Project description:Nutritional status influences feeding behaviors, food preferences and taste sensations. For example, zinc-deficient rats have been reported to show reduced and cyclic food intake patterns with increased preferences for NaCl. Although some impairments of the central nervous and endocrine systems have been speculated to be involved in these phenomena, the effects of short-term zinc deficiency on the brain have not been well examined to date. In this study, we performed a comprehensive analysis of the gene expression patterns in the rat diencephalon, which is a portion of the brain that includes the hypothalamus and thalamus, after short-term zinc deficiency and also during zinc recovery. The rats showed reduced and cyclic food intake patterns with increased salt preferences after a 10-day dietary zinc deficiency. A comparative analysis of their diencephalons using cDNA microarrays revealed that approximately 1% of the genes expressed in the diencephalons showed significantly altered expression levels. On the other hand, a 6-day zinc supplementation following the deprivation allowed for the recovery to initial food intake behaviors and salt preferences. The expression levels of most of the genes that had been altered by exposure to zinc deficient conditions were also recovered. These results show that feeding behaviors, taste preferences and gene expression patterns in the diencephalon respond quickly to changing zinc levels. This suggests that the gene expression changes observed in the diencephalon and the accompanying functional changes may be related to the development of deviations in feeding behaviors and increased preferences for NaCl in zinc-deficient rats. Four-week-old male Sprague-Dawley rats were purchased from Charles River Japan (Yokohama, Japan). Fifteen rats were individually housed in a stainless steel cage in a room with constant humidity at 22 ± 1 °C under a 12 h light-dark cycle (lights on at 8:00). Zinc-deficient diets (# D19488M, Research Diets, New Brunswick, NJ, USA) were based on the AIN-93G diet and contained 0.6 mg zinc / 1000 g diet (Table 1). For the control zinc-sufficient diets, zinc sulfate supplements were provided with up to 30.0 mg zinc / 1000 g diet. Rats were fed the control diets ad libitum for 1 week for adaptation and then were divided into two groups matched for body weight. For the zinc-deficient experiment, rats in the ZD group (n =9) were allowed to eat the zinc-deficient diets ad libitum. The rats in the PF group (n = 6) were pair-fed the control diets to match the intake of the ZD rats. Two fluid bottles with deionized water were attached to each cage for the entire experiment with the exception of the 48 h preference test, in which 300 mM NaCl was provided from days 6 to 8. Zinc was limited for 10 days to reduce the effects of differences in salt intake in the preference test between the two groups. For the zinc recovery experiment, the ZR (n = 9) and ZRPF (n = 6) groups were subjected to the same conditions as above. Briefly, after 1 week of adaptation, ZR rats were fed the zinc-deficient diets ad libitum, and ZRPF rats were pair-fed the control diets for 10 days. After that, the rats in both the ZR and ZRPF groups were fed the fixed amount (13 g) of the control diets for the 6 day zinc recovery period to avoid any differences in food intake between the two groups that would be caused by pair-feeding because the previous report showed rapidly increased food intake following the initiation of the zinc-sufficient diets after zinc deficiency [1]. The diet amounts were restricted to the average consumption of the ZR group on the last day of the zinc-deficient period. The 48 h two-bottle preference tests for 300 mM NaCl were performed from days 6 to 8 during the deficient period and from days 14 to 16 during the recovery period. The analysis removed one rat from the ZRPF group showing more than a 0.5 of preference ratio to the 300 mM NaCl solution and three rats from the ZR group showing less than 0.5 preference ratios as assessed by a preference test that was conducted during days 6 to 8. At the end of each experiment, the rats were deeply anesthetized with pentobarbital sodium. Blood samples were collected from the carotid arteries and stored at -80 °C. The brains were quickly removed from the bodies after decapitation, and the diencephalons were separated by forceps on ice. The diencephalons were washed in ice-cold phosphate-buffered saline (PBS), treated with RNAlater (Invitrogen, Carlsbad, CA, USA), and stored at -20 °C. The serum zinc concentrations were analyzed with an ICP-AES (SPS 1200 VR, Seiko Instruments, Chiba, Japan). The Animal Care Committee of the University of Tokyo approved all animal experiments. Four average rats from each group were selected based on body weights, plasma zinc concentrations, and salt preferences.

Project description:Dietary zinc status reversibly alters both the feeding behaviors of the rats and gene expression patterns in diencephalon

Project description:Dietary zinc status reversibly alters both the feeding behaviors of the rats and gene expression patterns in diencephalon

Project description:Feeding is an important activity for all animals providing nutrients essential for survival and reproduction. Not surprisingly, learning plays a critical role in feeding behavior through the establishment and strengthening of food preferences and aversions. That is, the integration of taste and post ingestive visceral signals in the brain results in memorial representations about the consequences associated with ingesting a particular food. For example, when ingestion of a food is followed by negative gastrointestinal consequences (e.g. nausea, sickness, or vomiting), the animal develops a conditioned taste aversion (CTA), which produces a switch from acceptance to avoidance of that and any like tasting stimulus. Despite recent advances in understanding CTA responsive intracellular signaling pathways in the amygdala, little is known about any long-term regulation of target gene expression following CTA memory consolidation and retrieval. The present study utilized oligo-nucleotide microarray to understand the genes and networks involved in Conditional Taste Aversion Behavior.

Project description:The sensation of hunger after a period of fasting and the sensation of satiety after eating is crucial to behavioral regulation of food intake, but the biological mechanisms regulating these sensations are incompletely understood. We studied the behavioral and physiological adaptation to fasting in the vinegar fly (Drosophila melanogaster). Here we show that flies demonstrated increased behavioral attraction to food odor when food-deprived with no corresponding increase in sensitivity in the peripheral olfactory system. Flies increased their food intake transiently in the post-fasted state, but returned to a stable baseline feeding level within 24 hr after return to food. This modulation in feeding was accompanied by a significant increase in the size of the crop organ of the digestive system, suggesting that fasted flies responded both by increasing their food intake and storing reserve food in their crop. The post-fasting feeding response was observed in both male and female flies of diverse genetic backgrounds. Expression profiling of head, body, and chemosensory tissues by microarray analysis revealed several hundred genes that are regulated by feeding state, including 247 genes in the fly head. We performed RNA interference-mediated knockdown of, takeout, one of the genes strongly downregulated by fasting in multiple tissues. When takeout was knocked down in all neurons the post-fasting feeding response was abolished. These observations suggest that a coordinated transcriptional response to internal physiological state may regulate both ingestive behaviors and chemosensory perception of food 6 Pool of flies were used for this experiment. For each pool, samples were taken at 0,24 and 48h and separated in each body part. 56 samples were used for the analysis.

Project description:The sensation of hunger after a period of fasting and the sensation of satiety after eating is crucial to behavioral regulation of food intake, but the biological mechanisms regulating these sensations are incompletely understood. We studied the behavioral and physiological adaptation to fasting in the vinegar fly (Drosophila melanogaster). Here we show that flies demonstrated increased behavioral attraction to food odor when food-deprived with no corresponding increase in sensitivity in the peripheral olfactory system. Flies increased their food intake transiently in the post-fasted state, but returned to a stable baseline feeding level within 24 hr after return to food. This modulation in feeding was accompanied by a significant increase in the size of the crop organ of the digestive system, suggesting that fasted flies responded both by increasing their food intake and storing reserve food in their crop. The post-fasting feeding response was observed in both male and female flies of diverse genetic backgrounds. Expression profiling of head, body, and chemosensory tissues by microarray analysis revealed several hundred genes that are regulated by feeding state, including 247 genes in the fly head. We performed RNA interference-mediated knockdown of, takeout, one of the genes strongly downregulated by fasting in multiple tissues. When takeout was knocked down in all neurons the post-fasting feeding response was abolished. These observations suggest that a coordinated transcriptional response to internal physiological state may regulate both ingestive behaviors and chemosensory perception of food

Project description:Hunger, driven by negative energy balance, elicits the search for and consumption of food. In mammals, this is orchestrated principally through the activity of neurons in the hypothalamus, direct manipulation of which can potently drive food intake. However, the neural circuits outside of the hypothalamus that control feeding are poorly understood. Here, we identify two functionally opponent cell types within the dorsal raphe nucleus (DRN), marked by the vesicular transporters for GABA (Vgat) or glutamate (VGLUT3), that project to many known feeding centers and rapidly control feeding. We find that DRNVgat neurons drive, while DRNVGLUT3 neurons suppress, food intake. Furthermore, through the development and application of cell type-specific molecular profiling technologies, we identify many differentially expressed transmembrane receptors, which may represent unique druggable targets. Local application of agonists for these receptors potently modulates feeding, recapitulating the effects of cell-specific manipulations. Together, these data establish a key role for the DRN in controlling food intake and add an important anatomic site that controls energy balance.

Project description:Quantitative mass spectrometry reveals food intake-induced neuropeptide level change in rat brain and functional assessment of selected neuropeptides as feeding regulators

Project description:The TGFβ cytokine family member, GDF15, reduces food intake and body weight and represents a potential treatment for obesity. Because the brain stem-restricted expression pattern of its receptor, GDNF Family Receptor α–like (GFRAL), presents an exciting opportunity to understand mechanisms of action for area postrema neurons in food intake, we generated GfralCre and conditional GfralCreERT mice to visualize and manipulate GFRAL neurons. We found infection or pathophysiologic states (rather than meal ingestion) stimulate GFRAL neurons. TRAP-Seq analysis of GFRAL neurons revealed their expression of a wide range of neurotransmitters and neuropeptides. Artificially activating GfralCre-expressing neurons inhibited feeding, decreased gastric emptying, and promoted a conditioned taste aversion (CTA). GFRAL neurons most strongly innervate the parabrachial nucleus (PBN), where they target CGRP-expressing (CGRPPBN) neurons. Silencing CGRPPBN neurons abrogated the aversive and anorexic effects of GDF-15. These findings suggest that GFRAL neurons link non-meal-associated, pathophysiologic signals to suppress nutrient uptake and absorption.

Project description:To understand the molecular basis underlying the response to food intake, RNA sequencing was utilized to analyze the stomach transcriptome of C. nasus with feeding group (CSI) and non-feeding group (CSN).