The relationship between the microbial composition and energy harvesting capacity is more complex than previously considered. While compositional changes in the faecal microbiota were confirmed, this was primarily a feature of high-fat feeding rather than genetically induced obesity. In addition, changes in the proportions of the major phyla were unrelated to markers of energy harvest which changed over time. The possibility of microbial adaptation to diet and time should be considered in future studies.
OBJECTIVEIncreased activity of the innate immune system has been implicated in the pathogenesis of the dyslipidemia and insulin resistance associated with obesity and type 2 diabetes. In this study, we addressed the potential role of Kupffer cells (liver-specific macrophages, KCs) in these metabolic abnormalities.RESEARCH DESIGN AND METHODSRats were depleted of KCs by administration of gadolinium chloride, after which all animals were exposed to a 2-week high-fat or high-sucrose diet. Subsequently, the effects of these interventions on the development of hepatic insulin resistance and steatosis were assessed. In further studies, the effects of M1-polarized KCs on hepatocyte lipid metabolism and insulin sensitivity were addressed.RESULTSAs expected, a high-fat or high-sucrose diet induced steatosis and hepatic insulin resistance. However, these metabolic abnormalities were prevented when liver was depleted of KCs. In vitro, KCs recapitulated the in vivo effects of diet by increasing hepatocyte triglyceride accumulation and fatty acid esterification, and decreasing fatty acid oxidation and insulin responsiveness. To address the mechanisms(s) of KC action, we inhibited a panel of cytokines using neutralizing antibodies. Only neutralizing antibodies against tumor necrosis factor-α (TNFα) attenuated KC-induced alterations in hepatocyte fatty acid oxidation, triglyceride accumulation, and insulin responsiveness. Importantly, KC TNFα levels were increased by diet in vivo and in isolated M1-polarized KCs in vitro.CONCLUSIONSThese data demonstrate a role for liver macrophages in diet-induced alterations in hepatic lipid metabolism and insulin sensitivity, and suggest a role for these cells in the etiology of the metabolic abnormalities of obesity/type 2 diabetes.
Our findings implicate NETs in the protumorigenic inflammatory environment in NASH, suggesting that their elimination may reduce the progression of liver cancer in NASH. (Hepatology 2018).
Rationale and Objectives: Although many clinical physiology and epidemiology studies show an association between obstructive sleep apnea (OSA) and markers of insulin resistance, no causal pathway has been established. The purpose of the current study was to determine if the intermittent hypoxia (IH) stimulus that characterizes OSA causes insulin resistance in the absence of obesity. Furthermore, we assessed the impact of IH on specific metabolic function in liver and muscle. Finally, we examined the potential mechanistic role of the autonomic nervous system (ANS) in mediating insulin resistance in response to IH. Methods and Results: Hyperinsulinemic euglycemic clamps were conducted and whole-body insulin sensitivity, hepatic glucose output, and muscle-specific glucose utilization assessed in conscious, chronically instrumented adult male C57BL/6J mice exposed to (1 ) IH (achieving a nadir of FI O 2 ϭ 5-6% at 60 cycles/h for 9 h), (2 ) intermittent air as a control, (3 ) IH with ANS blockade (hexamethonium), or (4 ) IA with ANS blockade. IH decreased whole-body insulin sensitivity compared with intermittent air (38.8 Ϯ 2.7 vs. 49.4 Ϯ 1.5 mg/ kg/min, p Ͻ 0.005) and reduced glucose utilization in oxidative muscle fibers, but did not cause a change in hepatic glucose output. Furthermore, the reduction in whole-body insulin sensitivity during IH was not restored by ANS blockade. Conclusion: We conclude that IH can cause acute insulin resistance in otherwise lean, healthy animals, and that the response is associated with decreased glucose utilization of oxidative muscle fibers, but that it occurs independently of activation of the ANS.
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