contributed equally to this work. Conflict of interest:The authors have declared that no conflict of interest exists. Nonstandard abbreviations used: type 2 diabetes mellitus (T2DM); white adipose tissue (WAT); monocyte chemotactic protein-1 (MCP-1); diet-induced obesity (DIO); macrophage inflammatory protein-1α (MIP-1α); macrophage antigen-1 (MAC-1); thiazolidinedione (TZD).
contributed equally to this work. Conflict of interest:The authors have declared that no conflict of interest exists. Nonstandard abbreviations used: type 2 diabetes mellitus (T2DM); white adipose tissue (WAT); monocyte chemotactic protein-1 (MCP-1); diet-induced obesity (DIO); macrophage inflammatory protein-1α (MIP-1α); macrophage antigen-1 (MAC-1); thiazolidinedione (TZD).
Uncoupling protein-3 (UCP3) is a mitochondrial protein that can diminish the mitochondrial membrane potential. Levels of muscle Ucp3 mRNA are increased by thyroid hormone and fasting. Ucp3 has been proposed to influence metabolic efficiency and is a candidate obesity gene. We have produced a Ucp3 knockout mouse to test these hypotheses. The Ucp3 (؊/؊) mice had no detectable immunoreactive UCP3 by Western blotting. In mitochondria from the knockout mice, proton leak was greatly reduced in muscle, minimally reduced in brown fat, and not reduced at all in liver. These data suggest that UCP3 accounts for much of the proton leak in skeletal muscle. Despite the lack of UCP3, no consistent phenotypic abnormality was observed. The knockout mice were not obese and had normal serum insulin, triglyceride, and leptin levels, with a tendency toward reduced free fatty acids and glucose. Knockout mice showed a normal circadian rhythm in body temperature and motor activity and had normal body temperature responses to fasting, stress, thyroid hormone, and cold exposure. The base-line metabolic rate and respiratory exchange ratio were the same in knockout and control mice, as were the effects of fasting, a 3-adrenergic agonist (CL316243), and thyroid hormone on these parameters. The phenotype of Ucp1/Ucp3 double knockout mice was indistinguishable from Ucp1 single knockout mice. These data suggest that Ucp3 is not a major determinant of metabolic rate but, rather, has other functions.Human obesity is the result of energy intake greater than metabolic expenditure and is increasing in incidence (1). On an evolutionary time scale, obesity is a recent development, attributed to the interaction of predisposing genetic backgrounds with a sedentary lifestyle and an abundance of food (2, 3). Little is known about the molecular mechanisms and genes that contribute to the regulation of metabolic rate. For example, metabolic efficiency decreases with increased food intake, and it increases with lowered food intake (4), but the mechanistic details are unknown.The discovery of uncoupling protein (UCP, 1 now named UCP1) illustrated one way to regulate metabolic efficiency. UCP1 uncouples oxidative phosphorylation by allowing leakage of protons into the mitochondrial matrix without the phosphorylation of ADP (5). Heat is released because UCP1 degrades the proton gradient energy without storing it chemically or using it to perform physical work. At the whole-body level, this shows up as metabolic inefficiency. Ucp1 is expressed only in brown adipose tissue (BAT), which is a major heat-producing tissue in small mammals. In addition to cold-induced thermogenesis, BAT and UCP1 have been implicated in diet-induced thermogenesis, the increased energy expenditure that accompanies increased food intake (6). Activation of BAT and increased expression of Ucp1 cause reduced adiposity (7-9). However, BAT is present in only small amounts in large mammals, so its role in regulating energy homeostasis in adult humans is problematic (10).Interest in UCPs incr...
Recent studies showed that germ-free (GF) mice are resistant to obesity when consuming a high-fat, high-carbohydrate Western diet. However, it remains unclear what mechanisms are involved in the antiobesity phenotype and whether GF mice develop insulin resistance and dyslipidemia with high-fat (HF) feeding. In the present study, we compared the metabolic consequences of HF feeding on GF and conventional (conv) C57BL/6J mice. GF mice consumed fewer calories, excreted more fecal lipids, and weighed significantly less than conv mice. GF/HF animals also showed enhanced insulin sensitivity with improved glucose tolerance, reduced fasting and nonfasting insulinemia, and increased phospho-Akt((Ser-473)) in adipose tissue. In association with enhanced insulin sensitivity, GF/HF mice had reduced plasma TNF-α and total serum amyloid A concentrations. Reduced hypercholesterolemia, a moderate accretion of hepatic cholesterol, and an increase in fecal cholesterol excretion suggest an altered cholesterol metabolism in GF/HF mice. Pronounced nucleus SREBP2 proteins and up-regulation of cholesterol biosynthesis genes indicate that enhanced cholesterol biosynthesis contributed to the cholesterol homeostasis in GF/HF mice. Our results demonstrate that fewer calorie consumption and increased lipid excretion contributed to the obesity-resistant phenotype of GF/HF mice and reveal that insulin sensitivity and cholesterol metabolism are metabolic targets influenced by the gut microbiota.
Recent data suggest that the gut microbiota plays a significant role in fat accumulation. However, it is not clear whether gut microbiota is involved in the pathophysiology of type 2 diabetes. To assess this issue, we modulated gut microbiota via antibiotics administration in two different mouse models with insulin resistance. Results from dose-determination studies showed that a combination of norfloxacin and ampicillin, at a dose of 1 g/L, maximally suppressed the numbers of cecal aerobic and anaerobic bacteria in ob/ob mice. After a 2-wk intervention with the antibiotic combination, both ob/ob and diet-induced obese and insulin-resistant mice showed a significant improvement in fasting glycemia and oral glucose tolerance. The improved glycemic control was independent of food intake or adiposity because pair-fed ob/ob mice were as glucose intolerant as the control ob/ob mice. Reduced liver triglycerides and increased liver glycogen correlated with improved glucose tolerance in the treated mice. Concomitant reduction of plasma lipopolysaccharides and increase of adiponectin further supported the antidiabetic effects of the antibiotic treatment in ob/ob mice. In summary, modulation of gut microbiota ameliorated glucose tolerance of mice by altering the expression of hepatic and intestinal genes involved in inflammation and metabolism, and by changing the hormonal, inflammatory, and metabolic status of the host.
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