Prodromes and biological markers in schizophrenia: Importance for the dopamine, glutamate, and neurodevelopmental hypothesis / Pródromos e indicadores biológicos en la esquizofrenia: Importancia para la hipótesis dopaminérgica, glutamatérgica y del neurodesarrollo

Abstract Background Since schizophrenia is a multifactorial mental illness, a basic understanding of its etiological components improves its understanding, diagnosis, and the selection of therapeutic targets. Objective To identify the prodromes and biological markers in schizophrenic or ultra-high risk (UHR) patients and elucidate their specificity. Method Narrative review of relevant sources in English and Spanish in the Medline-PubMed database on minor physical abnormalities, cognitive abnormalities, neuroanatomical, and synaptic and cell changes present in schizophrenic patients and/or subjects with a high risk of developing schizophrenia Results Patients with SZ and, to a lesser extent, UHR subjects present phenotypic and behavioral manifestations that correlate with underlying cell processes. The study of the latter makes it possible to characterize diagnostic biomarkers. At present, its clinical application is limited by factors such as poorly understood pathophysiology, lack of study models, homology with other psychiatric disorders, and the dearth of clinical trials conducted. Discussion and conclusion Schizophrenia is the final manifestation of damage to prenatal and post-natal neurodevelopment and is reflected during the prodromal stage in early biological markers with clinical relevance. It is necessary to establish new study models that will increase knowledge to offer specific biomarkers for use in early clinical diagnosis.

Resumen Antecedentes La esquizofrenia es una enfermedad mental multifactorial. Una comprensión básica de sus componentes etiológicos mejora su entendimiento, su diagnóstico y la selección de posibles blancos terapéuticos. Objetivo Reportar los pródromos e indicadores biológicos en pacientes esquizofrénicos o de ultra-alto riesgo (UHR) y dilucidar su especificidad. Método Revisión narrativa de fuentes relevantes en inglés y español en la base de datos Medline-PubMed sobre las anomalías física menores, anomalías cognitivas, cambios neuroanatómicos, sinápticos y celulares presentes en pacientes esquizofrénicos y/o en sujetos de UHR. Resultados Los pacientes con EZ y, de manera menos predominante, los sujetos de UHR presentan manifestaciones fenotípicas y conductuales que se correlacionan con los procesos celulares subyacentes. El estudio de éstos permite caracterizar diferentes biomarcadores diagnósticos. En la actualidad, su aplicación en la clínica es limitada por distintos factores como son la fisiopatología poco comprendida, la falta de modelos de estudio, la homología con otros trastornos psiquiátricos y los escasos ensayos clínicos realizados. Discusión y conclusión La esquizofrenia es la manifestación final de daños en el neurodesarrollo prenatal y post-natal, y se refleja durante la etapa prodrómica en indicadores biológicos tempranos con relevancia clínica. Se requiere establecer nuevos modelos de estudio que permitan ampliar el conocimiento para ofrecer biomarcadores específicos para ser usados en el diagnóstico clínico temprano.

Efectos de la melatonina sobre la macro-arquitectura del sueño en pacientes con demencia tipo Alzheimer / Melatonin effects on macro arquitecture sleep in Alzheimer's disease patients

The objective of the present study was to evaluate the 5 mg. melatonin effects on the sleep macro-architecture in eight patients with middle to moderate Alzheimer's disease (DTA). Using the polysomnography technique (PSG), we made a simple-blind, non-randomized, controlled with placebo study. The PSG was carried out according to the following order: night 1: placebo administration; night 2 and 3: continues melatonin administration. In the first night with melatonin treatment, the sleep latency to the first episode of Stage 2, Delta and REM sleep, was significantly diminished as compared with placebo (≤.05). No significant difference in total time of each sleep stage and sleep efficiency was observed. Nevertheless, a tendency to diminish the total time of nocturnal wake and increase of the total sleep time in the second night with melatonin treatment was observed. We conclude that melatonin can improve sleep in patients with middle to moderate DTA.

El objetivo del presente estudio fue determinar los efectos de 5 mg. de melatonina de liberación inmediata sobre la macro-arquitectura del sueño en ocho pacientes con diagnóstico de Demencia Tipo Alzheimer (DTA) de media a moderada. Utilizando la técnica polisomnográfica (PSG) se realizó un estudio simple ciego, no aleatorio, controlado con placebo. Los registros PSG se llevaron a cabo de la siguiente manera: Noche 1: administración de placebo; noche 2 y 3: administración continua de melatonina (5 mg). Observamos que el tratamiento con melatonina durante la primera noche de administración disminuyó significativamente la latencia de la fase 2, del sueño de ondas delta y el sueño de MOR al ser comparadas con el placebo (P ≤.05). No se observaron diferencias significativas en el tiempo total de cada fase de sueño; tampoco se observaron diferencias en la eficiencia del sueño en presencia de la melatonina. Sin embargo se observó una tendencia a la disminución del tiempo total de vigilia y un aumento del tiempo total de sueño, principalmente durante la segunda noche de tratamiento. Concluimos que la melatonina puede mejorar el sueño en pacientes con DTA de media a moderada.

La melatonina como un factor promotor de la diferenciación neuronal: implicaciones en el tratamiento de las demencias / Melatonin as a neuronal differentiation factor: therapeutic implications for dementia

Dementias are progressive and neurodegenerative neuropsychiatry disorders, with a high worldwide prevalence. These disorders affect memory and behavior, causing impairment in the performance of daily activities and general disability in the elders. Cognitive impairment in these patients is related to anatomical and structural alterations at cellular and sub-cellular levels in the Central Nervous System. In particular, amyloid plaques and neurofibrillar tangles have been defined as histopathological hallmarks of Alzheimer's disease. Likewise, oxidative stress and neuroinflammation are implicated in the etiology and progression of the disease. Neuronal precursors from human olfactory neuroepithelium have been recently characterized as an experimental model to identify neuropsychiatric disease biomarkers. Moreover, this model not only allows the study of neuropsychiatric physiopathology, but also the process of neurodevelopment at cellular, molecular and pharmacological levels. This review gathers the evidence to support the potential therapeutic use of melatonin for dementias, based on its antioxidant properties, its anti-inflammatory effect in the brain, and its ability to inhibit both tau hyper-phosphorylation and amyloid plaque formation. Furthermore, since melatonin stimulates neurogenesis, and promotes neuronal differentiation by inducing the early stages of neuritogenesis and dendrite formation, it has been suggested that melatonin could be useful to counteract the cognitive impairment in dementia patients.

Las demencias son enfermedades neuropsiquiátricas, progresivas, neurodegenerativas y con una alta prevalencia a nivel mundial. Ocupan uno de los primeros lugares como enfermedades que causan incapacidad en los adultos mayores. En estos pacientes el Sistema Nervioso Central presenta alteraciones anatómico-estructurales a nivel celular y subcelular que se asocian con deficiencias cognitivas. En particular, en la enfermedad de Alzheimer se han caracterizado marcadores histopatológicos como las placas amiloides y las marañas neurofibrilares. Se sabe que el estrés oxidativo y la neuroinflamación participan en la etiología y el desarrollo de la enfermedad. Recientemente se caracterizó a los precursores neuronales del neuroepitelio olfatorio humano como un modelo experimental adecuado para identificar biomarcadores de rasgo y para estudiar la fisiopatología de diversas enfermedades neuropsiquiátricas, así como el proceso del neurodesarrollo, a nivel celular, molecular y farmacológico. En este trabajo se presenta la evidencia que sustenta que la melatonina puede ser útil en el tratamiento de las demencias, por su capacidad antioxidante, por su efecto anti-inflamatorio, así como por el efecto inhibidor de la hiperfosforilación de la proteina tau y de la formación de placas amiloides. Además, al estimular la formación de nuevas neuronas, la neuritogénesis en sus etapas tempranas y la formación de dendritas, la melatonina podría contribuir a contrarrestar la pérdida de las funciones cognitivas que se observa en estos padecimientos.

El cultivo de precursores neuronales del epitelio olfatorio: Un modelo para estudiar la neurofisiopatología de la esquizofrenia / The culture of olfactory ephitelium neuronal precursors: A model for studying schizophrenia neurophysiopathology

Schizophrenia is a mental disorder characterized by delusions, hallucinations, disorganization in speech and thinking as well as alterations in social behavior, and affective flattening. Schizophrenic patients also have an olfactory deficit since prodromal stages of this disorder. The olfactory deficit could be present in schizophrenic patients due to anatomic and structural alteration of the Central Nervous System, or peripheral abnormalities in the olfactory epithelium. The major alterations of the Central Nervous System are diminished volumes of olfactory bulb and structures of primary olfactory cortex, hippocampus and amygdala. While, olfactory epithelium has functional abnormalities in cellular differentiation and electric response of sensory olfactory neurons, which suggest an impairment of the odor transduction. The cellular culture of olfactory epithelium has allowed isolating multipotential progenitor cells that have the ability to proliferate and differentiate in mature neurons and glia. This model could provide evidences on the causes that could explain the olfactory deficits in schizophrenia. Moreover, it will allow testing hypothesis on pathophysiological causes of this mental disorder in different of stages of the neurodevelopment. In addition, olfactory epithelial neuronal precursors constitute a novel model to detect genetic, proteomic and functional biomarkers that allow a biological diagnosis.

La esquizofrenia (EZ) es un trastorno psiquiátrico que se caracteriza por la presencia de delirios, alucinaciones, pensamiento desorganizado, lenguaje desestructurado, alteraciones del comportamiento social y aplanamiento afectivo, entre otros síntomas. Los pacientes con EZ también presentan un déficit en la capacidad olfatoria desde la fase prodrómica del trastorno. El déficit olfatorio en la EZ puede presentarse por alteraciones anatómico-estructurales del SNC o por anomalías a nivel periférico en el epitelio olfatorio. Las alteraciones principales del SNC son la disminución del volumen de los bulbos olfatorios, de estructuras de la corteza olfatoria primaria, del hipocampo y de la amígdala coronal. El epitelio olfatorio en los estadios tempranos de la EZ presenta anomalías funcionales en la diferenciación y en la respuesta biofísica de las neuronas sensoriales olfatorias, lo que sugiere que existe un desacoplamiento de la transducción olfatoria. El cultivo celular del epitelio olfatorio ha permitido aislar células progenitoras multipotenciales que poseen la capacidad de proliferar y diferenciarse en neuronas y glía. El estudio de este modelo podría aportar evidencia sobre las causas que explicarían el déficit olfatorio en la esquizofrenia y permitiría estudiar hipótesis que intenten explicar las causas de la fisiopatología de este trastorno en el neurodesarrollo así como detectar biomarcadores genéticos, proteómicos o funcionales que permitan un diagnóstico biológico.

Alteraciones del ciclo circadiano en las enfermedades psiquiátricas: papel sincronizador de la melatonina en el ciclo sueño-vigilia y la polaridad neuronal / Circadian cycle alterations in psychiatric diseases: melatonin role as a synchronizer of sleep-awake cycle and the neuronal polarity

Circadian rhythms are oscillations of physiological functions. The period of their oscillation is about 24 h, and can be synchronized by environmental periodic signals as night-day cycle. The endogenous periodical changes depend on various structural elements of the circadian system which consists of the effectors, the secondary oscillators, the synchronizers and the circadian pacemaker. In mammalian species, the physiological function better understood respect their oscillation pattern are the synthesis and release of several hormones (i.e. cortisol and melatonin), the body temperature, the sleep-awake cycle, the locomotive activity, cell proliferation, neuronal activity among other rhythms. The Suprachiasmatic nucleus is the main circadian pacemarker in mammals; its oscillation keeps the circadian system synchronized particularly with respect to the environment photo period. When light reaches the pigment melanopsin in ganglionar neurons in the retina, the photoperiod signal is sent to Suprachiasmatic nucleus, and its postsinaptic neurons distributes the temporal signal to pheripheral oscillators by nervous or humoral pathways. Among the oscillators, the pineal gland is a peripheral one modulated by Suprachiasmatic nucleus. At night, the indolamine melatonin is synthesized and released from pinealocytes, and reaches other peripheral oscillators. Melatonin interacts with membrane receptors on Suprachiasmatic nucleus pacemarker neurons, reinforcing the signal of the photoperiod. In mammals, exogenous melatonin synchronizes several circadian rhythms including locomotive activity and melatonin release. When this indolamine is applied directly into the Suprachiasmatic nucleus, it produces a phase advance of the endogenous melatonin peak and increases the amplitude of the oscillation. In humans, melatonin effect on the circadian system is evident because it changes the circadian rhythms phase in subjects with advanced sleep-phase syndrome, night workers or blind people. Also it reduces jet lag symptoms enhancing sleep quality and reseting the circadian system to local time. Melatonin effects on circadian rhythms indicate their role as a chronobiotic, since decreased daily melatonin levels that occur with age and in neuropsychiatric disorders are associated with disturbances in the sleep-awake cycle. In particular, it has been described that Alzheimer's disease patients have disturbed sleep-awake cycle and have decreased serum melatonin levels. Sleep disorders in Alzheimer's disease patients decrease when they are treated with melatonin. Moreover, sleep disturbances have been observed in bipolar disorder patients and often precede relapses of insomnia-associated mania and hypersomnia-associated depression. These disturbances are linked to delayed- and advanced- phases of circadian rhythms or arrhythmia; therefore, it has been suggested that bipolar disorder patients could be treated with light and dark therapy. In depressed patients, the levels of melatonin are low throughout the 24 hour period and have a delayed onset of the indolamine concentration and showed an advance of its peak. Schizophrenic patients have decreased levels in the plasmatic melatonin in both phases of the light-dark cycle. Melatonin administration to these patients increases their sleep efficiency. In addition, melatonin acts as a neuroprotector because of its potent antioxidant action and through its cytoskeletal modulation properties. In neurodegenerative animal models, its protector effect has been observed using okadaic acid. This neurotoxin is employed for reproducing cytoskeletal damage in neurons and increased oxidative stress levels, which are molecular events similar to those that occur in Alzheimer's disease. In N1E-115 cell cultures incubated with okadaic acid, the administration of melatonin diminishes hyperphosphorylated tau and oxidative stress levels, and prevents the neurocytoskeletal damage caused by the neurotoxin. Although it is known that melatonin plays a key role in the circadian rhythms entrainment, little is known about its synchronizing effects at molecular and structural level. In algae, it has been observed a link between morphological changes and the light-dark cycle and it is known that shape is determinated by the cytoskeletal structure. In particular, the alga Euglena gracilis changes its shape two times per day under the effect of a daily light-dark cycle. This alga has a long shape when there is a higher photosynthetic capacity at the half period of the day; on the contrary, it showed a rounded shape at the end of 24 h cycle. Also, the influence of the cell shape changes on the photosynthetic reactions was investigated by altering them with drugs that disrupt the cytoskeletal structure as cytochalasin B and colchicine. Both inhibitors blocked the rhythmic shape changes and the photo-synthetic rhythm. Moreover, there are some reports about cytoskeletal changes in plants targeted by circadian rhythms. Guarda cells of Vicia faba L. showed a diurnal cycle on the alpha and beta tubulin levels. In addition, it has been proposed that melatonin synchronizes different body rhythms through cytoskeletal rearrangements. In culture cells, nanomolar melatonin concentrations cause an increase in both the polimerization rate and microtubule formation through calmodulin antagonism. A cyclic pattern produced by melatonin in the actin microfilament organization has been demonstrated in canine kidney cells. Cyclic incubation of MDCK cells with nanomolar concentrations of melatonin, resembling the cyclic pattern of secretion and release to plasma produces a microfilament reorganization and the formation of domes. Studies in animals are controvertial regarding if the amount of microtubules in different tissues varies cyclically. In rats and baboons, melatonin administration or exposure of rats to darkness induced an increased number of microtubules in the pineal gland. However, in the hypothalamus, the exposure of rats to light resulted in an increase in the microtubular protein content. Similarly, (X-tubulin mRNA was augmented during the light phase in the hypothalamus, hippocampus and cortex. By contrast, in rats maintained in constant darkness, a decreased level in the tubulin content was observed in the visual cortex. Additional information on cycle variations observed in cytoskeletal molecules indicated that beta actin mRNA levels are lower during the day in the hippocampus and cortex. But no change was observed in actin protein levels in the cerebral cortex. However, increased levels of actin and its mRNA were observed in the hypothalamus. Exogenous melatonin administration at onset of night decreased the amount of actin in the hypothalamus, while the actin mRNA levels decreased when the administration was realized in the morning. In this review we will describe the synchronizer role of melatonin in the sleep-awake cycle and in the organization of cytoskeletal proteins and their mRNAs. Also, we will describe alterations in the melatonin secretion rhythm associated with a neuronal cytoskeleton disorganization in the neuropsychiatric diseases such as Alzheimer, depression, bipolar disorder and schizophrenia.

Los ritmos circadianos son patrones de oscilación con un periodo cercano a 24h que se observan en los procesos fisiológicos. En los mamíferos se han descrito funciones biológicas con regulación circádica tal como el ciclo sueño-vigilia. La administración de la melatonina, una indolamina secretada por la glándula pineal, sincroniza los ritmos circadianos. En los humanos, este efecto se ha estudiado en sujetos con síndrome de <

Melatonin reduces neuronal loss and cytoskeletal deterioration: implications for Psychiatry

This review article summarizes the potential role of circadian rhythmicity and melatonin in psychiatric disorders. The melatonin rhythm, with high blood levels at night and low values during the day, is a reflection of the biological clock, i.e., the suprachiasmatic nucleus (SCN). The SCN receive information about the prevailing light: dark conditions from specialized ganglion cells (only 1-2% of the total ganglion cells) in the retina. These unique cells contain a newly-discovered photopigment, melanopsin, which responds to a rather narrow band width of light that peaks at roughly 480 nm. The axons of these ganglion cells project via the retinohypothalamic tract through the optic nerve to the SCN, located just above the optic chiasm in the anterior hypothalamus. Via this pathway, light detected by the retina synchronizes the circadian clock to precisely 24 hours. In the absence of light, i.e., darkness, the SCN signals the pineal gland to produce melatonin via a complex neural pathway that involves fibers that project from the hypothalamus to the preganglionic sympathetic neurons in the intermediolateral cell column of the upper thoracic cord. Axons of these neurons exit the spinal cord to eventually synapse on neurons in the superior cervical ganglia. Then, postganglionic fibers convey the information to the pineal gland mediating the nighttime rise in melatonin synthesis. Because melatonin is only elevated at night, it is referred to as the <>. Disturbances in the rhythmicity of the biological clock and/or the melatonin rhythm likely contribute to psychophysiological disturbances and mood disorders. Major disturbances occur in circadian rhythmicity when light, which activates the SCN and inhibits melatonin production, is imposed during the normal dark period. Thus, even brief periods of light at night are readily detected by the specialized ganglion cells mentioned above; this sets off a chain of events that alter biological clock physiology and depresses nighttime melatonin levels when they should be elevated. Depressed circulating melatonin levels at night provide misinformation to all cells that can <> the message. This misinformation contributes to alterations in mood and negative psychological feelings of well-being. Melatonin has several major functions which probably assist in protecting humans from psychiatric illnesses. This indoleamine is widely known as a sleep-promoting factor. As such, it reduces the latency to sleep onset and improves sleep hygiene. Melatonin has been tested for its beneficial effects on sleep in children with neurodevelopmental disabilities, in individuals with delayed sleep phase syndrome and in elderly patients with insomnia. In each of these situations, melatonin has proven to be beneficial. Sleep disturbances are often associated with and probably contribute to psychiatric illness. Melatonin is also a potent free radical scavenger and antioxidant. It, as well as several of its metabolites, are powerful protectors against oxidative stress and free radical-mediated, mitochondrial-dependent cellular apoptosis. Melatonin seems to be particularly effective in protecting the brain from oxidative mutilation and loss of cells resulting from apoptosis. Given that a variety of neurodegenerative diseases, e.g., Alzheimer disease, parkinsonism, amyotrophic lateral sclerosis, have a free radical component, it is assumed that melatonin may be useful in fores talling the consequences of these debilitating conditions and improving the psychological makeup of these patients. Preliminary clinical trials suggest melatonin will be useful in this regard. A major action of melatonin in the Central Nervous System is protection of the neuronal cytoskeleton from oxidative damage. Structural damage to the cytoskeleton is consequential in the function of neurons and is not uncommonly associated with psychological illness and with neurodegenerative diseases. For example, tauopathies (tau is an important cytoskeletal protein) contribute to neuropsychiatric disorders. Damage to the tau protein, resulting from the hyperphos-phorylation of this important molecule, disrupts intraneuronal microtubules and alters synaptic physiology. The destruction of normal cytoskeletal function is often a result of excessive free radial generation. The free radical-mediated changes result in loss of neuronal polarization and cells die of apoptosis leading to neurobehavioral disorders and dementia. Given that melatonin is an antioxidant, it has been tested for its efficacy in reducing damage to the cytoskeleton as well as limiting the behavioral effects. In this capacity melatonin has been found highly effective in reducing damage to essential cytoskeletal elements and improving neurobehavioral outcomes. Overall, melatonin may well find utility in reducing neural deterioration with age as well as improving the psychological well-being of individuals. Melatonin is an inexpensive non-toxic molecule which should be considered for use in a number of psychiatric diseases and circadian rhythm disorders.

La melatonina (N-acetil-5-metoxitriptamina) es una indolamina que produce la glándula pineal durante la noche. Se libera directamente en la circulación general con un ritmo circadiano. En las enfermedades psiquiátricas se presentan alteraciones en los ritmos biológicos. La melatonina es un cronobiótico ya que sincroniza los ritmos biológicos como el ciclo sueño-vigilia, el de la temperatura corporal y el ciclo de liberación de cortisol, con el fotoperiodo. Esta indolamina no actúa como un hipnótico clásico. Los efectos que ejerce sobre el sueño son acortar su latencia, prolongar el periodo de sueño natural y reducir los despertares nocturnos. Por lo anterior, se ha descrito como un compuesto que <>. En humanos se ha demostrado que produce una mejoría en la calidad de sueño en niños con patología neurológica, así como en pacientes con enfermedad de Alzheimer, en personas de edad avanzada con insomnio, en pacientes con esquizofrenia de larga evolución, depresión mayor y trastornos de ansiedad, etc. Otras características de la melatonina, importantes para la psiquiatría, es que esta molécula cruza la barrera hematoencefálica y actúa como un antioxidante. En 1993 se descubrió que la melatonina es un potente captador de radicales libres, que son moléculas que producen daño y muerte celular. La melatonina y los metabolitos que se generan cuando esta indolamina interacciona con las especies libres de oxígeno y de nitrógeno son eficaces en la eliminación de estas moléculas dañinas. Además, la melatonina activa las enzimas antioxidantes, incluidas la superóxido dismutasa, la glutatión peroxidasa, la glutatión reductasa y la catalasa, y facilita el transporte de electrones a través de la cadena respiratoria mitocondrial, con lo que reduce la pérdida neuronal por apoptosis. Las acciones antioxidantes de la melatonina han sido bien documentadas en modelos experimentales de las enfermedades de Alzheimer, Parkinson y Huntington. En el caso de la toxicidad que produce el péptido beta amiloide, por la generación de una gran cantidad de radicales libres, la melatonina previene la apoptosis, la lipoperoxidación, la formación de carbonilos y el daño al ADN. La melatonina mejora también algunos de los síntomas de la enfermedad de Alzheimer -como la agitación y la falta de sueño que se presentan al atardecer-, mejora el ciclo sueño-vigilia y disminuye el deterioro cognoscitivo y la atrofia bilateral grave de los lóbulos temporales. La pérdida de memoria que se produce en la enfermedad de Alzheimer también se presenta después del daño producido por el procedimiento de isquemia-reperfusión y, en la enfermedad de Parkinson, debido a una excesiva liberación de glutamato, que a su vez causa daño en las células piramidales por los radicales libres que se generan. La melatonina abate la pérdida de neuronas piramidales producida por el ácido kaínico, un agonista glutamatérgico, y preserva la memoria de los animales expuestos a daño por el procedimiento de isquemia-reperfusión. A la fecha no se conoce con exactitud con qué porcentaje colabora cada uno de los mecanismos de acción de la melatonina para proteger a las células del deterioro morfo-funcional. Sin embargo, es el antioxidante más potente descrito a la fecha e incrementa los niveles de enzimas antioxidantes a través de la estimulación de los receptores membranales. Las enfermedades neuropsiquiátricas se han considerado como enfermedades del citoesqueleto. Esto se sustenta en el hecho de que existe una pérdida de las conexiones sinápticas, que son estructuradas por el citoesqueleto, entre el hipocampo y la corteza prefrontal en el caso de la esquizofrenia, la depresión y el trastorno bipolar. En el caso de las demencias existe una organización aberrante del citoesqueleto en filamentos helicoidales apareados. En modelos experimentales de células en cultivo se han logrado reproducir condiciones moleculares semejantes a las que se presentan en las demencias y en la esquizofrenia. La melatonina previene el daño producido por los radicales libres sobre neurocitoesqueleto e inhibe la hiperfosforilación de la proteína tau, que cumple un papel crucial en la estabilización de los axones, en la formación de nuevas neuritas y, por lo tanto, en el establecimiento de las conexiones sinápticas. Además, los daños que producen los antipsicóticos sobre el citoesqueleto, con concentraciones semejantes a las que se alcanzan durante tratamientos prolongados, son revertidos y bloqueados por la melatonina. En conclusión, la información descrita en esta revisión indica que la melatonina puede ser útil en el tratamiento de las enfermedades neuropsiquiátricas ya que es un potente antioxidante, que protege a las neuronas y a las células de la glía de la muerte neuronal y protege al neurocitoesqueleto que determina la polaridad morfofuncional y el establecimiento de las conexiones sinápticas. Estas propiedades y la capacidad de la melatonina de cruzar la barrera hematoencefálica hacen que esta molécula sea un agente neuroprotector relevante en la psiquiatría. Sin embargo, es necesario realizar estudios clínicos controlados para determinar los efectos benéficos de la melatonina en las enfermedades neuropsiquiátricas.

La melatonina: un coadyuvante potencial en el tratamiento de las demencias / Melatonin: A potential coadyuvant in dementia treatment

Alzheimer's disease is characterized by a progressive neuronal death and a lost of memory and cognition that unable the patient to perform daily tasks. Cytoskeleton alterations, identified as a major histopathologic hallmark of neurodegenerative diseases, occur in dementia. In this disease, neurons have pathologic inclusions containing fibrillar aggregates of hyperphosphorylated tau protein in absence of amyloid deposits. Abundant senile plaques and neurofibrillary tangles constitute the two major neuropathologic lesions present in hippocampal, neocortical, and forebrain cholinergic brain regions of Alzheimer's patients. Hyperphosphorylated tau and the subsequent formation of paired helical filaments loses the capabilities for maintaining highly asymmetrical neuronal polarity. Thus, in brains with a high content of hyperphosphorylated tau, microtubules are disassembled, the highly asymmetrical neural shape is lost and an impairment of axonal transport is produced together with a lost of dendrite arborizations. In addition, brain damage caused by free radicals occurs in Alzheimer's disease. This illness involves a reduction of the endogenous antioxidant enzyme system, increased senile-plaque formation, cytoskeletal collapse, and neuronal apoptosis induced by oxidative stress. Acetylcholinesterase inhibitors are the most commonly used compounds in the treatment of neurodegenerative diseases. However, despite their wide use in the treatment of Alzheimer's disease, these compounds have limited therapeutic effects and cause undesirable effects. Therefore it is necessary to investigate new alternatives in the Alzheimer's disease treatment. Considering that neurodegenerative diseases are cytoskeleton disorders, this cellular structure could be a drug target for therapeutic approaches by restoring normal cytoskeleton structure and by precluding damage caused by oxygen-reactive species. In this regard, melatonin, the indole secreted by the pineal gland during the dark phase of the photoperiod, has two important properties that may be useful for the treatment of mental disorders. One is that melatonin is a potent free-radical scavenger and the other is that this indole is a cytoskeletal modulator. A neuroprotective role for melatonin was initially suggested due to its free-radical scavenger properties. Melatonin detoxifies the highly toxic hydroxyl radical as well as the peroxyl radical, peroxynitrite anion, nitric oxide, and singlet oxygen, all of which can damage brain macromolecules. Moreover, melatonin stimulates the activity of antioxidative enzymes including superoxide dismutase, glutathione peroxidase, and glutathione reductase. Also, it is a lipophilic molecule able to cross the blood-brain barrier. All these properties make melatonin a highly effective pharmacologic agent against free-radical damage in the brain. Also, it is a useful neuroprotector in dementia because it synchronize the body rhythms with the photoperiod, which are altered in Alzheimer's disease and because normal circadian secretion of melatonin and sleep-wake cycle can be restored by the indolamine administration. Additionally, cytoskeletal modulation by melatonin is another relevant property of the indole for neurodegenerative diseases treatment. Direct assessment of melatonin effects on cytoskeletal organization in neuronal cells indicated that the indole promotes neuritogenesis in N1E-115 neuroblastoma cells at plasma melatonin concentration. Neurite formation is a complex process critical to establish synaptic connectivity that is lost in Alzheimer's disease. Neuritogenesis takes place by a dynamic cytoskeletal organization that involves microtubule enlargement, microfilament arrangement, and intermediate-filament reorganization. In particular, microtubule assembly participates in neurite formation elicited by melatonin through antagonism to calmodulin. Also, selective activation of protein kinase C (PKC) alpha by melatonin participates in vimentin intermediate filament rearrangements and actin dynamics for neurite outgrowth in neuroblastoma cells. In N1E-115 cells, melatonin at plasma and cerebrospinal fluid concentration caused an increase in microfilament arrays in stress fibers and their thickening, as well as increased growth cone formation, and augmented number of cells with microspikes. Recently, it was demonstrated that melatonin increased both the number of N1E-115 cells with filopodia and with long neurites through both PKC activation and Rho-associated kinase (ROCK) stimulation. The utility of melatonin to prevent damage in the cytoskeletal structure produced by neurodegenerative processes was demonstrated in N1E-115 neuroblastoma cells cultured with okadaic acid (OA), a specific inhibitor of the serine/threonine proteins phosphatases 1 and 2A that induces molecular and structural changes similar to those found in Alzheimer's disease. Melatonin prevented microtubule disruption followed by cell-shape changes and increased lipid peroxidation and apoptosis induced by OA. Melatonin effects on altered cytoskeletal organization induced by OA are dose-dependent and effects were observed at plasma -and cerebrospinal-fluid concentrations of the indole. These data support that melatonin can be useful in the treatment of neurodegenerative diseases by both its action on the cytoskeleton and by its free-radical scavenger properties.

La enfermedad de Alzheimer es una enfermedad neurodegenerativa progresiva que cursa con una deficiencia en las capacidades cognitivas, así como con la presencia de síntomas psiquiátricos y alteraciones conductuales. Las características histopatológicas más importantes en la enfermedad de Alzheimer son la formación de placas seniles, los ovillos neurofibrilares y un incremento en el estrés oxidativo. La polaridad estructural y la morfología neuronal se pierden en la enfermedad de Alzheimer. La proteína tau se encuentra anormalmente fosforilada, los microtúbulos se despolimerizan, se pierden la forma asimétrica de las neuronas y la conectividad sináptica, y se interrumpe el transporte axoplasmático. Asimismo, se ha sugerido que la inhibición o la pérdida en el balance de la formación de neuronas en el hipocampo puede participar en la fisiopatología de la enfermedad de Alzheimer debido a que el cerebro no puede reparar el daño neuronal y consecuentemente induce la pérdida de la cognición. Los agentes colinérgicos son los medicamentos más aceptados en el tratamiento de la enfermedad de Alzheimer en una etapa en que los síntomas se clasifican de medios a moderados. Sin embargo, el tratamiento de pacientes con enfermedad de Alzheimer grave es limitado. Por lo anterior se requiere la búsqueda de nuevas alternativas para el tratamiento de esta enfermedad. La melatonina es una indolamina que actúa como un potente antioxidante, como un modulador de la organización del citoesqueleto así como un factor de diferenciación celular. Diversos estudios han sugerido que la melatonina tiene un efecto neuroprotector por su capacidad de captar radicales libres. La melatonina disminuye la lipoperoxidación y la apoptosis producida por la administración de ácido ocadáico (AO) o peróxido de hidrógeno (H2O2). Se sabe que las especies reactivas de oxígeno producen alteraciones en la organización del citoesqueleto e influyen el estado de fosforilación de la proteína tau y que la melatonina previene la fosforilación de la proteína tau debido a su actividad antioxidante. Se ha descrito que la melatonina modula el arreglo de los microfilamentos de actina y la formación de fibras de tensión en las células Madin-Darby canine kidney (MDCK) por medio de una interacción concertada de la indolamina con la calmodulina y con la proteína cinasa C (PKC) y la participación de la proteína cinasa dependiente de Rho (ROCK). Asimismo, la melatonina participa en las etapas tempranas de la formación de neuritas en las células N1E-115 por medio de ROCK. Otros estudios han indicado que la melatonina previene el daño en el citoesqueleto producido por el AO en las células N1E-115. El AO se ha utilizado para reproducir en células en cultivo las alteraciones en el citoesqueleto y el incremento en el estrés oxidativo que ocurren en las neuronas de pacientes con enfermedad de Alzheimer. La melatonina en estas células previene la retracción del citoesqueleto, efecto del AO. La red del citoesqueleto se mantiene en el citoplasma y en las neuritas de las células N1E-115 cultivadas con melatonina, no obstante que sean tratadas con el AO posteriormente. Recientemente, se demostró que en las células de neuroblastoma N1E-115 incubadas con melatonina se previene la hiperfosforilación de la proteína tau causada por el AO. Aunado a lo anterior, se ha demostrado que la melatonina modula la formación de neuronas nuevas en un modelo in vitro utilizando células embrionarias y de corteza cerebral de ratón. La formación de neuronas inducida por la melatonina se corroboró utilizando células precursoras aisladas de animales adultos así como en animales adultos, y se encontró que la indolamina moduló la sobrevida de las células nuevas formadas, así como la diferenciación de éstas en neuronas nuevas. Las evidencias presentadas en esta revisión indican que la melatonina puede ser útil como un coadyuvante en el tratamiento de las demencias.

Formación de neuronas nuevas en el hipocampo adulto: neurogénesis

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SUMMARY New neuron formation in the adult brain was an interesting finding that extended the knowledge about brain plasticity. In 1966 Joseph Altman reported the incorporation of tritiated thymidine to neural cell DNA. This finding indicated the proliferation event in the adult brain. After twenty years of this finding, new information was generated that confirmed the new neuron formation in the adulthood. In this review, we will mention different aspects of the new neuron formation process called neurogenesis, as well as some of the factors that modulate such process, citing the information already known about the neuronal development stages that take place for the new neuron formation in the hippocampus. Finally, we will review some evidence about the neurogenic process in depression and in neurodegenerative diseases, as well as the possible role of the new neurons when they are integrated into the neuronal network. In the adult brain there are two regions where new neuron formation process takes place: the olfactory bulb and the hippocampus. New neurons are derived from neural stem cells, which reside in the subventricular zone of the lateral ventricles and in the subgranular zone of the dentate gyrus. Neural stem cells may proliferate and generate the rapid amplifying progenitor and neuroblast populations. These populations will migrate and differentiate in neurons to finally be integrated into the neuronal network. In the adult brain, neural stem cells have radial glial features expressing specific markers as the glial fibrilar acidic protein (GFAP), as well as the un-differentiated cell marker nestin. This characteristic makes suitable neural stem cells identification. Thus, the new neurons can be identified by both the specific marker expression and by electrophysiological properties. The different cell development stages during the neurogenic process have been characterized in the subventricular zone as well as in the subgranular zone of the dentate gyrus. In addition to the radial-glia features, neural stem cells show a slowly dividing ratio and once the neural stem cells divide by asymmetric division a rapid amplifying progenitor population is generated. In the hippocampus, phenotype analysis had allowed cell classification in three different types according to the kind of protein marker expression. These progenitors are generated during the expansion phase by symmetric cell division. Type 2a and 2b present short neuritic processes parallel to the granular cell layer and the Type 3 present longer processes integrated into the granular cell layer. During this step, where the migration and cell fate decision take place, the cells express different markers as the microtubule associated protein doublecortin, the homeobox gene related to the Drosophila gene prospero Prox-1 and the neuron-specific nuclear protein Neu-N. Once the cells exit the cell cycle, immature neurons are generated showing longer dendritic processes crossing the granular cell layer. These immature neurons will fully differentiate to be integrated into the neuronal network. At this final stage the cells are fully differentiated and the new neurons express specific markers as the calcium binding protein calbindin and their electrophysiological properties are similar to the old neurons. Neurogenesis is a complex process that is modulated and regulated by different factors. One of these is the niche which is formed by the neural stem cells, astrocytes and endothelial cells. Adult neural stem cells proliferate and differentiate depending on the cellular and molecular composition of the niche. The three components work in synchrony in both neurogenic areas with active proliferation. The role of the niche is the maintenance of the stem cells pool. The astrocytes modulate the proliferation of the neural stem cell and of the rapid amplifying cell population, as well as the migration of these cells by the action of the secreting factors. The niche also plays a key role in maintaining the astrocytic and the endothelial cell populations. Besides the niche, other factors are involved in the neurogenic process, such as the neurotransmitters (GABA, glutamate, serotonin, dopamine), hormones (prolactin, growth hormone), growth factors (FGF, EGF) and neurotrophins (BDNF, NT3). All of them modulate different steps of the process. Some other factors that influence the new neuron formation include the physical activity, enrichment environment and social interaction. It has been shown that physical activity increases the number of surviving newborn cells when rodents have free access to the running wheel. Another positive regulator of the neurogenic process is the enrichment environment. The influence of this factor on the new neuron formation was demonstrated when the animals were maintained in a cage with tunnels and toys. In addition, when the rodents were forced to learn a particular task, more new neurons were found in the dentate gyrus. Additionally, the social interaction has a positive influence on the new neuron formation. Even when neurogenesis is positively regulated by the afore mentioned factors, different conditions and factors have a negative influence on this process. It is known that psychological stress affects in a negative manner the neurogenic process. The stress decreases the proliferation of progenitor cells in the dentate gyrus. This negative effect involves glucocorticoids whose increased levels inhibit the new neuron formation. Also, an exogenous administered corticosterone suppresses the new neuron formation. Another negative factor on neurogenesis related to glucocorticoids, is the sleep deprivation, which impairs the neurogenic process by increasing corticosterone levels causing a reduction in cell proliferation. Also, the abuse drugs cause a negative effect in the new neuron formation. It is known that chronic alcoholism negatively impact neurogenesis as well as cocaine, drug that impairs the proliferation dynamics in the dentate gyrus. Psychiatric disorders, such as depression, have been associated with an impaired neurogenesis, which is reverted by antidepressant drugs. In contrast to the effects of stress, an antidepressant pharmacologic treatment increases the new neuron formation. The antidepressant effect is dependent on chronic treatment, consistent with the time course of the therapeutic action of these compounds. Recently, it has been shown that fluoxetine increases symmetric divisions of early progenitor cells and that these cells called or named neuronal progenitors targeted by fluoxetine in the adult brain. This report describes one mechanism for antidepressant; however, the mechanisms by which antidepressant drugs act is not known at all and can be complex. Nevertheless, it has been reported that antidepressants induce an increase in serotonin or norephinephrine levels which activate the corresponding receptors and their downstream signaling pathways. One of these signaling pathways is the cAMP-CREB cascade. This second messenger is upregulated in the hippocampus together with the activity of the cAMP-dependent protein kinase. On the same pathway, the cAMP response element binding protein (CREB) shows an increase in function and expression. In patients with neurodegeneration, a defect in the neurogenesis process has been described. In Alzheimer's disease, cell proliferation and the potential regenerative factors levels are diminished. However, several studies have revealed an increase in the expression of the neurogenic marker doublecortin. Recently, it has been reported the presence of proliferative cells in presenile Alzheimer hippocampus without indications for altered dentate gyrus. In addition to this finding, the influence of the enrichment environment on the new neuron formation has been explored. In these studies, it was shown that rodents housed under enrichment conditions had an increased neurotrophin 3 (NT-3) and brain derived neurotrophic factor, as well as an increased hippocampal neurogenesis accomplished with the improvement in the water maze performance. In another study, described by Lazarov in 2005, the enrichment environment leads a reduction in the levels of cerebral beta-amyloid and an increase in the genes associated with learning-memory, neurogenesis and cell survival pathways. In amyotrophic lateral sclerosis that is characterized by motor neuron degeneration the new neuron formation is impaired. By using mutant mice for the superoxide dismutase-1 enzyme, an enzyme that is altered in amyotrophic lateral sclerosis and with the precursor cells isolated from the subventricular zone of the this mutants there is a reduction in the incorporation of the DNA synthesis marker bromodeoxyuridine(BrdU), and in the response to mitogen stimulation, in presymptomatic and symptomatic mice, respectively. Evidence obtained so far strongly suggest that neural stem cells manipulation can be a good possibility to induce the neuron replacement in the treatment of neurodegenerative and psychiatric illnesses. However it is necessary to go deeply in the mechanisms and signaling pathways involved in the neurogenesis processes.

El neurocitoesqueleto: un nuevo blanco terapéutico para el tratamiento de la depresión

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Summary Postmortem and neuroimaging studies of Major Depressive Disorder patients have revealed changes in brain structure. In particular the reduction in prefrontal cortex and in hippocampus volume has been described. In addition, a variety of cytoarchitectural abnormalities have been described in limbic regions of major depressive patients. Decrease in neuronal density has been reported in the hippocampus, a structure involved in declarative, spatial and contextual memory. This structure undergoes atrophy in depressive illness along with impairment in cognitive function. Several studies suggest that reduction of hyppocampus volume is due to the decreased cell density and diminished axons and dendrites. These changes suggested a disturbance of normal neuronal polarity, established and maintained by elements of the neuronal cytoskeleton. In this review we describe evidence supporting that neuronal cytoskeleton is altered in depression. In addition, we present data indicating that the cytoskeleton can be a potential target in depression treatment. Neurons are structural polarized cells with a highly asymmetric shape. The cytoskeleton plays a key role in maintain the structural polarization in neurons which are differentiated in two structural domains: The somato-dendritic domain and the axonal domain. This differentiated asymmetric shape, depends of the cytoskeletal organization which support, transport and sorts various molecules and organelles in different compartments within the cell. Microtubules determine the asymmetrical shape and axonal structure of neurons and form the tracks for intracellular transport, of crucial importance in axonal flux. Actin microfilaments are involved in force generation during organization of neuronal shape in cellular internal and external movements and participate in growth cone formation. This important cytoskeletal organization preceed the formation of neurites that eventually will differentiated into axons or dendrites, a process that also comprises a dynamic assembly of the three cytoskeletal components. Intermediate filaments are known in neurons as neurofilaments spatially intercalated with microtubules in the axons and facilitate the radial axonal growth and the transport. Neurofilaments also act supporting other components of the cytoskeleton. All changes and movements of the cytoskeletal organization are coordinated by cytoskeletal associated proteins such as the protein tau and the microtubule associated proteins (MAPs). Also, specific interactions of microfilaments, microtubules and filaments which are regulated by extracellular signals take place in modulation of the cytoskeletal rearrangements. The polarized structure and the highly asymmetric shape of neurons are essentials for neuronal physiology and it appears to be lost in patients with a Major Depressive Disorder. Histopathological studies have shown that the hippocampus and frontal cortex of patients with major depressive disorder have diminished soma size, as well as, have decreased dendrites and cellular volume. Dendrite formation depends mainly in microfilaments organization as well as in polarization of the microtubule binding protein MAP2. In addition, there is a decreased synaptic connectivity and an increased oxidative stress, which originates abnormalities in the cytoskeletal structure. These neuronal changes originate alterations in the brain functionality such as decreased cognitive abilities and affective dis-regulations, usually encountered in patients with depression. Therefore, pathologic lesions implicating an altered cytoskeletal organization, may have an important role in decreased cognitive functions, observed in depression, as well as in changes in the brain volume, explained by a lost of neuronal processes such as axons, dendrite processes or dendritic spines, rather than by loss of neuronal or glial cell bodies. This explanation is supported by light immunomicroscopy of brain slices postmortem stained with specific antibodies. Psychological stress which causes oxidative stress has also been suggested to cause a decrease of neuronal volume in the prefrontal cortex, altering the synaptic connections established with the hippocampus. This conclusion was drawn from studies in animal models of psychological stress associated with molecular measurements where defects in the expression of MAP1 and sinaptophysin were found, suggesting that defects in cytoskeletal associated proteins could underlie some cytoarchitectural abnormalities described in depression. Together all the evidence accumulated indicates that major depression illness and bipolar depression are mental disorders that involve loss of axons and dendrites in neurons of the Central Nervous System, that in consequence cause disruption of synaptic connectivity. Thus is possible that depression can be considered as a cytoskeletal disorder, therefore this cellular structure could be a drug target for therapeutic approaches by restoring normal cytoskeleton structure and precluding damage caused by oxygen-reactive species. In this regard, melatonin, the hormone secreted by pineal gland during dark phase of the photoperiod, has two important properties that can be useful in treatment of mental disorders. First, the melatonin is a potent free-radical scavenger and second this hormone governs the assembly of the three main cytoskeletal components modulating the cytoskeletal organization. This notion is supported by direct action of melatonin effects on cytoskeletal organization in neuronal cells. In N1E-115 neuroblastoma cells, melatonin induced a two-fold increase in number of cells with neurites 1 day after plating; the effect lasting up to 4 days. Induction of neurite outgrowths is optimal at 1 nM melatonin and in presence of hormone the cells grew as clusters with long neurites forming a fine network to make contact with adjacent cells. Immunofluorescence of N1E-115 cells cultured under these conditions showed tubulin staining in long neurite processes connecting cells to each other. Neurite formation is a complex process that is critical to establish synaptic connectivity. Neuritogenesis takes place by a dynamic cytoskeletal organization that involves microtubule enlargement, microfilament arrangement, and intermediate- filament reorganization. In particular, it is known that vimentin intermediate filaments are reorganized during initial stages of neurite outgrowth in neuroblastoma cells and cultured hippocampal neurons. Evidence has been published indicating that increase in microtubule assembly participates in neurite formation elicited by melatonin antagonism to calmodulin. Moreover, recently it was reported that melatonin precludes cytoskeletal damage produced by high levels of free radicals produced by hydrogen peroxide, as well as, damage caused by higher doses of the antypsychotics haloperidol and clozapine. N1E-115 cells incubated with either 100 uM hydrogen peroxide, 100 uM haloperidol, or 100 uM clozapine undergo a complete cytoskeletal retraction around the nucleus. By contrast, NIE-115 cells incubated with hydrogen peroxide, clozapine, or haloperidol followed by the nocturnal cerebrospinal fluid concentration of melatonin (100 nM) showed a well preserved cytoskeleton and neuritogenesis. Thus melatonin is a neuroprotective compound, since protects the neurocytoskeletal organization against damage caused by high concentrations of antipsychotics and oxidative stress. As mentioned previously, polarity is intrinsic to neuronal function. In neurons, somatodendritic domain receives and decodes incoming information and axonal domain delivers information to target cells. Progressive loss of neuronal polarity is one of the histopathologic events in depression. Cytoskeletal collapse underlie the lost of structural polarity and it is known that precede neuronal death and disappearance of synaptic connectivity. Drugs that prevent the loss of polarity and cytoskeleton retraction intrinsic to these diseases, as well as damage in cytoskeletal structure produced by oxidative stress can be extremely useful in depression treatment. Melatonin is a potent free-radical scavenger that also acts as a cytoskeleton regulator; thus, we speculate that this hormone could be useful in prevention and alleviation of psychiatry diseases with synaptic connectivity disruption. Clinical trials show that melatonin administration is followed by alleviation of circadian disturbances and cognitive function in various neuropsychiatry diseases. Moreover, in depression, melatonin improves sleep. Thus, as suggestive as this information appears, controlled clinical trials will be necessary to investigate the beneficial effects of melatonin and other drugs in the depression treatment.

El efecto de la melatonina sobre la fosforilación de proteínas en una preparación de sinaptosomas del hipotálamo de la rata / Melatonin effects on rat hypothalamic synaptosome protein phosphorylation

Hay evidencias de que la melatonina podría participar en la patofisiología de algunas enfermedades mentales. Esta hormona modifica la síntesis y liberación de neurotransmisores en el sistema nervioso central. La fosforilación de proteínas desempeña un papel crucial en la fisiología neuronal. El particular, la fosforilación de la sinapsina I por la cinasa II dependiente de calmodulina, modula el transporte de las vesículas y la liberación de los neurotransisores en la terminal sináptica. Recientemente se describió que la melatonina in vitro inhibe la actividad y la autofosforilación de la cinasa II dependiente de calmodulina. Como una primera etapa para entender el mecanismo por medio del cual la melatonina modula la liberación de neurotransmisores, en este trabajo se estudiaron los efectos de la hormona sobre la fosforilación de proteínas en una preparación de sinaptosaomas obtenidos del hipotálamo de la rata. Los resultados señalaron que los sinaptosomas despolarizados con concentraciones altas de potasio liberaron 3H-GABA y aumentaron la fosforilación de las proteínas en un 50 por ciento. La melatonina (1 nM) inhibió la fosforilación de las proteínas de peso moleculara de 50,54, 58-60 y 87 kd en sinaptosomas basales (30 por ciento) y despolarizados con concentraciones altas de potasio (50 por ciento). Los resultados sugieren que la hormona, al actuar como un antagonista de calmodulina e inhibir la fosforilación de proteínas, puede modular la liberación de neurotransmisores

Mecanismo de acción intracelular del neuromodulador melatonina: estado actual y perspectivas / Intracellular action mechanisms of the melatonin neuromodulator. Actual state and perspectives

La melatonina es una hormona que es secretada por la glándula pineal durante el periodo de oscuridad. A pesar de que se conocen sus efectos farmacológicos y fisiológicos, su mecanismo de acción no se conoce con exactitud. En este artículo se revisó la evidencia que apoya que la melatonina interacciona con la calmodulina. La unión de la melatonina a la calmodulina sugiere que la hormona modula la actividad celular por medio de su unión intracelular a esta proteína. El antagonismo de la melatonina por la calmodulina podría modular rítmicamente muchas funciones celulares. Los efectos de la melatonina sobre el citoesqueleto microtubular sugieren que a bajas concentraciones (10-9 M), los efectos de la hormona sobre el citoesqueleto son mediados por un antagonismo de Ca++- calmodulina. A concentraciones farmacológicas (10-5 M) ocurre una unión inespecífica a la tubulina que prevalece sobre el antagonismo a la calmodulina. Dado que la melatonina y la calmodulina son estructuras filogenéticamente bien conservadas, la interacción melatonina-calmodulina probablemente represente un mecanismo primario para la regulación y la sincronización de la fisiología celular

Densidad de probables receptores dopaminérgicos en los linfocitos de los pacientes con esquizofrenia paranoide: resultados preliminares / Densitx of probable dopaminergic receptors in lymphocytes of patients with paranoid schizophrenia: preliminary results

Los estudios con tomografía por emisión de positores y los estudios postmortem indican que por lo menos un grupo de pacientes esquizofrénicos experimentan un aumento en la densidad de los receptores para la dopamina (tipo D2) a nivel central. Recientemente Bondy y Cols. (3) informaron que este incremento también podría observarse en los linfocitos de estos pacientes y que, además, pudiera ser un marcador de vulnerabilidad, es decir, una característica que se hereda junto con la propensión a padecer la enfermedad. Es evidente que, de ser esto cierto, constituiría un hallazgos trascedental en el estudio de tan devastaddora enfermedad. Sin embargo, la evidencia sobre los sitios de un unión dopaminérgicos en los linfocitos es muy controvertida ya que algunos autores (12) no han podido demostrar la unión específica de ligandos dopaminérgicos en estas células, por lo que en este trabajo estudiamos la unión de 3H-espiperona en linfocitos de pacientes esquizofrénicos y en voluntarios sanos