Hugo Bergen

Hypothalamic pro-opiomelanocortin mRNA is reduced by fasting in ob/ob and db/db mice, but is stimulated by leptin

Reduction in the activity of the α-melanocyte-stimulating hormone (α-MSH) system causes obesity, and infusions of α-MSH can produce satiety, raising the possibility that α-MSH may mediate physiological satiety signals. Since α-MSH is coded for by the pro-opiomelanocortin (POMC) gene, we examined if POMC gene expression would be inhibited by fasting in normal mice or in models of obesity characterized by leptin insufficiency (ob/ob) or leptin insensitivity (db/db). In wild-type mice, hypothalamic POMC mRNA was decreased >60% after a 2-day fast and was positively correlated with leptin mRNA. Similarly, compared with controls, POMC mRNA was decreased by at least 60% in both db/db and ob/ob mice. POMC mRNA was negatively correlated with both neuropeptide Y (NPY) and melanin-concentrating hormone (MCH) mRNA. Finally, treatment of both male and female ob/ob mice with leptin stimulated hypothalamic POMC mRNA by about threefold. These results suggest that impairment in production, processing, or responsiveness to α-MSH may be a common feature of obesity and that hypothalamic POMC neurons, stimulated by leptin, may constitute a link between leptin and the melanocortin system.

Hyperphagia and weight gain after gold-thioglucose: relation to hypothalamic neuropeptide Y and proopiomelanocortin.

Genetic obesity is associated with increased neuropeptide Y (NPY) messenger RNA (mRNA) and decreased POMC mRNA in the hypothalamus of ob/ob and db/db mice, or impaired sensitivity to aMSH (derived from POMC) in the yellow agouti mouse. Acquired obesity can be produced by chemically lesioning the hypothalamus with either monosodium glutamate (MSG) in neonates or gold thioglucose (GTG) in adult mice. The present study examined whether elevated NPY mRNA and/or decreased POMC mRNA in the hypothalamus are associated with obesity due to hypothalamic lesions. GTG injection into adult mice produced a profound obese phenotype, including hyperphagia, increased body weight, and increased leptin mRNA and peptide, in association with reduced hypothalamic NPY mRNA and POMC mRNA. MSG treatment produced virtual elimination of NPY mRNA in the arcuate nucleus and a reduction of hypothalamic POMC mRNA, and led to elevated leptin. MSG pretreatment did not attenuate GTG-induced hyperphagia and obese phenotype. These results do not support a role for NPY-synthesizing neurons in the arcuate nucleus in mediating hypothalamic acquired obesity, but are consistent with the hypothesis that decreased activity of hypothalamic neurons synthesizing POMC play a role in mediating hypothalamic obesity. (Endocrinology 139: 4483–4488, 1998) E synthesis of neuropeptide Y (NPY) in the arcuate nucleus has been proposed to play an important role in mediating the obese phenotype in genetically obese animals (1, 2). This hypothesis is widely viewed as credible because 1) experimental elevation of hypothalamic NPY can induce obesity (1); 2) in some forms of genetic obesity, NPY messenger RNA (mRNA) in the arcuate nucleus is elevated (3–6); 3) leptin inhibits NPY mRNA in the arcuate nucleus (3, 7); and 4) obesity is attenuated in leptindeficient ob/ob mice that lack NPY (8). On the other hand, reduced POMC activity is also implicated in obesity, as 1) obesity in yellow agouti mice is associated with interference in response to aMSH, which is derived from POMC (9–13); 2) genetic deletion of an aMSH receptor produces obesity (14); 3) central administration of aMSH or a melanocortin-4 receptor agonist inhibits food intake, whereas a melanocortin-4 receptor antagonist stimulates food intake (13, 15); and 4) the expression of hypothalamic POMC mRNA is reduced in genetically obese ob/ob and db/db mice and is stimulated by leptin (16–18). Obesity can be acquired through several perturbations, including hypothalamic damage. Hypothalamic obesity has been reported in humans (19) as well as in other species, for example after neonatal administration of monosodium glutamate (MSG) (20) or treatment of adult mice with gold thioglucose (GTG) (21). An ip injection of GTG produces a lesion in the ventromedial hypothalamus whose localization is reproducible and which recapitulates the severe obese phenotype characteristic of lesions of the hypothalamic ventromedial nucleus produced by other means (e.g. an electrical current, an excitotoxin, or a tumor). Therefore, GTG has been used as a powerful tool to assess mechanisms of hypothalamic obesity (22–32). The hypothalamic lesion produced by GTG is dependent on insulin and the glucose moiety of the GTG molecule and is blocked by glucose uptake inhibitors, so GTG has been thought to primarily target the glucosesensitive neurons of the hypothalamus (21, 33). This hypothesis was supported by the observation that mice with GTG lesions are insensitive to the satiety effects of glucose and the induction of feeding by 2-deoxyglucose, but are sensitive to the satiety effects of cholecystokinin (34). The present study examined whether increased hypothalamic NPY mRNA and/or decreased hypothalamic POMC mRNA are associated with GTGor MSG-induced hypothalamic obesity. Materials and Methods

Resistance to diet-induced obesity is associated with increased proopiomelanocortin mRNA and decreased neuropeptide Y mRNA in the hypothalamus.

Mechanisms mediating genetic susceptibility to diet-induced obesity have not been completely elucidated. Elevated hypothalamic neuropeptide Y (NPY) and decreased hypothalamic proopiomelanocortin (POMC) are thought to promote the development and maintenance of obesity. To assess the potential role of hypothalamic neuropeptide gene expression in diet-induced obesity, the present study examined effects of a high-fat diet on hypothalamic NPY and POMC mRNA in three strains of mice that differ in susceptibility to develop diet-induced obesity. C57BL/6J, CBA, and A/J mice were fed either normal rodent chow or a high-fat diet for 14 weeks after which hypothalamic gene expression was measured. On the high-fat diet, C57BL/6J mice gained the most weight, whereas A/J mice gained the least weight. On the high-fat diet, NPY mRNA significantly decreased as body weight increased in CBA and A/J mice, but not in C57BL/6J mice. In addition, POMC mRNA significantly increased as body weight increased in A/J mice, but not in CBA and C57BL/6J mice. Since decreased NPY mRNA and increased POMC mRNA would presumably attenuate weight gain, these results suggest that a high-fat diet produces compensatory changes in hypothalamic gene expression in mice resistant to diet-induced obesity but not in mice susceptible to diet-induced obesity.

Injection with gold thioglucose impairs sensitivity to glucose: evidence that glucose-responsive neurons are important for long-term regulation of body weight

It has been proposed, but never demonstrated, that glucose-responsive neurons are essential for the long-term regulation of body weight, and that mice injected with gold-thio-glucose (GTG) become obese due to destruction of glucose-responsive neurons. To assess these hypotheses, mice were injected with either saline (control) or a dose of GTG that produces obesity, and the effects on feeding of peripheral injection of saline, glucose, 2-deoxyglucose (2-DG), or cholecystokinin (CCK) were measured. In control mice, 2-DG increased, whereas glucose and CCK decreased, food intake significantly. In contrast, in GTG-treated mice, 2-DG and glucose did not have a significant effect on food intake. The GTG-treated mice remained sensitive to the inhibitory effect of CCK on food intake. These data indicate that i.p. injection of GTG, which produces obesity, also destroys glucose-responsive neurons, consistent with the hypothesis that glucose-responsive neurons contribute to the long-term regulation of body weight.

Ventromedial hypothalamic lesions produced by gold thioglucose do not impair induction of NPY mRNA in the arcuate nucleus by fasting

There is increasing evidence that neuropeptide Y (NPY) plays an important role in the regulation of food intake. Neuropeptide Y mRNA in the arcuate nucleus increases after fasting and it has been proposed that this increase in NPY activity occurs as a result of the decreased circulating levels of both insulin and glucose associated with a fast. Glucose-responsive neurons in the ventromedial nucleus (VMN) of the hypothalamus alter their activity in response to changes in circulating glucose levels and these neurons have been proposed to be involved in the regulation of feeding behavior and metabolism. However, it is not known if these glucose-responsive neurons are involved in the response of NPY mRNA in the arcuate nucleus to fasting. To address this relationship, mice were injected with either saline or gold thioglucose (GTG), which appears to act on glucose-responsive neurons, and killed 6 weeks later after a 72 h fast or under ad lib fed conditions. In situ hybridization histochemistry for NPY mRNA was performed on hypothalamic sections containing the arcuate nucleus. The number of labelled cells was counted and the density of autoradiographic silver grains overlying the cells was also quantified (i.e. pixels per cell). Fasting resulted in increased levels of total NPY mRNA (number of labelled cells multiplied by the pixels per cell) in the arcuate nucleus of both control and GTG-treated mice. In addition, the relative fasting-induced increase (i.e. the fasted to fed ratio) in number of cells detected, number of pixels per cell, and total NPY mRNA was similar in both the control and GTG-treated mice. These data suggest that GTG-sensitive VMN neurons play little role in the induction of NPY mRNA by fasting in the arcuate nucleus.

Exposure to Smoke During Development: Fetal Programming of Adult Disease

It is well established that smoking has potent effects on a number of parameters including food intake, body weight, metabolism, and blood pressure. For example, it is well documented that 1) there is an inverse relationship between smoking and body weight, and 2) smoking cessation is associated with weight gain. However, there is increasing evidence that smoking can exert deleterious effects on energy balance through maternal exposure during fetal development. Specifically, there appears to be an increased incidence of metabolic disease (including obesity), and cardiovascular disease in children and adults that were exposed to smoke during fetal development. The present review will examine the relationship between maternal smoke and adult disease in offspring. The epidemiological studies highlighting this relationship will be reviewed as well as the experimental animal models that point to potential mechanisms underlying this relationship. A better understanding of how smoking effects changes in energy balance may lead to treatments to ameliorate the long-lasting effects of perinatal exposure to smoke as well as increasing the health benefits associated with smoking cessation.

Mitochondrial dysfunction bridges negative affective disorders and cardiomyopathy in socially isolated rats: Pros and cons of fluoxetine.

Abstract Objectives Depression is tightly associated with cardiovascular comorbidity and accounts for high financial and social burden worldwide. Mitochondrial dysfunction contributes to the pathophysiology of depression and cardiovascular disorders; its contribution to depression-cardiovascular comorbidity has not yet been investigated. Methods Adolescent rats were subjected to 4 weeks of isolation (social isolation stress or SIS) or social conditions (control), and then they were divided into treatment (fluoxetine, 7.5 mg/kg/day for 21 days) and non-treatment groups. After different housing conditions and treatment, animals were evaluated by behavioural tests (n = 6–8) and mitochondrial assessments (n = 3) of brain and cardiac tissues. Results We found that juvenile SIS induced behavioural abnormalities and mitochondrial dysfunction in adulthood. We showed that juvenile SIS was associated with impaired respiratory chain complex, which leads to reactive oxygen species formation, oxidative damage and ATP abatement in both brain and heart. Administration of FLX (7.5 mg/kg/day) during the isolation period attenuated the effects of SIS on the brain mitochondria and behavioural abnormalities, but had little or no effect on SIS-induced mitochondrial dysfunction in cardiac tissue. Conclusions This suggests that juvenile SIS predisposes the co-occurrence of depression and cardiovascular disease through mitochondrial dysfunction and that therapeutic effect of fluoxetine is partly mediated by its effect on mitochondrial function.

Platinum (IV) coiled coil nanotubes selectively kill human glioblastoma cells

UNLABELLED Malignant glioma are often fatal and pose a significant therapeutic challenge. Here we have employed α-helical right handed coiled coils (RHCC) which self-assemble into tetrameric nanotubes that stably associate with platinum (Pt) (IV) compound. This Pt(IV)-RHCC complex showed superior in vitro and in vivo toxicity in human malignant glioma cells at up to 5 fold lower platinum concentrations when compared to free Pt(IV). Pt(IV)-RHCC nanotubes activated multiple cell death pathways in GB cells without affecting astrocytes in vitro or causing damage to normal mouse brain. This Pt(IV)-RHCC nanotubes may serve as a promising new therapeutic tool for low dose Pt(IV) prodrug application for highly efficient and selective treatment of human brain tumors. FROM THE CLINICAL EDITOR The prognosis of malignant glioma remains poor despite medical advances. Platinum, one of the chemotherapeutic agents used, has significant systemic side effects. In this article, the authors employed α-helical right handed coiled coil (RHCC) protein nanotubes as a carrier for cisplatin. It was shown that the new compound achieved higher tumor kill rate but lower toxicity to normal cells and thus may hold promise to be a highly efficient treatment for the future.

Dovitinib enhances temozolomide efficacy in glioblastoma cells

The multikinase inhibitor and FDA‐approved drug dovitinib (Dov) crosses the blood–brain barrier and was recently used as single drug application in clinical trials for GB patients with recurrent disease. The Dov‐mediated molecular mechanisms in GB cells are unknown. We used GB patient cells and cell lines to show that Dov downregulated the stem cell protein Lin28 and its target high‐mobility group protein A2 (HMGA2). The Dov‐induced reduction in pSTAT3Tyr705 phosphorylation demonstrated that Dov negatively affects the STAT3/LIN28/Let‐7/HMGA2 regulatory axis in GB cells. Consistent with the known function of LIN28 and HMGA2 in GB self‐renewal, Dov reduced GB tumor sphere formation. Dov treatment also caused the downregulation of key base excision repair factors and O6‐methylguanine‐DNA‐methyltransferase (MGMT), which are known to have important roles in the repair of temozolomide (TMZ)‐induced alkylating DNA damage. Combined Dov/TMZ treatment enhanced TMZ‐induced DNA damage as quantified by nuclear γH2AX foci and comet assays, and increased GB cell apoptosis. Pretreatment of GB cells with Dov (‘Dov priming’) prior to TMZ treatment reduced GB cell viability independent of p53 status. Sequential treatment involving ‘Dov priming’ and alternating treatment cycles with TMZ and Dov substantially reduced long‐term GB cell survival in MGMT+ patient GB cells. Our results may have immediate clinical implications to improve TMZ response in patients with LIN28+/HMGA2+ GB, independent of their MGMT methylation status.

Lithium attenuates the proconvulsant effect of adolescent social isolation stress via involvement of the nitrergic system

In this study, we tested whether acute administration of lithium mitigates the deleterious effect of adolescent social isolation stress (SIS) on seizure susceptibility. In comparison with socially conditioned (SC) mice, isolated conditioned (IC) mice exhibited an increase in seizure susceptibility to pentylenetetrazole. Acute administration of lithium (10mg/kg) reversed the proconvulsant effect of SIS in IC mice, but this effect was not observed in SC mice. Coadministration of subthreshold doses of lithium (3mg/kg) with nitric oxide synthase (NOS) inhibitors reversed the effect of SIS on seizure susceptibility and decreased hippocampal nitrite levels in IC animals. In addition, a subthreshold dose of a nitric oxide precursor reduced the protective effect of lithium on seizure susceptibility and increased nitrite levels in the hippocampus of IC mice. These results suggest that lithium exerts a protective influence against the proconvulsant effect of adolescent SIS via a nitrergic system that includes activation of neuronal NOS in the hippocampus.