Browsing by Author "Wang, Guoqing"
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- Central mechanisms of prolactin-releasing peptides orexigenic effect in chickensWang, Guoqing (Virginia Tech, 2015-06-29)Prolactin-releasing peptide (PrRP) is an endogenous hypothalamic neuropeptide that when exogenously injected increases food intake in chickens, but decreases it in rodents and goldfish. We designed three sets of experiments to elucidate the mechanisms of PrRP's orexigenic effect in chicks. In experiment one, food and water intake were evaluated in chicks after receiving intracerebroventricular (ICV) injection of the vehicle, 0.75, 3, 12, 47 or 188 pmol PrRP. The administration of 12 and 47 pmol PrRP increased food intake for up to 120 min after injection, and 188 pmol increased it for up to 180 min. The lowest effective dose was 3 pmol, which increased food intake for up to 60 min after injection. Water intake was not affected. To investigate the molecular mechanisms, c-Fos immunohistochemistry was performed and mRNA expression of some appetite-associated neurotransmitters was measured in chicks that received either vehicle or 188 pmol of PrRP. The rostral paraventricular nucleus (PVN) was activated which coincided with increased neuropeptide Y (NPY) mRNA expression in the whole hypothalamus. In experiment two, food and water intake were evaluated in chicks fed a high carbohydrate (HC), high fat (HF) or high protein (HP) diet after ICV injection of vehicle, 3 or 188 pmol PrRP. Chicks fed the HP diet increased food intake at a lower dose than chicks fed HF and HP diets after ICV PrRP injection. In addition, ICV injection of vehicle, 3 and 188 pmol PrRP were performed in chicks fed all three diets, and ICV PrRP injection induced preferential intake of the HP diet over HC and HF diets. The expression of some appetite-associated neuropeptides in the hypothalamus was also measured in chicks fed the HC, HF or HP diet after ICV injection of vehicle or 188 pmol PrRP. There was a diet effect on mRNA abundance of all appetite-associated genes measured (P < 0.05), with greater expression in chicks fed the HF or HP than HC diet. While neuropeptide Y (NPY) mRNA abundance was similar between vehicle and PrRP-injected chicks that consumed HP or HF diets, expression was greater (P < 0.05) in PrRP- than vehicle-injected chicks that consumed the HC. In experiment three, the orexigenic effect of PrRP was tested in chicks selected for low (LWS) and high (HWS) body weight after central administration of vehicle, 24, 94 and 375 pmol PrRP. The LWS chicks had a lower threshold and higher magnitude of food intake increase in response to PrRP injection. Results demonstrate that PrRP is a potent orexigenic factor in chickens and that effects are likely mediated through the hypothalamus. The orexigenic effect of PrRP was influenced by dietary macronutrient composition, and diet in turn influenced the food intake response to PrRP. These results may contribute to a novel understanding of appetite regulation.
- Effects of dietary macronutrient composition and exogenous neuropeptide Y on adipose tissue development in broiler chicksWang, Guoqing (Virginia Tech, 2018-06-11)The objective of this dissertation research was to investigate the effect of dietary macronutrient composition on neuropeptide Y (NPY)-mediated regulation of adipose tissue physiology in broiler chickens during the early post-hatch period. A high-carbohydrate (HC), high-fat (HF) or high-protein (HP) diet was fed to broiler chicks in all experiments and various facets of physiology were evaluated at day 4 post-hatch, including diet-, fasting-, and neuropeptide Y-induced effects on gene expression, cellular morphology, and lipid metabolism. Experiment 1 was designed to study the effects of diet on molecular changes in different adipose tissue depots (subcutaneous, clavicular and abdominal) after 3 hours of fasting and 1 hour of refeeding. Adipose tissue weights were decreased in chicks that consumed the HP diet, whereas adipocyte diameter was increased in response to the HF diet. There was greater expression of mRNAs encoding fatty acid binding protein 4 (FABP4) and monoglyceride lipase in chicks fed the HC and HF diets than the HP diet in all three adipose tissue depots. Fasting increased plasma non-esterified fatty acid concentrations in chicks fed the HC and HP diets. Results suggest that the heavier fat depots and larger adipocytes in chicks fed the HF diet are explained by greater rates of hypertrophy, whereas the HP diet led to a decrease in adipose tissue deposition, likely as a result of decreased rates of adipogenesis. Experiments 2 and 3 were designed to investigate how dietary macronutrient composition affects the effect of centrally or peripherally administered NPY, respectively, on lipid metabolism-associated factor mRNAs in adipose tissue. In experiment 2, vehicle or 0.2 nmol of NPY was injected intracerebroventricularly (ICV) and abdominal and subcutaneous fat samples were collected at 1 hour post-injection. In the subcutaneous fat, ICV NPY injection decreased peroxisome proliferator-activated receptor gamma (PPAR gamma) and sterol regulatory element-binding transcription factor 1 (SREBP1) mRNAs in chicks fed the HF diet, whereas there was an increase in SREBP1 expression in chicks fed the HF diet after NPY injection. Expression of PPAR gamma and FABP4 mRNAs increased in the abdominal fat of HF diet-fed chicks after NPY injection. Thus, HF diet consumption may have enhanced the sensitivity of chick adipose tissue to the effect of centrally-injected NPY on gene expression of adipogenesis-associated factors. In experiment 3, vehicle, 60, or 120 micrograms/kg BW of NPY was injected intraperitoneally (IP), and subcutaneous, clavicular, and abdominal fat was collected at 1 and 3 hours post-injection. Food intake and plasma NEFA concentrations were not different among chicks fed the HC, HF or HP diet after IP NPY injection, indicating that the effects of NPY on adipogenesis were independent of secondary effects due to altered energy intake. In response to the lower dose of NPY, the expression of NPY receptor sub-type 2 mRNA was increased at 1 hour post-injection in the subcutaneous fat of chicks fed the HP diet, whereas there was less 1-acylglycerol-3-phosphate O-acyltransferase 2 mRNA in the subcutaneous fat of chicks fed the HC diet. The higher dose of NPY was associated with greater AGPAT2 mRNA in the clavicular fat of chicks that consumed the HP diet and less CCAAT/enhancer-binding protein alpha in the abdominal fat of chicks that were provided the HF diet. However, there was also a decrease in the expression of some of these factors, although mechanisms are unclear. In conclusion, dietary macronutrient composition influenced the response of adipose tissue to the adipogenic effects of NPY and metabolic effects of short-term fasting and refeeding during the first week post-hatch. Collectively, this research may provide insights on understanding NPY's effects on the development of adipose tissue during the early life period and mechanisms underlying diet-dependent and depot-dependent differences in adipose tissue physiology across species.
- The effects of dietary macronutrient composition on lipid metabolismassociated factor gene expression in the adipose tissue of chickens are influenced by fasting and refeedingWang, Guoqing; McConn, Betty R.; Liu, Dongmin; Cline, Mark A.; Gilbert, Elizabeth R. (BMC, 2017-05-10)Background: Broiler chickens are compulsive feeders that become obese as juveniles and are thus a unique model for metabolic disorders in humans. However, little is known about the relationship between dietary composition, fasting and refeeding and adipose tissue physiology in chicks. Our objective was to determine how dietary macronutrient composition and fasting and refeeding affect chick adipose physiology during the early post-hatch period. Methods: Chicks were fed one of three isocaloric diets after hatch: high-carbohydrate (HC; control), high-fat (HF; 30% of ME from soybean oil) or high-protein (HP; 25% vs. 22% crude protein). At 4 days post-hatch, chicks were fed (continuous ad libitum access to food), fasted (3 h food withdrawal), or refed (fasted for 3 h and refed for 1 h). Subcutaneous, clavicular, and abdominal adipose tissue was collected for histological analysis and to measure gene expression, and plasma to measure non-esterified fatty acid (NEFA) concentrations (n = 6–10 per group). Results: Adipose tissue weights were reduced in chicks that were fed the HP diet and adipocyte diameter was greater in the adipose tissue of chicks that ate the HF diet. Consumption of diets differing in protein and fat content also affected gene expression; mRNAs encoding fatty acid binding protein 4 and a lipolytic enzyme, monoglyceride lipase, were greater in chicks fed the HC and HF than HP diet in all three adipose tissue depots. Fasting influenced gene expression in a depot-dependent manner, where most fasting and refeeding-induced changes were observed in the clavicular fat of chicks that consumed the HC diet. Fasting increased plasma NEFA concentrations in chicks fed the HC and HP diets. Conclusions: The decreased adipose tissue deposition in chicks fed the HP diet is likely explained by decreased rates of adipogenesis. Consumption of the HF diet was associated with greater adipose tissue deposition and larger adipocytes, likely as a result of greater rates of adipocyte hypertrophy. The depot-dependent effects of diet and fasting on gene expression may help explain mechanisms underlying metabolic distinctions among subcutaneous and visceral fat depots in humans.