The CB1 receptor antagonist, rimonabant, affects the endocannabinoid system and causes a sustained reduction in body weight (BW) despite the transient nature of the reduction in food intake. Therefore, in a multiple-dose study, female candy-fed Wistar rats were treated with rimonabant (10 mg/kg) and matched with pair-fed rats to distinguish between hypophagic action and hypothesized effects on energy expenditure. Within the first week of treatment, rimonabant reduced BW nearly to levels of standard rat chow-fed rats. Evaluation of energy balance (energy expenditure measured by indirect calorimetry in relation to metabolizable energy intake calculated by bomb calorimetry) revealed that increased energy expenditure based on increased fat oxidation contributed more to sustained BW reduction than reduced food intake. A mere food reduction through pair feeding did not result in comparable effects because animals reduced their energy expenditure to save energy stores. Because fat oxidation measured by indirect calorimetry increased immediately after dosing in the postprandial state, the acute effect of rimonabant on lipolysis was investigated in postprandial male rats. Rimonabant elevated free fatty acids postprandially, demonstrating an inherent pharmacological activity of rimonabant to induce lipolysis and not secondarily postabsorptively due to reduced food intake. We conclude that the weight-reducing effect of rimonabant was due to continuously elevated energy expenditure based on increased fat oxidation driven by lipolysis from fat tissue as long as fat stores were elevated. When the amount of endogenous fat stores declined, rimonabant-induced increased energy expenditure was maintained by a re-increase in food intake.
objective of the present study was to investigate in fed Wistar rats whether the cannabinoid-1 (CB1) receptor antagonist AVE1625 causes primary effects on metabolic blood and tissue parameters as well as metabolic rate, which are independent of reduced caloric intake. After single administration to rats postprandially, AVE1625 caused a slight dose-dependent increase in basal lipolysis. Six hours after single administration, liver glycogen content was dose-dependently reduced to ϳ60% of that of untreated controls. These findings demonstrate a primary acute effect of AVE1625 on induction of 1) lipolysis from fat tissue (increased FFA) and 2) glycogenolysis from the liver (reduced hepatic glycogen). Measured by indirect calorimetry, AVE1625 caused an immediate increase in total energy expenditure, a long-lasting increase of fat oxidation, and a transient increase of glucose oxidation, which were consistent with the acute findings on metabolic blood and tissue parameters. We conclude that, in addition to the well-investigated effects of CB1 receptor antagonists to reduce caloric intake and subsequently body weight, this pharmacological approach is additionally linked to inherently increased lipid oxidation. This oxidation is driven by persistently increased lipolysis from fat tissues, independently of reduced caloric intake, and might significantly contribute to the weight-reducing effect. cannabinoid receptors; lipolysis; glycogenolysis; energy expenditure OBESITY COMBINED WITH ITS COMORBIDITIES has become one of the major health problems not only in industrialized but also in developing countries (16,17,37). Epidemiological and clinical experiences have demonstrated that dietary and behavioural treatments of obesity alone are of limited efficacy (41). Therefore, tremendous efforts in the pharmaceutical industry have been undertaken to investigate efficacious pharmacological mechanisms for the treatment of obesity. Recently, cannabinoid-1 (CB1) receptor antagonism has been intensively investigated for its potential to reduce food intake and subsequently to treat obesity (12,31,33). CB1 receptors are widely distributed in the central (14) and peripheral nervous systems (10) as identified for the enteric nervous system of the gut in pigs, guinea pigs, rats, and mice (23, 35), as well as in the nodose ganglion in humans, rabbits, and rats (8, 28). Furthermore, CB1 receptors are also present in several peripheral tissues (32). Recently, peripheral CB1 receptors were reported to be present on adipocytes in humans, rats, and mice (3, 9, 38), on hepatocytes (30), and on pancreatic -cells in mice (21), and on thyroid cells in rats (36). CB1 receptors belong to the G protein-coupled receptor family and transmit their response via a G i/0 protein with subsequent decreases in cAMP (6, 19). Accordingly, CB1 receptor antagonism is connected to increased cellular cAMP levels (27). The localization of CB1 receptors in the hypothalamus, the center of regulation of food intake and energy balance, makes it very likely that the redu...
Myenteric neurones from 1-10-day-old rats were isolated from the small and large intestine by enzymatic digestion with collagenase. Single cells were collected and kept in culture for up to 1 week. After 1-5 days in culture, membrane potential and ionic currents were measured with the whole-cell patch-clamp technique. The intracellular Ca2+ concentration was measured with the fura-2 method. The short-chain fatty acid butyrate (50 mmol L-1) induced a reversible hyperpolarization of the myenteric neurones by about 10 mV. This hyperpolarization was concomitant with an inhibition of a TTX-sensitive Na+ current. The hyperpolarization could be suppressed by intracellular application of Cs+, a nonselective K+ channel blocker. Fura-2 experiments revealed that butyrate induced an increase of the intracellular Ca2+ concentration. The butyrate response was suppressed by thapsigargin, indicating that butyrate stimulates the release of intracellular Ca2+. This release is responsible for the voltage response, because intracellular chelation of Ca2+ inhibited the butyrate induced hyperpolarization. Consequently, butyrate acts on enteric neurones by releasing Ca2+ from intracellular stores with the consequence of the activation of K+ channels, followed by a hyperpolarization.
Acetyl CoA carboxylase isoforms 1 and 2 (ACC1/2) are key enzymes of fat utilization and their inhibition is considered to improve aspects of the metabolic syndrome. To identify pharmacological inhibitors of ACC1/2, a high throughput screen was performed which resulted in the identification of the lead compound 3 ( Gargazanli , G. ; Lardenois , P. ; Frost , J. ; George , P. Patent WO9855474 A1, 1998 ) as a moderate selective ACC2 inhibitor. Optimization of 3 led to 4m ( Zoller , G. ; Schmoll , D. ; Mueller , M. ; Haschke , G. ; Focken , I. Patent WO2010003624 A2, 2010 ) as a submicromolar dual ACC1/2 inhibitor of the rat and human isoforms. 4m possessed favorable pharmacokinetic parameters. This compound stimulated fat oxidation in vivo and reduced plasma triglyceride levels in a rodent model after subchronic administration. 4m is a suitable tool compound for the elucidation of the pharmacological potential of ACC1/2 inhibition.
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