Chronic Alcohol Intoxication and Cortical Ischemia: Study of Their Comorbidity and the Protective Effects of Minocycline

Chronic alcohol intoxication (CAI) increases both morbidity and mortality of stroke patients. Despite the high prevalence of CAI and ischemic stroke, studies addressing their comorbidity and/or protective alternatives remain scarce. Thus, the influence of CAI on both stroke outcome and minocycline treatment (recognized for its neuroprotective effect) was investigated. Female Wistar rats (35 days old) were treated with water or ethanol (6.5 g/kg/day, 22.5% w/v) for 55 days. Then, focal ischemia was induced by endothelin-1 in the motor cortex. Two hours later, four doses of 50 mg/kg of minocycline every 12 hours followed by five doses of 25 mg/kg every 24 hours were administered. Behavioral performance (open field and rotarod tests) and immunohistochemical (cellular density, neuronal death, and astrocytic activation) and biochemical (lipid peroxidation and nitrite levels) analyses were performed. CAI increased motor disruption, nitrite and lipid peroxidation levels, and neuronal loss caused by ischemia, whereas it reduced the astrogliosis. Minocycline was effective in preventing the motor and tissue damage caused by stroke. However, these effects were attenuated when CAI preceded stroke. Our data suggest that CAI beginning in adolescence contributes to a worse outcome in ischemic stroke survivors and reduces the benefits of minocycline, possibly requiring adjustments in therapy

Exposição à concentração subletal de metilmercúrio: genotoxicidade e alterações na proliferação celular

Mercury is a metal that stands out from the rest for present liquid under normal temperature and pressure. This xenobiotic is the largest source of pollution in many parts of the world and has been characterized toxic to the central nervous system (CNS). After dumping in liquid form directly into soil and riverbed, this heavy metal complex with various organic elements or it is converted to methylmercury (MeHg) by aquatic microbiota. The MeHg can move up the food chain, an event known as biomagnification, which directly affects human life. Thereby, the Amazon stands out for having all the components necessary for the maintenance of biogeochemical cycle of mercury as well as populations chronically exposed with this heavy metal. And this metal is considered a public health problem. It is well known that this xenobiotic after acute exposure to high doses promotes disorders related to the emergence of degenerative processes in the CNS, however, the effects at low concentrations are not yet fully described. Despite this cell type play an important role in the mercury intoxication process, the role of this metal on glial cells is not well known, especially on the genome and cell proliferation. Thus, this study aimed to evaluate the effect of exposure to this xenobiotic at low concentration on DNA and cell proliferation in C6 glial lineage cells. The biochemical (mitochondrial activity - measured by MTT assay -) and morphofunctional evaluations (membrane integrity - measured by the assay with dyes and AA BE -) confirmed the absence of cell death after exposure to heavy metals in a concentration of 3 μM for 24 hours. Even without causing cell death processes, the treatment with sublethal concentration of MeHg that was able to significantly increase the levels of markers of genotoxicity (DNA fragmentation, micronuclei, nuclear nucleoplasmic bridges and nuclear bud). At the same time, it was possible to observe a change in the cell cycle by increasing the mitotic index and a change in the cell cycle profile with increased cell population in S and G2 / M phases, suggesting an arrest cell cycle arrest. This change in cell cycle caused by MeHg exposure was followed by number of viable cells and cell confluence decrease, 24 hours after the withdrawal of MeHg of culture medium. The C6 cell line culture in addition showed an increase on doubling time parameter. This study demonstrates for the first time exposure to methylmercury low and sublethal concentration can promote genotoxic events and disturbances in cell proliferation in glial cell origin.FAPESPA - Fundação Amazônia de Amparo a Estudos e PesquisasCAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível SuperiorO mercúrio é um metal que se destaca dos demais por se apresentar líquido em temperatura e pressão normais. Este xenobiótico se apresenta como a maior fonte de poluição em várias partes do mundo e tem como característica ser altamente tóxico ao Sistema Nervoso Central (SNC). O despejo é na forma líquida diretamente no solo e leito dos rios. Este metal pesado é complexado com vários elementos presentes no solo ou sedimentos sendo convertido à metilmercúrio (MeHg) pela microbiota aquática. O MeHg apresenta a capacidade de se acumular ao longo da cadeia trófica, um evento conhecido como biomagnificação, o qual afeta diretamente a vida humana. Nesse sentido, a Região Amazônica se destaca por possuir todos os componentes necessários para a manutenção do ciclo biogeoquímico do mercúrio, além de populações cronicamente expostas a este metal pesado, sendo este fato considerado um problema de saúde pública. Tem-se conhecimento que este xenobiótico após a exposição aguda a altas doses promove desordens relacionadas ao surgimento de processos degenerativos no SNC, entretanto, os efeitos a baixas concentrações ainda não são totalmente conhecidos. Nesse sentido, se destacam as células gliais que atuam como mediadores no processo de neurotoxicidade desse metal, principalmente em baixas concentrações. Apesar de este tipo celular exibir um importante papel no processo de intoxicação mercurial, a ação deste metal sobre as células glias é pouco conhecida, principalmente sobre o genoma e a proliferação celular. Desta forma, este trabalho se propõe a avaliar o efeito da exposição a este xenobiótico em baixa concentração sobre o material genético e a proliferação celular em células da linhagem glial C6. As avaliações bioquímica (atividade mitocondrial – medida pelo ensaio de MTT –) e morfofuncional (integridade da membrana – avaliada pelo ensaio com os corantes BE e AA –) confirmaram a ausência de morte celular após a exposição ao metal pesado na concentração de 3 μM por um intervalo de 24 horas. Mesmo sem promover processos de morte celular, o tratamento com esta concentração subletal de MeHg foi capaz de aumentar significativamente os níveis dos marcadores de genotoxicidade (fragmentação do DNA, formação de micronúcleos, pontes nucleoplásmica e brotos nucleares). Ao mesmo tempo, foi possível observar uma alteração no ciclo celular através do aumento do índice mitótico e uma mudança no perfil do ciclo celular com aumento da população celular nas fases S e G2/M, sugerindo um aprisionamento nessa etapa. Esta mudança no ciclo celular, provocada por 24h de exposição ao MeHg, foi seguida de uma redução no número de células viáveis e confluência celular 24h após a retirada do MeHg e substituição do meio de cultura, além do aumento no tempo de duplicação da cultura do mesmo. Este estudo demonstrou pela primeira vez que a exposição ao metilmercúrio em concentração baixa e subletal é capaz de promover eventos genotóxicos e distúrbios na proliferação celular em células de origem glial

Intracellular accumulation and DNA damage caused by methylmercury in glial cells

Conselho Nacional de Desenvolvimento Cientifico e Tecnologico, Grant/Award Number: 307382/2019-2Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Programa de Pós Graduação em Epidemiologia e vigilância em Saúde. Ananindeua, PA, Brasil / Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Ananindeua, PA, Brasil.Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Programa de Pós Graduação em Epidemiologia e vigilância em Saúde. Ananindeua, PA, Brasil / Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Ananindeua, PA, Brasil.Universidade Federal do Pará - Campus de Altamira. Faculdade de Medicina. Altamira, PA, Brazil.Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Ananindeua, PA, Brasil.Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Ananindeua, PA, Brasil / Universidade Federal do Pará. Faculdade de Ciências Naturais. Belém, PA, Brazil.Mercury is widely used in industrial and extractive processes, and the improper disposal of waste or products containing this metal produces a significant impact on ecosystems, causing adverse effects on living organisms, including humans. Exposure to methylmercury, a highly toxic organic compound, causes important neurological and developmental impairments. Recently, the genotoxicity of mercurial compounds has gained prominence as one of the possible mechanisms associated with the neurological effects of mercury, mostly by disturbing the mitotic spindle and causing chromosome loss. In this sense, it is important to investigate if these compounds can also cause direct damage to DNA, such as single and double-strand breaks. Thus, the aim of this study was to investigate the cytotoxic and genotoxic potential of methylmercury in cell lines derived from neurons (B103) and glia (C6), exposed to methylmercury (MeHg) for 24 h, by analyzing cell viability, metabolic activity, and damage to DNA and chromosomes. We found that in comparison to the neuronal cell line, glial cells showed higher tolerance to MeHg, and therefore a higher LC50 and consequent higher intracellular accumulation of Hg, which led to the occurrence of several genotoxic effects, as evidenced by the presence of micronuclei, bridges, sprouts, and chromosomal aberration

Therapeutic concentration of morphine reduces oxidative stress in glioma cell line

Morphine is a potent analgesic opioid used extensively for pain treatment. During the last decade, global consumption grew more than 4-fold. However, molecular mechanisms elicited by morphine are not totally understood. Thus, a growing literature indicates that there are additional actions to the analgesic effect. Previous studies about morphine and oxidative stress are controversial and used concentrations outside the range of clinical practice. Therefore, in this study, we hypothesized that a therapeutic concentration of morphine (1 μM) would show a protective effect in a traditional model of oxidative stress. We exposed the C6 glioma cell line to hydrogen peroxide (H₂O₂) and/or morphine for 24 h and evaluated cell viability, lipid peroxidation, and levels of sulfhydryl groups (an indicator of the redox state of the cell). Morphine did not prevent the decrease in cell viability provoked by H₂O₂) but partially prevented lipid peroxidation caused by 0.0025% H₂O₂) (a concentration allowing more than 90% cell viability). Interestingly, this opioid did not alter the increased levels of sulfhydryl groups produced by exposure to 0.0025% H₂O₂), opening the possibility that alternative molecular mechanisms (a direct scavenging activity or the inhibition of NAPDH oxidase) may explain the protective effect registered in the lipid peroxidation assay. Our results demonstrate, for the first time, that morphine in usual analgesic doses may contribute to minimizing oxidative stress in cells of glial origin. This study supports the importance of employing concentrations similar to those used in clinical practice for a better approximation between experimental models and the clinical setting

Morphine Protects against Methylmercury Intoxication: A Role for Opioid Receptors in Oxidative Stress?

<div><p>Mercury is an extremely dangerous environmental contaminant responsible for episodes of human intoxication throughout the world. Methylmercury, the most toxic compound of this metal, mainly targets the central nervous system, accumulating preferentially in cells of glial origin and causing oxidative stress. Despite studies demonstrating the current exposure of human populations, the consequences of mercury intoxication and concomitant use of drugs targeting the central nervous system (especially drugs used in long-term treatments, such as analgesics) are completely unknown. Morphine is a major option for pain management; its global consumption more than quadrupled in the last decade. Controversially, morphine has been proposed to function in oxidative stress independent of the activation of the opioid receptors. In this work, a therapeutic concentration of morphine partially protected the cellular viability of cells from a C6 glioma cell line exposed to methylmercury. Morphine treatment also reduced lipid peroxidation and totally prevented increases in nitrite levels in those cells. A mechanistic study revealed no alteration in sulfhydryl groups or direct scavenging at this opioid concentration. Interestingly, the opioid antagonist naloxone completely eliminated the protective effect of morphine against methylmercury intoxication, pointing to opioid receptors as the major contributor to this action. Taken together, the experiments in the current study provide the first demonstration that a therapeutic concentration of morphine is able to reduce methylmercury-induced oxidative damage and cell death by activating the opioid receptors. Thus, these receptors may be a promising pharmacological target for modulating the deleterious effects of mercury intoxication. Although additional studies are necessary, our results support the clinical safety of using this opioid in methylmercury-intoxicated patients, suggesting that normal analgesic doses could confer an additional degree of protection against the cytotoxicity of this xenobiotic.</p></div

Direct scavenging activity of increasing concentrations of morphine against free radicals.

<p>Morphine was incubated with a 1,1diphenyl-2-picrylhydrazyl solution; results are shown as mean ± standard deviation (n = 9). *P<0.01 versus control group. ^#P<0.01 versus all groups.</p

Viability of C6 cells exposed to increasing concentrations of methylmercury (MeHg) for 24 h.

<p>Data are expressed as mean ± standard deviation (n = 4). *P<0.01 versus all groups.</p

Lipid peroxidation in C6 cells incubated with 1 µM morphine and/or 6 µM methylmercury (MeHg) for 24 h.

<p>Data are reported as mean ± standard deviation (n = 3). *P<0.05 versus control group; #P<0.05 versus control and MeHg groups.</p

Nitrites in C6 cells exposed to 1 µM morphine and/or 6 µM methylmercury (MeHg) for 24 h.

<p>Data are shown as mean ± standard deviation (n = 3). *P<0.01 versus all groups.</p

Viability of C6 cells incubated with 1 µM morphine and/or 6 µM methylmercury (MeHg) for 24 h.

<p>Data are reported as mean ± standard deviation (n = 3). *P<0.05 versus all groups.</p