The Yellow Agouti Mutation Alters Some But Not All Responses to Diet and Exercise

Objective: Effects of ectopic expression of the agouti signaling protein were studied on responses to diet restriction and exercise in C57BL/6J (B6) mice and obese B6 mice congenic for the yellow agouti mutation [B6.Cg‐A^y (A^y)]. Research Methods and Procedures: Adult male A^y mice were either kept sedentary or exercised on a running wheel and fed ad libitum or diet restricted until weight matched to ad libitum‐fed B6 control mice. Body composition, plasma lipids, leptin, and adiponectin were measured. mRNA levels for leptin, adiponectin, lipoprotein lipase, and pyruvate dehydrogenase kinase 4 were measured in a visceral (epididymal) and a subcutaneous (femoral) fat depot by real‐time polymerase chain reaction. Results: Correlations among traits exhibited one of three patterns: similar lines for B6 and A^y mice, different slopes for B6 and A^y mice, and/or different intercepts for B6 and A^y mice. Correlations involving plasma leptin, mesenteric and epididymal adipose weights, or low‐density lipoprotein‐cholesterol were most likely to have different slopes and/or intercepts in B6 and A^y mice. mRNA levels for leptin, Acrp30, pyruvate dehydrogenase kinase 4, and lipoprotein lipase in epididymal adipose tissue were not correlated with corresponding levels in femoral adipose tissue. Discussion: The agouti protein interferes with leptin signaling at melanocortin receptors in the hypothalamus of A^y mice. Our results are consistent with the hypothesis that the melanocortin portion of the leptin‐signaling pathway mediates effects primarily on certain fat depots and on some, but not all, components of cholesterol homeostasis.     

Agouti-Related Maturation and Tissue Distribution of oc-Melanocyte Stimulating Hormone in Wild-Type (AwJ/AwJ) and Mutant (Ay/a,a/a) Mice

Because of ectopic overproduction of agouti protein, yellow alleles (A^y and A^vy) of the murine agouti gene may secondarily modulate the synthesis, maturation (i.e., acetylation), and/or tissue deployment of α-Melanocyte Stimulating Hormone (MSH). We used HPLC to test the hypothesis that A^y/a mice exhibit altered concentrations of desacetyl-, monoacetyl-, and diacetyl-α-MSH in pituitaries, sera, and telogen hair bulbs when compared to black (a/a) mice. We also used RIA to measure total MSH in those same tissues of A^y/a, a/a, and white-bellied agouti (A^wJ/A^wJ) mice (Strain C57BL/6J). We found no evidence that A^y/a mice possessed an imbalance of des-, mono-, and diacetylated α-MSH species. However, radioimmunoassay (RIA) analyses of total MSH suggest that wild-type agouti mice (A^wJ/A^wJ) exhibited significantly decreased (P < 0.05) tissue levels of total α-MSH in pituitaries, sera, and regenerating hair bulbs when compared to those of mutant A^y/a and a/a mice.     

The Yellow Mouse Obesity Syndrome and Mechanisms of Agouti-Induced Obesity

The yellow mouse obesity syndrome is due to dominant mutations at the Agouti locus, which is characterized by obesity, hyperinsulinemia, insulin resistance, hyperglycemia, hyperleptinemia, increased linear growth, and yellow coat color. This syndrome is caused by ectopic expression of Agouti in multiple tissues. Mechanisms of Agouti action in obesity seem to involve, at least in part, competitive melanocortin antagonism. Both central and peripheral effects have been implicated in Agouti-induced obesity. An Agouti-Related Protein (AGRP) has been described recently. It has been shown to be expressed in mice hypothalamus and to act similarly to agouti as a potent antagonist to central melanocortin receptor MC4-R, suggesting that AGRP is an endogenous MC4-R ligand. Mice lacking MC4-R become hyperphagic and develop obesity, implying that agouti may lead to obesity by interfering with MC4-R signaling in the brain and consequently regulating food intake. Furthermore, food intake is inhibited by intracerebro-ventricular injection of a potent melanocortin agonist and was reversed by administration of an MC4-R antagonist. The direct cellular actions of Agouti include stimulation of fatty acid and triglyceride synthesis via a Ca²⁺-dependent mechanism. Agouti and insulin act in an additive manner to increase lipogenesis. This additive effect of agouti and insulin is demonstrated by the necessity of insulin in eliciting weight gain in transgenic mice expressing agouti specifically in adipose tissue. This suggests that agouti expression in adipose tissue combined with hyperinsulinemia may lead to increased adiposity. The roles of melanocortin receptors or agouti-specific receptor(s) in agouti regulation of adipocyte metabolism and other peripheral effects remain to be determined. In conclusion, both central and peripheral actions of agouti contribute to the yellow mouse obesity syndrome and this action is mediated at least in part by antagonism with melanocortin receptors and/or regulation of intracellular calcium.     

Mechanisms mediating renal sympathetic activation to leptin in obesity

Leptin plays a critical role in the control of energy homeostasis. The sympathetic cardiovascular actions of leptin have emerged as a potential link between obesity and hypertension. We previously demonstrated that in mice, modest obesity induced by 10 wk of a high-fat diet is associated with preservation of leptin ability to increase renal sympathetic nerve activity (SNA) despite the resistance to the metabolic effects of leptin. Here, we examined whether selective leptin resistance exists in mice with late-stage diet-induced obesity (DIO) produced by 20 wk of a high-fat diet. The decrease in food intake and body weight induced by intraperitoneal or intracerebroventricular injection of leptin was significantly attenuated in the DIO mice. Regional SNA responses to intravenous leptin were also attenuated in DIO mice. In contrast, intracerebroventricularly administered leptin caused contrasting effects on regional SNA in DIO mice. Renal SNA response to intracerebroventricular leptin was preserved, whereas lumbar and brown adipose tissue SNA responses were attenuated. Intact renal SNA response to leptin combined with the increased cerebrospinal fluid leptin levels in DIO mice represents a potential mechanism for the adverse cardiovascular consequences of obesity. Lastly, we examined the role of phosphoinositol-3 kinase (PI3K) and melanocortin receptors (MCR) in mediating the preserved renal SNA response to leptin in obesity. Presence of PI3K inhibitor (LY294002) or MC3/4R antagonist (SHU9119) significantly attenuated the renal SNA response to leptin in DIO and agouti obese mice. Our results demonstrate the importance of PI3K and melanocortin receptors in the transduction of leptin-induced renal sympathetic activation in obesity.     

Ghrelin-induced food intake and growth hormone secretion are altered in melanocortin 3 and 4 receptor knockout mice

Ghrelin stimulates food intake in part by activating hypothalamic neuropeptide Y (NPY) neurons/agouti related peptide (AGRP) neurons. We investigated the role of AGRP/melanocortin signaling in ghrelin-induced food intake by studying melanocortin 3 and 4 receptor knockout (MC3R KO and MC4R KO) mice. We also determined whether reduced ghrelin levels and/or an altered sensitivity to the GH-stimulating effects of ghrelin accompany the obesity syndromes of MC3R KO and MC4R KO mice. Compared to wild-type (WT) mice, the effects of ghrelin on food intake were reduced in MC3R KO and MC4R KO mice and circulating ghrelin levels were reduced in female MC4R KO mice. Female MC3R KO and MC4R KO mice exhibited a diminished responsiveness to the GH-releasing effects of ghrelin. Thus, deletion of the MC3R or MC4R results in a decreased sensitivity to ghrelin and verifies the involvement in the melanocortin system in ghrelin-induced food intake.     

Interactions of α-Melanotropin and Agouti on B16 Melanoma Cells: Evidence for Inverse Agonism of Agouti

Abstract

α-Melanocyte-stimulating hormone (α-MSH, α-melanotropin) and agouti control the switch between eumelanin and pheomelanin synthesis in mammalian melanocytes. Here we investigated interactions between α-MSH, agouti protein, cAMP elevating agents and phorbol ester on mouse B16 melanoma cells. Agouti (K_d 3.7nmol/l) and α-MSH (K_d 2.3 nmol/l) had similar affinities to the MC1 melanocortin receptor. Both α-MSH and agouti induced MC1 receptor down-regulation. Agouti antagonized melanogenesis induced by α-MSH, forskolin, cholera toxin (CT), and pertussis toxin (PT). It also reduced the constitutive melanin formation of long-term cultures. Cell proliferation was inhibited by agouti (43% at 100 nM). This effect was reversed by α-MSH, forskolin, or CT. B16-G4F cells, a cell variant that lacks the MC1 receptor, did not respond to agouti. From these results we conclude that agouti shows the characteristics of an inverse agonist acting through the MC1 receptor.     

The Leptin,Dopamine and Serotonin Receptors in Hypothalamic POMC-Neurons of Normal and Obese Rodents

The pro-opiomelanocortin (POMC)-expressing neurons of the hypothalamic arcuate nucleus (ARC) are involved in the control of food intake and metabolic processes. It is assumed that, in addition to leptin, the activity of these neurons is regulated by serotonin and dopamine, but only subtype 2C serotonin receptors (5-HT_2CR) was identified earlier on the POMC-neurons. The aim of this work was a comparative study of the localization and number of leptin receptors (LepR), types 1 and 2 dopamine receptors (D₁R, D₂R), 5-HT_1BR and 5-HT_2CR on the POMC-neurons and the expression of the genes encoding them in the ARC of the normal and diet-induced obese (DIO) rodents and the agouti mice (A ^y /a) with the melanocortin obesity. As shown by immunohistochemistry (IHC), all the studied receptors were located on the POMC-immunopositive neurons, and their IHC-content was in agreement with the expression of their genes. In DIO rats the number of D₁R and D₂R in the POMC-neurons and their expression in the ARC were reduced. In DIO mice the number of D₁R and D₂R did not change, while the number of LepR and 5-HT_2CR was increased, although to a small extent. In the POMC-neurons of agouti mice the number of LepR, D₂R, 5-HT_1BR and 5-HT_2CR was increased, and the D₁R number was reduced. Thus, our data demonstrates for the first time the localization of different types of the serotonin and dopamine receptors on the POMC-neurons and a specific pattern of the changes of their number and expression in the DIO and melanocortin obesity.     

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.     

The Asp298Asn polymorphism of melanocortin-4 receptor (MC4R) in pigs: evidence for its potential effects on MC4R constitutive activity and cell surface expression

In humans and mice, melanocortin receptor 4 (MC4R) and melanocortin receptor accessory protein 2 (MRAP2) can form a complex and control energy balance, thus regulating body weight and obesity. In pigs, a missense variant (p.Asp298Asn) of MC4R has been suggested to be associated with growth and fatness; however, the effect of Asp298Asn substitution on MC4R function is controversial, limiting its application in animal breeding. Here we examined the effect of this polymorphism on MC4R constitutive activity, cell surface expression and signaling, and its interaction with MRAP2 in pigs. We found that: (i) both pig MC4R^Asp and MC4R^Asn can be activated by its ligands (α-MSH and ACTH) and stimulate cAMP/PKA signaling pathway, as detected by pGL3–CRE–luciferase reporter assay, indicating that, like pMC4R^Asp, pMC4R^Asn is coupled to the cAMP/PKA signaling pathway; (ii) compared with pMC4R^Asp, pMC4R^Asn loses the basal constitutive activity and shows a decreased surface expression, as detected by dual-luciferase reporter assay and Nano-HiBiT system; (iii) as in other vertebrates, both pMC4R^Asp and pMC4R^Asn can interact with pMRAP2, thus decreasing receptor surface expression and enhancing ligand sensitivity, although, in contrast to pMC4R^Asp, the basal constitutive activity of pMC4R^Asn cannot be affected by pMRAP2; and (iv) RNA-seq data analysis revealed a co-expression of MC4R and MRAP2 in pig hypothalamus. Taken together, our data provide convincing evidence that Asp298Asn substitution decreases the constitutive activity and cell surface expression of MC4R or MC4R–MRAP2 complex, which may affect energy balance and be a valuable selection marker for breeding programs in pigs.     

Hemodynamic actions and mechanisms of systemically administered α-MSH analogs in mice

α-Melanocyte-stimulating hormone (α-MSH) regulates important physiological functions including energy homeostasis and inflammation. Potent analogs of α-MSH, [Nle⁴, d-Phe⁷]-α-MSH (NDP-α-MSH) and melanotan-II (MT-II), are widely used in pharmacological studies, but the hemodynamic effects associated with their systemic administration have not been thoroughly examined. Therefore, we investigated the hemodynamic actions of these compounds in anesthetized and conscious C57Bl/6N mice using peripheral routes of administration. NDP-α-MSH and MT-II induced mild changes in blood pressure and heart rate in anesthetized mice compared to the effects observed in conscious mice, suggesting that anesthesia distorts the hemodynamic actions of α-MSH analogs. In conscious mice, NDP-α-MSH and MT-II increased blood pressure and heart rate in a dose-dependent manner, but the tachycardic effect was more prominent than the pressor effect. Pretreatment with the melanocortin (MC) 3/4 receptor antagonist SHU9119 abolished these hemodynamic effects. Furthermore, the blockade of β₁-adrenoceptors with metoprolol prevented the pressor effect and partly the tachycardic action of α-MSH analogs, while the ganglionic blocker hexamethonium abrogated completely the difference in heart rate between vehicle and α-MSH treatments. These findings suggest that the pressor effect is primarily caused by augmentation of cardiac sympathetic activity, but the tachycardic effect seems to involve withdrawal of vagal tone in addition to sympathetic activation. In conclusion, the present results indicate that systemic administration of α-MSH analogs elevates blood pressure and heart rate via activation of MC_3/4 receptor pathways. These effects and the consequent increase in cardiac workload should be taken into account when using α-MSH analogs via peripheral routes of administration.     

An intrinsic gut leptin-melanocortin pathway modulates intestinal microsomal triglyceride transfer protein and lipid absorption

Fat is delivered to tissues by apoB-containing lipoproteins synthesized in the liver and intestine with the help of an intracellular chaperone, microsomal triglyceride transfer protein (MTP). Leptin, a hormone secreted by adipose tissue, acts in the brain and on peripheral tissues to regulate fat storage and metabolism. Our aim was to identify the role of leptin signaling in MTP regulation and lipid absorption using several mouse models deficient in leptin receptor (LEPR) signaling and downstream effectors. Mice with spontaneous LEPR B mutations or targeted ablation of LEPR B in proopiomelanocortin (POMC) or agouti gene related peptide (AGRP) expressing cells had increased triglyceride in plasma, liver, and intestine. Furthermore, melanocortin 4 receptor (MC4R) knockout mice expressed a similar triglyceride phenotype, suggesting that leptin might regulate intestinal MTP expression through the melanocortin pathway. Mechanistic studies revealed that the accumulation of triglyceride in the intestine might be secondary to decreased expression of MTP and lipid absorption in these mice. Surgical and chemical blockade of vagal efferent outflow to the intestine in wild-type mice failed to alter the triglyceride phenotype, demonstrating that central neural control mechanisms were likely not involved in the observed regulation of intestinal MTP. Instead, we found that enterocytes express LEPR, POMC, AGRP, and MC4R. We propose that a peripheral, local gut signaling mechanism involving LEPR B and MC4R regulates intestinal MTP and controls intestinal lipid absorption.     

Coupled Site-Directed Mutagenesis/Transgenesis Identifies Important Functional Domains of the Mouse Agouti Protein

The agouti locus encodes a novel paracrine signaling molecule containing a signal sequence, an N-linked glycosylation site, a central lysine-rich basic domain, and a C-terminal tail containing 10 cysteine (Cys) residues capable of forming five disulfide bonds. When overexpressed, agouti causes a number of pleiotropic effects including yellow coat and adult-onset obesity. Numerous studies suggest that agouti causes yellow coat color by antagonizing the binding of α-melanocyte-stimulating hormone (α-MSH) to the α-MSH-(melanocortin-1) receptor. With the goal of identifying functional domains of agouti important for its diverse biological activities, we have generated 14 agouti mutations by in vitro site-directed mutagenesis and analyzed these mutations in transgenic mice for their effects on coat color and obesity. These studies demonstrate that the signal sequence, the N-linked glycosylation site, and the C-terminal Cys residues are important for full biological activity, while at least a portion of the lysine-rich basic domain is dispensable for normal function. They also show that the same functional domains of agouti important in coat color determination are important for inducing obesity, consistent with the hypothesis that agouti induces obesity by antagonizing melanocortin binding to other melanocortin receptors.     

INTERACTION OF MELANIN-CONCENTRATING HORMONE (MCH), NEUROPEPTIDE E-I (NEI), NEUROPEPTIDE G-E (NGE), AND α-MSH WITH MELANOCORTIN AND MCH RECEPTORS ON MOUSE B16 MELANOMA CELLS

Melanin-concentrating hormone (MCH) and α-melanocyte-stimulating hormone (α-MSH) are known to exhibit mostly functionally antagonistic, but in some cases agonistic activities, e.g., in pigment cells and in the brain. Neuropeptide E-I (NEI) displays functional MCH-antagonist and MSH-agonist activity in different behavioral paradigms; the role of neuropeptide G-E (NGE) is not known. This study addressed the question of possible molecular interactions between α-MSH, MCH and the MCH-precursor-derived peptides NEI and NGE at the level of the pigment cell MCH receptor subtype (MCH-R_pc) and the different melanocortin (MC) receptors. Radioreceptor assays using [¹²⁵I]MCH, [¹²⁵I]α-MSH and [¹²⁵I]NEI as radioligands and bioassays were performed with MC1-R-positive and MC1-R-negative mouse B16 melanoma cells and with COS cells expressing the different MC receptors. The IC₅₀s of α-MSH and NEI or NGE for [¹²⁵I]MCH displacement from mouse MCH-R_pc were 80-fold and, respectively, > 300-fold higher than that of MCH, and the IC₅₀s for MCH and NEI or NGE for [¹²⁵I]α-MSH displacement from mouse MC1-R were 50,000-fold and > 200,000-fold higher than that of α-MSH. No high-affinity binding sites for NEI were detected on B16 melanoma cells and there was no significant displacement of [¹²⁵I]α-MSH by MCH, NEI or NGE with MC3-R, MC4-R and MC5-R expressed in COS cells. At concentrations of 100 nM to 10 μM, however, MCH, NEI and NGE induced cAMP formation and melanin synthesis which could be blocked by agouti protein or inhibitors of adenylate cyclase or protein kinase A. This shows that mammalian MCH-precursor-derived peptides may mimic MSH signalling via MC1-R activation at relatively high, but physiologically still relevant concentrations, as e.g. found in autocrine/paracrine signalling mechanisms.     

Melanocortin receptors in rat liver cells: change of gene expression and intracellular localization during acute-phase response

MCRs are known to be expressed predominantly in the brain where they mediate metabolic and anti-inflammatory functions. Leptin plays an important role in appetite and energy regulation via signaling through melanocortin receptors (MCRs) in the brain. As serum levels of MCR ligands are elevated in a clinical situation [acute-phase response (APR)] to tissue damage, where the liver is responsible for the metabolic changes, we studied hepatic gene expression of MCRs in a model of muscle tissue damage induced by turpentine oil (TO) injection in rats. A significant increase in gene expression of all five MCRs (MC4R was the highest) in liver at the RNA and protein level was detected after TO injection. A similar pattern of increase was also found in the brain. Immunohistology showed MC4R in the cytoplasm, but also in the nucleus of parenchymal and non-parenchymal liver cells, whereas MC3R-positivity was mainly cytoplasmic. A time-dependent migration of MC4R protein from the cytoplasm into the nucleus was observed during APR, in parallel with an increase in α-MSH and leptin serum levels. An increase of MC4R was detected at the protein level in wild-type mice, while such an increase was not observed in IL-6ko mice during APR. Moreover, treatment of isolated liver cells with melanocortin agonists (α-MSH and THIQ) inhibited the endotoxin-induced upregulation of the acute-phase cytokine (IL-6, IL1β and TNF-α) gene expression in Kupffer cells and of chemokine gene expression in hepatocytes. MCRs are expressed not only in the brain, but also in liver cells and their gene expression in liver and brain tissue is upregulated during APR. Due to the presence of specific ligands in the serum, they may mediate metabolic changes and exert a protective effect on liver cells.     

The effects of melanocortin agonists and antagonists on leptin-induced fever in rats

1. Over three experiments, separate groups of adult male Sprague–Dawley rats received intracerebroventricular (ICV) injections of either vehicle, recombinant rat leptin (1 μg), or leptin (4 μg), then two ICV injections, 30 min apart of vehicle/vehicle, leptin (4 μg)/vehicle, vehicle/α-MSH (300 ng), or leptin/α-MSH, and then vehicle/vehicle, leptin (4 μg)/vehicle, vehicle/ SHU-9119 (200 ng; a MC 3/4 receptor antagonist), or leptin/SHU-9119. Core temperatures (T_c), food intake and body weights were monitored.

2. Four microgram leptin resulted in the induction of fever, an effect blocked by injection of α-MSH. Antagonism of MC 3/4 receptors with SHU-9119 did not augment leptin-induced fever, but did block the inhibitory actions of leptin on food intake.

3. These data demonstrate the inhibitory effects of exogenous α-MSH on leptin-induced fever, but suggest that endogenous melanocortin action at MC 3/4 receptors does not tonically inhibit febrigenesis caused by leptin administration.

Genetics of obesity in KK mouse and effects of A y allele on quantitative regulation

KK mouse is known as a polygenic model for non-insulin-dependent diabetes mellitus with moderate obesity. To identify the quantitative trait loci (QTLs) responsible for the body weight in KK, linkage analysis with 97 microsatellite markers was carried out into 192 F₂ progeny, comprising 93 mice with a/a genotype at agouti locus and 99 mice with A ^y /a genotype, of a cross between C57BL/6J female and KK-A^y (A^y congenic) male, thereby the influence of A ^y allele on the quantitative regulation of body weight was also examined. In F₂ a/a mice, we identified a QTL on Chromosome (Chr) 4, and two loci with suggestive linkage on Chrs 15 and 18. In F₂ A ^y /a mice, a QTL was identified on Chr 6, and two loci with suggestive linkage were identified on Chrs 4 and 16. That the QTL on Chr 4 was held in common between F₂ a/a and F₂ A ^y /a progenies implies that this locus may be a primary component regulating body weight in KK and KK-A^y. These results suggest that the body weight in KK is controlled by multiple genes, and the different combination of loci is involved in the presence of A ^y allele. The QTL on Chr 6 seemed to determine the body weight by controlling fat deposition, because the linkage was identified on body weight and adiposity, and is suggested to be a component involved in the metabolic pathway in obesity caused by the A ^y allele. Received: 16 December 1997 / Accepted: 16 March 1998