Ultrastructural Changes of Caudate Nucleus in Mice Chronically Treated with Manganese.

Manganese (Mn) is able to cross the blood-brain barrier and induces functional and structural alterations during the intoxication by this metal. Therefore, the effects of chronic administration of Mn in the caudate nucleus of mice were evaluated by electron microscopy. Male albino mice were injected intraperitoneally with MnCl2 (5 mg/kg/d) 5 d per week during 9 weeks. The control group received only 0.9% of NaCl solution. The caudate nuclei were extracted and subsequently processed to be observed on a conventional transmission electron microscope at 2, 4, 6, and 9 weeks after treatment. A high percentage of vacuolated and swollen mitochondria were found throughout all the analyzed periods. Myelin disarrangement and ultrastructural alterations related to edema were observed increased in Mn-treated mice at week 9. Granular degeneration of myelin at week 9 accompanied with deposition of electron dense granules in the neuropil was also observed. Edema in neuropil and glial cells was detected from week 2 to week 9 accompanied by swollen mitochondria. Neuronal bodies, synaptic terminals, and perivascular cells were found swollen. Decreased electron density in postsynaptic areas and decreased and dispersed synaptic vesicles in presynaptic areas were noted in Mn-treated animals. Some neurons from Mn-treated mice showed cisternae dilation of the Golgi apparatus. These results suggest that Mn-treatment produces structural alterations in the caudate nucleus that could be responsible for some of the neurotoxic effects of this metal.

Longterm melatonin administration alleviates paraquat mediated oxidative stress in Drosophila melanogaster / La administración de melatonina a largo plazo mitiga el estrés oxidativo mediado por paraquat en Drosophila melanogaster

We investigated the effect of melatonin (MEL) in the activities of cytosolic superoxide dismutase (SOD) and catalase as well as in the levels of H2O2 and mitochondrial malondialdehyde (MDA) in paraquat-intoxicated Drosophila melanogaster. Paraquat (40 mM) was administrated for 36 h. Three groups of flies intoxicated with paraquat were used: PQ (exposed during 36h to paraquat), PQ-MEL (exposed during 36h to paraquat and then treated with MEL [0.43 mM] for 12 days) and PQ-Control (maintained in standard corn meal for 12 days). Two additional groups without pre-intoxication with PQ were added: Control (maintained in standard corn meal) and MEL (treated with MEL for 12 days). Immediately after PQ intoxication the concentration of MDA (17.240 ± 0.554 nmoles MDA/mg protein) and H2O2 (3.313 ± 0.086 nmol hydrogen peroxide/mg protein) and the activities of SOD and catalase (419.667 ± 0.731 and 0.216 ± 0.009 Units/mg of protein, respectively) in the PQ group were significantly increased with respect to Control. After 12 days of intoxication with PQ, the PQ-Control flies showed increases in H2O2 (4.336 ± 0.108) and MDA levels (8.620 ± 0.156), and in the activities of SOD and catalase (692.570 ± 0.433 and 0.327 ± 0.003, respectively) as compared to PQ-MEL (p<0.001). Treatment with MEL extended the life span of the groups PQ-MEL and MEL when compared to their corresponding controls. Motor activity decreased significantly in PQ-Control and PQ-MEL flies, suggesting that the damage caused by PQ affected the nervous system of flies. Our findings showed that oxidative damage caused by paraquat was observed even after 12 days and that melatonin mitigates this damage.

Investigamos el efecto de la melatonina (MEL) en la actividad de la superóxido dismutasa citosólica (SOD) y la catalasa, así como en las concentraciones del H2O2 y del malondialdehido mitocondrial (MDA) en la toxicidad inducida por paraquat (PQ) en Drosophila melanogaster. El paraquat (40 mM) fue administrado durante 36h. Tres grupos de moscas se utilizaron después de la intoxicación con paraquat: PQ (expuestas a paraquat durante 36 h), PQ-MEL (expuestas durante 36 horas a PQ y luego tratadas con MEL [0,43 mM] por 12 días) y PQ-Control (mantenidas en medio estándar por 12 días). Se incluyeron dos grupos adicionales sin pre-intoxicación con PQ: Control (mantenido en medio estándar) y MEL (tratado con MEL por 12 días). Inmediatamente después de la intoxicación con PQ, las concentraciones de MDA (17,240 ± 0,554 nmol de MDA/mg de proteína), H2O2 (3,313 ± 0,086 nmol de H2O2/mg de proteína) y las actividades de la SOD y catalasa (419,667 ± 0,731 y 0,216 ± 0,009 unidades/mg de proteína, respectivamente) se incrementaron significativamente con respecto al Control. Doce días después de la intoxicación con PQ, las moscas PQ-Control mostraron un aumento en la concentración de H2O2 (4,336 ± 0,108), de los niveles de MDA (8,620 ± 0,156) y en las actividades de la SOD y la catalasa (692,570 ± 0,433 y 0,327 ± 0,003, respectivamente) en comparación con el grupo PQ-MEL (p<0,001). El tratamiento con MEL extendió el tiempo de vida de los grupos PQ-MEL y MEL en comparación con sus correspondientes controles. La actividad motora disminuyó significativamente en las moscas de los grupos PQ-Control y PQ-MEL, lo que sugiere que el PQ afectó el sistema nervioso de las moscas. Nuestros hallazgos demostraron que el daño oxidativo causado por paraquat en las moscas fue observado aún después de 12 días de intoxicadas y que la melatonina logró mitigar este daño.

Longterm melatonin administration alleviates paraquat mediated oxidative stress in Drosophila melanogaster.

We investigated the effect of melatonin (MEL) in the activities of cytosolic superoxide dismutase (SOD) and catalase as well as in the levels of H2O2 and mitochondrial malondialdehyde (MDA) in paraquat-intoxicated Drosophila melanogaster. Paraquat (40 mM) was administrated for 36 h. Three groups of flies intoxicated with paraquat were used: PQ (exposed during 36h to paraquat), PQ-MEL (exposed during 36h to paraquat and then treated with MEL [0.43 mM] for 12 days) and PQ-Control (maintained in standard corn meal for 12 days). Two additional groups without pre-intoxication with PQ were added: Control (maintained in standard corn meal) and MEL (treated with MEL for 12 days). Immediately after PQ intoxication the concentration of MDA (17.240 +/- 0.554 nmoles MDA/mg protein) and H2O2 (3.313 +/- 0.086 nmol hydrogen peroxide/mg protein) and the activities of SOD and catalase (419.667 + 0.731 and 0.216 +/- 0.009 Units/mg of protein, respectively) in the PQ group were significantly increased with respect to Control. After 12 days of intoxication with PQ, the PQ-Control flies showed in- creases in H2O2 (4.336 +/- 0.108) and MDA levels (8.620 +/- 0.156), and in the activities of SOD and catalase (692.570 +/- 0.433 and 0.327 +/- 0.003, respectively) as compared to PQ-MEL (p<0.001). Treatment with MEL extended the life span of the groups PQ-MEL and MEL when compared to their corresponding controls. Motor activity decreased significantly in PQ-Control and PQ-MEL flies, suggesting that the damage caused by PQ affected the nervous system of flies. Our findings showed that oxidative damage caused by paraquat was observed even after 12 days and that melatonin mitigates this damage.

The life span of Drosophila melanogaster is affected by melatonin and thioctic acid.

Aging and reduced longevity are due in part to the action of free radicals (FR). Melatonin (Mel) and thioctic acid (TA) are effective in protecting against the damage caused by FR. In this study, the effect of Mel and TA on the life cycle of Drosophila melanogaster was determined. We used a control group of flies, another group that was provided with Mel (0.43 mM) throughout their life cycle (Mel-c), a third group received Mel upon reaching adulthood (Mel-a) and two groups were fed with TA (2.15 mM) in the same manner (TA-c and TA-a). The number of eclosed, survival, phenotype changes, motor activity and the content of malondialdehyde (MDA) was evaluated in each group. Mel-c increased the eclosion rate and the motor activity of the flies. Mel-c and Mel-a increased the life span and decreased the concentrations of MDA. By contrast, TA-c diminished the eclosion rate, produced phenotypic changes and increased MDA levels and motor activity of the flies. TA-a extended the life span of flies, and did not alter MDA levels and motor activity when compared with the control group. In conclusion, Mel mitigated the effects caused by FR generated during aging, while TA-c increased lipid peroxidation and altered the phenotype of flies.

The life span of Drosophila melanogaster is affected by melatonin and thioctic acid / El ciclo de vida de la Drosophila melanogaster es afectado por la melatonina y el ácido tióctico

Aging and reduced longevity are due in part to the action of free radicals (FR). Melatonin (Mel) and thioctic acid (TA) are effective in protecting against the damage caused by FR. In this study, the effect of Mel and TA on the life cycle of Drosophila melanogaster was determined. We used a control group of flies, another group that was provided with Mel (0.43 mM) throughout their life cycle (Mel-c), a third group received Mel upon reaching adulthood (Mel-a) and two groups were fed with TA (2.15 mM) in the same manner (TA-c and TA-a). The number of eclosed, survival, phenotype changes, motor activity and the content of malondialdehyde (MDA) was evaluated in each group. Mel-c increased the eclosion rate and the motor activity of the flies. Mel-c and Mel-a increased the life span and decreased the concentrations of MDA. By contrast, TA-c diminished the eclosion rate, produced phenotypic changes and increased MDA levels and motor activity of the flies. TA-a extended the life span of flies, and did not alter MDA levels and motor activity when compared with the control group. In conclusion, Mel mitigated the effects caused by FR generated during aging, while TA-c increased lipid peroxidation and altered the phenotype of flies.

El envejecimiento y la disminución de la longevidad se deben, en parte, a la acción de los radicales libres (RL). La melatonina (Mel) y el ácido tióctico (AT) son antioxidantes efectivos contra el daño ocasionado por los RL. En este estudio se determinó el efecto de la Mel y el AT en el ciclo de vida de la Drosophila melanogaster. Se utilizó un grupo de moscas control, otro grupo al que se le suministró Mel (0,43 mM) durante todo su ciclo de vida (Mel-c), un tercer grupo recibió Mel al alcanzar la adultez (Mel-a) y dos grupos a los que se le suministró AT (2,15 mM) de la misma manera (AT-c y AT-a). Se evaluó el número de eclosionados, la sobrevida, el fenotipo, la actividad motora y el contenido de malondialdehído (MDA) en cada uno de los grupos. Mel-c incrementó la tasa de eclosión y aumentó la actividad motora. Mel-a y Mel-c aumentaron la sobrevida y disminuyeron las concentraciones de MDA. Por el contrario, el AT-c disminuyó la tasa de eclosión, produjo cambios fenotípicos, no afectó la sobrevida de las moscas, aumentó los niveles de MDA y la actividad motora. El AT-a extendió la duración de la vida de los animales, no alteró los niveles de MDA, ni la actividad motora al comparar con el grupo control. En conclusión, la Mel mitigó los efectos causados por los RL generados durante el envejecimiento, mientras que el AT-c aumentó la peroxidación lipídica y alteró el fenotipo de las moscas.

Ultrastructural study of the hypothalamus in mice chronically treated with manganese / Estudio ultraestructural del hipotálamo de ratones tratados crónicamente con manganeso

Manganese (Mn) is an essential metal that is an integral part of some metalloproteins and acts as a cofactor of several enzymes. Mn is able to cross the blood-brain barrier and enter the nervous system. It has a low toxicity but exposure to high concentrations or for prolonged periods of time produce neurological disorders in humans that initially cause hallucinations and compulsive behaviour followed by stiffness, muscle weakness, ataxia, memory loss and a tremor resembling Parkinson’s disease. This study assessed the ultrastructural alterations produced in the hypothalamus of male albino mice injected intraperitoneally with MnCl2 (5 mg Mn/Kg/day) and a control group injected with NaCl 0.9% (0.1 mL) daily for 9 weeks. The animals were sacrificed by cervical dislocation. The hypothalamus was extracted and subsequently processed to be observed on the conventional transmission electron microscope at 2, 4, 6 and 9 weeks of treatment. After 2 weeks it was observed a slight disruption of the Golgi apparatus and the myelin fibers. After 4 weeks the disorganization was accentuated and dilatation of the endoplasmic reticulum (ER) and alterations of mitochondria were observed. After 6 weeks the normal pattern of the myelin sheath was lost. After 9 weeks of treatment it was found swollen mitochondria with lost of crystae, a marked dilatation of rough and smooth endoplasmic reticulum and dendrites with a high degree of swelling. These results suggest that the neurotoxic effect of Mn increases as time of exposure passes and produces ultrastructural alterations of nerve cells in the hypothalamus.

El manganeso (Mn) es un metal esencial que forma parte de algunas metaloproteínas y actúa como cofactor de varias enzimas. El Mn es capaz de atravesar la barrera hematoencefálica e ingresar al sistema nervioso. Presenta baja toxicidad, pero la exposición a altas concentraciones o por tiempos prolongados produce alteraciones neurológicas en humanos que inicialmente provocan alucinaciones y conducta compulsiva seguidas por rigidez, debilidad muscular, ataxia, pérdida de la memoria y temblor, síntomas similares a los de la enfermedad de Parkinson. En el presente estudio se evaluaron los efectos tóxicos del Mn sobre la ultraestructura del hipotálamo de ratones. Se inyectaron intraperitonealmente ratones albinos machos con MnCl2 (5 mg Mn/Kg/día durante 9 semanas). El grupo control recibió NaCl 0,9% (0,1 mL/dosis). Los animales se sacrificaron por dislocación cervical, extrayéndose y disecándose el hipotálamo, que posteriormente se procesó para realizar observaciones al microscopio electrónico de transmisión convencional a las 2; 4; 6 y 9 semanas de tratamiento. A las 2 semanas, se observó ligera desorganización en el aparato de Golgi y en las fibras mielínicas. A las 4 semanas, se acentuó la desorganización y se comenzó a observar dilatación del retículo endoplasmático liso y rugoso asi como mitocondrias alteradas. A las 6 semanas, se encontró pérdida del patrón normal de la cubierta mielínica. Finalizadas las 9 semanas de tratamiento, se observaron mitocondrias hinchadas con pérdida de las crestas, dilatación acentuada del retículo endoplasmático rugoso y liso y dendritas con cierto grado de edema. Estos resultados parecen indicar que el efecto neurotóxico del Mn aumenta a medida que transcurre el tiempo de exposición para producir alteraciones ultraestructurales de las células nerviosas del hipotálamo.

Ultrastructural changes of the olfactory bulb in manganese-treated mice

The effect of manganese toxicity on the ultrastructure of the olfactory bulb was evaluated. Male albino mice were injected intraperitoneally with MnCl2 (5 mg/Kg/day) five days per week during nine weeks. The control group received NaCl (0.9%). The olfactory bulbs of five mice from each group were processed for transmission electron microscopy after 2, 4, 6 and 9 weeks of manganese treatment. On week 2, some disorganization of the myelin sheaths was observed. After 4 weeks, degenerated neurons with dilated cisternae of rough endoplasmic reticulum and swollen mitochondria appeared. A certain degree of gliosis with a predominance of astrocytes with swollen mitochondria, disorganization of the endomembrane system, dilation of the perinuclear cisternae and irregularly shaped nuclei with abnormal chromatin distribution were observed after 6 weeks. Some glial cells showed disorganization of the Golgi apparatus. On week 9, an increase in the number of astrocytes, whose mitochondrial cristae were partially or totally erased, and a dilation of the rough endoplasmic reticulum were found. Neurons appear degenerated, with swollen mitochondria and a vacuolated, electron dense cytoplasm. These changes seem to indicate that the olfactory bulb is sensitive to the toxic effects of manganese.

Ultrastructural changes of the olfactory bulb in manganese-treated mice

The effect of manganese toxicity on the ultrastructure of the olfactory bulb was evaluated. Male albino mice were injected intraperitoneally with MnCl2 (5 mg/Kg/day) five days per week during nine weeks. The control group received NaCl (0.9%). The olfactory bulbs of five mice from each group were processed for transmission electron microscopy after 2, 4, 6 and 9 weeks of manganese treatment. On week 2, some disorganization of the myelin sheaths was observed. After 4 weeks, degenerated neurons with dilated cisternae of rough endoplasmic reticulum and swollen mitochondria appeared. A certain degree of gliosis with a predominance of astrocytes with swollen mitochondria, disorganization of the endomembrane system, dilation of the perinuclear cisternae and irregularly shaped nuclei with abnormal chromatin distribution were observed after 6 weeks. Some glial cells showed disorganization of the Golgi apparatus. On week 9, an increase in the number of astrocytes, whose mitochondrial cristae were partially or totally erased, and a dilation of the rough endoplasmic reticulum were found. Neurons appear degenerated, with swollen mitochondria and a vacuolated, electron dense cytoplasm. These changes seem to indicate that the olfactory bulb is sensitive to the toxic effects of manganese.(AU)

Ultrastructural changes of the olfactory bulb in manganese-treated mice.

The effect of manganese toxicity on the ultrastructure of the olfactory bulb was evaluated. Male albino mice were injected intraperitoneally with MnCl2 (5 mg/Kg/day) five days per week during nine weeks. The control group received NaCl (0.9%). The olfactory bulbs of five mice from each group were processed for transmission electron microscopy after 2, 4, 6 and 9 weeks of manganese treatment. On week 2, some disorganization of the myelin sheaths was observed. After 4 weeks, degenerated neurons with dilated cisternae of rough endoplasmic reticulum and swollen mitochondria appeared. A certain degree of gliosis with a predominance of astrocytes with swollen mitochondria, disorganization of the endomembrane system, dilation of the perinuclear cisternae and irregularly shaped nuclei with abnormal chromatin distribution were observed after 6 weeks. Some glial cells showed disorganization of the Golgi apparatus. On week 9, an increase in the number of astrocytes, whose mitochondrial cristae were partially or totally erased, and a dilation of the rough endoplasmic reticulum were found. Neurons appear degenerated, with swollen mitochondria and a vacuolated, electron dense cytoplasm. These changes seem to indicate that the olfactory bulb is sensitive to the toxic effects of manganese.

Paraquat-induced oxidative stress in drosophila melanogaster: effects of melatonin, glutathione, serotonin, minocycline, lipoic acid and ascorbic acid.

The efficacy of melatonin, glutathione, serotonin, minocycline, lipoic acid and ascorbic acid in counteracting the toxicity of paraquat in Drosophila melanogaster was examined. Male Oregon wild strain flies were fed for 5 days with control food or food containing the test substance. They were transferred in groups of five to vials containing only filter paper soaked with 20 mM paraquat in 5% sucrose solution. Survival was determined 24 and 48 h later. All the substances assayed increased the survival of D. melanogaster. At equimolar concentrations (0.43 mM) melatonin was more effective than serotonin, lipoic acid and ascorbic acid. However, lower concentrations of glutathione (0.22 mM) and minocycline (0.05 mM) were as efficient as melatonin. The highest survival rate (38.6%) after 48 h of paraquat treatment was found with 2.15 mM of lipoic acid. No synergistic effect of melatonin with glutathione, serotonin, minocycline, lipoic acid and ascorbic acid was detected.

Receptores a neurotransmisores y suicidio. Revisión / Neurotransmitters receptor and suicide. A review

Los estudios epidemiológicos muestran una relación muy estrecha entre depresión y suicidio, ya que se ha observado que un porcentaje elevado de los suicidios han sido diagnosticados previamente como deprimidos; sin embargo, los mecanismos etiológicos involucrados en estos dos tipos de trastornos todavía no son bien conocidos. En los últimos años se ha postulado que la alteración del metabolismo de los neutransmisores monoamínicos presentes en el cerebro es responsable de los desórdenes depresivos. Esta hipótesis se ha convertido en el principal centro de atracción de las investigaciones bioquímicas. Además de la noradrenalina, serotonina y dopamina, también se han estudiado otros neurotransmisores, tales como la acetilcolina y el ácido gamma aminobutírico. Se han analizado sus concentraciones y la de sus metabolitos en orina, plasma y líquido cefalorraquídeo, así como sus receptores en diferentes regiones del cerebro de suicidas o de individuos deprimidos muertos por causas naturales