Distribution and density of melatonin receptors in human main pancreatic islet cell types

Recent investigations of our group established that melatonin modulates hormone secretion of pancreatic islets via melatonin receptor types MT1 and MT2. Expression of MT1 and MT2 has been shown in mouse, rat, and human pancreatic islets as well as in the β‐, α‐, and δ‐cell lines INS‐1, αTC1.9, and QGP‐1. In view of these earlier investigations, this study was performed to analyze in detail the distribution and density of melatonin receptors on the main islet cell types in human pancreatic tissue obtained from nondiabetic and type 2 diabetic patients. Immunohistochemical analysis established the presence of MT1 and MT2 in β‐, α‐, and δ‐cells, but notably, with differences in receptor density. In general, the lowest MT1 and MT2 receptor density was measured in α‐cells compared to the 2 other cell types. In type 2 diabetic islets, MT1 and MT2 receptor density was increased in δ‐cells compared to normoglycemic controls. In human islets in batch culture of a nondiabetic donor, an increase of somatostatin secretion was observed under melatonin treatment while in islets of a type 2 diabetic donor, an inhibitory influence could be observed, especially in the presence of 5.5 mmol/L glucose. These data suggest the following: i) cell‐type‐specific density of MT1 and MT2 receptors in human pancreatic islets, which should be considered in context of the hormone secretion of islets, ii) the influence of diabetes on density of MT1 and MT2 as well as iii) the differential impact of melatonin on somatostatin secretion of nondiabetic and type 2 diabetic islets.     

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.     

Melatonin influences insulin secretion primarily via MT(1) receptors in rat insulinoma cells (INS-1) and mouse pancreatic islets

Several studies have revealed that melatonin affects the insulin secretion via MT(1) and MT(2) receptor isoforms. Owing to the lack of selective MT(1) receptor antagonists, we used RNA interference technology to generate an MT(1) knockdown in a clonal β-cell line to evaluate whether melatonin modulates insulin secretion specifically via the MT(1) receptor. Incubation experiments were carried out, and the insulin concentration in supernatants was measured using a radioimmunoassay. Furthermore, the intracellular cAMP was determined using an enzyme-linked immunosorbent assay. Real-time RT-PCR indicated that MT(1) knockdown resulted in a significant increase in the rIns1 mRNA and a significantly elevated basal insulin secretion of INS-1 cells. Incubation with melatonin decreased the amount of glucagon-like peptide 1 or inhibited the glucagon-stimulated insulin release of INS-1 cells, while, in MT(1) -knockdown cells, no melatonin-induced reduction in insulin secretion could be found. No decrease in 3-isobutyl-1-methylxanthine-stimulated intracellular cAMP in rMT(1) -knockdown cells was detectable after treatment with melatonin either, and immunocytochemistry proved that MT(1) knockdown abolished phosphorylation of cAMP-response-element-binding protein. In contrast to the INS-1 cells, preincubation with melatonin did not sensitize the insulin secretion of rMT(1) -knockdown cells. We also monitored insulin secretion from isolated islets of wild-type and melatonin-receptor knockout mice ex vivo. In islets of wild-type mice, melatonin treatment resulted in a decrease in insulin release, whereas melatonin treatment of islets from MT(1) knockout and MT(1/2) double-knockout mice did not show a significant effect. The data indicate that melatonin inhibits insulin secretion, primarily via the MT(1) receptor in rat INS-1 cells and isolated mouse islets.     

Melatonin inhibits insulin secretion in rat insulinoma β-cells (INS-1) heterologously expressing the human melatonin receptor isoform MT2

Melatonin exerts some of its effects via G-protein-coupled membrane receptors. Two membrane receptor isoforms, MT1 and MT2, have been described. The MT1 receptor is known to inhibit second messenger cyclic adenosine monophosphate (cAMP) signaling through receptor-coupling to inhibitory G-proteins (G(i) ). Much less is known about the MT2 receptor, but it has also been implicated in signaling via G(i) -proteins. In rat pancreatic β-cells, it has recently been reported that the MT2 receptor plays an inhibitory role in the cyclic guanosine monophosphate (cGMP) pathway. This study addresses the signaling features of the constitutively expressed human recombinant MT2 receptor (hMT2) and its impact on insulin secretion, using a rat insulinoma β-cell line (INS-1). On the basis of a specific radioimmunoassay, insulin secretion was found to be more strongly reduced in the clones expressing hMT2 than in INS-1 controls, when incubated with 1 or 100 nm melatonin. Similarly, cAMP and cGMP levels, measured by specific enzyme-linked immunosorbent assays (ELISAs), were reduced to a greater extent in hMT2 clones after melatonin treatment. In hMT2-expressing cells, the inhibitory effect of melatonin on insulin secretion was blocked by pretreatment with pertussis toxin, demonstrating the coupling of the hMT2 to G(i) -proteins. These results indicate that functional hMT2 expression leads to the inhibition of cyclic nucleotide signaling and a reduction in insulin release. Because genetic variants of the hMT2 receptor are considered to be risk factors in the development of type 2 diabetes, our results are potentially significant in explaining and preventing the pathogenesis of this disease.     

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.     

Molecular deficiency (ies) in MT1 melatonin signaling pathway underlies the melatonin‐unresponsive phenotype in MDA‐MB‐231 human breast cancer cells

Melatonin has been shown repeatedly to inhibit the growth of human breast tumor cells in vitro and in vivo. Its antiproliferative effects have been well studied in MCF‐7 human breast cancer cells and several other estrogen receptor α (ERα)‐positive human breast cancer cell lines. However, the MDA‐MB‐231 breast cancer cell line, an ERα‐negative cell line widely used in breast cancer research, has been shown to be unresponsive to melatonin's growth‐suppressive effect in vitro. Here, we examined the effect of melatonin on the cell proliferation of several ERα‐negative breast cancer cell lines including MDA‐MB‐231, BT‐20, and SK‐BR‐3 cells. Although the MT1 G‐protein‐coupled receptor is expressed in all three cell lines, melatonin significantly suppressed the proliferation of SK‐BR‐3 cells without having any significant effect on the growth of MDA‐MB‐231 and BT‐20 cells. We confirmed that the MT1‐associated Gα proteins are expressed in MDA‐MB‐231 cells. Further studies demonstrated that the melatonin unresponsiveness in MDA‐MB‐231 cells may be caused by aberrant signaling downstream of the Gαi proteins, resulting in differential regulation of ERK1/2 activity.     

Sleep well. Untangling the role of melatonin MT1 and MT2 receptors in sleep

The pharmacological potential of targeting selectively melatonin MT1 or MT2 receptors has not yet been exploited in medicine. Research using selective MT1/MT2 receptor ligands and MT1/MT2 receptor knockout mice has indicated that the activation of MT2 receptors selectively increases non‐rapid eye movement (NREM) sleep whereas MT1 receptors seem mostly implicated in the regulation of REM sleep. Moreover, MT1 knockout mice show an increase in NREM sleep, while MT2 knockout a decrease, suggesting an opposite role of these two receptors. A recent paper in mice by Sharma et al (J Pineal Res, 2018, e12498) found that MT1 but not MT2 receptors are expressed on orexin neurons in the perifornical lateral hypothalamus (PFH). Moreover, after injecting melatonin or luzindole into the mouse PFH, the authors suggest that melatonin promotes NREM sleep because activates PFH MT1 receptors, which in turn inhibit orexin neurons that are important in promoting arousal and maintaining wakefulness. In this commentary, we have critically commented on some of these findings on the bases of previous literature. In addition, we highlighted the fact that no conclusions could be drawn on the melatonin receptor subtype mediating the effects of melatonin on sleep because the authors used the non‐selective MT1/MT2 receptors antagonist luzindole. More solid research should further characterize the pharmacological function of these two melatonin receptors in sleep.     

Glucagon‐like peptide 1‐potentiated insulin secretion and proliferation of pancreatic β‐cells GLP‐1促进胰岛素分泌和胰岛β细胞增殖的机制

Glucagon‐like peptide‐1 (GLP‐1) is the primary incretin hormone secreted from the intestine upon uptake of food to stimulate insulin secretion from pancreatic β‐cells. GLP‐1 exerts its effects by binding to its G‐protein coupled receptors and subsequently activating adenylate cyclase, leading to generation of cyclic adenosine monophosphate (cAMP). cAMP stimulates insulin secretion via activation of its effectors PKA and Epac2 in pancreatic β‐cells. In addition to its insulinotropic effects, GLP‐1 also preserves pancreatic β‐cell mass by stimulating β‐cell proliferation. Unlike the action of sulphonylureas in lowering blood glucose levels, action of GLP‐1 is affected by and interplays with glucose levels. Due to such advantages, GLP‐1‐based therapeutics have been rapidly developed and used clinically for treatment of type 2 diabetes. However, molecular mechanisms underlying how GLP‐1 potentiates diminished glucose‐stimulated insulin secretion and β‐cell proliferation under diabetic conditions are not well understood. Here, we review the actions of GLP‐1 in regulation of insulin secretion and pancreatic β‐cell proliferation.     

Protection of melatonin in experimental models of newborn hypoxic‐ischemic brain injury through MT1 receptor

The function of melatonin as a protective agent against newborn hypoxic‐ischemic (H‐I) brain injury is not yet well studied, and the mechanisms by which melatonin causes neuroprotection in neurological diseases are still evolving. This study was designed to investigate whether expression of MT1 receptors is reduced in newborn H‐I brain injury and whether the protective action of melatonin is by alterations of the MT1 receptors. We demonstrated that there was significant reduction in MT1 receptors in ischemic brain of mouse pups in vivo following H‐I brain injury and that melatonin offers neuroprotection through upregulation of MT1 receptors. The role of MT1 receptors was further supported by observation of increased mortality in MT1 knockout mice following H‐I brain injury and the reversal of the inhibitory role of melatonin on mitochondrial cell death pathways by the melatonin receptor antagonist, luzindole. These data demonstrate that melatonin mediates its neuroprotective effect in mouse models of newborn H‐I brain injury, at least in part, by the restoration of MT1 receptors, the inhibition of mitochondrial cell death pathways and the suppression of astrocytic and microglial activation.     

The inhibition of TNF‐α‐induced leucocyte apoptosis by melatonin involves membrane receptor MT1/MT2 interaction

The pro‐apoptotic signalling cascades induced by tumour necrosis factor‐alpha (TNF‐α) have been intensively studied in multiple cellular systems. So far, it is known that TNF‐α can simultaneously activate survival and apoptotic cell death responses. The balance between these signals determines the ultimate response of the cell to TNF‐α. Moreover, emerging evidence suggests that melatonin may be involved in the protection of different cell types against apoptosis. Thus, the objective of this study was to evaluate the effect of melatonin on TNF‐α‐induced apoptosis in human leucocytes. Cells were treated with TNF‐α alone or in the presence of cycloheximide (CHX), which promotes caspase‐8 activation by eliminating the endogenous caspase‐8 inhibitor, c‐FLIP. Treatment with TNF‐α/CHX led to apoptotic cell death, as ascertained by annexin V/propidium iodide (PI) staining. Likewise, in the presence of CHX, TNF‐α stimulation produced cFLIP down‐regulation and subsequent caspase‐8 activation, thus directly triggering caspase‐3 activation and causing Bid truncation and subsequent caspase‐9 activation. Conversely, pre‐incubation of cells with melatonin inhibited TNF‐α‐/CHX‐evoked leucocyte apoptosis. Similarly, pretreatment of leucocytes with melatonin increased cFLIP protein levels, thereby preventing TNF‐α‐/CHX‐mediated caspase processing. Blockade of melatonin membrane receptor MT1/MT2 or extracellular signal‐regulated kinase (ERK) pathway with luzindole or PD98059, respectively, abolished the inhibitory effects of melatonin on leucocyte apoptosis evoked by TNF‐α/CHX. In conclusion, the model proposed by these findings is that the MT1/MT2 receptors, which are under the positive control of melatonin, trigger an ERK‐dependent signalling cascade that interferes with the anti‐apoptotic protein cFLIP modulating the cell life/death balance of human leucocytes.     

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.     

Melatonin and its receptor MT1 are involved in the downstream reaction to luteinizing hormone and participate in the regulation of luteinization in different species

The functions of melatonin in preovulatory fluid remain elusive. In the current study, we observed that the extremely high level of expression of MT1 in mice granulosa cells was rapidly induced by hCG (equivalent LH) within 2 hours and this was referred as MT1 surge. In cumulus cells, serotonin N‐acetyltransferase (SNAT) was also upregulated by hCG and led to elevated melatonin levels in ovarian follicle fluid. Melatonin application before MT1 surge significantly promoted embryo implantation, and this was probably attributed to a rise in progesterone levels in the serum. The mechanistic studies indicated that melatonin/MT1 (MLT/MT1) signaling remarkably improved the expression of corpus luteum marker genes, that is, Akr1c18 and Cyp11a1. High‐throughput sequencing results suggested that extracellular matrix (ECM) receptor interaction, focal adhesion, and activation of PI3K/Akt pathway which are involved in granulosa cell luteinization might mediate the actions of MLT/MT1 signal. In addition, this effect on luteinization was compared in different species. It was verified that high melatonin levels exist in serum at estrum of cows and help to improve the first estrus fecundation rate. These results suggested that both melatonin and MT1 are involved in the downstream reaction of hCG (LH) and they play important roles in luteinization. These findings provide the novel information on the physiology of melatonin in animal reproduction.     

Melatonin impedes Tet1‐dependent mGluR5 promoter demethylation to relieve pain

Melatonin (N‐acetyl‐5‐methoxytryptamine)/MT2 receptor‐dependent epigenetic modification represents a novel pathway in the treatment of neuropathic pain. Because spinal ten‐eleven translocation methylcytosine dioxygenase 1 (Tet1)‐dependent epigenetic demethylation has recently been linked to pain hypersensitivity, we hypothesized that melatonin/MT2‐dependent analgesia involves spinal Tet1‐dependent demethylation. Here, we showed that spinal Tet1 gene transfer by intrathecal delivery of Tet1‐encoding vectors to naïve rats produced profound and long‐lasting nociceptive hypersensitivity. In addition, enhanced Tet1 expression, Tet1‐metabotropic glutamate receptor subtype 5 (mGluR5) promoter coupling, demethylation at the mGluR5 promoter, and mGluR5 expression in dorsal horn neurons were observed. Rats subjected to spinal nerve ligation and intraplantar complete Freund's adjuvant injection displayed tactile allodynia and behavioral hyperalgesia associated with similar changes in the dorsal horn. Notably, intrathecal melatonin injection reversed the protein expression, protein‐promoter coupling, promoter demethylation, and pain hypersensitivity induced by Tet1 gene transfer, spinal nerve ligation, and intraplantar complete Freund's adjuvant injection. All the effects caused by melatonin were blocked by pretreatment with a MT2 receptor‐selective antagonist. In conclusion, melatonin relieves pain by impeding Tet1‐dependent demethylation of mGluR5 in dorsal horn neurons through the MT2 receptor. Our findings link melatonin/MT2 signaling to Tet1‐dependent epigenetic demethylation of nociceptive genes for the first time and suggest melatonin as a promising therapy for the treatment of pain.     

Inhibiting MT2‐TFE3‐dependent autophagy enhances melatonin‐induced apoptosis in tongue squamous cell carcinoma

Autophagy modulation is a potential therapeutic strategy for tongue squamous cell carcinoma (TSCC). Melatonin possesses significant anticarcinogenic activity. However, whether melatonin induces autophagy and its roles in cell death in TSCC are unclear. Herein, we show that melatonin induced significant apoptosis in the TSCC cell line Cal27. Apart from the induction of apoptosis, we demonstrated that melatonin‐induced autophagic flux in Cal27 cells as evidenced by the formation of GFP‐LC3 puncta, and the upregulation of LC3‐II and downregulation of SQSTM1/P62. Moreover, pharmacological or genetic blockage of autophagy enhanced melatonin‐induced apoptosis, indicating a cytoprotective role of autophagy in melatonin‐treated Cal27 cells. Mechanistically, melatonin induced TFE3^(Ser321) dephosphorylation, subsequently activated TFE3 nuclear translocation, and increased TFE3 reporter activity, which contributed to the expression of autophagy‐related genes and lysosomal biogenesis. Luzindole, a melatonin membrane receptor blocker, or MT2‐siRNA partially blocked the ability of melatonin to promote mTORC1/TFE3 signaling. Furthermore, we verified in a xenograft mouse model that melatonin with hydroxychloroquine or TFE3‐siRNA exerted a synergistic antitumor effect by inhibiting autophagy. Importantly, TFE3 expression positively correlated with TSCC development and poor prognosis in patients. Collectively, we demonstrated that the melatonin‐induced increase in TFE3‐dependent autophagy is mediated through the melatonin membrane receptor in TSCC. These data also suggest that blocking melatonin membrane receptor‐TFE3‐dependent autophagy to enhance the activity of melatonin warrants further attention as a treatment strategy for TSCC.