentate gyrus of the hippocampus, but how eligibility of individual neurons to recruitment is determined remains elusive. We identified thousands of largely bistable (CpG methylated or unmethylated) regions within neuronal gene bodies, established during mouse dentate gyrus development. Reducing DNA methylation and the proportion of the methylated epialleles at bistable regions compromised novel context-induced neuronal activation. Conversely, increasing methylation and the frequency of the methylated epialleles at bistable regions enhanced intrinsic excitability. Single-nuclei profiling revealed enrichment of specific epialleles from a subset of bistable regions in activated neurons. Genes displaying both differential methylation and expression in activated neurons defined a network of proteins regulating neuronal excitability and structural plasticity. We propose a model in which bistable regions create neuron heterogeneity, and constellations of exonic epialleles dictate, via modulating gene expression and neuronal excitability, eligibility to a coding ensemble

Project description:Variations in the human FTO gene have been linked to obesity and altered connectivity and function of the dopaminergic neurocircuitry. Here we report that FTO in D2 medium spiny neurons (MSNs) of mice regulates the excitability of these cells in vitro and in vivo as well as controls D2 MSN globus pallidus external projections. Lack of FTO in D2 MSNs translates into increased locomotor responses to novelty, associated with altered timing behavior without affecting reward responses to drugs of abuse and highly palatable food, or the ability to discount rewards. Pharmacological manipulation of D1R- and D2R-dependent pathways in these animals reveals an altered balance between D1 MSN- and D2 MSN-mediated control of motor output. These findings hold the potential to target a novel avenue for control of basal ganglia motor function, where modulation of FTO-dependent signaling in D2 MSNs may promote D1 MSN regulated locomotor behavior without altering reward signaling or inciting impulsivity.