Arginine availability modulates arginine metabolism and TNFα production in peritoneal macrophages from Zucker Diabetic Fatty rats. Charlotte Breuillard,Linda Belabed,Sandra Bonhomme,Marie-Céline Blanc-Quintin,Nathalie Neveux,Rémy Couderc,Jean-Pascal De Bandt,Luc Cynober,Sylviane Darquy Clinical nutrition (Edinburgh, Scotland)
31
2012
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Excess weight and type 2 diabetes lead to increased susceptibility to infections. Our aim was to investigate the role of diabetes-induced decreased arginine (Arg) availability and of a possible dysregulation of Arg metabolism in macrophages favoring inflammation and dysimmunity via altered nitric oxide (NO) and cytokine productions. | 22182949
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Maternal high-fat diet programs Wnt genes through histone modification in the liver of neonatal rats. Ke-Feng Yang,Wei Cai,Jia-Li Xu,Wen Shi Journal of molecular endocrinology
49
2012
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Maternal high-fat (HF) diets during gestation and lactation have been shown to contribute to metabolic disorders in offspring. Molecular and epigenetic mechanisms underlying this connection may be essential for the prevention and treatment of the fetal origins of metabolic diseases. The current study examined the impact of maternal HF diets on Wnt signaling and histone modification in offspring. Time-pregnant Sprague-Dawley rats were fed either control diet or HF diet during gestation and lactation and then the neonatal offspring of both groups were investigated. The neonatal offspring born to dams fed on HF diets exhibited increases in serum glucose and liver triglyceride levels. Maternal exposure to the HF diet also repressed the mRNA expression of Wnt1 and nuclear β-catenin protein in the liver of offspring. The altered Wnt1 gene expression may be due to the changes of acetylation of H4 at its promoter as well as acetylation of H4 and methylation of H3K9 at coding region. Maternal exposure to the HF diet induced suppression of the Wnt/β-catenin signaling pathway through histone modification, potentially increasing the risk of metabolic syndrome. | 22696509
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Effect of high-fat diet on stress responsiveness in borderline hypertensive rats. Mitra A, Crump EM, Alvers KM, Robertson KL, Rowland NE Stress
14
42-52. Epub 2010 Jul 28.
2011
Show Abstract
Stress in combination with genetic susceptibility is a factor in the development of hypertension. We used borderline hypertensive rats to investigate whether exposure to high-fat and/or junk-food diet at different stages of ontogeny has programing consequences on stress responses. Wistar dams were fed a high- or low-fat diet for 6 weeks prior to mating with spontaneously hypertensive males, and during gestation. At birth, litters were fostered either to a dam in the same or an alternative diet condition as during gestation. After weaning, male offspring were fed either a control-chow diet or an intermittent junk food fatty diet. Between postnatal days 57-61, half of the rats in each dietary group received daily social defeat sessions using a resident-intruder protocol, and the other half were unstressed controls. Blood pressure was measured indirectly both before and after each defeat session. On the final day, rats were killed for physiological measures. Socially defeated rats showed large increases in serum corticosterone concentration and adrenal hypertrophy, indicating the effectiveness of this non-adapting stressor. Serum corticosterone level was also higher in rats fed with the junk-food diet post-weaning compared with those fed with chow only, but there were no significant effects of gestational or lactational dietary history. | 20666663
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Different roles of zinc plus arachidonic acid on insulin sensitivity between high fructose- and high fat-fed rats. Inkyung Hwang,Taeho Yoon,Changhoon Kim,Byungmann Cho,Sooil Lee,Moon K Song Life sciences
88
2011
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This study was to determine the effects of zinc plus arachidonic acid (ZA) treatment on the insulin action in the specific ZA target organs using hyperinsulinemic euglycemic clamp method. | 21167181
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Differential muscle gene expression as a function of disease progression in Goto-Kakizaki diabetic rats. Nie J, Xue B, Sukumaran S, Jusko WJ, Dubois DC, Almon RR Molecular and cellular endocrinology
2011
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The Goto-Kakizaki (GK) rat, a polygenic non-obese model of type 2 diabetes, is a useful surrogate for study of diabetes-related changes independent of obesity. GK rats and appropriate controls were killed at 4, 8, 12, 16 and 20 weeks post-weaning and differential muscle gene expression along with body and muscle weights, plasma hormones and lipids, and blood cell measurements were carried out. Gene expression analysis identified 204 genes showing 2-fold or greater differences between GK and controls in at least 3 ages. Array results suggested increased oxidative capacity in GK muscles, as well as differential gene expression related to insulin resistance, which was also indicated by HOMA-IR measurements. In addition, potential new biomarkers in muscle gene expression were identified that could be either a cause or consequence of T2DM. Furthermore, we demonstrate here the presence of chronic inflammation evident both systemically and in the musculature, despite the absence of obesity.Copyright © 2011. Published by Elsevier Ireland Ltd. | 21356272
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Mechanistic modeling of the effects of glucocorticoids and circadian rhythms on adipokine expression. Siddharth Sukumaran,William J Jusko,Debra C DuBois,Richard R Almon The Journal of pharmacology and experimental therapeutics
337
2011
Show Abstract
A mechanism-based model was developed to describe the effects of methylprednisolone (MPL), circadian rhythms, and the glucose/free fatty acid (FFA)/insulin system on leptin and adiponectin expression in white adipose tissue in rats. Fifty-four normal Wistar rats received 50 mg/kg MPL intramuscularly and were sacrificed at various times. An additional set of 54 normal Wistar rats were sacrificed at 18 time points across the 24-h light/dark cycle and served as controls. Measurements included plasma MPL, glucocorticoid receptor (GR) mRNA, leptin mRNA, adiponectin mRNA, plasma leptin, adiponectin, glucose, FFA, and insulin. MPL pharmacokinetics was described by a two-compartment model with two absorption components. All measured plasma markers and mRNA expression exhibited circadian patterns except for adiponectin and were described by Fourier harmonic functions. MPL caused significant down-regulation in GR mRNA with the nadir occurring at 5 h. MPL disrupted the circadian patterns in plasma glucose and FFA by stimulating their production. Plasma glucose and FFA subsequently caused an increase in plasma insulin. Furthermore, MPL disrupted the circadian patterns in leptin mRNA expression by stimulating its production. This rise was closely followed by an increase in plasma leptin. Both leptin mRNA and plasma leptin peaked at 12 h after MPL and eventually returned back to their circadian baselines. MPL and insulin had opposing effects on adiponectin mRNA expression and plasma adiponectin, which resulted in biphasic pharmacodynamic profiles. This small systems model quantitatively describes, integrates, and provides additional insights into various factors controlling adipokine gene expression. | 21398515
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Feeding behavior and performance of lambs are influenced by flavor diversity. Villalba JJ, Bach A, Ipharraguerre IR J Anim Sci
2011
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This study determined whether early experiences by sheep to the same feed, but presented in multiple or single flavors influence intake, profile of hormones involved in feed intake regulation, and the subsequent acceptability of novel feeds. Thirty-five, 2-mo-old lambs were randomly assigned to 5 treatments (7 lambs/treatment). Lambs in 1 treatment (Diversity) were fed simultaneously an unflavored control - plain ration of alfalfa and barley (75:25) and the same ration mixed (0.2%) with 1 of 3 flavors: (1) sweet, (2) umami, and (3) bitter. The other 4 treatments (Monotonous diets) received just 1 of the four rations. All animals were fed their respective rations from 0800 to 1600 for 60 d. On d 55, intake was recorded every 30 min for 8 h. On day 58 lambs were bled 1 h pre-feeding and at 30, 60, 210, 300, and 540 min post-feeding. Preference tests were conducted by offering simultaneously novel feeds of either (1) high-energy, (2) high-protein content, (3) beet pulp mixed with phytochemicals, or (4) low-quality feeds. Lambs in Diversity consumed more feed than lambs in the other treatments (P < 0.001). Lambs in Diversity consumed equivalent amounts of Plain and Umami feeds, with Umami being consumed at a greater level (P < 0.001) than the Bitter and Sweet feeds. Lambs in Diversity tended to grow faster than lambs in the other treatments (P = 0.06). On d 55, lambs in Diversity showed lower (P < 0.05) intakes than the other treatments during the 2 peaks of food consumption: 30 min and 270 min from feeding, and a trend for the lowest plasmatic concentrations of ghrelin (P = 0.06). In contrast, lambs in Diversity consumed more feed than lambs exposed to monotonous flavors at 60, 90, 120, and 180 min from feeding (P < 0.05). Lambs in Diversity also showed the lowest concentration of CCK and GLP-1 (P < 0.001). There was a trend for the greatest concentration of leptin (P = 0.14) and IGF-1 (P = 0.16) in Diversity, and for the lowest concentration of leptin in Bitter (P = 0.14). Previous experience with flavored feeds affected preference for high-energy and low-quality feeds, and for beet pulp mixed with phytochemicals (treatment x feed x day effect; P < 0.05). Thus, exposure to diverse flavors has the potential to increase feed intake and induce a more even consumption of feed across time by reducing peaks and nadirs of intake compared with exposure to monotonous rations. Flavor diversity may also influence initial acceptability and preference for novel feeds. | 21454862
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Dietary intervention prior to pregnancy reverses metabolic programming in male offspring of obese rats. Zambrano E, Martínez-Samayoa PM, Rodríguez-González GL, Nathanielsz PW J Physiol
588
1791-9. Epub 2010 Mar 29.
2010
Show Abstract
Obesity involving women of reproductive years is increasing dramatically in both developing and developed nations. Maternal obesity and accompanying high energy obesogenic dietary (MO) intake prior to and throughout pregnancy and lactation program offspring physiological systems predisposing to altered carbohydrate and lipid metabolism. Whether maternal obesity-induced programming outcomes are reversible by altered dietary intake commencing before conception remains an unanswered question of physiological and clinical importance. We induced pre-pregnancy maternal obesity by feeding female rats with a high fat diet from weaning to breeding 90 days later and through pregnancy and lactation. A dietary intervention group (DINT) of MO females was transferred to normal chow 1 month before mating. Controls received normal chow throughout. Male offspring were studied. Offspring birth weights were similar. At postnatal day 21 fat mass, serum triglycerides, leptin and insulin were elevated in MO offspring and were normalized by DINT. At postnatal day 120 serum glucose, insulin and homeostasis model assessment (HOMA) were increased in MO offspring; glucose was restored, and HOMA partially reversed to normal by DINT. At postnatal day 150 fat mass was increased in MO and partially reversed in DINT. At postnatal day 150, fat cell size was increased by MO. DINT partially reversed these differences in fat cell size. We believe this is the first study showing reversibility of adverse metabolic effects of maternal obesity on offspring metabolic phenotype, and that outcomes and reversibility vary by tissue affected. | 20351043
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FoxM1 Is Up-Regulated by Obesity and Stimulates {beta}-Cell Proliferation. Davis DB, Lavine JA, Suhonen JI, Krautkramer KA, Rabaglia ME, Sperger JM, Fernandez LA, Yandell BS, Keller MP, Wang IM, Schadt EE, Attie AD Mol Endocrinol
2010
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beta-Cell mass expansion is one mechanism by which obese animals compensate for insulin resistance and prevent diabetes. FoxM1 is a transcription factor that can regulate the expression of multiple cell cycle genes and is necessary for the maintenance of adult beta-cell mass, beta-cell proliferation, and glucose homeostasis. We hypothesized that FoxM1 is up-regulated by nondiabetic obesity and initiates a transcriptional program leading to beta-cell proliferation. We performed gene expression analysis on islets from the nondiabetic C57BL/6 Leptin(ob/ob) mouse, the diabetic BTBR Leptin(ob/ob) mouse, and an F2 Leptin(ob/ob) population derived from these strains. We identified obesity-driven coordinated up-regulation of islet Foxm1 and its target genes in the nondiabetic strain, correlating with beta-cell mass expansion and proliferation. This up-regulation was absent in the diabetic strain. In the F2 Leptin(ob/ob) population, increased expression of Foxm1 and its target genes segregated with higher insulin and lower glucose levels. We next studied the effects of FOXM1b overexpression on isolated mouse and human islets. We found that FoxM1 stimulated mouse and human beta-cell proliferation by activating many cell cycle phases. We asked whether FOXM1 expression is also responsive to obesity in human islets by collecting RNA from human islet donors (body mass index range: 24-51). We found that the expression of FOXM1 and its target genes is positively correlated with body mass index. Our data suggest that beta-cell proliferation occurs in adult obese humans in an attempt to expand beta-cell mass to compensate for insulin resistance, and that the FoxM1 transcriptional program plays a key role in this process. | 20660304
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Basal Plasma Levels of Insulin, Leptin, Ghrelin, and Amylin Do Not Signal Adiposity in Rats Recovering from Forced Overweight. Gloy VL, Lutz TA, Langhans W, Geary N, Hillebrand JJ Endocrinology
2010
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This study examined how adiposity signals are related to adiposity during recovery from forced overweight (OW). Rats were rendered OW by chronic intragastric overfeeding (OW). Overfeeding was stopped when OW rats reached 126-129% of saline-infused normal-weight (NW) rats. Adipose tissue (AT) mass was estimated by computed tomography, and blood was drawn from chronic atrial cannulas throughout. Basal levels (i.e. after 2-3 h fasts late in the diurnal phase) of the hypothesized adiposity signals insulin, leptin, ghrelin, and amylin were assayed. OW rats gained approximately 130 g more body weight (BW) and approximately 100 g more AT mass during overfeeding. Plasma levels of insulin and leptin increased, whereas those of ghrelin decreased, linearly with AT mass; amylin did not change reliably. During recovery, OW rats' BW and AT mass decreased but were still elevated vs. NW rats after 39 d. OW rats' insulin returned to NW levels on d 1 of recovery and decreased below NW levels thereafter. Leptin was no longer elevated after d 8 of recovery. Ghrelin and amylin did not change reliably during recovery. Although AT mass decreased in OW rats during each intermeasurement interval between d 0 and d 23 of recovery, insulin and leptin did so during only the first interval (d 0-5). Insulin and leptin levels were exponentially related to AT mass during recovery. These data indicate that basal insulin, leptin, ghrelin, and amylin do not encode AT mass in rats dynamically regulating BW and adiposity during recovery from OW. | 20668029
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