Genetic deletion of MT1 and MT2 melatonin receptors differentially abrogates the development and expression of methamphetamine‐induced locomotor sensitization during the day and the night in C3H/HeN mice

Abstract: This study explored the role of the melatonin receptors in methamphetamine (METH)‐induced locomotor sensitization during the light and dark phases in C3H/HeN mice with genetic deletion of the MT₁ and/or MT₂ melatonin receptors. Six daily treatments with METH (1.2 mg/kg, i.p.) in a novel environment during the light phase led to the development of locomotor sensitization in wild‐type (WT), MT₁KO and MT₂KO mice. Following four full days of abstinence, METH challenge (1.2 mg/kg, i.p.) triggered the expression of locomotor sensitization in METH‐pretreated but not in vehicle (VEH)‐pretreated mice. In MT₁/MT₂KO mice, the development of sensitization during the light phase was significantly reduced and the expression of sensitization was completely abrogated upon METH challenge. During the dark phase the development of locomotor sensitization in METH‐pretreated WT, MT₁KO and MT₂KO mice was statistically different from VEH‐treated controls. However, WT and MT₂KO, but not MT₁KO mice receiving repeated VEH pretreatments during the dark phase expressed a sensitized response to METH challenge that is of an identical magnitude to that observed upon 6 days of METH pretreatment. We conclude that exposure to a novel environment during the dark phase, but not during the light phase, facilitated the expression of sensitization to a METH challenge in a manner dependent on MT₁ melatonin receptor activation by endogenous melatonin. We suggest that MT₁ and MT₂ melatonin receptors are potential targets for pharmacotherapeutic intervention in METH abusers.     

Detection of recombinant and endogenous mouse melatonin receptors by monoclonal antibodies targeting the C‐terminal domain

Melatonin receptors play important roles in the regulation of circadian and seasonal rhythms, sleep, retinal functions, the immune system, depression, and type 2 diabetes development. Melatonin receptors are approved drug targets for insomnia, non‐24‐hour sleep‐wake disorders, and major depressive disorders. In mammals, two melatonin receptors (MTRs) exist, MT₁ and MT₂, belonging to the G protein‐coupled receptor (GPCR) superfamily. Similar to most other GPCRs, reliable antibodies recognizing melatonin receptors proved to be difficult to obtain. Here, we describe the development of the first monoclonal antibodies (mABs) for mouse MT₁ and MT₂. Purified antibodies were extensively characterized for specific reactivity with mouse, rat, and human MT₁ and MT₂ by Western blot, immunoprecipitation, immunofluorescence, and proximity ligation assay. Several mABs were specific for either mouse MT₁ or MT₂. None of the mABs cross‐reacted with rat MTRs, and some were able to react with human MTRs. The specificity of the selected mABs was validated by immunofluorescence microscopy in three established locations (retina, suprachiasmatic nuclei, pituitary gland) for MTR expression in mice using MTR‐KO mice as control. MT₂ expression was not detected in mouse insulinoma MIN6 cells or pancreatic beta‐cells. Collectively, we report the first monoclonal antibodies recognizing recombinant and native mouse melatonin receptors that will be valuable tools for future studies.     

Melatonin‐mediated inhibition of Purkinje neuron P‐type Ca2+ channels in vitro induces neuronal hyperexcitability through the phosphatidylinositol 3‐kinase‐dependent protein kinase C delta pathway

Although melatonin receptors are widely expressed in the mammalian central nervous system and peripheral tissues, there are limited data regarding the functions of melatonin in cerebellar Purkinje cells. Here, we identified a novel functional role of melatonin in modulating P‐type Ca²⁺ channels and action‐potential firing in rat Purkinje neurons. Melatonin at 0.1 μm reversibly decreased peak currents (I_Ba) by 32.9%. This effect was melatonin receptor 1 (MT_R1) dependent and was associated with a hyperpolarizing shift in the voltage dependence of inactivation. Pertussis toxin pretreatment, intracellular application of QEHA peptide, and a selective antibody raised against the G_β subunit prevented the inhibitory effects of melatonin. Pretreatment with phosphatidylinositol 3‐kinase (PI3K) inhibitors abolished the melatonin‐induced decrease in I_Ba. Surprisingly, melatonin responses were not regulated by Akt, a common downstream target of PI3K. Melatonin treatment significantly increased protein kinase C (PKC) activity 2.1‐fold. Antagonists of PKC, but not of protein kinase A, abolished the melatonin‐induced decrease in I_Ba. Melatonin application increased the membrane abundance of PKC_δ, and PKC_δ inhibition (either pharmacologically or genetically) abolished the melatonin‐induced I_Ba response. Functionally, melatonin increased spontaneous action‐potential firing by 53.0%; knockdown of MT_R1 and blockade of P‐type channels abolished this effect. Thus, our results suggest that melatonin inhibits P‐type channels through MT_R1 activation, which is coupled sequentially to the βγ subunits of G_i/o‐protein and to downstream PI3K‐dependent PKC_δ signaling. This likely contributes to its physiological functions, including spontaneous firing of cerebellar Purkinje neurons.     

Molecular and cellular pharmacological properties of 5‐methoxycarbonylamino‐N‐acetyltryptamine (MCA‐NAT): a nonspecific MT3 ligand

Abstract: 5‐Methoxycarbonylamino‐N‐acetyltryptamine (MCA‐NAT) has been initially described as a ligand at non MT₁, non MT₂ melatonin binding site (MT3) selective versus MT₁ and MT₂, two membrane melatonin receptors. MCA‐NAT activity has been reported by others in different models, in vivo, particularly in the intra‐ocular pressure (IOP) models in rabbits and monkeys. Its activity was systematically linked to either MT3 or to a new, yet unknown, melatonin receptor. In this article, the melatonin receptor pharmacology of MCA‐NAT is described. MCA‐NAT has micromolar range affinities at the melatonin receptors MT₁ and MT₂, while in functional studies, MCA‐NAT proved to be a powerful MT₁/MT₂ partial agonist in the sub‐micromolar range. These data strongly suggest that MCA‐NAT actions might be mediated by these receptors in vivo. Finally, as described by others, we show that MCA‐NAT is unable to elicit any type of receptor‐like functional responses from Chinese hamster ovary cells over‐expressing quinone reductase 2, the MT3.     

Melatonin enhances the human mesenchymal stem cells motility via melatonin receptor 2 coupling with Gαq in skin wound healing

Melatonin, a circadian rhythm–promoting molecule, has a variety of biological functions, but the functional role of melatonin in the motility of mesenchymal stem cells (MSCs) has yet to be studied. In a mouse skin excisional wound model, we found that transplantation of umbilical cord blood (UCB)‐MSCs pretreated with melatonin enhanced wound closure, granulation, and re‐epithelialization at mouse skin wound sites, where relatively more UCB‐MSCs which were engrafted onto the wound site were detected. Thus, we identified the signaling pathway of melatonin, which affects the motility of UCB‐MSCs. Melatonin (1 μm ) significantly increased the motility of UCB‐MSCs, which had been inhibited by the knockdown of melatonin receptor 2 (MT₂). We found that Gαq coupled with MT₂ and that the binding of Gαq to MT₂ uniquely stimulated an atypical PKC isoform, PKCζ. Melatonin induced the phosphorylation of FAK and paxillin, which were concurrently downregulated by blocking of the PKC activity. Melatonin increased the levels of active Cdc42 and Arp2/3, and it has the ability to stimulate cytoskeletal reorganization‐related proteins such as profilin‐1, cofilin‐1, and F‐actin in UCB‐MSCs. Finally, a lack of MT₂ expression in UCB‐MSCs during a mouse skin transplantation experiment resulted in impaired wound healing and less engraftment of stem cells at the wound site. These results demonstrate that melatonin signaling via MT₂ triggers FAK/paxillin phosphorylation to stimulate reorganization of the actin cytoskeleton, which is responsible for Cdc42/Arp2/3 activation to promote UCB‐MSCs motility.     

Melatonin‐mediated inhibition of Cav3.2 T‐type Ca2+ channels induces sensory neuronal hypoexcitability through the novel protein kinase C‐eta isoform

Recent studies implicate melatonin in the antinociceptive activity of sensory neurons. However, the underlying mechanisms are still largely unknown. Here, we identify a critical role of melatonin in functionally regulating Cav3.2 T‐type Ca²⁺ channels (T‐type channel) in trigeminal ganglion (TG) neurons. Melatonin inhibited T‐type channels in small TG neurons via the melatonin receptor 2 (MT₂ receptor) and a pertussis toxin‐sensitive G‐protein pathway. Immunoprecipitation analyses revealed that the intracellular subunit of the MT₂ receptor coprecipitated with Gα_o. Both shRNA‐mediated knockdown of Gα_o and intracellular application of QEHA peptide abolished the inhibitory effects of melatonin. Protein kinase C (PKC) antagonists abolished the melatonin‐induced T‐type channel response, whereas inhibition of conventional PKC isoforms elicited no effect. Furthermore, application of melatonin increased membrane abundance of PKC‐eta (PKC_η) while antagonism of PKC_η or shRNA targeting PKC_η prevented the melatonin‐mediated effects. In a heterologous expression system, activation of MT₂ receptor strongly inhibited Cav3.2 T‐type channel currents but had no effect on Cav3.1 and Cav3.3 current amplitudes. The selective Cav3.2 response was PKC_η dependent and was accompanied by a negative shift in the steady‐state inactivation curve. Furthermore, melatonin decreased the action potential firing rate of small TG neurons and attenuated the mechanical hypersensitivity in a mouse model of complete Freund's adjuvant‐induced inflammatory pain. These actions were inhibited by T‐type channel blockade. Together, our results demonstrated that melatonin inhibits Cav3.2 T‐type channel activity through the MT₂ receptor coupled to novel G_βγ‐mediated PKC_η signaling, subsequently decreasing the membrane excitability of TG neurons and pain hypersensitivity in mice.     

Melatonin ameliorates amyloid beta‐induced memory deficits,tau hyperphosphorylation and neurodegeneration via PI3/Akt/GSk3β pathway in the mouse hippocampus

Alzheimer's disease (AD) is the most prevalent age‐related neurodegenerative disease, pathologically characterized by the accumulation of amyloid beta (Aβ) aggregation in the brain, and is considered to be the primary cause of cognitive dysfunction. Aβ aggregates lead to synaptic disorder, tau hyperphosphorylation, and neurodegeneration. In this study, the underlying neuroprotective mechanism of melatonin against Aβ_1‐42‐induced neurotoxicity was investigated in the mice hippocampus. Intracerebroventricular (i.c.v.) Aβ_1‐42‐injection triggered memory impairment, synaptic disorder, hyperphosphorylation of tau protein, and neurodegeneration in the mice hippocampus. After 24 hr of Aβ_1‐42 injection, the mice were treated with melatonin (10 mg/kg, intraperitonially) for 3 wks, reversed the Aβ_1‐42‐induced synaptic disorder via increasing the level of presyanptic (Synaptophysin and SNAP‐25) and postsynaptic protein [PSD95, p‐GluR1 (Ser845), SNAP23, and p‐CREB (Ser133)], respectively, and attenuated the Aβ_1‐42‐induced memory impairment. Chronic melatonin treatment attenuated the hyperphosphorylation of tau protein via PI3K/Akt/GSK3β signaling by activating the p‐PI3K, p‐Akt (Ser 473) and p‐GSK3β (Ser9) in the Aβ_1‐42‐treated mice. Furthermore, melatonin decreased Aβ_1‐42‐induced apoptosis through decreasing the overexpression of caspase‐9, caspase‐3, and PARP‐1 level. Additionally, the evaluation of immunohistochemical analysis of caspase‐3, Fluorojade‐B, and Nissl staining indicated that melatonin prevented neurodegeneration in Aβ_1‐42‐treated mice. Our results demonstrated that melatonin has neuroprotective effect against Aβ_1‐42‐induced neurotoxicity through decreasing memory impairment, synaptic disorder, tau hyperphosphorylation, and neurodegeneration via PI3K/Akt/GSK3β signaling in the Aβ_1‐42‐treated mouse model of AD. On the basis of these results, we suggest that melatonin could be an effective, promising, and safe neuroprotective candidate for the treatment of progressive neurodegenerative disorders, such as AD.     

Enhanced recovery from ischemia–reperfusion injury in PI3Kα dominant negative hearts: Investigating the role of alternate PI3K isoforms,increased glucose oxidation and MAPK signaling

Classical ischemia–reperfusion (IR) preconditioning relies on phosphatidylinositol 3-kinase (PI3K) for protective signaling. Surprisingly, inhibition of PI3Kα activity using a dominant negative (DN) strategy protected the murine heart from IR injury. It has been proposed that increased signaling through PI3Kγ may contribute to the improved recovery of PI3KαDN hearts following IR. To investigate the mechanism by which PI3KαDN hearts are protected from IR injury, we created a double mutant (PI3KDM) model by crossing p110γ^−/– (PI3KγKO) with cardiac-specific PI3KαDN mice. The PI3KDM model has morphological and hemodynamic features that are characteristic of both PI3Kγ^–/– and PI3KαDN mice. Interestingly, when subjected to IR using ex vivo Langendorff perfusion, PI3KDM hearts showed significantly enhanced functional recovery when compared to wildtype (WT) hearts. However, signaling downstream of PI3K through Akt and GSK3β, which has been associated with IR protection, was reduced in PI3KDM hearts. Using ex vivo working heart perfusion, we found no difference in functional recovery after IR between PI3KDM and PI3KαDN; also, glucose oxidation rates were significantly increased in PI3KαDN hearts when compared to WT, and this metabolic shift has been associated with enhanced IR recovery. However, we found that PI3KαDN hearts still had enhanced recovery when perfused exclusively with fatty acids (FA). We then investigated parallel signaling pathways, and found that mitogen-activated protein kinase signaling was increased in PI3KαDN hearts, possibly through the inhibition of negative feedback loops downstream of PI3Kα.     

Enhancement of high glucose‐induced PINK1 expression by melatonin stimulates neuronal cell survival: Involvement of MT2/Akt/NF‐κB pathway

Hyperglycemia is a representative hallmark and risk factor for diabetes mellitus (DM) and is closely linked to DM‐associated neuronal cell death. Previous investigators reported on a genome‐wide association study and showed relationships between DM and melatonin receptor (MT), highlighting the role of MT signaling by assessing melatonin in DM. However, the role of MT signaling in DM pathogenesis is unclear. Therefore, we investigated the role of mitophagy regulators in high glucose‐induced neuronal cell death and the effect of melatonin against high glucose‐induced mitophagy regulators in neuronal cells. In our results, high glucose significantly increased PTEN‐induced putative kinase 1 (PINK1) and LC‐3B expressions; as well it decreased cytochrome c oxidase subunit 4 expression and Mitotracker? fluorescence intensity. Silencing of PINK1 induced mitochondrial reactive oxygen species (ROS) accumulation and mitochondrial membrane potential impairment, increased expressions of cleaved caspases, and increased the number of annexin V‐positive cells. In addition, high glucose‐stimulated melatonin receptor 1B (MTNR1B) mRNA and PINK1 expressions were reversed by ROS scavenger N‐acetyl cysteine pretreatment. Upregulation of PINK1 expression in neuronal cells is suppressed by pretreatment with MT₂ receptor‐specific inhibitor 4‐P‐PDOT. We further showed melatonin stimulated Akt phosphorylation, which was followed by nuclear factor kappa‐light‐chain‐enhancer of activated B cells (NF‐κB) phosphorylation and nuclear translocation. Silencing of PINK1 expression abolished melatonin‐regulated mitochondrial ROS production, cleaved caspase‐3 and caspase‐9 expressions, and the number of annexin V‐positive cells. In conclusion, we have demonstrated the melatonin stimulates PINK1 expression via an MT₂/Akt/NF‐κB pathway, and such stimulation is important for the prevention of neuronal cell apoptosis under high glucose conditions.     

Protein interactome mining defines melatonin MT1 receptors as integral component of presynaptic protein complexes of neurons

In mammals, the hormone melatonin is mainly produced by the pineal gland with nocturnal peak levels. Its peripheral and central actions rely either on its intrinsic antioxidant properties or on binding to melatonin MT₁ and MT₂ receptors, belonging to the G protein‐coupled receptor (GPCR) super‐family. Melatonin has been reported to be involved in many functions of the central nervous system such as circadian rhythm regulation, neurotransmission, synaptic plasticity, memory, sleep, and also in Alzheimer's disease and depression. However, little is known about the subcellular localization of melatonin receptors and the molecular aspects involved in neuronal functions of melatonin. Identification of protein complexes associated with GPCRs has been shown to be a valid approach to improve our understanding of their function. By combining proteomic and genomic approaches we built an interactome of MT₁ and MT₂ receptors, which comprises 378 individual proteins. Among the proteins interacting with MT₁, but not with MT₂, we identified several presynaptic proteins, suggesting a potential role of MT₁ in neurotransmission. Presynaptic localization of MT₁ receptors in the hypothalamus, striatum, and cortex was confirmed by subcellular fractionation experiments and immunofluorescence microscopy. MT₁ physically interacts with the voltage‐gated calcium channel Ca_v2.2 and inhibits Ca_v2.2‐promoted Ca²⁺ entry in an agonist‐independent manner. In conclusion, we show that MT₁ is part of the presynaptic protein network and negatively regulates Ca_v2.2 activity, providing a first hint for potential synaptic functions of MT₁.     

Melatonin MT1 and MT2 receptor ERK signaling is differentially dependent on Gi/o and Gq/11 proteins

G protein-coupled receptors (GPCRs) transmit extracellular signals into cells by activating G protein- and β-arrestin-dependent pathways. Extracellular signal-regulated kinases (ERKs) play a central role in integrating these different linear inputs coming from a variety of GPCRs to regulate cellular functions. Here, we investigated human melatonin MT₁ and MT₂ receptors signaling through the ERK1/2 cascade by employing different biochemical techniques together with pharmacological inhibitors and siRNA molecules. We show that ERK1/2 activation by both receptors is exclusively G protein-dependent, without any participation of β-arrestin1/2 in HEK293 cells. ERK1/2 activation by MT₁ is only mediated though G_i/o proteins, while MT₂ is dependent on the cooperative activation of G_i/o and G_q/11 proteins. In the absence of G_q/11 proteins, however, MT₂-induced ERK1/2 activation switches to a β-arrestin1/2-dependent mode. The signaling cascade downstream of G proteins is the same for both receptors and involves activation of the PI3K/PKCζ/c-Raf/MEK/ERK cascade. The differential G protein dependency of MT₁- and MT₂-mediated ERK activation was confirmed at the level of EGR1 and FOS gene expression, two ERK1/2 target genes. G_i/o/G_q/11 cooperativity was also observed in Neuroscreen-1 cells expressing endogenous MT₂, whereas in the mouse retina, where MT₂ is engaged into MT₁/MT₂ heterodimers, ERK1/2 signaling is exclusively G_i/o-dependent. Collectively, our data reveal differential signaling modes of MT₁ and MT₂ in terms of ERK1/2 activation, with an unexpected G_i/o/G_q/11 cooperativity exclusively for MT₂. The plasticity of ERK activation by MT₂ is highlighted by the switch to a β-arrestin1/2-dependent mode in the absence of G_q/11 proteins and by the switch to a G_i/o mode when engaged into MT₁/MT₂ heterodimers, revealing a new mechanism underlying tissue-specific responses to melatonin.     

Macrophage migration inhibitory factor deficiency augments cardiac dysfunction in Type 1 diabetic murine cardiomyocytes

Background: It has become evident that macrophage migration inhibitory factor (MIF) is associated with the development of Type 1 diabetes mellitus. The aim of the present study was to determine whether MIF plays a role in cardiac contractile dysfunction in T1DM mice. Methods: Mechanical and intracellular Ca²⁺ properties were measured in cardiomyocytes isolated from wild‐type (WT) and MIF‐knockout (MIF‐KO) mice administrated or not streptozotocin (200 mg/kg, i.p.). Relative stress signaling was evaluated using western blot analysis. Results: Peak shortening (PS) and maximal velocity of shortening/relengthening (±dL/dt) were reduced and the duration of relengthening (TR90) was prolonged in both WT and MIF‐KO cardiomyocytes treated with STZ (P < 0.01 vs control), which may be associated with reduced intracellular Ca²⁺ decay in both groups. However, STZ‐treated WT cardiomyocytes demonstrated significantly better contractile function and intracellular Ca²⁺ properties compared with STZ‐treated MIF‐KO cardiomyocytes (all P < 0.05). Interestingly, the physiological data clearly showed that blood glucose levels were significantly higher in STZ‐treated MIF‐KO mice than STZ‐treated WT mice (P < 0.01). Moreover, phosphorylation of AMP‐activated protein kinase (AMPK) and its direct downstream target acetyl‐CoA carboxylase (ACC) was markedly lower in hearts from STZ‐treated MIF‐KO mice than STZ‐treated WT mice (P < 0.05). There were no significant differences between untreated WT and MIF‐KO control groups. Conclusions: There is a beneficial action of MIF in the management of cardiac dysfunction in T1DM. The cardioprotective effect of MIF may be associated with AMPK signaling.     

Copper chelators promote nonamyloidogenic processing of AβPP via MT1/2/CREB‐dependent signaling pathways in AβPP/PS1 transgenic mice

Copper is essential for the generation of reactive oxygen species (ROS), which are induced by amyloid‐β (Aβ) aggregation; thus, the homeostasis of copper is believed to be a therapeutic target for Alzheimer’s disease (AD). Although clinical trials of copper chelators show promise when applied in AD, the underlying mechanism is not fully understood. Here, we reported that copper chelators promoted nonamyloidogenic processing of AβPP through MT_1/2/CREB‐dependent signaling pathways. First, we found that the formation of Aβ plaques in the cortex was significantly reduced, and learning deficits were significantly improved in AβPP/PS1 transgenic mice by copper chelator tetrathiomolybdate (TM) administration. Second, TM and another copper chelator, bathocuproine sulfonate (BCS), promoted nonamyloidogenic processing of AβPP via inducing the expression of ADAM10 and the secretion of sAβPPα. Third, the inducible ADAM10 production caused by copper chelators can be blocked by a melatonin receptor (MT_1/2) antagonist (luzindole) and a MT₂ inhibitor (4‐P‐PDOT), suggesting that the expression of ADAM10 depends on the activation of MT_1/2 signaling pathways. Fourth, three of the MT_1/2‐downstream signaling pathways, Gq/PLC/MEK/ERK/CREB, Gs/cAMP/PKA/ERK/CREB and Gs/cAMP/PKA/CREB, were responsible for copper chelator‐induced ADAM10 production. Based on these results, we conclude that copper chelators regulate the balance between amyloidogenic and nonamyloidogenic processing of AβPP via promoting ADAM10 expression through MT_1/2/CREB‐dependent signaling pathways.     

Evidence of the receptor‐mediated influence of melatonin on pancreatic glucagon secretion via the Gαq protein‐coupled and PI3K signaling pathways

Abstract: Melatonin has been shown to modulate glucose metabolism by influencing insulin secretion. Recent investigations have also indicated a regulatory function of melatonin on the pancreatic α‐cells. The present in vitro and in vivo studies evaluated whether melatonin mediates its effects via melatonin receptors and which signaling cascade is involved. Incubation experiments using the glucagon‐producing mouse pancreatic α‐cell line αTC1 clone 9 (αTC1.9) as well as isolated pancreatic islets of rats and mice revealed that melatonin increases glucagon secretion. Preincubation of αTC1.9 cells with the melatonin receptor antagonists luzindole and 4P‐PDOT abolished the glucagon‐stimulatory effect of melatonin. In addition, glucagon secretion was lower in the pancreatic islets of melatonin receptor knockout mice than in the islets of the wild‐type (WT) control animals. Investigations of melatonin receptor knockout mice revealed decreased plasma glucagon concentrations and elevated mRNA expression levels of the hepatic glucagon receptor when compared to WT mice. Furthermore, studies using pertussis toxin, as well as measurements of cAMP concentrations, ruled out the involvement of Gαi‐ and Gαs‐coupled signaling cascades in mediating the glucagon increase induced by melatonin. In contrast, inhibition of phospholipase C in αTC1.9 cells prevented the melatonin‐induced effect, indicating the physiological relevance of the Gαq‐coupled pathway. Our data point to the involvement of the phosphatidylinositol 3‐kinase signaling cascade in mediating melatonin effects in pancreatic α‐cells. In conclusion, these findings provide evidence that the glucagon‐stimulatory effect of melatonin in pancreatic α‐cells is melatonin receptor mediated, thus supporting the concept of melatonin‐modulated and diurnal glucagon release.     

Nociceptive responses in melatonin MT2 receptor knockout mice compared to MT1 and double MT1/MT2 receptor knockout mice

Melatonin, a neurohormone that binds to two G protein-coupled receptors MT₁ and MT_2, is involved in pain regulation, but the distinct role of each receptor has yet to be defined. We characterized the nociceptive responses of mice with genetic inactivation of melatonin MT₁ (MT₁^−/−), or MT₂ (MT₂^−/−), or both MT₁/MT₂ (MT₁^−/−/MT₂^−/−) receptors in the hot plate test (HPT), and the formalin test (FT). In HPT and FT, MT₁^−/− display no differences compared to their wild-type littermates (CTL), whereas both MT₂^−/− and MT₁^−/−/MT₂^−/− mice showed a reduced thermal sensitivity and a decreased tonic nocifensive behavior during phase 2 of the FT in the light phase. The MT₂ partial agonist UCM924 induced an antinociceptive effect in MT₁^−/− but not in MT₂^−/− and MT₁^−/−/MT₂^−/− mice. Also, the competitive opioid antagonist naloxone had no effects in CTL, whereas it induced a decrease of nociceptive thresholds in MT₂^−/− mice. Our results show that the genetic inactivation of melatonin MT₂, but not MT₁ receptors, produces a distinct effect on nociceptive threshold, suggesting that the melatonin MT₂ receptor subtype is selectively involved in the regulation of pain responses.     

Substance P (SP)-neurokinin-1 receptor (NK-1R) alters adipose tissue responses to high-fat diet and insulin action

Peripheral administration of a specific neurokinin-1 receptor (NK-1R) antagonist to mice leads to reduced weight gain and circulating levels of insulin and leptin after high-fat diet (HFD). Here, we assessed the contribution of substance P (SP) and NK-1R in diet-induced obesity using NK-1R deficient [knockout (KO)] mice and extended our previous findings to show the effects of SP-NK-1R interactions on adipose tissue-associated insulin signaling and glucose metabolic responses. NK-1R KO and wild-type (WT) littermates were fed a HFD for 3 wk, and obesity-associated responses were determined. Compared with WT, NK-1 KO mice show reduced weight gain and circulating levels of leptin and insulin in response to HFD. Adiponectin receptor mRNA levels are higher in mesenteric fat and liver in NK-1 KO animals compared with WT, after HFD. Mesenteric fat from NK-1R KO mice fed with HFD has reduced stress-activated protein kinase/c-Jun N-terminal kinase and protein kinase C activation compared with WT mice. After glucose challenge, NK-1R KO mice remove glucose from the circulation more efficiently than WT and pair-fed controls, suggesting an additional peripheral effect of NK-1R-mediated signaling on glucose metabolism. Glucose uptake experiments in isolated rat adipocytes showed that SP directly inhibits insulin-mediated glucose uptake. Our results further establish a role for SP-NK-1R interactions in adipose tissue responses, specifically as they relate to obesity-associated pathologies such as glucose intolerance and insulin resistance. Our results highlight this pathway as an important therapeutic approach for type 2 diabetes.