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.

Minocycline increases the activity of superoxide dismutase and reduces the concentration of nitric oxide, hydrogen peroxide and mitochondrial malondialdehyde in manganese treated Drosophila melanogaster.

The toxicity caused by high concentrations of manganese (Mn) could be due to a production of free radicals. Minocycline is an effective antioxidant with a high potential to capture free radicals. We investigated the effect of minocycline in the activities of superoxide dismutase (SOD) and catalase, and in the concentrations of nitric oxide (NO), hydrogen peroxide (H2O2) and mitochondrial malondialdehyde (MDA) in manganese-treated Drosophila melanogaster. Five groups of flies were used: (1) control: not treated; (2) continuously treated with minocycline (0.05 mM); (3) treated with 30 mM Mn for 6 days and then no additional treatment; (4) continuously treated with Mn; (5) treated only with Mn for 6 days and then treated with minocycline; (6) simultaneously treated with Mn and minocycline. On the 6th day, Mn treatment caused 50% mortality; in the surviving flies increased levels of MDA (67.93%), NO (11.04%), H2O2 (14.62%) and SOD and catalase activity (165.34 and 71.43%, respectively) were detected. All the flies continuously treated with Mn died by the 21st day. On day 40, MDA levels were decreased in groups two, three and five (43.04, 29.67, and 34.72% respectively), as well as NO in group two (29.21%) and H2O2 in groups two and five (53.94% and 78.69%, respectively), while in group three the concentration of H2O2 was increased (408.25%). In conclusion, Mn exerted a pro-oxidant effect on the 6th day as shown by the increased levels of oxidative markers. Minocycline extended the lifespan, increased the activity of SOD and reduced the levels of NO, H2O2 and mitochondrial MDA.

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.

Minocycline, but not ascorbic acid, increases motor activity and extends the life span of Drosophila melanogaster.

In the present study we compared the effects of minocycline and ascorbic acid in the life span, motor activity and lipid peroxidation of Drosophila melanogaster, in an effort to find a substance capable of providing protection against oxidative stress in aging. In the flies treated with minocycline a very significant increase in the life span (101 +/- 1.33 days) was observed when compared to those treated with ascorbic acid and controls (42.3% and 38.4%, respectively). The motor activity of minocycline treated flies also increased significantly with respect to control and ascorbic acid fed flies, from the 3rd to the 9th week of treatment. With regard to lipid peroxidation, it was found that the levels of malondialdehyde (MDA) in flies treated with minocycline showed no statistical differences to the control on the first day of treatment, but a significantly lower content on the day of 50% survival. In contrast, in flies treated with ascorbic acid significantly elevated levels of MDA compared to control and minocycline treated flies were detected throughout. These results suggest a protective effect of minocycline against oxidative stress and aging in D. melanogaster. An inhibitory effect on reactive oxygen species production may be an important contributing factor.

[Copper intoxication decreases lifespan and induces neurologic alterations in Drosophila melanogaster]. / La intoxicación con cobre disminuye la sobrevida e induce alteraciones neurológicas en Drosophila melanogaster.

Wilson disease is a hereditary disorder caused by mutations of the ATP7B gene, which leads to intoxication with copper as a result of an unbalance of copper homeostasis. The clinical manifestations resulting from this intoxication are related to the affectation of liver and the encephalon in most cases. Several animal models are currently available for the study of the malady. However, in such models no neurological symptoms are observed, which limits their use for the study of pathogenic effects of this disease on the central nervous system. The aim of the present study was to evaluate if copper feeding could induce a disease state in Drosophila melanogaster to model Wilson disease. The effect of the feeding of copper at the doses of 31 microM and 47 microM on the survival was initially evaluated. Next, behavioral experiments were conducted to determine whether the motor performance was altered by the 47 microM concentration. The results suggest that copper treatment decreases the viability of the flies. In addition, the decrease of viability was associated to an increase and decrease of spontaneous motor activity at early and late stages of the intoxication, respectively. Finally, the role of the dopaminergic neurotransmission system on the observed motor alterations was evaluated. The dopamine precursor L-dopa increased motor activity. In contrast, D2 receptor antagonist, Fluphenazine, was able to block both the increase and decrease of motor activity scores induced by copper. These results suggest that Drosophila melanogaster could be used as a model organism for the study of possible interventions with potential neuroprotective effects in Wilson disease.

Minocycline, but not ascorbic acid, increases motor activity and extends the life span of Drosophila melanogaster / La minociclina, pero no el ácido ascórbico, incrementa la actividad motora y extiende el período de vida de Drosophila melanogaster

In the present study we compared the effects of minocycline and ascorbic acid in the life span, motor activity and lipid peroxidation of Drosophila melanogaster, in an effort to find a substance capable of providing protection against oxidative stress in aging. In the flies treated with minocycline a very significant increase in the life span (101 ± 1.33 days) was observed when compared to those treated with ascorbic acid and controls (42.3% and 38.4%, respectively). The motor activity of minocycline treated flies also increased significantly with respect to control and ascorbic acid fed flies, from the 3rd to the 9th week of treatment. With regard to lipid peroxidation, it was found that the levels of malondialdehyde (MDA) in flies treated with minocycline showed no statistical differences to the control on the first day of treatment, but a significantly lower content on the day of 50% survival. In contrast, in flies treated with ascorbic acid significantly elevated levels of MDA compared to control and minocycline treated flies were detected throughout. These results suggest a protective effect of minocycline against oxidative stress and aging in D. melanogaster. An inhibitory effect on reactive oxygen species production may be an important contributing factor.

En el presente estudio se compararon los efectos del ácido ascórbico y la minociclina en la duración del periodo de vida, la actividad motora y la peroxidación lipídica de Drosophila melanogaster en un esfuerzo por encontrar una sustancia capaz de proporcionar protección contra el estrés oxidativo en el envejecimiento. En las moscas tratadas con minociclina se observó un aumento significativo en la duración de la vida (101 ± 1,33 días) en comparación con los tratados con ácido ascórbico y los controles (42,3% y 38,4%, respectivamente). La actividad motora de las moscas tratadas con minociclina aumentó significativamente cuando se comparó con las tratadas con ácido ascórbico y el control, desde la 3ra hasta la 9na semana de tratamiento. Con respecto a la peroxidación lipídica, se encontró que los niveles de malondialdehído (MDA) en moscas tratadas con minociclina no mostraron diferencias estadísticas con relación al control en el primer día de tratamiento; sin embargo, se detecto una disminución significativa de la concentración de MDA cuando se alcanzó el 50% de sobrevida. En contraste, en moscas tratadas con ácido ascórbico observamos que los niveles de MDA estaban significativamente elevados, cuando se compararon con las moscas tratadas con minociclina y el control a lo largo de todo el tratamiento. Estos resultados sugieren un efecto protector de la minociclina frente al estrés oxidativo y el envejecimiento en D. melanogaster, aunque un efecto inhibidor sobre la producción de especies reactivas del oxígeno puede ser un factor contribuyente importante.

La intoxicación con cobre disminuye la sobrevida e induce alteraciones neurológicas en Drosophila melanogaster / Copper intoxication decreases lifespan and induces neurologic alterations in Drosophila melanogaster

La enfermedad de Wilson, es un trastorno hereditario autosómico recesivo causado por mutaciones del gen de la trifosfatasa de adenosina (ATP7B). Dicha mutación ocasiona intoxicación con cobre, generando manifestaciones clínicas por los efectos tóxicos del metal, principalmente a nivel del hígado y el encéfalo. Recientemente se han desarrollado modelos genéticos de la enfermedad para su estudio clínico. Sin embargo, la utilidad de los mismos es limitada por el hecho de que en tales modelos no se observan manifestaciones neurológicas. El presente estudio tuvo como objetivo desarrollar un modelo de la enfermedad de Wilson en Drosophila melanogaster. Inicialmente se evaluó el efecto de la suplementación con concentraciones de 31 µM y 47 µM de cobre en la sobrevida. Posteriormente se realizaron estudios de conducta para determinar si existían alteraciones en el desempeño motor asociadas al tratamiento con la dosis de 47 µM de cobre. Los resultados obtenidos sugieren que el tratamiento con cobre disminuye la viabilidad de la Drosophila. La disminución de la sobrevida estuvo asociada a un aumento y una disminución de los registros de actividad motora en las etapas tempranas y tardías de la intoxicación respectivamente. Por último, se evaluó el papel del sistema de neurotransmisión dopaminérgico sobre las alteraciones conductuales inducidas por el cobre. El tratamiento con el precursor de la dopamina, L-dopa, indujo un aumento de la actividad motora similar al inducido por el cobre. Por el contrario, el tratamiento con Flufenazina, un antagonista de los receptores dopaminérgicos D2, fue capaz de impedir las alteraciones conductuales en todas las edades evaluadas. Estos resultados sugieren que la Drosophila melanogaster podría ser empleada como modelo para el estudio de posibles intervenciones con potencial terapéutico en la enfermedad de Wilson.

Wilson disease is a hereditary disorder caused by mutations of the ATP7B gene, which leads to intoxication with copper as a result of an unbalance of copper homeostasis. The clinical manifestations resulting from this intoxication are related to the affectation of liver and the encephalon in most cases. Several animal models are currently available for the study of the malady. However, in such models no neurological symptoms are observed, which limits their use for the study of pathogenic effects of this disease on the central nervous system. The aim of the present study was to evaluate if copper feeding could induce a disease state in Drosophila melanogaster to model Wilson disease. The effect of the feeding of copper at the doses of 31 µM and 47 µM on the survival was initially evaluated. Next, behavioral experiments were conducted to determine whether the motor performance was altered by the 47 µM concentration. The results suggest that copper treatment decreases the viability of the flies. In addition, the decrease of viability was associated to an increase and decrease of spontaneous motor activity at early and late stages of the intoxication, respectively. Finally, the role of the dopaminergic neurotransmission system on the observed motor alterations was evaluated. The dopamine precursor L-dopa increased motor activity. In contrast, D2 receptor antagonist, Fluphenazine, was able to block both the increase and decrease of motor activity scores induced by copper. These results suggest that Drosophila melanogaster could be used as a model organism for the study of possible interventions with potential neuroprotective effects in Wilson disease.

Experimental depression induces renal oxidative stress in rats.

Depression has been associated to inflammatory and oxidative events. Previous report has shown renal oxidative stress in patients with depression. In order to analyze if depressive status is related to renal oxidative and inflammatory events, Sprague Dawley rats were submitted to forced swimming test (FST) and the renal oxidative metabolism, monocyte-macrophage infiltration and Angiotensin II (Ang II) expression were determined. Rats were submitted to FST daily (30 min) for 15 days. Motor activity was analyzed before FST. Kidney sections were homogenized to measure nitric oxide (NO), malondialdehyde (MDA), reduced glutathione (GSH) and catalase activity by enzymatic and biochemical methods. Renal frozen sections were studied for superoxide anion (O2-), monocyte/macrophage infiltration and Ang II expression by histochemical and immunofluorescence methods. In addition, three groups of FST rats were treated with losartan, sertraline or water for 18 days with further renal O2-analysis. In the FST group, struggle time, motor activity, food intake and body weight gain were found decreased. Increased number of glomerular, interstitial and tubular O2-positive cells was observed in FST rats. High renal content of nitrite/nitrate (NO), MDA and decreased amount of GSH were found in FST rats. Values of renal ED-1 or Ang II positive cells in FST rats remained similar to controls; however, AT1 receptor blocking (losartan) and sertraline reduced both depressive-like behavior and renal O2-expression. These data suggests that depression-like behavior in rats is involved in kidney oxidative stress probably mediated by AT1 receptors.

Forced swimming test decreases chemotactic responsiveness and expression of CD11a in rat monocytes.

OBJECTIVES: Previous reports have shown that the depressive status in humans and experimental animals is associated with decreased immune response. Since monocyte chemotaxis and expression of CD11a are pivotal mechanisms in immune response, impairment of these events could explain the diminished immune response in depression. METHODS: To test this, rats were submitted to the forced swimming test (FST) for 3 and 15 days. Animals were sacrificed at days 4 (3 days' FST), 16 (15 days' FST) and 30 (15 days' FST and 15 days of recovery time). At these times, a blood sample was obtained for serum and leukocyte isolation. Mononuclear leukocytes were obtained by Histopaque gradient. Chemotaxis responsiveness was determined in Boyden chambers using zymosan-activated rat serum. Cellular CD11a expression and serum CD11a were determined by immunofluorescence and ELISA, respectively. RESULTS: Decreased chemotaxis was observed in FST animals at days 4 and 16 with total recovery at day 30. Diminished expression of cellular CD11a was observed at day 16 and remained decreased at day 30. There were no significant differences in serum CD11a content. CONCLUSION: Decreased chemotactic response and expression of CD11a found in this experimental model of depression could be important mechanisms to induce impairment immune response in experimental and clinical depression.

Forced swimming test increases superoxide anion positive cells and angiotensin II positive cells in the cerebrum and cerebellum of the rat.

Situations of stress are capable of inducing depression and oxidative stress in the brain. Previous reports have shown that angiotensin II (Ang II) induces the production of superoxide anion (O(2)(-)), and impairment of endothelial function in cerebral microvessels in vivo. Substances that reduce angiotensin functions may be important in the treatment of depression. These data suggest a role for both Ang II and O(2)(-) in depression; thus, the aim of this study was to determine the effect of forced swimming test (FST), a model of stress/depression, on the cellular expression of Ang II and O(2)(-) in the central nervous system. To induce stress/depression, rats were subjected to FST daily (30 min) for 15 days. Unstressed animals were used as controls. Motor activity was automatically analyzed daily before swimming. Cerebrum and cerebellum frozen sections were studied for O(2)(-) by a histochemical method and for Ang II producing cells by a polyclonal antibody. In the FST group, struggle time, total horizontal activity, ambulatory movements, and vertical movements, were significantly decreased when the data from the 1st and 15th day were compared. Food intake and body weight gain also decreased when unstressed and FST rats were compared at the 15th day. Increased number of cerebrum and cerebellum O(2)(-), and Ang II positive cells, were observed in FST rats. Significant correlation was found between O(2)(-) positive cells and Ang II positive cell in the cerebrum. These results suggest that stress/depression situations could be involved in the increase of Ang II and oxidative stress in the central nervous system, with possible implications in the depressive condition.

Stress-induced muscle and cutaneous hyperalgesia: differential effect of milnacipran.

We previously demonstrated that repeated swim stress produces long-term cutaneous hyperalgesia in rats. We have now determined the effect of stress upon muscle nociception and the anti-nociceptive efficacy of the norepinephrine-serotonin reuptake inhibitor, milnacipran (MIL) in this model. Rats were subjected to either 10-20 min daily sessions of forced swimming (FS) for 3 days, or sham swimming (SS) or control (CT). Maximal forelimb grip strength and hot plate response latencies were estimated before and after the conditioning to assess muscle and thermal nociception, respectively. MIL (1-30 mg/kg/i.p.) or vehicle was started 7 days before the conditioning protocol. There were significant reductions in maximal grip strength and hot plate latencies only in FS/vehicle rats. Subsequent carrageenan administration (2 mg/75 microl each triceps) diminished grip strength in all groups 24 h later, with grip strength lower in FS/vehicle and SS/vehicle rats than in CT/vehicle rats. Treatment with MIL before the stress prevented the reduction in grip strength in all groups but it was ineffective in preventing FS-induced reductions in hot plate response latencies. Thus, repeated stress produces muscle hyperalgesia that can be pharmacologically dissociated from cutaneous hyperalgesia, suggesting that different mechanisms may underlie these two phenomena.

Role of mu-opioid and NMDA receptors in the development and maintenance of repeated swim stress-induced thermal hyperalgesia.

Repeated exposure to swimming stress induces a long-lasting hyperalgesia in the rat by mechanisms to be elucidated. Since opioid and glutamate neurotransmitter systems modulate pain, we now evaluated the effect of pharmacological blockade of opioid and glutamate receptors subtypes on forced swimming stress-induced hyperalgesia. Male rats were daily subjected to 10-20 min of forced or sham swimming for 3 days and thermal nociception was estimated twice, before each behavioral conditioning and 24 h after the last, using hot plate test. Selective opioid and NMDA receptor antagonists were administered i.p. either before each conditioning session or before the second nociception assessment. Unlike sham swimming rats, forced swimming rats showed significant reductions in hot plate response latencies (hyperalgesia) after the last swimming session, as compared to pre-stress values. Rats treated with the opioid receptor antagonists naloxone (0.1 mg/kg, non-subtype-selective) and naloxonazine (5 mg/kg, mu(1)-subtype-selective), before each forced swimming, did not become hyperalgesic, whereas those treated before the second post-stress assessment of nociception developed hyperalgesia. Naltrindole (0.5 mg/kg, delta-subtype-selective) and nor-binaltorphimine (0.5mg/kg, kappa-subtype-selective) were inactive in both administration schedules. The efficacy of morphine (3-7.5 mg/kg) to produce analgesia in forced swimming rats was lower than in sham swimming rats. Rats treated with the NMDA antagonist ketamine (5 mg/kg) before the forced swimming or the second post-stress assessment of nociception did not have hyperalgesia. Thus, swim stress-induced hyperalgesia might be initiated by the repeated stimulation of mu-opioid and NMDA receptors but maintained only by the activity of NMDA receptors.

Repeated swim stress increases pain-induced expression of c-Fos in the rat lumbar cord.

We have previously demonstrated that repeated swim stress produces a long-lasting cutaneous hyperalgesia in rats. We have now looked at c-Fos expression in the spinal lumbar cord of male Sprague-Dawley rats subjected to 10-20 min daily sessions of forced swimming for 3 consecutive days. Control rats were subjected to sham swimming or were completely naive. Forty-eight hours later, nociception was assessed by recording for 90 min the nociceptive behavior evoked the injection of 1% formalin in the hind paw. Thirty min later, the rats' spinal cords were removed for c-Fos immunocytochemistry. Total pain scores were 45% higher in swim stressed rats compared to control animals due an increased nociceptive behavior during last 70 min of the recording period. In addition, the number of c-Fos-immunoreactive nuclei was 40% higher in the lumbar ipsilateral dorsal horn (L4-L5) of swim stressed rats than in controls, being the highest relative increase, relative to the control groups, observed in laminae III-IV, followed by laminae V-VI, with the smallest difference in laminae I-II. c-Fos expression in the contralateral dorsal horn was higher in swim stressed rats than in sham and nai;ve rats. In the absence of a nociceptive stimulus, a low level of c-Fos expression was observed mainly in laminae I, II, V, and VI, being higher in swim stressed rats than in sham rats. These findings suggest that repeated inescapable and uncontrollable stress could induce a sensitization and activation of sensory neurons at the spinal level.