MC4R-null Mice Research Articles

Collateralizing ventral subiculum melanocortin 4 receptor circuits regulate energy balance and food motivation

Hippocampal dysfunction is associated with major depressive disorder, a serious mental illness characterized by not only depressed mood but also appetite disturbance and dysregulated body weight. However, the underlying mechanisms by which hippocampal circuits regulate metabolic homeostasis remain incompletely understood. Here we show that collateralizing melanocortin 4 receptor (MC4R) circuits in the ventral subiculum (vSUB), one of the major output structures of the hippocampal formation, affect food motivation and energy balance. Viral-mediated cell type- and projection-specific input-output circuit mapping revealed that the nucleus accumbens shell (NAcSh)-projecting vSUBMC4R+ neurons send extensive collateral projections of to various hypothalamic nuclei known to be important for energy balance, including the arcuate, ventromedial and dorsomedial nuclei, and receive monosynaptic inputs mainly from the ventral CA1 and the anterior paraventricular nucleus of thalamus. Chemogenetic activation of NAcSh-projecting vSUBMC4R+neurons lead to increase in motivation to obtain palatable food without noticeable effect on homeostatic feeding. Viral-mediated restoration of MC4R signaling in the vSUB partially restores obesity in MC4R-null mice without affecting anxiety- and depression-like behaviors. Collectively, these results delineate vSUBMC4R+ circuits to the unprecedented level of precision and identify the vSUBMC4R signaling as a novel regulator of food reward and energy balance.

Deletion of the Feeding-Induced Hepatokine TSK Ameliorates the Melanocortin Obesity Syndrome.

Work in recent decades has established that metabolic hormones released by endocrine cells and diverse other cell types serve to regulate nutrient intake and energy homeostasis. Tsukushi (TSK) is a leucine-rich repeat-containing protein secreted primarily by the liver that exerts an inhibitory effect on brown fat sympathetic innervation and thermogenesis. Despite this, physiological regulation of TSK and the mechanisms underlying its effects on energy balance remain poorly understood. Here we show that hepatic expression and plasma concentrations of TSK are induced by feeding and regulated by melanocortin-4 receptor (MC4R) signaling. We generated TSK and MC4R-double-knockout mice to elucidate the nature of cross talk between TSK and the central regulatory circuit of energy balance. Remarkably, TSK inactivation restores energy balance, ameliorates hyperphagia, and improves metabolic health in MC4R-deficient mice. TSK ablation enhances thermogenic gene expression in brown fat, dampens obesity-association inflammation in the liver and adipose tissue, and protects MC4R-null mice from diet-induced nonalcoholic steatohepatitis. At the cellular level, TSK deficiency augments feeding-induced c-Fos expression in the paraventricular nucleus of the hypothalamus. These results illustrate physiological cross talk between TSK and the central regulatory circuit in maintaining energy balance and metabolic homeostasis.

372-OR: Ablation of the Hepatokine TSK Protects Mice against Obesity and Metabolic Disorders Caused by MC4R Deficiency

Endocrine hormones released by peripheral tissues, such as adipose tissue, skeletal muscle and the liver, play an important role in metabolic crosstalk and homeostasis and contribute to disease pathogenesis. We recently identified Tsukushi (TSK) as a liver-enriched secreted factor that is highly inducible in response to increased energy expenditure. TSK null mice were resistant to diet-induced obesity, insulin resistance, and diet-induced NASH as a result of enhanced sympathetic activation and brown fat thermogenesis. However, the mechanisms underlying TSK action remain incompletely elucidated. Melanocortin 4 receptor (MC4R) is a key regulator of energy balance and its mutations represent the most common monogenic cause of obesity in human. In this study, we generated TSK/MC4R double knockout mice to explore potential crosstalk between the TSK and MC4R signaling pathways. While MC4R-null mice developed severe obesity when fed standard rodent chow, TSK inactivation nearly completely abolished the defects of energy balance caused by MC4R deficiency. Remarkably, ablation of TSK normalized food intake and corrected hepatic steatosis, adipose tissue inflammation, and insulin resistance in MC4R null mice. TSK deficiency also rescued the impairments of thermogenic gene expression caused by MC4R deficiency. Those results suggest that TSK likely acts downstream or in parallel to MC4R signaling to regulate feeding behavior and energy expenditure. Our work supports a rationale for therapeutic blockade of TSK for the treatment of obesity and metabolic disease caused by MC4R mutations. Disclosure Q. Wang: None. J. Lin: None. Funding National Institutes of Health (DK102456, AG055379, DK114220)

A gut–brain axis regulating glucose metabolism mediated by bile acids and competitive fibroblast growth factor actions at the hypothalamus

ObjectiveBile acids have been implicated as important regulators of glucose metabolism via activation of FXR and GPBAR1. We have previously shown that FGF19 can modulate glucose handling by suppressing the activity of hypothalamic AGRP/NPY neurons. As bile acids stimulate the release of FGF19/FGF15 into the circulation, we pursued the potential of bile acids to improve glucose tolerance via a gut–brain axis involving FXR and FGF15/FGF19 within enterocytes and FGF receptors on hypothalamic AGRP/NPY neurons. MethodsA 5-day gavage of taurocholic acid, mirroring our previous protocol of a 5-day FGF19 treatment, was performed. Oral glucose tolerance tests in mice with genetic manipulations of FGF signaling and melanocortin signaling were used to define a gut–brain axis responsive to bile acids. ResultsThe taurocholic acid gavage led to increased serum concentrations of taurocholic acid as well as increases of FGF15 mRNA in the ileum and improved oral glucose tolerance in obese (ob/ob) mice. In contrast, lithocholic acid, an FXR antagonist but a potent agonist for GPBAR1, did not improve glucose tolerance. The positive response to taurocholic acid is dependent upon an intact melanocortinergic system as obese MC4R-null mice or ob/ob mice without AGRP did not show improvements in glucose tolerance after taurocholate gavage. We also tested the FGF receptor isoform necessary for the bile acid response, using AGRP:Fgfr1−/− and AGRP:Fgfr2−/− mice. While the absence of FGFR1 in AGRP/NPY neurons did not alter glucose tolerance after taurocholate gavage, manipulations of Fgfr2 caused bidirectional changes depending upon the experimental model. We hypothesized the existence of an endogenous hypothalamic FGF, most likely FGF17, that acted as a chronic activator of AGRP/NPY neurons. We developed two short peptides based on FGF8 and FGF17 that should antagonize FGF17 action. Both of these peptides improved glucose homeostasis after a 4-day course of central and peripheral injections. Significantly, daily average blood glucose from continuous glucose monitoring was reduced in all tested animals but glucose concentrations remained in the euglycemia range. ConclusionsWe have defined a gut–brain axis that regulates glucose metabolism mediated by antagonistic fibroblast growth factors. From the intestine, bile acids stimulate FGF15 secretion, leading to activation of the FGF receptors in hypothalamic AGRP/NPY neurons. FGF receptor intracellular signaling subsequently silences AGRP/NPY neurons, leading to improvements of glucose tolerance that are likely mediated by the autonomic nervous system. Finally, short peptides that antagonize homodimeric FGF receptor signaling within the hypothalamus have beneficial effects on glucose homeostasis without inducing hypoglycemia. These peptides could provide a new mode of regulating glucose metabolism.

Abstract P213: Metabolic and Cardiovascular Effects of Melanocortin-4 Receptors in Leptin Receptor-expressing Neurons

Studies in both humans and rodents have clearly established a role for melanocortin-4 receptor (MC4R) in energy homeostasis, sympathetic and cardiovascular function. Both MC4R-deficient humans and rodents develop severe obesity while keeping the sympathetic tone and blood pressure below or within the normal range, indicating that MC4R is required for obesity-associated sympathetic overdrive and hypertension. Indeed, sympathetic overdrive and cardiovascular side effect have been a major problem in developing anti-obesity drugs that target MC4R. Thus, better understanding the neural substrates that mediate distinct metabolic and sympathetic actions of MC4R is needed to provide a more specific target to treat obesity and associated hypertension. We have recently mapped the pattern of co-expression of MC4R and leptin receptor (LepR) and found that, throughout entire mouse brain, these two metabolically important receptors are uniquely co-expressed only in neurons of two brain regions, including the lateral hypothalamic area (LHA) and the periaqueductal gray (PAG). To specifically test the role of MC4R in LepR-expressing neurons, we generated mice with MC4R expression only in LepR-positive neurons by breeding Cre-dependently “reactivatable” MC4R-null mice (MC4R-TB) to LepR-Cre mice. We found that specific re-expression of MC4Rs only in LepR-positive neurons partially suppresses body weight gain especially in female mice (MC4R-TB 31.73 ± 2.2g vs. MC4R-TB::LepR-Cre 27.97 ± 1.8 g, p=0.0013). Direct multi-fiber recording of renal nerve activity (RSNA), however, revealed that neither baseline activity nor MC4R agonist-induced RSNA is significantly altered by restoration of MC4R signaling in LepR-positive neurons (change of RSNA in MC4R-TB 8.844 ± 3.05 vs. MC4R-TB::LepR-Cre 11.95 ± 2.7, p>0.05). Our results suggest that MC4R signaling in leptin-responsive neurons is sufficient to suppress body weight in female mice, but seemingly has no effect on sympathetic traffic to the kidney. Further investigation of the effect of MC4Rs in LepR-positive neurons on blood pressure regulation is underway.

Regulation of glucose tolerance and sympathetic activity by MC4R signaling in the lateral hypothalamus.

Melanocortin 4 receptor (MC4R) signaling mediates diverse physiological functions, including energy balance, glucose homeostasis, and autonomic activity. Although the lateral hypothalamic area (LHA) is known to express MC4Rs and to receive input from leptin-responsive arcuate proopiomelanocortin neurons, the physiological functions of MC4Rs in the LHA are incompletely understood. We report that MC4RLHA signaling regulates glucose tolerance and sympathetic nerve activity. Restoring expression of MC4Rs specifically in the LHA improves glucose intolerance in obese MC4R-null mice without affecting body weight or circulating insulin levels. Fluorodeoxyglucose-mediated tracing of whole-body glucose uptake identifies the interscapular brown adipose tissue (iBAT) as a primary source where glucose uptake is increased in MC4RLHA mice. Direct multifiber sympathetic nerve recording further reveals that sympathetic traffic to iBAT is significantly increased in MC4RLHA mice, which accompanies a significant elevation of Glut4 expression in iBAT. Finally, bilateral iBAT denervation prevents the glucoregulatory effect of MC4RLHA signaling. These results identify a novel role for MC4RLHA signaling in the control of sympathetic nerve activity and glucose tolerance independent of energy balance.

Hypothalamic Agouti-Related Peptide Neurons and the Central Melanocortin System Are Crucial Mediators of Leptin’s Antidiabetic Actions

Leptin has beneficial effects on glucose metabolism via actions in the hypothalamus, but the roles of specific subgroups of neurons responsible for these antidiabetic effects remain unresolved. We generated diabetic Lep(ob/ob) or Lepr(db/db) mice lacking or re-expressing leptin receptors (LepRb) in subgroups of neurons to explore their contributions to leptin's glucose-lowering actions. We show that agouti-related peptide (AgRP)-expressing neurons are both required and sufficient to correct hyperglycemia by leptin. LepRb in pro-opiomelanocortin (POMC) neurons or steroidogenic factor-1 (SF1) neurons are not required. Furthermore, normalization of blood glucose by leptin is blunted in Lep(ob/ob)/MC4R-null mice, but not in Lep(ob/ob) mice lacking neuropeptide Y (NPY) or gamma-aminobutyric acid (GABA) in AgRP neurons. Leptin's ability to improve glucose balance is accompanied by a reduction in circulating glucagon. We conclude that AgRP neurons play a crucial role in glucose-lowering actions by leptin and that this requires the melanocortin system, but not NPY and GABA.

Glutamate Mediates the Function of Melanocortin Receptor 4 on Sim1 Neurons in Body Weight Regulation

The melanocortin receptor 4 (MC4R) is a well-established mediator of body weight homeostasis. However, the neurotransmitter(s) that mediate MC4R function remain largely unknown; as a result, little is known about the second-order neurons of the MC4R neural pathway. Single-minded 1 (Sim1)-expressing brain regions, which include the paraventricular nucleus of hypothalamus (PVH), represent key brain sites that mediate melanocortin action. We conditionally restored MC4R expression in Sim1 neurons in the background of Mc4r-null mice. The restoration dramatically reduced obesity in Mc4r-null mice. The anti-obesity effect was completely reversed by selective disruption of glutamate release from those same Sim1 neurons. The reversal was caused by lower energy expenditure and hyperphagia. Corroboratively, selective disruption of glutamate release from adult PVH neurons led to rapid obesity development via reduced energy expenditure and hyperphagia. Thus, this study establishes glutamate as the primary neurotransmitter that mediates MC4Rs on Sim1 neurons in body weight regulation.

The expression of MC4Rs in D1R neurons regulates food intake and locomotor sensitization to cocaine

While it is known that mice lacking melanocortin 4 receptor (MC4R) expression develop hyperphagia resulting in early-onset obesity, the specific neural circuits that mediate this process remain unclear. Here, we report that selective restoration of MC4R expression within dopamine-1 receptor-expressing neurons [MC4R/dopamine 1 receptor (D1R) mice] partially blunts the severe obesity seen in MC4R-null mice by decreasing meal size, but not meal frequency, in the dark cycle. We also report that both acute cocaine-induced anorexia and the development of locomotor sensitization to repeated administration of cocaine are blunted in MC4R-null mice and normalized in MC4R/D1R mice. Neuronal retrograde tracing identifies the lateral hypothalamic area as the primary target of MC4R-expressing neurons in the nucleus accumbens. Biochemical studies in the ventral striatum show that phosphorylation of DARPP-32(Thr) (-34) and GluR1(Ser) (-845) is diminished in MC4R-null mice after chronic cocaine administration but rescued in MC4R/D1R mice. These findings highlight a physiological role of MC4R-mediated signaling within D1R neurons in the long-term regulation of energy balance and behavioral responses to cocaine.

Double deletion of melanocortin 4 receptors and SAPAP3 corrects compulsive behavior and obesity in mice

Compulsive behavior is a debilitating clinical feature of many forms of neuropsychiatric disease, including Tourette syndrome, obsessive-compulsive spectrum disorders, eating disorders, and autism. Although several studies link striatal dysfunction to compulsivity, the pathophysiology remains poorly understood. Here, we show that both constitutive and induced genetic deletion of the gene encoding the melanocortin 4 receptor (MC4R), as well as pharmacologic inhibition of MC4R signaling, normalize compulsive grooming and striatal electrophysiologic impairments in synapse-associated protein 90/postsynaptic density protein 95-associated protein 3 (SAPAP3)-null mice, a model of human obsessive-compulsive disorder. Unexpectedly, genetic deletion of SAPAP3 restores normal weight and metabolic features of MC4R-null mice, a model of human obesity. Our findings offer insights into the pathophysiology and treatment of both compulsive behavior and eating disorders.

Olfactory ability and object memory in three mouse models of varying body weight, metabolic hormones, and adiposity

Physiological and nutritional state can modify sensory ability and perception through hormone signaling. Obesity and related metabolic disorders present a chronic imbalance in hormonal signaling that could impact sensory systems. In the olfactory system, external chemical cues are transduced into electrical signals to encode information. It is becoming evident that this system can also detect internal chemical cues in the form of molecules of energy homeostasis and endocrine hormones, whereby neurons of the olfactory system are modulated to change animal behavior towards olfactory cues. We hypothesized that chronic imbalance in hormonal signaling and energy homeostasis due to obesity would thereby disrupt olfactory behaviors in mice. To test this idea, we utilized three mouse models of varying body weight, metabolic hormones, and visceral adiposity — 1) C57BL6/J mice maintained on a condensed-milk based, moderately high-fat diet (MHF) of 32% fat for 6months as the diet-induced obesity model, 2) an obesity-resistant, lean line of mice due to a gene-targeted deletion of a voltage-dependent potassium channel (Kv1.3-null), and 3) a genetic model of obesity as a result of a gene-targeted deletion of the melanocortin 4 receptor (MC4R-null). Diet-induced obese (DIO) mice failed to find a fatty-scented hidden peanut butter cracker, based solely on olfactory cues, any faster than an unscented hidden marble, initially suggesting general anosmia. However, when these DIO mice were challenged to find a sweet-scented hidden chocolate candy, they had no difficulty. Furthermore, DIO mice were able to discriminate between fatty acids that differ by a single double bond and are components of the MHF diet (linoleic and oleic acid) in a habituation–dishabituation paradigm. Obesity-resistant, Kv1.3-null mice exhibited no change in scented object retrieval when placed on the MHF-diet, nor did they perform differently than wild-type mice in parallel habituation–dishabituation paradigms of fatty food-related odor components. Genetically obese, MC4R-null mice successfully found hidden scented objects, but did so more slowly than lean, wild-type mice, in an object-dependent fashion. In habituation–dishabituation trials of general odorants, MC4R-null mice failed to discriminate a novel odor, but were able to distinguish two fatty acids. Object memory recognition tests for short- and long-term memory retention demonstrated that maintenance on the MHF diet did not modify the ability to perform these tasks independent of whether mice became obese or were resistant to weight gain (Kv1.3-null), however, the genetically predisposed obese mice (MC4R-null) failed the long-term object memory recognition performed at 24h. These results demonstrate that even though both the DIO mice and genetically predisposed obese mice are obese, they vary in the degree to which they exhibit behavioral deficits in odor detection, odor discrimination, and long-term memory.

Hypothalamic Sirt1 and regulation of food intake

The hypothalamus controls food intake [1]. It regulates food intake by integrating information on nutritional status from periphery through nutrients, hormones, and autonomic nervous system. Previous studies revealed that numerous neuropeptides are expressed in the hypothalamus and contribute to the neural networks that regulate food intake. Among them, the melanocortin system—which consists of proopiomelanocortin (POMC), agouti-related peptides (AgRP), and melanocortin receptors—is the most fundamental system regulating food intake. POMC is a precursor for alpha-melanocyte-stimulating hormone (a-MSH), which is an agonist for melanocortin type 4 receptor (MC4R), and AgRP is an inverse agonist for MC4R and counteracts the function of a-MSH. In fact, POMC-null mice [2] and MC4R-null mice [3] are obese, and cases of highly obese humans with MC4R gene mutations have been reported [4–6]. Within the hypothalamus, the arcuate nucleus (ARC), paraventricular nucleus (PVN), and lateral hypothalamic (LH) area are centers for controlling food intake. ARC is the ‘‘first-order center’’ for regulating food intake. It is located at the mediobasal hypothalamus, where the blood– brain barrier is quite permissive, making ARC the place for sensing nutrients and hormone levels. ARC contains two types of neurons: anorexigenic POMC and orexigenic AgRP. These neurons project axons to the ‘‘second-order centers,’’ which are located in PVN and LH, and competitively regulate the activity of these nuclei [7, 8]. The most-studied feeding-related hormone is leptin. In the hypothalamic neurons, leptin activates the Janus kinase 2–signal transducer and activator of transcription 3 (JAK2STAT3) pathway, leading to nuclear translocation of phosphorylated STAT3. STAT3 suppresses food intake by transactivating the anorexigenic Pomc gene and transrepressing the orexigenic Agrp gene. Insulin is also known as a central regulator for food intake. Neuron-specific insulin receptor knockout mice exhibit increased food intake and obesity [9]. Insulin signaling is transmitted from the insulin receptor to phosphoinositide 3-kinase (PI3K), which subsequently activates a serine/threonine kinase protein kinase B (Akt). FoxO1 is a transcription factor and one of the substrates for Akt. Phosphorylation of FoxO1 by Akt results in cytoplasmic shuttling from the nucleus, thereby inactivating FoxO1 as a transcription factor [10]. FoxO1 is expressed in ARC AgRP and POMC neurons, and FoxO1 in these neurons are located in the nucleus under fasted condition but is shuttled to cytoplasm by feeding [11, 12]. Overexpression of constitutively active FoxO1 in the mediobasal hypothalamus of rats by adenoviral microinjection leads to loss of feeding inhibitory effect of leptin and results in body weight gain [11]. Hypothalamus-specific constitutively active FoxO1 knockin mice also have increased food intake and decreased energy expenditure, and consequently these mice develop obesity [13]. Silent mating type information regulation 2 homolog (sirtuin 1; Sirt1) is a nicotinamide adenine dinucleotide (NAD)-dependent deacetylase and serves as an energy sensor [14]. Sirt1 is the mammalian ortholog of Sir2, which is crucial for caloric-restriction-induced longevity [15–17]. Sirt1 is expressed in POMC and AgRP neurons in ARC and T. Kitamura (&) T. Sasaki Metabolic Signal Research Center, Institute for Molecular and Cellular Regulation, Gunma University, 3-39-15 Showa-machi, Maebashi, Gunma 371-8512, Japan e-mail: kitamura@gunma-u.ac.jp

Melanocortin 4 receptor signaling in dopamine 1 receptor neurons is required for procedural memory learning

It is now widely recognized that exposure to palatable foods engages reward circuits that promote over-eating and facilitate the development of obesity. While the melanocortin 4 receptor (MC4R) has previously been shown to regulate food intake and energy expenditure, little is known about its role in food reward. We demonstrate that MC4R is co-expressed with the dopamine 1 receptor (D1R) in the ventral striatum. While MC4R-null mice are hyperphagic and obese, they exhibit impairments in acquisition of operant responding for a high fat reinforcement. Restoration of MC4R signaling in D1R neurons normalizes procedural learning without affecting motivation to obtain high fat diet. MC4R signaling in D1R neurons is also required for learning in a non-food-reinforced version of the cued water maze. Finally, MC4R signaling in neostriatal slices increases phosphorylation of the Thr34 residue of DARPP-32, a protein phosphatase-1 inhibitor that regulates synaptic plasticity. These data identify a novel requirement for MC4R signaling in procedural memory learning.

Kv1.3 gene-targeted deletion alters longevity and reduces adiposity by increasing locomotion and metabolism in melanocortin-4 receptor-null mice

Gene-targeted deletion of the voltage-gated potassium channel, Kv1.3, results in 'super-smeller' mice that have altered firing patterns of mitral cells in the olfactory bulb, modified axonal targeting to glomerular synaptic units, and behaviorally have an increased ability to detect and discriminate odors. Moreover, the Kv1.3-null mice weighed less than their wild-type counterparts, have modified ingestive behaviors, and are resistant to fat deposition following a moderately high-fat dietary regime. In this study, we investigate whether or not gene-targeted deletion of Kv1.3 (Shaker family member) can abrogate weight gain in a genetic model of obesity, the melanocortin-4 receptor-null mouse (MC4R-null). Mice with double gene-targeted deletions of Kv1.3 and MC4R were generated by interbreeding Kv1.3 (Kv)- and MC4R-null mouse lines to homozygosity. Developmental weights, nose to anus length, fat pad weight, fasting serum chemistry, oxygen consumption, carbon dioxide respiration, locomotor activity and caloric intake were monitored in control, Kv-null, MC4R-null and Kv/MC4R-null mice. Physiological and metabolic profiles were acquired at postnatal day 60 (P60) in order to explore changes linked to body weight at the reported onset of obesity in the MC4R-null model. Gene-targeted deletion of Kv1.3 in MC4R-null mice reduces body weight by decreasing fat deposition and subsequent fasting leptin levels, without changing the overall growth, fasting blood glucose or serum insulin. Gene-targeted deletion of Kv1.3 in MC4R-null mice significantly extended lifespan and increased reproductive success. Basal or light-phase mass-specific metabolic rate and locomotor activity were not affected by genetic deletion of Kv1.3 in MC4R-null mice but dark-phase locomotor activity and mass-specific metabolism were significantly increased resulting in increased total energy expenditure. Gene-targeted deletion of Kv1.3 can reduce adiposity and total body weight in a genetic model of obesity by increasing both locomotor activity and mass-specific metabolism.

Gamma-MSH/MC3R natriuretic signaling system: The possible explanation for contrasting blood pressure effects of agouti mutation and melanocortin receptor knockout

Overweight and obesity are the major risk factors of arterial hypertension. Recent studies indicate that adipose tissue hormone, leptin, is involved in the development of obesity-induced hypertension. Models of genetically determined obesity in rodents are commonly used to study the pathogenesis of obesity-associated hypertension. One of such models are agouti yellow obese (A y/a) mice which ubiquitously overexpress agouti protein—an endogenous antagonist of melanocortin receptors normally synthesized only in the hair follicle. In A y/a mice, agouti protein is synthesized also in the hypothalamus and blocks the anorectic effect of leptin mediated by alpha-melanocyte-stimulating hormone (α-MSH) which binds to melanocortin type 3 and 4 receptors (MC3R and MC4R). Consequently, A y/a mice are hyperphagic, obese, hyperinsulinemic and hyperleptinemic. Blood pressure is increased in A y/a mice due to increased serum leptin level. In contrast, blood pressure is reduced in MC4R-null mice despite obesity and hyperleptinemia, and is not increased by the administration of leptin in these animals, suggesting an essential role of the melanocortin pathway in the hypertensive effect of leptin. Herein, I propose the hypothesis which might explain why blood pressure is increased in A y/a mice but reduced in MC4R−/− mice, although hypothalamic melanocortin signaling is impaired in both models. According to this proposal, in MC4R−/− mice the natriuretic effect of γ-MSH mediated by intrarenal MC3R is preserved and counteracts prohypertensive mechanisms triggered by leptin. In contrast, in A y/a mice, ubiquitously expressed agouti protein blocks not only hypothalamic MC4R but also renal MC3R and thus impairs γ-MSH-induced natriuresis, leading to blood pressure elevation due to unopposed central and/or peripheral pressor effects of leptin.

Kv1.3 gene-targeted deletion reduces fat deposition and total body weight in melanocortin 4 receptor (MC4R)-null mice: A model of hypothalamic-driven late-onset obesity.

Mice with gene-targeted deletion of Kv1.3, a voltage-gated potassium channel of the Shaker family, are thin and do not gain weight when challenged with a moderately high-fat diet. Kv1.3 has been shown to modulate glucose uptake in white adipose tissue and be expressed by mitochondria. Kv1.3 is also expressed in brain regions important for feeding and metabolism such as the hypothalamus and olfactory bulb, where its activity is modulated by insulin. To address hypothalamic Kv1.3 contribution, we generated doubly homozygous MC4R/Kv1.3-null mice (mmkk) to ascertain if deletion of Kv1.3 channel protein could abrogate weight gain in a model of hypothalamic obesity. At 9 months, mmkk mice weighed 18% less than MC4R-null mice. This phenomenon began to emerge around postnatal day 60 (P60) at which point there is lower visceral and subcutaneous fat pad deposition in the mmkk mice with no change in nose to anus length. To characterize the onset of the reduced adiposity phenotype, locomotor activity, mass-specific metabolic rate ( V O2 ), and ingestive behaviors were monitored in P60–P75 mice. These experiments revealed no differences in ingestive behaviors but locomotor activity (66% in females, 50% in males) and V O2 (21% in females, 12% in males) were increased in mmkk mice above that of MC4R-null mice. These results indicate Kv1.3 deletion reduces fat deposition and total body weight in a model of hypothalamic-driven, late-onset obesity possibly through increased locomotor activity and V O2 . This work was supported by: NIH DC 003387 and DC 00044, and FSU CRC Competitive Planning Grant.

Themahoganoidmutation (Mgrn1md)improves insulin sensitivity in mice with mutations in the melanocortin signaling pathway independently of effects on adiposity

Mahoganoid (Mgrn1(md)) is a mutation of the mahogunin (Mgrn1) gene. The hypomorphic allele suppresses the yellow pigmentation and obesity of the A(y) mouse that ubiquitously overexpresses agouti signaling protein (ASP). To assess the physiological effects of MGRN1 on energy and glucose homeostasis, we generated animals doubly mutant for Mgrn1(md) and A(y), Lep(ob), or a null allele of Mc4r, and diet-induced obesity (DIO) mice segregating for Mgrn1(md). Mgrn1(md) suppressed the obesity, hyperglycemia, and hyperinsulinemia of A(y) mice. Mgrn1(md) suppressed A(y)-induced obesity by reducing food intake, and reduced adiposity in Lep(ob)/Lep(ob) females, but did not alter the body weight or body composition of mice fed a high-fat diet. There was no effect of Mgrn1(md) on weight gain, body composition, energy intake, or energy expenditure in Mc4r-null animals. Mgrn1(md) reduced circulating insulin concentrations in DIO, A(y), and Mc4r-null but not Lep(ob)/Lep(ob) mice. The effect of Mgrn1(md) on circulating insulin concentrations was not due primarily to reductions in fat mass, since the plasma insulin concentrations of Mgrn1(md) mice segregating for either A(y) or Mc4r-null alleles, adjusted for fat mass and plasma glucose, were reduced compared with A(y) and Mc4r mice, respectively. The effect of Mgrn1(md) on insulin sensitivity of Mc4r-null mice suggests that Mgrn1(md) may be increasing insulin sensitivity via the hypothalamic melanocortin-3 receptor pathway.

Divergence of Melanocortin Pathways in the Control of Food Intake and Energy Expenditure

Activation of melanocortin-4-receptors (MC4Rs) reduces body fat stores by decreasing food intake and increasing energy expenditure. MC4Rs are expressed in multiple CNS sites, any number of which could mediate these effects. To identify the functionally relevant sites of MC4R expression, we generated a loxP-modified, null Mc4r allele (loxTB Mc4r) that can be reactivated by Cre-recombinase. Mice homozygous for the loxTB Mc4r allele do not express MC4Rs and are markedly obese. Restoration of MC4R expression in the paraventricular hypothalamus (PVH) and a subpopulation of amygdala neurons, using Sim1-Cre transgenic mice, prevented 60% of the obesity. Of note, increased food intake, typical of Mc4r null mice, was completely rescued while reduced energy expenditure was unaffected. These findings demonstrate that MC4Rs in the PVH and/or the amygdala control food intake but that MC4Rs elsewhere control energy expenditure. Disassociation of food intake and energy expenditure reveals unexpected divergence in melanocortin pathways controlling energy balance.

Melanocortin-4 receptor-null mice display normal affective licking responses to prototypical taste stimuli in a brief-access test

We tested whether MC4R null mice display altered gustatory function relative to wild-type controls that may contribute to the characteristic hyperphagia and obesity associated with this gene deletion. Mice were tested for their licking responses to prototypical taste solutions (sucrose, NaCl, quinine, citric acid) in series of daily 30-min sessions in which a range of concentrations of each tastant was available in randomized blocks of 5-s trials. Notwithstanding some minor deviations, the concentration-response functions of the MC4R null and wild-type mice were basically the same for all of the prototypical compounds tested here. Thus, taste-based appetitive and avoidance behavior is expressed in the absence of the MC4 receptor, demonstrating that this critical component in the melanocortin system is not required for normal affective gustatory function to be maintained.

A metabolic defect promotes obesity in mice lacking melanocortin-4 receptors.

Melanocortin-4 receptor (Mc4r)-null mice exhibit late-onset obesity. To determine whether aberrant metabolism contributes to the obesity, food consumption by Mc4r-null mice was restricted to (pair-fed to) that consumed by wild-type (WT) mice. Pair-fed Mc4r-null females maintained body weights intermediate to that of WT and nonpair-fed Mc4r-null females, whereas pairfeeding normalized the body weights of Mc4r-null male mice. Fat pad and circulating leptin levels were elevated in both male and female pair-fed Mc4r-null mice compared with WT mice. Oxygen consumption of Mc4r-null mice with similar body weights as WT controls was reduced by 20%. Locomotor activity of young nonobese Mc4r-null males was significantly lower than that of WT males; however, locomotion of young nonobese females was normal. Core body temperature of Mc4r-null mice was normal, and they responded normally to cold exposure. Young nonobese Mc4r-null females were unable to induce uncoupling protein 1 (UCP1) in brown adipose tissue in response to peripheral leptin administration, whereas UCP1 mRNA was increased by 60% in the WT females. These results indicate that Mc4r deficiency enhances caloric efficiency, similar to that seen in the agouti obesity syndrome and in melanocortin-3 receptor-null mice.