Neurotoxicity induced by toluene: In silico and in vivo evidences of mitochondrial dysfunction and dopaminergic neurodegeneration.

Toluene is an air pollutant widely used as an organic solvent in industrial production and emitted by fossil fuel combustion, in addition to being used as a drug of abuse. Its toxic effects in the central nervous system have not been well established, and how and which neurons are affected remains unknown. Hence, this study aimed to fill this gap by investigating three central questions: 1) How does toluene induce neurotoxicity? 2) Which neurons are affected? And 3) What are the long-term effects induced by airborne exposure to toluene? To this end, a Caenorhabditis elegans model was employed, in which worms at the fourth larval stage were exposed to toluene in the air for 24 h in a vapor chamber to simulate four exposure scenarios. After the concentration-response curve analysis, we chose scenarios 3 (E3: 792 ppm) and 4 (E4: 1094 ppm) for the following experiments. The assays were performed 1, 48, or 96 h after removal from the exposure environments, and an irreversible reduction in neuron fluorescence and morphologic alterations were observed in different neurons of exposed worms, particularly in the dopaminergic neurons. Moreover, a significant impairment in a dopaminergic-dependent behavior was also associated with negative effects in healthspan endpoints, and we also noted that mitochondria may be involved in toluene-induced neurotoxicity since lower adenosine 5'-triphosphate (ATP) levels and mitochondrial viability were observed. In addition, a reduction of electron transport chain activity was evidenced using ex vivo protocols, which were reinforced by in silico and in vitro analysis, demonstrating toluene action in the mitochondrial complexes. Based on these findings model, it is plausible that toluene neurotoxicity can be initiated by complex I inhibition, triggering a mitochondrial dysfunction that may lead to irreversible dopaminergic neuronal death, thus impairing neurobehavioral signaling.

Rutin protects Huntington's disease through the insulin/IGF1 (IIS) signaling pathway and autophagy activity: Study in Caenorhabditis elegans model.

Huntington's disease (HD) is inherited neurodegenerative disease, it is characterized by excessive motor movements and cognitive and emotional deficits. HD is caused by an abnormally long polyglutamine (polyQ) expansion in the huntingtin (Htt) protein, which confers toxic functions to mutant Htt leading to neurodegeneration. Rutin is a flavonoid found in plants, buckwheat, some teas and also in apples. Although previous studies have already indicated that rutin has some protective effects in HD's models, the underlying mechanisms are still unknown. In our study, we investigated the effects of rutin in Caenorhabditis elegans model of HD. We assessed polyQ aggregation, oxidative damage, neurodegeneration level and lifespan, and investigated the possible role of autophagy and insulin/IGF1 (IIS) signaling pathways in the beneficial effects induced by rutin. Overall, our data demonstrate that chronic rutin treatment reduced polyglutamine (polyQ) protein aggregation in muscle, reduced polyQ-mediated neuronal death in ASH sensory neurons, and extended lifespan. The possible mechanisms involved are antioxidant activity, activation of protein degradation (autophagy) and insulin/IGF1 (IIS) signaling pathways. These findings indicate that rutin consumption might be helpful in preventing HD and also provide possible pathways to be explored to search for new therapies against proteinopathies related to aging.