Dorsal and median raphe neuronal firing dynamics characterized by nonlinear measures.

The dorsal (DRN) and median (MRN) raphe are important nuclei involved in similar functions, including mood and sleep, but playing distinct roles. These nuclei have a different composition of neuronal types and set of neuronal connections, which among other factors, determine their neuronal dynamics. Most works characterize the neuronal dynamics using classic measures, such as using the average spiking frequency (FR), the coefficient of variation (CV), and action potential duration (APD). In the current study, to refine the characterization of neuronal firing profiles, we examined the neurons within the raphe nuclei. Through the utilization of nonlinear measures, our objective was to discern the redundancy and complementarity of these measures, particularly in comparison with classic methods. To do this, we analyzed the neuronal basal firing profile in both nuclei of urethane-anesthetized rats using the Shannon entropy (Bins Entropy) of the inter-spike intervals, permutation entropy of ordinal patterns (OP Entropy), and Permutation Lempel-Ziv Complexity (PLZC). Firstly, we found that classic (i.e., FR, CV, and APD) and nonlinear measures fail to distinguish between the dynamics of DRN and MRN neurons, except for the OP Entropy. We also found strong relationships between measures, including the CV with FR, CV with Bins entropy, and FR with PLZC, which imply redundant information. However, APD and OP Entropy have either a weak or no relationship with the rest of the measures tested, suggesting that they provide complementary information to the characterization of the neuronal firing profiles. Secondly, we studied how these measures are affected by the oscillatory properties of the firing patterns, including rhythmicity, bursting patterns, and clock-like behavior. We found that all measures are sensitive to rhythmicity, except for the OP Entropy. Overall, our work highlights OP Entropy as a powerful and useful quantity for the characterization of neuronal discharge patterns.

Acute intrahippocampal administration of melanin-concentrating hormone impairs memory consolidation and decreases the expression of MCHR-1 and TrkB receptors.

Interest in the role of melanin-concentrating hormone (MCH) in memory processes has increased in recent years, with some studies reporting memory-enhancing effects, while others report deleterious effects. Due to these discrepancies, this study seeks to provide new evidence about the role of MCH in memory consolidation and its relation with BDNF/TrkB system. To this end, in the first experiment, increased doses of MCH were acutely administered in both hippocampi to groups of male rats (25, 50, 200, and 500 ng). Microinjections were carried out immediately after finishing the sample trial of two hippocampal-dependent behavioral tasks: the Novel Object Recognition Test (NORT) and the modified Elevated Plus Maze (mEPM) test. Results indicated that a dose of 200 ng of MCH or higher impaired memory consolidation in both tasks. A second experiment was performed in which a dose of 200 ng of MCH was administered alone or co-administered with the MCHR-1 antagonist ATC-0175 at the end of the sample trial in the NORT. Results showed that MCH impaired memory consolidation, while the co-administration with ATC-0175 reverted this detrimental effect. Moreover, MCH induced a significant decrease in hippocampal MCHR-1 and TrkB expression with no modification in the expression of BDNF and NMDA receptor subunits NR1, NR2A, and NR2B. These results suggest that MCH in vivo elicits pro-amnesic effects in the rat hippocampus by decreasing the availability of its receptor and TrkB receptors, thus linking both endogenous systems to memory processes.

Generation and characterization of Ccdc28b mutant mice links the Bardet-Biedl associated gene with mild social behavioral phenotypes.

CCDC28B (coiled-coil domain-containing protein 28B) was identified as a modifier in the ciliopathy Bardet-Biedl syndrome (BBS). Our previous work in cells and zebrafish showed that CCDC28B plays a role regulating cilia length in a mechanism that is not completely understood. Here we report the generation of a Ccdc28b mutant mouse using CRISPR/Cas9 (Ccdc28b mut). Depletion of CCDC28B resulted in a mild phenotype. Ccdc28b mut animals i) do not present clear structural cilia affectation, although we did observe mild defects in cilia density and cilia length in some tissues, ii) reproduce normally, and iii) do not develop retinal degeneration or obesity, two hallmark features of reported BBS murine models. In contrast, Ccdc28b mut mice did show clear social interaction defects as well as stereotypical behaviors. This finding is indeed relevant regarding CCDC28B as a modifier of BBS since behavioral phenotypes have been documented in BBS. Overall, this work reports a novel mouse model that will be key to continue evaluating genetic interactions in BBS, deciphering the contribution of CCDC28B to modulate the presentation of BBS phenotypes. In addition, our data underscores a novel link between CCDC28B and behavioral defects, providing a novel opportunity to further our understanding of the genetic, cellular, and molecular basis of these complex phenotypes.

In vivo uptake of a fluorescent conjugate of melanin-concentrating hormone in the rat brain.

Melanin-concentrating hormone (MCH) is a hypothalamic neuropeptide synthesized by posterior hypothalamic and incerto-hypothalamic neurons that project throughout the central nervous system. The MCHergic system modulates several important functions such as feeding behavior, mood and sleep. MCH exerts its biological functions through interaction with the MCHR-1 receptor, the only functional receptor present in rodents. The internalization process of MCHR-1 triggered by MCH binding was described in vitro in non-neuronal heterologous systems with over-expression of MCHR-1. Reports of in vivo MCHR-1 internalization dynamics are scarce, however, this is an important process to explore based on the critical functions of the MCHergic system. We had previously determined that 60 min after intracerebroventricular (i.c.v.) microinjections of MCH conjugated with fluorophore rhodamine (R-MCH), the dorsal and median raphe nucleus presented R-MCH positive labeled neurons. In the present work, we further studied the in vivo uptake process focusing on the distribution and time-dependent pattern of R-MCH positive cells 10, 20 and 60 min (T10, T20 and T60, respectively) after i.c.v. microinjection of R-MCH. We also explored this uptake process to see whether it was receptor- and clathrin-dependent and examined the phenotype of R-MCH positive cells and their proximity to MCHergic fibers. We found a great number of R-MCH positive cells with high fluorescence intensity in the lateral septum, nucleus accumbens and hippocampus at T20 and T60 (but not at T10), while a lower number with low intensity was observed in the dorsal raphe nucleus. At T20, in rats pre-treated with a MCHR-1 antagonist (ATC-0175) or with phenylarsine oxide (PAO), a clathrin endocytosis inhibitor, a robust decrease (> 50 %) of R-MCH uptake occurred in these structures. The R-MCH positive cells were identified as neurons (NeuN positive, GFAP negative) and some MCHergic fibers run in the vicinities of them. We concluded that neurons localized at structures that were close to the ventricular surfaces could uptake R-MCH in vivo through a receptor-dependent and clathrin-mediated process. Our results support volume transmission of MCH through the cerebrospinal fluid to reach distant targets. Finally, we propose that R-MCH would be an effective tool to study MCH-uptake in vivo.

Melanin-concentrating hormone (MCH) in the median raphe nucleus: Fibers, receptors and cellular effects.

Serotonergic neurons of the median raphe nucleus (MnR) and hypothalamic melanin-concentrating hormone (MCH)-containing neurons, have been involved in the control of REM sleep and mood. In the present study, we examined in rats and cats the anatomical relationship between MCH-containing fibers and MnR neurons, as well as the presence of MCHergic receptors in these neurons. In addition, by means of in vivo unit recording in urethane anesthetized rats, we determined the effects of MCH in MnR neuronal firing. Our results showed that MCH-containing fibers were present in the central and paracentral regions of the MnR. MCHergic fibers were in close apposition to serotonergic and non-serotonergic neurons. By means of an indirect approach, we also analyzed the presence of MCHergic receptors within the MnR. Accordingly, we microinjected MCH conjugated with the fluorophore rhodamine (R-MCH) into the lateral ventricle. R-MCH was internalized into serotonergic and non-serotonergic MnR neurons; some of these neurons were GABAergic. Furthermore, we determined that intracerebroventricular administration of MCH induced a significant decrease in the firing rate of 53 % of MnR neurons, while the juxtacellular administration of MCH reduced the frequency of discharge in 67 % of these neurons. Finally, the juxtacellular administration of the MCH-receptor antagonist ATC-0175 produced an increase in the firing rate in 78 % of MnR neurons. Hence, MCH produces a strong regulation of MnR neuronal activity. We hypothesize that MCHergic modulation of the MnR neuronal activity may be involved in the promotion of REM sleep and in the pathophysiology of depressive disorders.

Melanin-concentrating hormone receptor-1 is located in primary cilia of the dorsal raphe neurons.

The melanin-concentrating hormone (MCH) is a peptidergic neuromodulator synthesized by neurons of the posterior hypothalamus and incerto-hypothalamic area. These neurons project throughout the central nervous system, including the dorsal raphe nucleus (DRN). In rodents, MCH exerts its biological functions through the MCHR-1 receptor. We previously demonstrated that intra-DRN MCH administration increases REM sleep time and induces a pro-depressive behavior. We also determined that MCH modulates the neuronal firing rate and serotonin release within this nucleus. Previous studies in mice identified the presence of MCHR-1 in neurons located in the olfactory tubercle, hypothalamus, and nucleus accumbens, in a specialized neuronal appendage: the neuronal primary cilia. However, the subcellular location of MCHR-1 protein in the DRN is still unknown. Hence, the aim of the present study was to explore, by means of single and double immunohistochemical procedures, whether MCHR-1 is present in neuronal primary cilia in serotonergic and GABAergic neurons located in the DRN of the rat. We demonstrated colocalization of MCHR-1 with type III adenylyl cyclase (AC-III), a neuronal ciliary marker, in the DRN and confirmed their colocalization in the hippocampus and cerebral cortex of the rat. We quantified the proportion of serotoninergic and GABAergic neurons that coexpress MCHR-1 at the mid-caudal and mid-rostral levels of the DRN: 4% and 12%, respectively. Furthermore, approximately 10% of the total number of MCHR-1 immunoreactive primary cilia belonged to serotonergic neurons, whilst 12% were appendages of GABAergic neurons. These morphological data allow us to conclude that the mechanism by which MCH modulates the activity of DRN neurons is through MCHR-1 receptors present in the primary cilia of different neurochemical phenotypes. New experiments are needed to understand the functional rationale of the unexpected localization of these receptors and to explore their presence in other neuronal phenotypes.

Melanin-concentrating hormone does not modulate serotonin release in primary cultures of fetal raphe nucleus neurons.

Melanin-concentrating hormone (MCH) is a neuropeptide present in neurons located in the hypothalamus that densely innervate serotonergic cells in the dorsal raphe nucleus (DRN). MCH administration into the DRN induces a depressive-like effect through a serotonergic mechanism. To further understand the interaction between MCH and serotonin, we used primary cultured serotonergic neurons to evaluate the effect of MCH on serotonergic release and metabolism by HPLC-ED measurement of serotonin (5-HT) and 5-hydroxyindolacetic acid (5-HIAA) levels. We confirmed the presence of serotonergic neurons in the E14 rat rhombencephalon by immunohistochemistry and showed for the first time evidence of MCHergic fibers reaching the area. Cultures obtained from rhombencephalic tissue presented 2.2 ±â€¯0.7% of serotonergic and 48.9 ±â€¯5.4% of GABAergic neurons. Despite the low concentration of serotonergic neurons, we were able to measure basal cellular and extracellular levels of 5-HT and 5-HIAA without the addition of any serotonergic-enhancer drug. As expected, 5-HT release was calcium-dependent and induced by depolarization. 5-HT extracellular levels were significantly increased by incubation with serotonin reuptake inhibitors (citalopram and nortriptyline) and a monoamine-oxidase inhibitor (clorgyline), and were not significantly modified by a 5-HT1A autoreceptor agonist (8-OHDPAT). Even though serotonergic cells responded as expected to these pharmacological treatments, MCH did not induce significant modifications of 5-HT and 5-HIAA extracellular levels in the cultures. Despite this unexpected result, we consider that assessment of 5-HT and 5-HIAA levels in primary serotonergic cultures may be an adequate approach to study the effect of other drugs and modulators on serotonin release, uptake and turnover.

The Expression of Hypoxia-Induced Gene 1 (Higd1a) in the Central Nervous System of Male and Female Rats Differs According to Age.

HIGD1A (hypoxia-induced gene domain protein-1a), a mitochondrial inner membrane protein present in various cell types, has been mainly associated with anti-apoptotic processes in response to stressors. Our previous findings have shown that Higd1a mRNA is widely expressed across the central nervous system (CNS), exhibiting an increasing expression in the spinal cord from postnatal day 1 (P1) to 15 (P15) and changes in the distribution pattern from P1 to P90. During the first weeks of postnatal life, the great plasticity of the CNS is accompanied by cell death/survival decisions. So we first describe HIGD1A expression throughout the brain during early postnatal life in female and male pups. Secondly, based on the fact that in some areas this process is influenced by the sex of individuals, we explore HIGD1A expression in the sexual dimorphic nucleus (SDN) of the medial preoptic area, a region that is several folds larger in male than in female rats, partly due to sex differences in the process of apoptosis during this period. Immunohistochemical analysis revealed that HIGD1A is widely but unevenly expressed throughout the brain. Quantitative Western blot analysis of the parietal cortex, diencephalon, and spinal cord from both sexes at P1, P5, P8, and P15 showed that the expression of this protein is predominantly high and changes with age but not sex. Similarly, in the sexual dimorphic nucleus, the expression of HIGD1A varied according to age, but we were not able to detect significant differences in its expression according to sex. Altogether, these results suggest that HIGD1A protein is expressed in several areas of the central nervous system following a pattern that quantitatively changes with age but does not seem to change according to sex.

Distribution of MCH-containing fibers in the feline brainstem: Relevance for REM sleep regulation.

Neurons that utilize melanin-concentrating hormone (MCH) as a neuromodulator are localized in the postero-lateral hypothalamus and incerto-hypothalamic area. These neurons project diffusely throughout the central nervous system and have been implicated in critical physiological processes, such as sleep. Unlike rodents, in the order carnivora as well as in humans, MCH exerts its biological functions through two receptors: MCHR-1 and MCHR-2. Hence, the cat is an optimal animal to model MCHergic functions in humans. In the present study, we examined the distribution of MCH-positive fibers in the brainstem of the cat. MCHergic axons with distinctive varicosities and boutons were heterogeneously distributed, exhibiting different densities in distinct regions of the brainstem. High density of MCHergic fibers was found in the dorsal raphe nucleus, the laterodorsal tegmental nucleus, the periaqueductal gray, the pendunculopontine tegmental nucleus, the locus coeruleus and the prepositus hypoglossi. Because these areas are involved in the control of REM sleep, the present anatomical data support the role of this neuropeptidergic system in the control of this behavioral state.

Melanin-concentrating hormone projections to the dorsal raphe nucleus: An immunofluorescence and in vivo microdialysis study.

Melanin-concentrating hormone (MCH)-containing neurons are localized in the lateral hypothalamus and incerto-hypothalamic areas, and project to several brain regions including the dorsal raphe nucleus (DRN). The MCHergic system has been involved in the regulation of emotional states and we have demonstrated that MCH microinjections into the rat DRN promote a depressive-like state. To understand the MCHergic transmission into the DRN, in the present study we characterized the distribution and density of the MCHergic fibers along the rostro-caudal axis of the rat DRN and their anatomical relationship with the 5-HT- and GABA-containing neurons. Additionally, a functional in vivo microdialysis study was carried out in order to evaluate the MCH effects on the 5-HT extracellular levels. Immunolabeling studies showed that MCHergic fibers were widely distributed throughout the rostro-caudal DRN extent and a reduced density at the most caudal level was observed. Interestingly, MCHergic fibers appeared in close apposition to 5-HT and GABA-containing neurons. Microdialysis studies evidenced an opposite effect of two concentrations of MCH on 5-HT levels: the lower concentration (30 µM) produced a significant and long-lasting (up to 120 min) decrease while the higher (100 µM) induced a slight and brief (20 min) increase. Morphological and functional results strongly suggest that both 5-HT- and GABA-containing neurons of the DRN are modulated by MCH. A different sensitivity of these neurons to MCH may explain the dose-response effect on 5-HT release. The decrease in extracellular 5-HT levels may account for the depressive-like effect induced by MCH reported in our previous studies.

MCH levels in the CSF, brain preproMCH and MCHR1 gene expression during paradoxical sleep deprivation, sleep rebound and chronic sleep restriction.

Neurons that utilize melanin-concentrating hormone (MCH) as neuromodulator are located in the lateral hypothalamus and incerto-hypothalamic area. These neurons project throughout the central nervous system and play a role in sleep regulation. With the hypothesis that the MCHergic system function would be modified by the time of the day as well as by disruptions of the sleep-wake cycle, we quantified in rats the concentration of MCH in the cerebrospinal fluid (CSF), the expression of the MCH precursor (Pmch) gene in the hypothalamus, and the expression of the MCH receptor 1 (Mchr1) gene in the frontal cortex and hippocampus. These analyses were performed during paradoxical sleep deprivation (by a modified multiple platform technique), paradoxical sleep rebound and chronic sleep restriction, both at the end of the active (dark) phase (lights were turned on at Zeitgeber time zero, ZT0) and during the inactive (light) phase (ZT8). We observed that in control condition (waking and sleep ad libitum), Mchr1 gene expression was larger at ZT8 (when sleep predominates) than at ZT0, both in frontal cortex and hippocampus. In addition, compared to control, disturbances of the sleep-wake cycle produced the following effects: paradoxical sleep deprivation for 96 and 120 h reduced the expression of Mchr1 gene in frontal cortex at ZT0. Sleep rebound that followed 96 h of paradoxical sleep deprivation increased the MCH concentration in the CSF also at ZT0. Twenty-one days of sleep restriction produced a significant increment in MCH CSF levels at ZT8. Finally, sleep disruptions unveiled day/night differences in MCH CSF levels and in Pmch gene expression that were not observed in control (undisturbed) conditions. In conclusion, the time of the day and sleep disruptions produced subtle modifications in the physiology of the MCHergic system.

Melanin-concentrating hormone (MCH) modulates the activity of dorsal raphe neurons.

Hypothalamic neurons that utilize melanin-concentrating hormone (MCH) as a neuromodulator are localized in the postero-lateral hypothalamus and incerto-hypothalamic area. These neurons send dense projections to the dorsal raphe nucleus (DRN). Serotonergic neurons of the DRN are involved in the control of sleep and play a critical role in major depression. Previously, we demonstrated that microinjections of MCH into the DRN resulted in an increase in REM sleep and produce a depressive-like effect. In the present study we examined the mechanisms that mediate these effects by employing neuroanatomical and electrophysiological techniques. First, we determined that rhodamine-labeled MCH (R-MCH), when microinjected into the lateral ventricle, is internalized in serotonergic and non-serotonergic DRN neurons in rats and cats. These data strongly suggest that these neurons express MCHergic receptors. Second, in rats, we demonstrated that the microinjection of MCH into the lateral ventricle results in a significant decrease in the firing rate in 59% of the neurons recorded in the DRN; the juxtacellular administration of MCH reduced the discharge in 80% of these neurons. Some of the neurons affected by MCH were likely serotonergic on the basis of their electrophysiological and pharmacological properties. We conclude that MCH reduces the activity of serotonergic neurons of the DRN. These and previous data suggest that the MCHergic modulation of serotonergic activity within the DRN is involved in the regulation of REM sleep as well as in the pathophysiology of depressive disorders.

Melanin-Concentrating Hormone (MCH): Role in REM Sleep and Depression.

The melanin-concentrating hormone (MCH) is a peptidergic neuromodulator synthesized by neurons of the lateral sector of the posterior hypothalamus and zona incerta. MCHergic neurons project throughout the central nervous system, including areas such as the dorsal (DR) and median (MR) raphe nuclei, which are involved in the control of sleep and mood. Major Depression (MD) is a prevalent psychiatric disease diagnosed on the basis of symptomatic criteria such as sadness or melancholia, guilt, irritability, and anhedonia. A short REM sleep latency (i.e., the interval between sleep onset and the first REM sleep period), as well as an increase in the duration of REM sleep and the density of rapid-eye movements during this state, are considered important biological markers of depression. The fact that the greatest firing rate of MCHergic neurons occurs during REM sleep and that optogenetic stimulation of these neurons induces sleep, tends to indicate that MCH plays a critical role in the generation and maintenance of sleep, especially REM sleep. In addition, the acute microinjection of MCH into the DR promotes REM sleep, while immunoneutralization of this peptide within the DR decreases the time spent in this state. Moreover, microinjections of MCH into either the DR or MR promote a depressive-like behavior. In the DR, this effect is prevented by the systemic administration of antidepressant drugs (either fluoxetine or nortriptyline) and blocked by the intra-DR microinjection of a specific MCH receptor antagonist. Using electrophysiological and microdialysis techniques we demonstrated also that MCH decreases the activity of serotonergic DR neurons. Therefore, there are substantive experimental data suggesting that the MCHergic system plays a role in the control of REM sleep and, in addition, in the pathophysiology of depression. Consequently, in the present report, we summarize and evaluate the current data and hypotheses related to the role of MCH in REM sleep and MD.

Prodepressive effect induced by microinjections of MCH into the dorsal raphe: time course, dose dependence, effects on anxiety-related behaviors, and reversion by nortriptyline.

Melanin-concentrating hormone (MCH) administered within the rat dorsal raphe nucleus (DRN) has been shown to elicit prodepressive behaviors in the forced-swim test. The present study was designed to evaluate the time course (30 and 60 min) and dose dependence (25-100 ng) of this effect, and whether it would be antagonized by an intra-DRN microinjection of the MCH-1 receptor antagonist ATC0175 (ATC, 1 mmol/l) or intraperitoneal pretreatment with the noradrenergic antidepressant nortriptyline (20 mg/kg). The results showed that the behavioral effect of MCH was time and dose dependent as immobility was increased, and climbing decreased, only by the 50 ng MCH dose at T30. The effect was mediated by MCH-1 receptors as a significant blockade of this behavioral response was observed in ATC-pretreated animals. ATC did not by itself modify animal behavior. Nortriptyline also prevented the prodepressive-like effect of MCH. Concomitantly, the effect of MCH (50 ng) at T30 on anxiety-related behaviors was assessed using the elevated plus-maze. Interestingly, these behaviors were unchanged. In conclusion, MCH administration within the DRN elicits, through the MCH-1 receptor, a depression-related behavior that is not accompanied by changes in anxiety and that is prevented by a noradrenergic antidepressant.

Avances en el estudio de la neurobiología de la depresión: rol de la hormona concentradora de melanina / Progress made in studies in the neurobiology of depression: a role for the melanin-concentrating hormone

Introducción: la depresión mayor (DM) es una enfermedad psiquiátrica frecuente, con importante morbilidad y una relación estrecha con el suicidio. Objetivo: hacer una puesta a punto de los avances en el estudio de la neurobiología de la DM, enfocándonos en el posible rol de la hormona concentradora de melanina (MCH) en esta patología. Metodología: revisión de la bibliografía con énfasis en nuestros propios trabajos originales. Resultados: la MCH es un neuromodulador peptídico sintetizado por neuronas del hipotálamo. Las neuronas MCHérgicas envían proyecciones hacia diversas regiones del sistema nervioso central, incluyendo las áreas vinculadas con la regulación de la vigilia y del sueño, así como a diversas estructuras del sistema límbico que participan en la regulación del humor. Aunque numerosos estudios han relacionado el sistema MCHérgico con el control de la homeostasis energética, hallazgos recientes han permitido señalar un rol de este sistema en los mecanismos de generación del sueño. A su vez, una convergencia de datos provenientes de diversos estudios sugiere que la MCH estaría involucrada en la fisiopatología de la DM. Nuestros propios estudios preclínicos tienden a indicar que la MCH promueve la generación del sueño REM y un estado tipo depresivo. Ambos efectos estarían siendo mediados a través de la modulación de la actividad de las neuronas serotoninérgicas del núcleo dorsal del rafe. Conclusiones: estudios preclínicos sugieren un rol protagónico del sistema MCHérgico en la fisiopatología de la depresión. Resta confirmar si esta afirmación es cierta en pacientes con DM. (AU)

Introduction: major depression disorder (MDD) is a common psychiatric condition, it has high morbility rates and is closely related to suicide.Objective: to provide an update in the study of the neurobiology of depression, focusing on the potential role of the melanin-concentrating hormone (MCH) in this condition.Method: a bibliographical review with an emphasis on our own original studies.Results: the melanin-concentrating hormone is a peptide neuromodulator syhthetized by neurones in the hypothalamus. MCHergic neurons send projection towards different areas in the central nervous system, including areas associated to the regulation of the sleep-wake cycle, as well as different structures in the limbic system that take part in the regulation of mood. In spite of several studies having proved the MCHergic system with the control of energetic homeostasis, recent findings have enabled to identify a role for this system in the sleep generator mechanisms. Similarly, data arising from several studies suggests that MCH would be involved in the major depression disorder. Our own preclinical studies tend to pint out the MCH promotes the generation of REM sleep and a type of depression. Apparently both effects would be mediated through the modulation of the activity on the serotoninergic neurons in the dorsal raphe nucleus.Conclusions: paraclinical studies suggest the leading role of the MCHergic system in the pathophysiology of depression. It is to be proved still, whether this affirmation is true for patients with major depression disorder.

Introdução: a depressão maior (DM) é uma enfermidade psiquiátrica frequente, com morbidade considerável e estreitamente relacionada com o suicídio.Objetivo: fazer uma atualização dos avanços no estudo da neurobiologia da DM, focando no possível papel do hormônio concentrador melanina (MCH) nesta patologia.Metodologia: revisão da bibliografia com ênfase em nossos trabalhos originais.Resultados: o MCH é um neuromodulador peptídico sintetizado pelos neurônios do hipotálamo. Os neurônios MCHérgicos enviam projeções a diversas regiões del sistema nervoso central, incluindo as áreas vinculadas com a regulação da vigília e do sono, bem como a diversas estruturas do sistema límbico que participam na regulação do humor. Embora numerosos estudos hajam relacionado o sistema MCHérgico com o controle da homeostase energética, descobrimentos recentes permitiram identificar um papel deste sistema nos mecanismos de geração do sono. Por outro lado, uma convergência de dados provenientes de diversos estudos sugere que o MCH estaria relacionado com a fisiopatologia da DM. Nossos estudos preclínicos tendem a indicar que o MCH promove a geração do sono REM e um estado tipo depressivo. Ambos efeitos estariam sendo mediados pela modulação da atividade dos neurônios serotoninérgicos do núcleo dorsal do rafe.Conclusões: estudos preclínicos sugerem um protagonismo do sistema MCHérgico na fisiopatologia da depressão. É necessário confirmar se esta afirmação é correta em pacientes com DM.

Avances en el estudio de la neurobiología de la depresión: rol de la hormona concentradora de melanina / Progress made in studies in the neurobiology of depression: a role for the melanin-concentrating hormone

Introducción: la depresión mayor (DM) es una enfermedad psiquiátrica frecuente, con importante morbilidad y una relación estrecha con el suicidio. Objetivo: hacer una puesta a punto de los avances en el estudio de la neurobiología de la DM, enfocándonos en el posible rol de la hormona concentradora de melanina (MCH) en esta patología. Metodología: revisión de la bibliografía con énfasis en nuestros propios trabajos originales. Resultados: la MCH es un neuromodulador peptídico sintetizado por neuronas del hipotálamo. Las neuronas MCHérgicas envían proyecciones hacia diversas regiones del sistema nervioso central, incluyendo las áreas vinculadas con la regulación de la vigilia y del sueño, así como a diversas estructuras del sistema límbico que participan en la regulación del humor. Aunque numerosos estudios han relacionado el sistema MCHérgico con el control de la homeostasis energética, hallazgos recientes han permitido señalar un rol de este sistema en los mecanismos de generación del sueño. A su vez, una convergencia de datos provenientes de diversos estudios sugiere que la MCH estaría involucrada en la fisiopatología de la DM. Nuestros propios estudios preclínicos tienden a indicar que la MCH promueve la generación del sueño REM y un estado tipo depresivo. Ambos efectos estarían siendo mediados a través de la modulación de la actividad de las neuronas serotoninérgicas del núcleo dorsal del rafe. Conclusiones: estudios preclínicos sugieren un rol protagónico del sistema MCHérgico en la fisiopatología de la depresión. Resta confirmar si esta afirmación es cierta en pacientes con DM...

Melanin-concentrating hormone control of sleep-wake behavior.

The melanin-concentrating hormone (MCH) is a 19 aminoacid peptide found in mammals predominantly in neurons located in the lateral hypothalamus and incerto-hypothalamic area. The biological function of MCH is mediated by two G-protein-coupled receptors known as MCHR1 and MCHR2, although the latter is expressed only in carnivores, primates and man. The MCHR1 couples to Gi, Gq and Go proteins, with Gi leading to the inhibition of both excitatory and inhibitory synaptic events. Within the central nervous system (CNS) MCH participates in a number of functions including sleep-wake behavior. In this respect, MCHergic neurons project widely throughout the CNS to brain regions involved in the regulation of behavioral states. MCHergic neurons are silent during wakefulness (W), increase their firing during slow wave sleep (SWS) and still more during REM sleep (REMS). Studies in knockout mice for MCH (MCH(-/-)) have shown a reduction in SWS and an increase of W during the light and the dark phase of the light-dark cycle. Moreover, in response to food deprivation a marked reduction in REMS time was observed in these animals. Conflicting effects on sleep variables have been reported in MCHR1(-/-) mice by different authors. The i.c.v. administration of MCH increases REMS and SWS in the rat. In addition, an enhancement of REMS has been described following the microinjection of the neuropeptide into the nucleus pontis oralis of the cat, while its infusion into the dorsal raphe nucleus (DR) and the basal forebrain (horizontal limb of the diagonal band of Broca) is followed by an increase of REMS and a reduction of W in the rat. Immunoneutralization of MCH in the DR augmented W and suppressed REMS in the rat, as did the s.c. injection of selective MCHR1 antagonists. The robust REMS-inducing effect of MCH is likely related to the deactivation of monoaminergic, orexinergic, glutamatergic, cholinergic (W-on) and GABAergic (REM-off) neurons involved in the generation of W and the inhibition of REMS. On the basis of preclinical studies, it can be proposed that selective MCHR1 receptor agonists could constitute potential therapeutic modalities in the arsenal of insomnia pharmacotherapy. Due to the lack of adequate animal models, the role of the MCHR2 on sleep is still unknown.

Microinjection of melanin concentrating hormone into the lateral preoptic area promotes non-REM sleep in the rat.

The ventrolateral preoptic area (VLPO) has been recognized as one of the key structures responsible for the generation of non-REM (NREM) sleep. The melanin-concentrating hormone (MCH)-containing neurons, which are located in the lateral hypothalamus and incerto-hypothalamic area, project widely throughout the central nervous system and include projections to the VLPO. The MCH has been associated with the central regulation of feeding and energy homeostasis. In addition, recent findings strongly suggest that the MCHergic system promotes sleep. The aim of the present study was to determine if MCH generates sleep by regulating VLPO neuronal activity. To this purpose, we characterized the effect of unilateral and bilateral microinjections of MCH into the VLPO on sleep and wakefulness in the rat. Unilateral administration of MCH into the VLPO and adjacent dorsal preoptic area did not modify sleep. On the contrary, bilateral microinjections of MCH (100 ng) into these areas significantly increased light sleep (LS, 39.2±4.8 vs. 21.6±2.5 min, P<0.05) and total NREM sleep (142.4±23.2 vs. 86.5±10.5 min, P<0.05) compared to control (saline) microinjections. No effect was observed on REM sleep. We conclude that MCH administration into the VLPO and adjacent dorsal lateral preoptic area promotes the generation of NREM sleep.

Microinjection of the 5-HT7 receptor antagonist SB-269970 into the rat brainstem and basal forebrain: site-dependent effects on REM sleep.

The effects of SB-269970, a selective 5-HT7 receptor antagonist, on spontaneous sleep were studied in adult rats implanted for chronic sleep recordings. The 5-HT7 receptor ligand was microinjected into the horizontal limb of the diagonal band of Broca (HDB) and the laterodorsal tegmental nucleus (LDT) during the light period of the 12-h light/12-h dark cycle. For comparative purposes the compound was administered systemically and, in addition, injected directly into the dorsal raphe nucleus (DRN). Microinjection of SB-269970 into the HDB and the DRN induced a significant reduction of rapid-eye-movement sleep (REMS). Similar effects were observed after systemic administration of the 5-HT7 receptor antagonist. On the other hand, local infusion of the compound into the LDT provoked the opposite effect. It is proposed that the deactivation of GABAergic cells located in the HDB, DRN and LDT is responsible for the changes induced by SB-269970 on REM sleep values. It is suggested that the antidepressant effect of the 5-HT7 receptor antagonist could partly depend on the involvement of neuronal systems located in the DRN and the HDB.

Microinjection of the melanin-concentrating hormone into the lateral basal forebrain increases REM sleep and reduces wakefulness in the rat.

AIMS: To examine the effects of bilateral microinjection of melanin-concentrating hormone (MCH) 50 and 100 ng into the horizontal limb of the diagonal band of Broca (HDB) on sleep variables during the light phase of the light-dark cycle of the rat. MAIN METHODS: Male Wistar rats were implanted for chronic sleep recordings. In addition, a guide cannula was implanted above the right and left HDB. Following the microinjection of MCH or control solution the electroencephalogram and the electromyogram were recorded for 6 h. Data was collected and classified as either wakefulness (W), light sleep, slow wave sleep (SWS) or REM sleep (REMS). Latencies for SWS and REMS, as well as the number of REM periods and the mean duration of REM episodes were also determined. KEY FINDINGS: MCH 50 and 100 ng significantly decreased W during the first 2-h of recording. Moreover, MCH 100 ng significantly reduced REMS latency and increased REMS time during the first 2-h block of the recording, due to an increase in the number of REM periods. SIGNIFICANCE: Our findings tend to suggest that the basal forebrain participates in the effects of MCH on W and REMS through the deactivation of cholinergic, glutamatergic and γ-aminobutyric acid (GABA)-ergic cells.