Normal Distribution of Body Weight Gain in Male Sprague‐Dawley Rats Fed a High‐Energy Diet

Objective: To investigate the effect of a high‐energy (HE) diet on caloric intake, body weight, and related parameters in outbred male Sprague‐Dawley (SD) rats. Research Methods and Procedures: Twenty‐eight SD rats were fed either chow (C) for 19 weeks or HE diet for 14 weeks and then C for 5 weeks. Blood hormones and metabolites were assayed, and expression of uncoupling protein‐1 and hypothalamic energy‐balance‐related genes were determined by Northern blotting and in situ hybridization, respectively. Results: HE rats gained body weight more rapidly than C animals with a range of weight gains, but there was no evidence that weight gain was bimodally distributed. Caloric intake was transiently elevated after introduction of the HE diet. Transfer of HE rats back to C resulted in a drop in caloric intake, but a stable body weight. In terminal analysis, two of four dissected adipose tissue depots were heavier in rats that had previously been fed HE diet. Blood leptin, insulin, glucose, and nonesterified fatty acids were not different between the groups. Uncoupling protein‐1 mRNA was elevated in interscapular brown adipose tissue from HE rats. There was a trend for agouti‐related peptide mRNA in the hypothalamic arcuate nucleus to be higher in HE rats. Discussion: Contrary to other studies of the SD rat on HE diet, body weight and other measured parameters were normally distributed. There was no segregation into two distinct populations on the basis of susceptibility to diet‐induced obesity. This characteristic may be dependent on the breeding colony from which animals were sourced.     

Self‐Selected Macronutrient Diet Affects Energy and Glucose Metabolism in Brown Fat‐Ablated Mice

Objective: Obese transgenic UCP‐DTA mice have largely ablated brown adipose tissue and develop obesity and diabetes, which are highly susceptible to a high‐fat diet. We investigated macronutrient self‐selection and its effect on development of obesity, diabetes, and energy homeostasis in UCP‐DTA mice. Research Methods and Procedures: UCP‐DTA and wild‐type littermates were fed a semisynthetic macronutrient choice diet (CD) ad libitum from weaning until 17 weeks. Energy homeostasis was assessed by measurement of food intake, food digestibility, body composition, and energy expenditure. Diabetes was assessed by blood glucose measurements and insulin tolerance test. Results: Wild‐type and UCP‐DTA mice showed a high fat preference and increased energy digestion on CD compared with a low‐fat standard diet. On CD, wild‐type mice accumulated less body fat (16.9%) than UCP‐DTA (32.6%) mice, although they had a higher overall energy intake. Compared with wild‐type mice, resting metabolic rate was reduced in UCP‐DTA mice irrespective of diet. UCP‐DTA mice progressively decreased their carbohydrate intake, resulting in an almost complete avoidance of carbohydrate. UCP‐DTA mice developed severe insulin resistance but showed decreased fed and fasted blood glucose on CD. Discussion: In contrast to wild‐type mice, UCP‐DTA mice were not able to reduce their weight gain efficiency on CD. This suggests that, because of the high fat preference of the background strain and the increased metabolic efficiency, brown adipose tissue‐deficient mice still develop obesity and insulin resistance on a macronutrient CD even when decreasing overall energy intake. Through the avoidance of carbohydrates, however, they are able to maintain normoglycemia.     

Mice with Low Metabolic Rates Are Not Susceptible to Weight Gain When Fed a High‐Fat Diet

Objective: Mice divergently selected for high or low food intake (FI) at constant body mass differ in their resting metabolic rates (RMRs). Low‐intake individuals (ML) have significantly lower RMR (by 30%) compared with those from the high‐intake line (MH). We hypothesized that MLs might, therefore, be more likely to increase their body and fat mass when exposed to a high‐fat diet (HFD). Research Methods and Procedures: We exposed both lines to a diet with 44.9% calories from fat for 3 weeks while measuring FI, fecal production, and body mass and then returned the mice to standard chow. Results: When exposed to the HFD, both lines significantly decreased their FI (MH, 40% to 45%; ML, 31% to 35%). This decrease occurred simultaneously with a significant increase in apparent energy absorption efficiency (AEAE). When returned to chow, FI and AEAE returned to the levels observed prior to HFD exposure. Because of the adjustments in FI, the absorbed energy was maintained in the MLs and, thus, body mass remained constant. The MH individuals overcompensated for the elevated energy content and AEAE on the HFD and, therefore, absorbed lower energy than when feeding on chow. These mice also did not significantly change their body mass when on the HFD and must have made adjustments in their energy expenditures. Both lines and both sexes increased in fat content on the HFD, but these effects were not different between lines or sexes. Discussion: We found no support for the hypothesis that mice with low RMRs were more susceptible to weight gain when fed the HFD.     

Influence of dietary saturated fat content on adiposity,macrophage behavior,inflammation, and metabolism: composition matters

We examined the effects of three high-fat diets (HFD), differing in the percentage of total calories from saturated fat (SF) (6%, 12%, and 24%) but identical in total fat (40%), on body composition, macrophage behavior, inflammation, and metabolic dysfunction in mice. Diets were administered for 16 weeks. Body composition and metabolism [glucose, insulin, triglycerides, LDL-cholesterol (LDL-C), HDL-cholesterol (HDL-C), total cholesterol (TC)] were examined monthly. Adipose tissue (AT) expression of marker genes for M1 and M2 macrophages and inflammatory mediators [Toll-like receptor (TLR)-2, TLR-4, MCP-1, tumor necrosis factor (TNF)-α, interleukin (IL)-6, IL-10, suppressor of cytokine signaling (SOCS)1, IFN-γ] was measured along with activation of nuclear factor kappa-B (NFκB), c-Jun N-terminal kinase (JNK), and p38- mitogen-activated protein kinase (MAPK). AT macrophage infiltration was examined using immunohistochemistry. Circulating MCP-1, IL-6, adiponectin, and leptin were also measured. SF content, independent of total fat, can profoundly affect adiposity, macrophage behavior, inflammation, and metabolic dysfunction. In general, the 12%-SF diet, most closely mimicking the standard American diet, led to the greatest adiposity, macrophage infiltration, and insulin resistance (IR), whereas the 6%-SF and 24%-SF diets produced lower levels of these variables, with the 24%-SF diet resulting in the least degree of IR and the highest TC/HDL-C ratio. Macrophage behavior, inflammation, and IR following HFD are heavily influenced by dietary SF content; however, these responses are not necessarily proportional to the SF percentage.     

二氢杨梅素对高脂饮食诱导的小鼠肥胖的影响及其机制

目的:观察二氢杨梅素(DHM)对高脂饮食诱导小鼠肥胖的影响,并探讨其作用机制是否与促进WAT棕色化有关。方法:60只c57bl/6j小鼠随机分为6组(n=10):①正常对照组(ND组):普通饲料喂养、②正常对照+低剂量DHM组(ND+L-DHM组):普通饲料喂养同时用低剂量DHM(125 mg/(kg·d))处理、③正常对照+高剂量DHM组(ND+H-DHM组):普通饲料喂养同时用高剂量DHM(250 mg/(kg·d))处理、④高脂饮食组(HFD):高脂饲料喂养、⑤高脂饮食+低剂量DHM组(HFD+L-DHM组):高脂饲料喂养同时用低剂量DHM处理、⑥高脂饮食+高剂量DHM组(HFD+H-DHM组):高脂饲料喂养同时用高剂量DHM处理。16周后小鼠空腹过夜,取血测空腹血糖和血脂,随后处死动物,测体长,算出Lee's指数;取肩胛下、腹股沟和附睾处脂肪组织称重后,甲醛固定、HE染色观察脂肪细胞大小,免疫组化检测解偶联蛋白1(UCP1)的表达;实验期间每4周测一次小鼠体重。结果:与ND组相比较,HFD组小鼠体重显著升高,提示肥胖小鼠模型复制成功。此外,HFD组小鼠体脂重量、脂肪细胞直径、Lee's指数和血糖显著增加、脂肪细胞UCP1的表达升高;使用L-DHM和H-DHM处理HFD小鼠后,体脂重量、脂肪细胞直径、Lee's指数和血糖等指标显著逆转,而脂肪细胞UCP1的表达升高更为显著;但L-DHM和H-DHM对正常小鼠上述指标无显著影响。结论:二氢杨梅素抑制高脂饮食诱导的小鼠肥胖,其机制可能与促进WAT棕色化有关。     

Comparison of Fat Storage between Fischer 344 and Obesity‐Resistant Lou/C Rats Fed Different Diets**

Objective: We aimed to characterize further the Lou/C (LOU) and Fischer 344 (F344) rat strains for nutritional traits to validate their use as contrasting strains for molecular genetic studies. Research Methods and Procedures: Five batches of LOU and F344 rats were used to measure caloric intake, weight gain, and body composition when fed a chow diet, a self‐selection diet (together with the study of preferences for macronutrients), hypercaloric diets, and a chow diet in a cold environment. Results: Despite a higher caloric intake when fed a chow diet, LOU rats showed a lower weight gain, final body weight, and percentage of fat tissue, together with a higher percentage of carcass weight, than F344 rats. When fed a self‐selection diet, LOU males ingested less protein and more fat than F344 males, and the reverse was observed for females. In this condition, feed efficiency was reduced in LOU but increased in F344 rats compared with the chow diet. Diet‐induced obesity was observed in F344 rats but not in LOU rats fed hypercaloric diets. In a cold environment, both LOU and F344 rats displayed an increased percentage of brown adipose tissue compared with control groups, together with a higher caloric intake. Discussion: The study shows robust nutritional differences between the LOU rat, a lean strain with a low feed efficiency and resistant to diet‐induced obesity, and the contrasting F344 rat strain. It also shows the interest in these strains for studying the genetic components of resistance to obesity.     

SIRT6 protects against pathological damage caused by diet‐induced obesity

The NAD+‐dependent SIRT6 deacetylase is a therapeutic candidate against the emerging metabolic syndrome epidemic. SIRT6, whose deficiency in mice results in premature aging phenotypes and metabolic defects, was implicated in a calorie restriction response that showed an opposite set of phenotypes from the metabolic syndrome. To explore the role of SIRT6 in metabolic stress, wild type and transgenic (TG) mice overexpressing SIRT6 were fed a high fat diet. In comparison to their wild‐type littermates, SIRT6 TG mice accumulated significantly less visceral fat, LDL‐cholesterol, and triglycerides. TG mice displayed enhanced glucose tolerance along with increased glucose‐stimulated insulin secretion. Gene expression analysis of adipose tissue revealed that the positive effect of SIRT6 overexpression is associated with down regulation of a selective set of peroxisome proliferator‐activated receptor‐responsive genes, and genes associated with lipid storage, such as angiopoietin‐like protein 4, adipocyte fatty acid‐binding protein, and diacylglycerol acyltransferase 1, which were suggested as potential targets for drugs to control metabolic syndrome. These results demonstrate a protective role for SIRT6 against the metabolic consequences of diet‐induced obesity and suggest a potentially beneficial effect of SIRT6 activation on age‐related metabolic diseases.     

Changing Diet and Exercise Behaviors in Individuals at Risk for Weight Gain

To date, there have been very few studies on the primary prevention of obesity and/or weight gain. This paper identifies three time periods that might be appropriate for such efforts at weight gain prevention-the 25 to 35 year age window, the perimeno pausal period, and the year following successful weight loss. Research is encouraged that compares these three time periods and various intervention strategies. Several different approaches to primary prevention are identified, including group treatment pro grams with weekly meetings vs. less intensive, community- based interventions; focusing on those who are currently at ideal body weight vs. including those who are over weight as well; and targeting weight gain prevention per se vs. attempting to produce modest weight losses and/or modify cardiovascular risk factors. This paper suggests that primary prevention efforts should include exercise, changes in quality and quantity of food consumed, behavior modification, and some degree of therapist contact, but the manner in which these changes should be implemented to produce long-term habit change remains unclear.     

Isocaloric intake of a high‐fat diet promotes insulin resistance and inflammation in Wistar rats

The aim of this study was to investigate the effect of isocaloric intake from a high‐fat diet (HFD) on insulin resistance and inflammation in rats. Male Wistar rats were fed on an HFD (n = 12) or control diet (n = 12) for 12 weeks. Subsequently, all animals were euthanized, and blood glucose, insulin, free fatty acids, C‐reactive protein, lipid profile, cytokines and hepatic‐enzyme activity were determined. Carcass chemical composition was also analyzed. During the first and the twelfth weeks of the experimental protocol, the oral glucose tolerance test and insulin tolerance test were performed and demonstrated insulin resistance (P < 0.05) in the HFD group. Although food intake (g) was lower (P < 0.05) in the HFD group compared with the control group, the concentration of total cholesterol, low‐density lipoprotein, C‐reactive protein and liver weight were all significantly higher. The kinase inhibitor of κB, c‐Jun N‐terminal kinase and protein kinase B expressions were determined in the liver and skeletal muscle. After an insulin stimulus, the HFD group demonstrated decreased (P = 0.05) hepatic protein kinase B expression, whereas the kinase inhibitor of κB phospho/total ratio was elevated in the HFD muscle (P = 0.02). In conclusion, the isocaloric intake from the HFD induced insulin resistance, associated with impaired insulin signalling in the liver and an inflammatory response in the muscle. Copyright © 2012 John Wiley & Sons, Ltd.     

Insulin resistance is improved in high‐fat fed mice by photobiomodulation therapy at 630 nm

Photobiomodulation therapy (PBMT) in the infrared spectrum exerts positive effects on glucose metabolism, but the use of PBMT at the red spectrum has not been assessed. Male Swiss albino mice were divided into low‐fat control and high‐fat diet (HFD) for 12 weeks and were treated with red (630 nm) PBMT or no treatment (Sham) during weeks 9 to 12. PBMT was delivered at 31.19 J/cm², 60 J total dose per day for 20 days. In HFD‐fed mice, PBMT improved glucose tolerance, insulin resistance and fasting hyperinsulinemia. PBMT also reduced adiposity and inflammatory infiltrate in adipose tissue. Phosphorylation of Akt in epididymal adipose tissue and rectus femoralis muscle was improved by PBMT. In epididymal fat PBMT reversed the reduced phosphorylation of AS160 and the reduced Glut4 content. In addition, PBMT reversed the alterations caused by HFD in rectus femoralis muscle on proteins involved in mitochondrial dynamics and β‐oxidation. In conclusion, PBMT at red spectrum improved insulin resistance and glucose metabolism in HFD‐fed mice.      

Culture on Tissue‐Specific Coatings Derived from α‐Amylase‐Digested Decellularized Adipose Tissue Enhances the Proliferation and Adipogenic Differentiation of Human Adipose‐Derived Stromal Cells

While extracellular matrix (ECM)‐derived coatings have the potential to direct the response of cell populations in culture, there is a need to investigate the effects of ECM sourcing and processing on substrate bioactivity. To develop improved cell culture models for studying adipogenesis, the current study examines the proliferation and adipogenic differentiation of human adipose‐derived stem/stromal cells (ASCs) on a range of ECM‐derived coatings. Human decellularized adipose tissue (DAT) and commercially available bovine tendon collagen (COL) are digested with α‐amylase or pepsin to prepare the coatings. Physical characterization demonstrates that α‐amylase digestion generates softer, thicker, and more stable coatings, with a fibrous tissue‐like ultrastructure that is lost in the pepsin‐digested thin films. ASCs cultured on the α‐amylase‐digested ECM have a more spindle‐shaped morphology, and proliferation is significantly enhanced on the α‐amylase‐digested DAT coatings. Further, the α‐amylase‐digested DAT provides a more pro‐adipogenic microenvironment, based on higher levels of adipogenic gene expression, glycerol‐3‐phosphate dehydrogenase (GPDH) enzyme activity, and perilipin staining. Overall, this study supports α‐amylase digestion as a new approach for generating bioactive ECM‐derived coatings, and demonstrates tissue‐specific bioactivity using adipose‐derived ECM to enhance ASC proliferation and adipogenic differentiation.     

Dietary alpha‐ketoglutarate promotes beige adipogenesis and prevents obesity in middle‐aged mice

Aging usually involves the progressive development of certain illnesses, including diabetes and obesity. Due to incapacity to form new white adipocytes, adipose expansion in aged mice primarily depends on adipocyte hypertrophy, which induces metabolic dysfunction. On the other hand, brown adipose tissue burns fatty acids, preventing ectopic lipid accumulation and metabolic diseases. However, the capacity of brown/beige adipogenesis declines inevitably during the aging process. Previously, we reported that DNA demethylation in the Prdm16 promoter is required for beige adipogenesis. DNA methylation is mediated by ten–eleven family proteins (TET) using alpha‐ketoglutarate (AKG) as a cofactor. Here, we demonstrated that the circulatory AKG concentration was reduced in middle‐aged mice (10‐month‐old) compared with young mice (2‐month‐old). Through AKG administration replenishing the AKG pool, aged mice were associated with the lower body weight gain and fat mass, and improved glucose tolerance after challenged with high‐fat diet (HFD). These metabolic changes are accompanied by increased expression of brown adipose genes and proteins in inguinal adipose tissue. Cold‐induced brown/beige adipogenesis was impeded in HFD mice, whereas AKG rescued the impairment of beige adipocyte functionality in middle‐aged mice. Besides, AKG administration up‐regulated Prdm16 expression, which was correlated with an increase of DNA demethylation in the Prdm16 promoter. In summary, AKG supplementation promotes beige adipogenesis and alleviates HFD‐induced obesity in middle‐aged mice, which is associated with enhanced DNA demethylation of the Prdm16 gene.     

Dietary n‐3 long‐chain polyunsaturated fatty acids modify phosphoenolpyruvate carboxykinase activity and lipid synthesis from glucose in adipose tissue of rats fed a high‐sucrose diet

Long‐chain polyunsaturated n‐3 fatty acids (n‐3 LCPUFAs) have hypolipidemic effects and modulate intermediary metabolism to prevent or reverse insulin resistance in a way that is not completely elucidated. Here, effects of these fatty acids on the lipid profile, phosphoenolpyruvate carboxykinase (PEPCK) activity, lipid synthesis from glucose in epididymal adipose tissue (Ep‐AT) and liver were investigated. Male rats were fed a high‐sucrose diet (SU diet), containing either sunflower oil or a mixture of sunflower and fish oil (SU–FO diet), and the control group was fed a standard diet. After 13 weeks, liver, adipose tissue and blood were harvested and analysed. The dietary n‐3 LCPUFAs prevented sucrose‐induced increase in adiposity and serum free fat acids, serum and hepatic triacylglycerol and insulin levels. Furthermore, these n‐3 LCPUFAs decreased lipid synthesis from glucose and increased PEPCK activity in the Ep‐AT of rats fed the SU–FO diet compared to those fed the SU diet, besides reducing lipid synthesis from glucose in hepatic tissue. Thus, the inclusion of n‐3 LCPUFAs in the diet may be beneficial for the prevention or attenuation of dyslipidemia and insulin resistance, and for reducing the risk of related chronic diseases. Copyright © 2013 John Wiley & Sons, Ltd.