89 research outputs found

    In vitro model for the study of the role of the mesopontine region in rapid eye movement (REM) sleep and wakefulness

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    Esteban Pino: Laboratorio de Neurofisiología Celular y Sináptica. Dpto. de Fisiología, Facultad de Medicina. Universidad de la República.-- Héctor Kunizawa: Laboratorio de Neurofisiología Celular y Sináptica. Dpto. de Fisiología, Facultad de Medicina. Universidad de la República.-- Jack Yamuy: A Greater Los Angeles Healthcare System; UCLA School of Medicine, Los Angeles, USA.-- Michel Borde: Laboratorio de Neurofisiología Celular y Sináptica. Dpto. de Fisiología, Facultad de Medicina. Universidad de la República.-- Contacto: Michel Borde. E-mail: [email protected] estudio de las estrategias neurales para la organización del comportamiento en vertebrados constituye un desafío mayor para la Neurociencia. El avance del conocimiento en este campo depende de manera crítica de la utilización de modelos experimentales adecuados que admitan múltiples niveles de análisis (p.ej: comportamental, circuital, celular, sináptico, molecular) y abordajes multitécnicos. Nos propusimos analizar in vitro una red neural de la unión mesopontina del tronco encefálico crítica-mente implicada en el control del sueño de movimientos oculares rápidos (S-REM). Pese al cúmulo de evidencias que apoyan el papel desempeñado por esta red en relación al S-REM, los mecanismos celu-lares y sinápticos que subyacen a este control son poco conocidos y continúan siendo objeto de intensa investigación. Para avanzar en el conocimiento de estos mecanismos, se llevó a cabo la caracterización morfológica y funcional de una rodaja de tronco encefálico de la rata, en la que las estructuras críticas para el control del S-REM, i.e.: núcleos tegmentales laterodorsal y pedúnculopontino, y su proyección al núcleo reticular pontis oralis (PnO), están presentes y son operativas. La inclusión del núcleo mo-tor del trigémino en la rodaja permitió detectar cambios de la excitabilidad de las motoneuronas ante manipulaciones farmacológicas del PnO, representativos de los cambios del tono muscular asociados a maniobras similares realizadas in vivo. La utilización de este modelo in vitro de S-REM, permitirá aportar a la dilucidación de las estrategias neurales que operan en niveles intermedios de organización del SN en mamíferos para la generación y regulación de un estado comportamental.The study of the neural basis of behavior is a major challenge in Neuroscience. Advancing our knowledge in this field depends, critically, on the use of experimental paradigms that provide multiple levels of analysis, as well as powerful techniques. We have selected, as a model of a neural plan that organizes a complex behavior, a neural network located in the mesopontine junction. This region is thought to be both necessary and sufficient for the generation of rapid eye movement (REM) sleep, although the cellular and synaptic mechanisms involved in the control of this behavioral state at the mesopontine level are still under debate and remain poorly understood. As part of a long term effort to gain insight into these mechanisms, we carried out the morphological and functional characterization of a slice preparation of rat brainstem and we demonstrate that critical structures for the control of REM sleep - the laterodorsal and pedunculopontine tegmental nuclei and their projection to the oral part of the pontine reticular nucleus (PnO) - are present and are operational. The presence of the tri-geminal motor nucleus in the slice sought to include in the experimental model a structure capable of expressing changes of the excitability of the motorneurons caused by pharmacological manipulations of the PnO, representative of changes of muscle tone associated with similar maneuvers performed in vivo. The use of this in vitro model of REM sleep will provide critical information to elucidate neural strategies that operate at intermediate levels of central nervous system organization in mammals to control behavioral states.O estudo de estratégias neurais para a organização do comportamento em vertebrados constitui um desafio maior para a neurociencia. O avanço do conhecimento nessa área depende criticamente da utilização de modelos experimentais adequados que suportem múltiplos níveis de análise (por exemplo: comportamental, circuital, celular, sináptico e molecular) e abordagens por múltiplas técnicas. Decidiu-se analisar in vitro uma rede neural da união mesopontina do tronco encefálico criticamente envolvida no controle do sono de movimentos oculares rápidos (S-REM). Apesar da riqueza de provas que sustentam o papel desta rede em relação ao S-REM, os mecanismos celulares e sinápticos subja-centes a este controle são pouco conhecidos e permanecem sob intensa investigação. Para avançar no conhecimento desses mecanismos, caracterizou-se morfológica e funcionalmente uma fatia de tronco encefálico de rato, na qual as estruturas críticas para o controle do S-REM, i.e.: núcleos tegmentais laterodorsal e pedunculopontino, e sua projeção para o núcleo reticular pontis oralis (PnO) estão pre-sentes e operantes. A inclusão do núcleo motor do trigêmeo na fatia permitiu detectar mudanças da ex-citabilidade das motoneuronas provocadas por manipulações farmacológicas do PnO, representativas das alterações do tônus muscular associados com operações semelhantes quando realizados in vivo. A utlização deste modelo in vitro de S-REM permitirá contribuir para a elucidação de estratégias neurais que operam em níveis intermedios de organização do SN de mamíferos para a geração e regulação de um estado comportamental

    Clinical and polysomnographic course of childhood narcolepsy with cataplexy.

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    Our aim was to investigate the natural evolution of cataplexy and polysomnographic features in untreated children with narcolepsy with cataplexy. To this end, clinical, polysomnographic, and cataplexy-video assessments were performed at diagnosis (mean age of 10 ± 3 and disease duration of 1 ± 1 years) and after a median follow-up of 3 years from symptom onset (mean age of 12 ± 4 years) in 21 children with narcolepsy with cataplexy and hypocretin 1 deficiency (tested in 19 subjects). Video assessment was also performed in two control groups matched for age and sex at first evaluation and follow-up and was blindly scored for presence of hypotonic (negative) and active movements. Patients' data at diagnosis and at follow-up were contrasted, compared with controls, and related with age and disease duration. At diagnosis children with narcolepsy with cataplexy showed an increase of sleep time during the 24 h; at follow-up sleep time and nocturnal sleep latency shortened, in the absence of other polysomnographic or clinical (including body mass index) changes. Hypotonic phenomena and selected facial movements decreased over time and, tested against disease duration and age, appeared as age-dependent. At onset, childhood narcolepsy with cataplexy is characterized by an abrupt increase of total sleep over the 24 h, generalized hypotonia and motor overactivity. With time, the picture of cataplexy evolves into classic presentation (i.e., brief muscle weakness episodes triggered by emotions), whereas total sleep time across the 24 h decreases, returning to more age-appropriate levels

    Complex movement disorders at disease onset in childhood narcolepsy with cataplexy

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    Narcolepsy with cataplexy is characterized by daytime sleepiness, cataplexy (sudden loss of bilateral muscle tone triggered by emotions), sleep paralysis, hypnagogic hallucinations and disturbed nocturnal sleep. Narcolepsy with cataplexy is most often associated with human leucocyte antigen-DQB1*0602 and is caused by the loss of hypocretin-producing neurons in the hypothalamus of likely autoimmune aetiology. Noting that children with narcolepsy often display complex abnormal motor behaviours close to disease onset that do not meet the classical definition of cataplexy, we systematically analysed motor features in 39 children with narcolepsy with cataplexy in comparison with 25 age- and sex-matched healthy controls. We found that patients with narcolepsy with cataplexy displayed a complex array of ‘negative’ (hypotonia) and ‘active’ (ranging from perioral movements to dyskinetic–dystonic movements or stereotypies) motor disturbances. ‘Active’ and ‘negative’ motor scores correlated positively with the presence of hypotonic features at neurological examination and negatively with disease duration, whereas ‘negative’ motor scores also correlated negatively with age at disease onset. These observations suggest that paediatric narcolepsy with cataplexy often co-occurs with a complex movement disorder at disease onset, a phenomenon that may vanish later in the course of the disease. Further studies are warranted to assess clinical course and whether the associated movement disorder is also caused by hypocretin deficiency or by additional neurochemical abnormalities

    Role of the Lateral Paragigantocellular Nucleus in the Network of Paradoxical (REM) Sleep: An Electrophysiological and Anatomical Study in the Rat

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    The lateral paragigantocellular nucleus (LPGi) is located in the ventrolateral medulla and is known as a sympathoexcitatory area involved in the control of blood pressure. In recent experiments, we showed that the LPGi contains a large number of neurons activated during PS hypersomnia following a selective deprivation. Among these neurons, more than two-thirds are GABAergic and more than one fourth send efferent fibers to the wake-active locus coeruleus nucleus. To get more insight into the role of the LPGi in PS regulation, we combined an electrophysiological and anatomical approach in the rat, using extracellular recordings in the head-restrained model and injections of tracers followed by the immunohistochemical detection of Fos in control, PS-deprived and PS-recovery animals. With the head-restrained preparation, we showed that the LPGi contains neurons specifically active during PS (PS-On neurons), neurons inactive during PS (PS-Off neurons) and neurons indifferent to the sleep-waking cycle. After injection of CTb in the facial nucleus, the neurons of which are hyperpolarized during PS, the largest population of Fos/CTb neurons visualized in the medulla in the PS-recovery condition was observed in the LPGi. After injection of CTb in the LPGi itself and PS-recovery, the nucleus containing the highest number of Fos/CTb neurons, moreover bilaterally, was the sublaterodorsal nucleus (SLD). The SLD is known as the pontine executive PS area and triggers PS through glutamatergic neurons. We propose that, during PS, the LPGi is strongly excited by the SLD and hyperpolarizes the motoneurons of the facial nucleus in addition to local and locus coeruleus PS-Off neurons, and by this means contributes to PS genesis

    Gene Expression Profiling of Two Distinct Neuronal Populations in the Rodent Spinal Cord

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    BACKGROUND: In the field of neuroscience microarray gene expression profiles on anatomically defined brain structures are being used increasingly to study both normal brain functions as well as pathological states. Fluorescent tracing techniques in brain tissue that identifies distinct neuronal populations can in combination with global gene expression profiling potentially increase the resolution and specificity of such studies to shed new light on neuronal functions at the cellular level. METHODOLOGY/PRINCIPAL FINDINGS: We examine the microarray gene expression profiles of two distinct neuronal populations in the spinal cord of the neonatal rat, the principal motor neurons and specific interneurons involved in motor control. The gene expression profiles of the respective cell populations were obtained from amplified mRNA originating from 50-250 fluorescently identified and laser microdissected cells. In the data analysis we combine a new microarray normalization procedure with a conglomerate measure of significant differential gene expression. Using our methodology we find 32 genes to be more expressed in the interneurons compared to the motor neurons that all except one have not previously been associated with this neuronal population. As a validation of our method we find 17 genes to be more expressed in the motor neurons than in the interneurons and of these only one had not previously been described in this population. CONCLUSIONS/SIGNIFICANCE: We provide an optimized experimental protocol that allows isolation of gene transcripts from fluorescent retrogradely labeled cell populations in fresh tissue, which can be used to generate amplified aRNA for microarray hybridization from as few as 50 laser microdissected cells. Using this optimized experimental protocol in combination with our microarray analysis methodology we find 49 differentially expressed genes between the motor neurons and the interneurons that reflect the functional differences between these two cell populations in generating and transmitting the motor output in the rodent spinal cord

    Modelo in vitro para el estudio del papel de la unión mesopontina en la generación del sueño de movimientos oculares rápidos y la vigilia

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    El estudio de las estrategias neurales para la organización del comportamiento en vertebrados constituye un desafío mayor para la Neurociencia. El avance del conocimiento en este campo depende de manera crítica de la utilización de modelos experimentales adecuados que admitan múltiples niveles de análisis (p;ej: comportamental, circuital, celular, sináptico, molecular) y abordajes multitécnicos. Nos propusimos analizar in vitro una red neural de la unión mesopontina del tronco encefálico críticamente implicada en el control del sueño de movimientos oculares rápidos (S-REM). Pese al cúmulo de evidencia que apoyan el papel desempeñado por esta red en relación al S-REM, los mecanismos celulares y sinápticos que subyacen a este control son poco conocidos y continúan siendo objeto de intensa investigación.Para avanzar en el conocimiento de estos mecanismos, se llevó a cabo la caracterización morfológica y funcional de una rodaja de tronco encefálico de la rata, en la que las estructuras críticas para el control del  S-REM,  i;e;: núcleos tegmentales laterodorsal y pedúnculopontino, y su proyección al núcleo reticular pontis oralis (PnO), están presentes y son operativas. La inclusión del núcleo motor del trigémino en la rodaja permitió detectar cambios de la excitabilidad de las motoneuronas ante manipulaciones farmacológicas del PnO, representativos de los cambios del tono muscular asociados a maniobras similares realizadas in vivo. La utilización de este modelo in vitro de S-REM, permitirá aportar a la dilucidación de las estrategias neurales que operan en niveles intermedios de organización del SN en mamíferos para la generación y regulación de un estado comportamental
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