Impaired diet-induced thermogenesis in brown adipose tissue from rats made obese with parasagittal hypothalamic knife-cuts

Two experiments were performed to determine if bilateral parasagittal hypothalamic knife-cuts (KCs), which produce long-term overeating and obesity, after biochemical indices of brown adipose tissue (BAT) reactivity to thermogenic stimuli. In the first study, responses to environmental cold were tested. Four weeks after surgery, KC rats had gained 4-5 times more weight than controls and were obese (increased Lee Obesity Index and weight of gonadal white fat). Before being sacrificed, groups of KC and control rats were exposed to 4 degrees C for 21 hr or remained at 28 degrees C. Interscapular BAT weighed 300% more in KC rats, due largely to increased white fat content. Functional indices of BAT thermogenic capacity (protein content, DNA content, cytochrome oxidase activity and mitochondrial guanosine diphosphate (GDP) binding) were normal at 28 degrees C. Exposure to 4 degrees C produced greatly enhanced responses but these were equivalent for both groups. This suggested an intact capacity for non-shivering thermogenesis in obese KC rats. In the second study, the same BAT responses were examined in other rats fed a palatable "cafeteria" diet (CAFE). One week after surgery, KC and control rats were subdivided into groups that received chow alone or chow plus four different palatable foods daily. Before sacrificing 4-5 weeks later, KC rats had gained 3-4 times more weight than controls and were obese. Interscapular BAT weighed 200-300% more in KC rats. CAFE feeding produced larger increments in all variables for KC vs. control rats. Most importantly, GDP binding was reduced in both KC groups, and significantly more so after CAFE feeding.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hypothalamus and Brown Fat: White and Brown Adipose Tissue Lipolysis in Weanling Rats with Dorsomedial Hypothalamic Lesions

Weanling male Sprague-Dawley rats received bilateral electrolytic lesions in the dorsomedial hypothalamic nuclei (DMN); sham-operated animals served as controls. The animals were fed lab chow and given tap water ad libitum. Fourteen days after the hypothalamic operation they were weighed and measured to assess ponderal and linear growth gains and Lee Index and were sacrificed on the following day. Body weight, body weight gain over two weeks, nose-tail length and gain in nose-tail length, and food intake were all highly significantly reduced in DMNL rats in comparison with controls. Lee Index and efficiency of food utilization were normal, however. Epididymal fat pads weighed less in both absolute and relative (percentage body weight) terms than in controls. Basal lipolysis was increased and epinephrine-stimulated lipolysis was decreased in DMNL rats, as was the protein content of the epididymal fat pads. Lipid content was normal, however. Interscapular brown adipose tissue (BAT) was significantly lighter in DMNL rats than in controls in absolute terms, but all other parameters measured were normal, as were plasma glucose, glycerol, and free fatty acids. Comparison with results from rats that received ventromedial hypothalamic lesions shortly after weaning indicates a differential effect in most epididymal fat pad parameters but similarities to changes in BAT. These data add to previous demonstrations of normal responses to homeostatic challenges in the growth-retarded, hypophagic-hypodipsic rat with lesions in the dorsomedial hypothalamic nucleus.     

Comparative effects of the antipsychotics sulpiride and risperidone in female rats on energy balance, body composition, fat morphology and macronutrient selection

Previous studies showed that the antipsychotic drugs (APDs) sulpiride (SUL) and risperidone (RIS) induced body weight gain (BWG), hyperphagia, and increased serum levels of leptin, prolactin and corticosterone in female rats. Neither SUL nor RIS increased BWG or food intake (FI) in male rats. To further develop the animal model of APD-induced obesity, SUL (20 mg/kg/sc), RIS (0.5 mg/kg/sc) or vehicle (1 cm³/kg/sc) were administered to female Wistar rats for 10 or 12 days. Body composition, fat tissue morphology, energy expenditure and food efficiency were assessed in animals fed a high-fat diet. In another experiment, macronutrient selection was evaluated in animals fed with pure diets. SUL and RIS significantly increased BWG and FI, with a stronger effect of SUL. Both drugs increased fat gain and food efficiency, and did not modify energy expenditure. Obesity was due to adipocyte hyperplasia. SUL-treated rats significantly decreased fat intake (p=0.039), showed a tendency to increase protein intake and did not modify carbohydrate consumption. No differences were observed between the RIS and the vehicle group. The macronutrient selection pattern differs from that observed in obese people undergoing APD treatment and in most animal models of obesity. Those findings suggest that SUL administration does not properly model APD treatment in humans. Results on macronutient selection in RIS-treated rats must be considered as preliminary, since in this experiment the animals did not gain weight significantly. Other diet protocols and lower APD doses must be tested to further characterize the RIS model.     

Lateral and medial hypothalamic lesions do not acutely affect brown adipose tissue thermogenesis

The acute effect of lateral (LH) and medial (MH) hypothalamic lesions on mitochondrial GDP binding in brown adipose tissue (BAT) (an index of thermogenic state) was studied one and two days postlesion. Groups of rats were lesioned, sham-lesioned, or unoperated and were all fasting. An additional group of unoperated rats had access to food throughout the study. The objective was to determine whether the hypermetabolic state and rapid weight loss known to be induced by LH lesions were attributable to the activation of BAT thermogenesis, and, if so, whether these effects were specific for LH lesions. No effect of either lesion on BAT thermogenic state could be detected at either time studied. Despite that fact, LH-lesioned rats, but not MH-lesioned rats, were hyperthermic at both times. We conclude that the prolonged hyperthermia which occurs shortly after LH lesions is not due to an activation of BAT thermogenesis. Instead, it can be likened to the febrile state in which an initial and brief activation of both nonshivering thermogenesis in BAT and shivering thermogenesis in muscles occurs only during the rising phase of the fever and is suppressed as soon as a stable hyperthermic state is reached. It thus appears unlikely that substantial and prolonged activation of BAT thermogenesis is a major mechanism that promotes exaggerated short-term weight loss in the LH-lesioned rat.     

Ventromedial and dorsomedial hypothalamic syndromes in the weanling rat: Is the “center” concept really outmoded?

This report juxtaposes findings from weanling rats with precise lesions in the ventromedial (VMNL rats) to data of weanling rats with lesions in the dorsomedial (DMNL) hypothalamic nuclei. Despite the proximity of the two nuclei their destruction produces opposite effects in most cases but similar responses in other parameters. Absolute and relative food intake are normal in VMNL rats yet they become obese in the face of normal body weight gains. DMNL rats show both reduced absolute food intake and body weight but normal relative food intake and body composition. Both VMNL and DMNL cause reduced linear growth and running wheel activity. DMNL rats defend their lower body weight set point against various challenges and maintain normal body composition. Organ growth in both absolute and relative terms is reduced in VMNL rats. In DMNL rats relative organ growth is normal. Pancreatic growth, protein/pancreas and content and concentrations of several pancreatic enzymes are normal in DMNL but reduced in VMNL rats. Mean 24-hour plasma growth hormone (GH) and corticosterone (B) levels are reduced and insulin levels are greatly elevated in VMNL rats; prolactin (PRL) levels are normal. In DMNL rats, GH, B, insulin and somatomedin activity are normal but PRL is elevated. Circadian rhythms of GH, insulin and triiodothyronine are normal in DMNL rats but B levels are disrupted, as they are in VMNL rats. Glucose incorporation and oxidation in adipose tissue of VMNL rats are enhanced in VMNL rats but normal in DMNL rats. Gluconeogenesis in VMNL rats is enhanced as early as 4 hours post-operatively; in DMNL rats it is normal at this time and several weeks thereafter. Basal lipolysis in epididymal fat pads is elevated in both VMNL and DMNL rats but epinephrine-stimulated lipolysis is elevated in VMNL and decreased in DMNL rats. Both VMNL and DMNL rats show normal basal and epinephrine-stimulated lipolysis in interscapular brown adipose tissue. Several hepatic enzymes are normal in DMNL and depressed in VMNL rats. The above data suggest that the DMN and its circuitry are part of an "organismic" set point system with a "true" body weight and no fat set point, as seems to be the case in the VMNL rat.     

Investigation into the effects of the novel antipsychotic ziprasidone on weight gain and reproductive function in female rats

Weight gain and sexual dysfunction are serious side effects of certain antipsychotic drugs. Ziprasidone, a novel antipsychotic with a unique receptor binding profile, is reported to have a low propensity for such side effects. Previous results from this laboratory have demonstrated substantial weight gain following sub-chronic treatment with olanzapine and risperidone. Risperidone induced weight gain and markedly impaired reproductive function while olanzapine induced weight gain, without affecting reproductive function. The aim of this study was to investigate effects of ziprasidone on weight gain and reproductive function in female rats. Ziprasidone (1 and 2.5 mg/kg i.p.) or vehicle was administered once daily for 28 days and body weight, food and water intake measured, in addition to histological examination of vaginal lavage to determine the stage of the oestrous cycle. On day 28, the rats were sacrificed and the uterine weights recorded, intra-abdominal fat weight and plasma prolactin levels measured. Ziprasidone failed to induce significant weight gain during weeks 1–3, however, significant weight gain was observed on day 28 at 2.5 mg/kg (p < 0.05). Ziprasidone had no effect on food intake at any time point. A significant reduction in water intake (p < 0.05) was observed during the first week of treatment with 2.5 mg/kg ziprasidone. Ziprasidone had no effect on intra-abdominal fat weight, wet or dry uterine weight or plasma prolactin levels. All ziprasidone treated animals displayed a normal four-day oestrous cycle. This study is the first to report that ziprasidone is without effect on reproductive function or ingestive behaviour in the rat.     

Effects of cholecystokinin on sympathetic activity to interscapular brown adipose tissue.

The effects of injecting cholecystokinin (CCK) into the third ventricle or into selected hypothalamic sites on electrical firing rate of sympathetic nerves to interscapular brown fat (IBAT) has been investigated in anesthetized rats. The hypothesis for these experiments was that there was a reciprocal relationship between sympathetic activity and food intake. Since CCK reduces food intake we predicted that CCK would stimulate sympathetic activity to IBAT. Following the injection of CCK into the third ventricle there was an increase in firing rate of sympathetic nerves to IBAT. When the peptide was injected into either the ventromedial hypothalamic nucleus (VMH) or lateral hypothalamic area (LHA), there was likewise an increase in sympathetic firing rate. The injection of CCK into the paraventricular nucleus produced a small decrease in sympathetic firing rate. In contrast, no effect was seen following injection of CCK into the preoptic area or dorsomedial hypothalamic nucleus. Thus, the VMH or LHA appear to be the principal hypothalamic areas mediating the stimulation of sympathetic activity to IBAT which is observed following the third ventricular injection of CCK. These studies support the hypothesis of a reciprocal relationship between the effects of CCK on the thermogenic component of the sympathetic nervous system and food intake and identify the VMH and LHA as the primary sites for this effect.     

Paradoxical [correction of parodoxical] effect of orexin A: hypophagia induced by hyperthermia

This experiment tested the effect of the sympathetic and thermogenic activation induced by orexin A on eating behavior. The food intake, firing rate (FR) of the sympathetic nerves to interscapular brown adipose tissue (IBAT), IBAT and abdominal temperatures (T(IBAT) and T(ab)), and heart rate (HR) were monitored in 24 h-fasting male Sprague-Dawley rats for 15 h after food presentation. Orexin A (1.5 nmol) was injected into the lateral cerebral ventricle 6 h before food presentation while FR, T(IBAT) and T(ab), and HR were also monitored. The same variables were controlled in rats receiving orexin A contemporaneously to food presentation. Two other groups of control animals were tested with the same procedure, however orexin A was substituted by saline. The results showed that food intake was significantly lower in the group receiving orexin A 6 h before food presentation in comparison to all the other groups. FR, T(IBAT) and T(ab), and HR were significantly higher in the rats receiving orexin A with respect to rats receiving saline. These findings demonstrate that orexin A, so-called for its orexigen action, can also induce hypophagia. On the other hand, orexin A always induces an activation of the thermogenesis. These results suggest a revision of the role played by orexin A in the control of food intake, assigning to this peptide a primary role in the thermoregulation. The possibility that orexin A can induce hypophagia is well demonstrated by this experiment, so that the scientific community should use a different name for this peptide. An appropriate name could be 'hyperthermine' A.     

Long-term effects of lateral hypothalamic lesions on brown adipose tissue in rats

A classic feature of animals with lateral hypothalamic (LH) lesions is their regulation of body weight at sub-normal levels. The present studies were done to determine whether this is associated with enhanced thermogenic activity of their brown adipose tissue (BAT). Three groups of young chow-fed male Holtzman rats were formed: (1) animals receiving bilateral radiofrequency heat lesions of the dorsal LH and then permitted free access to chow (LH rats); (2) non-lesioned animals that were pair-fed (PF) to the lesioned rats during a 2 week post-operative recovery period (Phase 1); (3) non-lesioned, ad lib fed (NORM) controls. After Phase 1, each group was divided and permitted free access to chow alone or an additional selection of palatable, novel food items (a "cafeteria" diet) for 2-3 weeks (Phase 2) to stimulate diet-induced thermogenesis in BAT. Finally, half of each sub-group was exposed to 4 degrees C for 15 hr to stimulate nonshivering thermogenesis in BAT. During Phase 1 LHs and PFs ate 50% less than NORMs. This resulted in a weight deficit of 16% for LHs and 12% for PFs. After the additional period of feeding palatable foods (Phase 2) LHs collectively weighed 14% less than NORMs whereas previously PFs had a weight deficit of only 4%. They gained less weight than NORMs or PFs despite a similar energy intake. LHs had small deposits of gonadal white adipose tissue [both total amount and expressed per metabolic body mass (kg 0.75)]. The weight of interscapular BAT was less in the LHs but its concentration of protein (mg/g) was higher.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mesencephalic lesions in female rats resulting in normophagia and reduced body weight.

The effects of bilateral mescencephalic lesions in the area of the ventral noradrenergic bundle (VNA) were studied in immature and mature female rats. The food intake consumption of the immature lesioned rats did not differ from sham operated controls whether fed a chow or high fat diet. However, after the surgery the body weights of the two groups began to diverge with the immature lesioned rats obtaining a significantly lower body weight. By the end of the study the immature lesioned rats were also significantly shorter than the controls. Both groups showed normal body composition throughout the measurement period. Upon refeeding after a one day fast the immature female rats defended their lower than normal pre-fast body weight. These data are in good agreement with our earlier findings using immature male rats. The mature lesioned animals also showed normal food consumption when fed a chow type diet. However the lesioned animals did show a brief hyperphagia when placed on a high fat diet. Unlike the immature lesioned rats the body weight of these lesioned animals did not differ from their sham operated controls. It is suggested that lesions in the area of the VNA may result in hyperphagia or, in no effects on food intake or body weight as reported by others or normophagia with reduced body weight. Exact lesion placement may be responsible for these divergent findings.     

An activated sympathetic nervous system affects white adipocyte differentiation and lipolysis in a rat model of Parkinson's disease

Weight loss is an important nonmotor symptom associated with Parkinson's disease (PD). However, the cellular factors responsible for PD‐induced weight loss remain unclear. Because the sympathetic nervous system plays an important role in lipid metabolism and fat cell differentiation, this study investigates whether PD‐induced changes to this system are associated with weight loss in a rat model of PD. Body weight and food intake were measured in control and PD‐model rats. After 10 weeks, retroperitoneal white adipose tissues (RWAT) were removed and weighed. Markers of the sympathetic nervous system were measured in the brainstem dorsal medulla and RWAT. Free fat acids (FFA), triglycerides (TG), adipocyte differentiation‐related genes, and lipolysis‐related molecules in the RWAT and serum were analyzed. Differences in body weight and food intake were insignificant in PD‐model rats and control rats; however, relative RWAT weight and adipocyte surface area were significantly reduced in the PD group. Changes in markers of the sympathetic nervous system were observed in the brainstem dorsal medulla and RWAT of PD rats. Decreased mRNA expression levels of genes involved in adipocyte differentiation, decreased TG levels in RWAT, increased FFA in RWAT, and increased lipolysis‐related molecules in RWAT and serum FFA were observed in PD rats. This study demonstrates that degenerated dopaminergic neurons in the nigrostriatal system correlate with increases in sympathetic nervous system function, resulting in lipolysis and inhibition of fat cell differentiation. These factors ultimately result in the decrease of RWAT in PD‐model rats. © 2014 Wiley Periodicals, Inc.     

Relationship between uptake of norepinephrine by hypothalamic homogenates and the activity of brown adipose tissue

It has previously been established that norepinephrine (NE) in the central nervous system is involved in feeding and the development of obesity. The present experiments were carried out to investigate the relationship between the uptake of NE by a crude hypothalamic homogenate and NE-mediated sympathetic activity in interscapular brown adipose tissue (IBAT). Sympathetic nervous system activity was assessed by measuring the binding of the purine nucleotide guanosine-5′-diphosphate (GDP) to mitochondria isolated from IBAT. Four situations known to alter food intake and sympathetic activity, namely, corticotropin releasing factor infusion, adrenalectomy, fenfluramine treatment and obesity due to genetic transmission were studied. In each case, [³H]NE uptake by the hypothalamic preparation and GDP binding to IBAT mitochondria were measured. A highly significant negative correlation between the uptake of NE by hypothalamic homogenates and the binding of GDP to IBAT mitochondria was obtained in both lean and obese animals. These findings are discussed with regard to the regulation of food intake and sympathetic nervous system mediated thermogenesis.     

Lateral hypothalamic 'command neurons' with axonal projections to regions involved in both feeding and thermogenesis

The concept of 'command neurons', whereby single neurons mediate complex and complementary motor functions to generate a stereotyped behaviour, is well developed in invertebrate physiology. The term has also been adopted more recently to explain the neural basis of 'fight or flight'. In this study we have investigated the possibility that single lateral hypothalamic neurons have the necessary neuroanatomical connections to coordinate two complementary limbs of body weight control, feeding and thermogenesis, thereby acting as 'command neurons'. The transynaptic retrograde transport of pseudorabies virus (Bartha) from a thermogenic endpoint in the brown adipose tissue of rats has been used in conjunction with other neuronal tracers, introduced into putative CNS feeding centres, to assess the potential for the involvement of command neurons in coordinating these processes. In discrete regions of the lateral hypothalamus, neurons have been identified which have the necessary complement of orexigenic peptides and collateral branching axons to both putative feeding sites and thermogenic sites in brown fat to qualify as candidate central command neurons controlling body weight.     

Large changes in food intake in diabetic rats fed high-fat and low-fat diets

Groups of male Sprague-Dawley rats were predominantly fed either a high-fat or a high-carbohydrate (CHO) diet. For designated 2-day periods, their diets were switched. After baseline measurements of food and water intake, the rats were made diabetic by injections of either 40 or 46-50 mg/kg streptozotocin. Food and water intake gradually increased over a 15-day period for rats on the CHO diet. Whenever the diets were switched, many of the rats showed large changes in food and fluid intake. Body weight showed a gradual decline, but the rats retained half of the dissectable abdominal body fat at sacrifice. Measurements of plasma glucose, insulin and glucagon proved that the rats were diabetic. The changes in average food intake were reasonably consistent with the "utilizable fuel" theory for the control of food intake assuming that the CHO component of each diet was non-utilizable. The distribution of the fat/CHO utilizable fuel ratio in both experiments was flat and non-normal showing that some rats ate as much of the high fat diet as the high CHO diet. Other rats tended to avoid the high fat to an extent that was greater than predicted by the theory, suggesting that the fat diet may have caused malaise. Thus, the individual rat data did not provide strong support for the "utilizable fuel" theory.     

The role of the vagus nerve in mediating the long-term anorectic effects of leptin

Leptin, the product of the obese (ob) gene, is mainly known for its regulatory role of energy balance by direct activation of hypothalamic receptors. Recently, its function in the acute control of food intake was additionally attributed to activation of the vagus nerve to regulate meal termination. Whether vagal afferent neurones are involved in longer term effects of leptin on food intake, however, remains undetermined. Using vagotomised (VGX) rats, we sought to clarify the contributions of vagal afferents in mediating the long-lasting effect of leptin on appetite suppression. Intraperitoneal (i.p.) injection of leptin (3.5 mg/kg) attenuated food intake at 4, 6, 8 and 24 h and body weight at 24 h postinjection in SHAM-operated rats; however, this response was not abrogated by vagotomy. In a separate study using immunohistochemistry, we observed leptin-induced Fos expression in the nucleus tractus solitarii, a brain structure where vagal afferent fibres terminate. This signal was not attenuated in VGX animals compared to the SHAM group. Moreover, leptin treatment led to a similar level of nuclear STAT3 translocation, a marker of leptin signalling, in the hypothalami of SHAM and VGX animals. In addition to the effects of leptin, vagotomy surgery itself resulted in a decrease of 24 h food intake. Analyses of brains from saline-treated VGX animals revealed a significant induction of Fos in the nucleus tractus solitarii and changes in agouti-related peptide and pro-opiomelanocortin mRNA expression in the hypothalamus compared to their SHAM counterparts, indicating that the vagotomy surgery itself induced a modification of brain activity in areas involved in regulating appetite. Collectively, our data suggest that vagal afferents do not constitute a major route of mediating the regulatory effect of leptin on food intake over a period of several hours.     

Long-term administration of MC4 receptor antagonist HS014 causes hyperphagia and obesity in rats

In this study we investigated the long term effects of a potent and selective melanocortin 4 (MC4) receptor antagonist (HS014) on food intake, body weight, body composition and blood glucose levels in adult rats. HS014 was injected i.c.v. either by twice-daily injections (2 x 1 nmol) for 6 days or administered by continuous infusion with osmotic minipumps (0.16 nmol/h) for 2 weeks. The results show a considerable increase in food intake and body weight after both of the treatments without any signs of tachyphylaxis. After 2 weeks of treatment with osmotic pumps, the HS014-treated rats (average weight 425g) had 20% higher body weight than the controls rats (average 360 g). When i.c.v. injections were terminated, the body weight of the twice-daily HS014-treated rats returned to the levels of control group, whereas the rats treated with continuous infusion of HS014 remained hyperphagic and still gained weight. Blood glucose levels in the rats treated with HS014 infusion were significantly increased. Analysis of body composition in HS014-infused rats indicated that body weight was increased due to fat deposits. These data show for the first time that chronic administration of exogenous MC4 receptor antagonist causes hyperphagia and severe obesity in rats. These data also indicate that the melanocortic control of food intake is very robust and suggest that changes induced by such treatment overcome negative feedback signals.     

Integrated metabolic control of food intake

Inhibition of glycolysis and fatty acid oxidation by combined treatment with 2-deoxyglucose (2DG) and methyl palmoxirate, or inhibition of glycolysis and lipolysis by combined treatment with 2DG and nicotonic acid synergistically increased food intake in rats. Methyl palmoxirate treatment alone increased food intake in rats fed a high-fat, but not low-fat diet. These results provide direct evidence for a mechanism in the control of food intake that integrates signals generated by the metabolism of glucose and fatty acids. In addition, they strongly indicate a role for fatty acid oxidation in the control of eating and raise the possibility that an interaction between glucose and fat metabolism underlies the link between regulation of body fat stores and short-term food intake.     

Simultaneous POMC gene transfer to hypothalamus and brainstem increases physical activity, lipolysis and reduces adult-onset obesity

Pro-opiomelanocortin (POMC) neurons are identified in two brain sites, the arcuate nucleus of the hypothalamus and nucleus of the solitary tract (NTS) in brainstem. Earlier pharmacological and POMC gene transfer studies demonstrate that melanocortin activation in either site alone improves insulin sensitivity and reduces obesity. The present study, for the first time, investigated the long-term efficacy of POMC gene transfer concurrently into both sites in the regulation of energy metabolism in aged F344xBN rats bearing adult-onset obesity. Pair feeding was included to reveal food-independent POMC impact on energy expenditure. We introduced adeno-associated virus encoding either POMC or green fluorescence protein to the two brain areas in 22-month-old rats, then recorded food intake and body weight, assessed oxygen consumption, serum leptin, insulin and glucose, tested voluntary wheel running, analysed POMC expression, and examined fat metabolism in brown and white adipose tissues. POMC mRNA was significantly increased in both the hypothalamus and NTS region at termination. Relative to pair feeding, POMC caused sustained weight reduction and additional fat loss, lowered fasting insulin and glucose, and augmented white fat hormone-sensitive lipase activity and brown fat uncoupling protein 1 level. By wheel running assessment, the POMC animals ran twice the distance as the Control or pair-fed rats. Thus, the dual-site POMC treatment ameliorated adult-onset obesity effectively, involving a moderate hypophagia lasting ～60 days, enhanced lipolysis and thermogenesis, and increased physical activity in the form of voluntary wheel running. The latter finding provides a clue for countering age-related decline in physical activity.     

Short- and long-term effects of antipsychotic drug treatment on weight gain and H1 receptor expression

The present study investigated body weight gain, food intake, open-field activity and brain histamine H1 receptor mRNA and protein expression in rats treated with three types of antipsychotics. Rats were divided into eight groups and treated with aripiprazole (2.25 mg/kg/day), olanzapine (1.5 mg/kg/day), haloperidol (0.3 mg/kg/day) or vehicle (as control) for 1 or 12 weeks. Administration of olanzapine for 1 week led to a threefold increase in body weight gain and a 35% increase in fat deposits compared to controls (p<0.05). In the 12-week olanzapine treatment group, accumulative food intake was significantly higher in the first 7 weeks of treatment compared to controls (p<0.018), while body weight gain was significantly greater in the first 8 weeks compared to controls (p<0.045). Using in situ hybridization, we found that olanzapine treatment, but not aripiprazole or haloperidol treatment, significantly reduced H1 receptor mRNA expression in the arcuate hypothalamic nucleus (Arc: −18%, p=0.006, 1 week; −20%, p=0.008, 12 weeks) and ventromedial hypothalamic nucleus (VMH: −22%, p=0.006, 1 week; −19%, p=0.042, 12 weeks) compared to controls. The quantitative autoradiography data showed a reduction in VMH H1 receptor binding density after 1 (−12%, p=0.040) and 12 (−10%, p=0.094) weeks of olanzapine treatment. There were significant negative correlations between the levels of H1 receptor mRNA expression, and body weight gain and energy efficiency in the Arc and VMH after 1- and 12-week antipsychotic treatments in all groups. In addition, H1 receptor mRNA expression in the Arc showed a significant negative correlation with food intake and fat mass in all groups. Furthermore, there were negative correlations between H1 receptor binding density in the VMH and total fat mass and body weight gain after 1 week of antipsychotic treatment. The present study suggests that downregulated VMH and Arc H1 receptor expression may be a key factor contributing to olanzapine-induced obesity.     

Interrelations between Sympathoadrenal System andHypothalamo-Pituitary-Adrenocortical/Thyroid Systemsin Rats Exposed to Cold Stress

The interrelations between sympathoadrenal (SA) system and hypothalamo-pituitary-adrenocortical (HPA) or hypothalamo-pituitary-thyroid (HPT) system during cold stress were examined by measuring plasma levels of dihydroxyphenylalanine (DOPA), catecholamine and their metabolites in adrenalectomized (ADX) and thyroidectomized (TX) rats exposed to cold stress (?3 °C). Plasma levels of adrenocorticotropic hormone (ACTH), corticosterone (CORT), thyroid-stimulating hormone (TSH) and thyroid hormones in cold-stressed rats were measured also. Plasma ACTH levels were increased transiently after 1 h of cold exposure, after which the circadian rhythm and plasma levels of ACTH were similar to those of normal rats. Plasma CORT levels were also elevated after 1 h of cold exposure; the increased levels of CORT tended to return to normal levels after 9 h of cold, but remained higher than those of normal rats during at least 24 h of cold exposure. Plasma ACTH levels of 5 day cold-stressed rats were no longer elevated above those of control rats and plasma CORT levels were only slightly higher than in control animals. However, plasma levels of TSH and free thyroid hormones were elevated after 1 day and remained elevated after 5 days of cold exposure. Thus, cold stress appears to activate chronically the HPT system, but only transiently activates the HPA system. ADX rats had higher basal plasma levels of dihydroxyphenylglycol (DHPG), methoxyhydroxyphenylglycol (MHPG), DOPA and homovanillic acid (HVA) than those of sham-operated (SHAM) rats, but norepinephrine (NE) levels were not significantly greater than in SHAM animals. TX rats had higher basal plasma levels of NE, epinephrine (EPI) and dopamine (DA), as well as much higher plasma levels of the metabolites. Exposure to cold increased plasma NE levels in both ADX and TX rats, but the increments in TX rats were much greater than in SHAM and ADX groups. Plasma EPI levels were not significantly elevated during cold exposure in SHAM rats, but were highly elevated in TX rats exposed to cold. TX rats had much larger increments in plasma levels of DHPG, MHPG, DA, dihydroxyphenylacetic acid (DOPAC) and HVA during cold exposure than those of SHAM and ADX rats. These results are consistent with the view that endogenous glucocorticoids restrain responses of catecholamine synthesis, release, reuptake, and metabolism in sympathetic nervous system of cold-stressed animals, but that in the absence of an effective HPT system, there is enhanced sympathoadrenal medullary function and augmentation of their responses to cold as a means for maintaining body temperature when the HPT thermogenesis system is impaired.