Long-term in vivo polychlorinated biphenyl 126 exposure induces oxidative stress and alters proteomic profile on islets of Langerhans.

It has been recently proposed that exposure to polychlorinated biphenyls (PCBs) is a risk factor to type 2 diabetes mellitus (DM2). We investigated this hypothesis using long-term in vivo PCB126 exposure to rats addressing metabolic, cellular and proteomic parameters. Male Wistar rats were exposed to PCB126 (0.1, 1 or 10 µg/kg of body weight/day; for 15 days) or vehicle by intranasal instillation. Systemic alterations were quantified by body weight, insulin and glucose tolerance, and blood biochemical profile. Pancreatic toxicity was measured by inflammatory parameters, cell viability and cycle, free radical generation, and proteomic profile on islets of Langerhans. In vivo PCB126 exposure enhanced the body weight gain, impaired insulin sensitivity, reduced adipose tissue deposit, and elevated serum triglycerides, cholesterol, and insulin levels. Inflammatory parameters in the pancreas and cell morphology, viability and cycle were not altered in islets of Langerhans. Nevertheless, in vivo PCB126 exposure increased free radical generation and modified the expression of proteins related to oxidative stress on islets of Langerhans, which are indicative of early ß-cell failure. Data herein obtained show that long-term in vivo PCB126 exposure through intranasal route induced alterations on islets of Langerhans related to early end points of DM2.

Absorption of PCB126 by upper airways impairs G protein-coupled receptor-mediated immune response.

PCB126 is a dioxin-like polychlorinated biphenyl (PCB) environmental pollutant with a significant impact on human health, as it bioaccumulates and causes severe toxicity. PCB126-induced immune toxicity has been described, although the mechanisms have not been fully elucidated. In this study, an in vivo protocol of PCB126 intoxication into male Wistar rats by intranasal route was used, which has not yet been described. The intoxication was characterised by PCB126 accumulation in the lungs and liver, and enhanced aryl hydrocarbon receptor expression in the liver, lungs, kidneys, and adipose tissues. Moreover, an innate immune deficiency was characterised by impairment of adhesion receptors on blood leukocytes and by reduced blood neutrophil locomotion and oxidative burst activation elicited by ex vivo G protein-coupled receptor (GPCR) activation. Specificity of PCB126 actions on the GPCR pathway was shown by normal burst oxidative activation evoked by Toll-like receptor 4 and protein kinase C direct activation. Moreover, in vivo PCB180 intoxication did not alter adhesion receptors on blood leukocytes either blood neutrophil locomotion, and only partially reduced the GPCR-induced burst oxidative activation on neutrophils. Therefore, a novel mechanism of in vivo PCB126 toxicity is described which impairs a pivotal inflammatory pathway to the host defence against infections.

Ultrasmall cationic superparamagnetic iron oxide nanoparticles as nontoxic and efficient MRI contrast agent and magnetic-targeting tool.

Fully dispersible, cationic ultrasmall (7 nm diameter) superparamagnetic iron oxide nanoparticles, exhibiting high relaxivity (178 mM(-1)s(-1) in 0.47 T) and no acute or subchronic toxicity in Wistar rats, were studied and their suitability as contrast agents for magnetic resonance imaging and material for development of new diagnostic and treatment tools demonstrated. After intravenous injection (10 mg/kg body weight), they circulated throughout the vascular system causing no microhemorrhage or thrombus, neither inflammatory processes at the mesentery vascular bed and hepatic sinusoids (leukocyte rolling, adhesion, or migration as evaluated by intravital microscopy), but having been spontaneously concentrated in the liver, spleen, and kidneys, they caused strong negative contrast. The nanoparticles are cleared from kidneys and bladder in few days, whereas the complete elimination from liver and spleen occurred only after 4 weeks. Ex vivo studies demonstrated that cationic ultrasmall superparamagnetic iron oxide nanoparticles caused no effects on hepatic and renal enzymes dosage as well as on leukocyte count. In addition, they were readily concentrated in rat thigh by a magnet showing its potential as magnetically targeted carriers of therapeutic and diagnostic agents. Summarizing, cationic ultrasmall superparamagnetic iron oxide nanoparticles are nontoxic and efficient magnetic resonance imaging contrast agents useful as platform for the development of new materials for application in theranostics.

Estudo experimental da exposição ao PCB126 sobre a indução de Diabetes mellitus tipo II / Experimental study of PCB126 exposure on induction of Diabetes mellitus type II

A exposição ambiental aos poluentes orgânicos persistentes tem recebido amplo destaque na literatura recentemente devido à extensa associação entre o desenvolvimento de doenças metabólicas, obesidade e/ou diabetes mellitus, e a presença destes poluentes, principalmente os organoclorados, como as bifenilas policloradas (PCBs), no organismo. Por outro lado, os mecanismos de ação destes poluentes é controverso devido à elevada quantidade de representantes destas classes, gerando diversidade de protocolos de exposição e escassez de estudos experimentais. Por isto, foi objetivo deste trabalho elucidar os mecanismos de ação tóxica do PCB126, nas doses de 0,1; 1 ou 10 µg/kg de massa corpórea, em ratos Wistar machos, durante quinze dias, expostos por instilação intranasal. O procotolo de exposição empregado foi caracterizado e considerado suficiente para causar toxicidade, uma vez que foram observadas alterações no sistema imune, metabolismo e em parâmetros relacionados à gênese do diabetes mellitus. A caracterização da exposição foi determinada pela quantificação da concentração de PCB126 no fígado e pulmão (CG/MS) e pelo aumento da expressão do receptor aril hidrocarboneto (AhR) no rim, fígado, pulmão e tecido adiposo (Western Blot). O efeito imunossupressor do PCB126 foi evidenciado pelo comprometimento da produção de células na medula óssea e, consequentemente, no número de células totais no sangue circulante. Adicionalmente, foi evidenciada a interferência do poluente na via de ativação mediada por receptores acoplados à proteína G (GPCRs), principalmente em neutrófilos, alterando importantes funções destas células, como a expressão de moléculas de adesão, geração de espécies reativas de oxigênio e migração. Entre as alterações metabólicas observadas, destacamos o aumento dos níveis de triglicerídeos e colesterol sérico, aumento da liberação de ácidos graxos livres; aumento da atividade da enzima hepática gama glutamil transferase; aumento da resistência à insulina e aumento da geração de óxido nítrico pelas ilhotas de Langerhans, dados estes, possivelmente relacionados ao comprometimento das células beta (ß) pancreáticas, confirmados pelo aumento da expressão de GLUT4 no tecido adiposo, aumento da concentração de insulina sérica e aumento do estresse oxidativo nas ilhotas de Langerhans. Em conjunto, os dados obtidos destacam importantes alterações causadas pela exposição intranasal ao PCB126, evidenciando a participação do poluente na gênese do diabetes mellitus do tipo II

The environmental exposure to persistent organic pollutants has been widely highlighted in recent literature due to the extensive association between the development of metabolic diseases, obesity and/or diabetes mellitus, and presence of these pollutants, especially organochlorines such as polychlorinated biphenyls (PCBs) in organism. Moreover, the mechanisms of action of these pollutants are controversial due to the high number of PCBs congeners, diversity of exposure protocols and lack of experimental studies. Therefore, the aim of this study was to elucidate the mechanisms of PCB126's toxic action at doses of 0.1; 1 or 10 µg/kg body weight in male Wistar rats exposed by intranasal instillation for 15 days. The established exposure procotol was characterized and considered sufficient to cause toxicity since changes were observed in the immune system, metabolism and in parameters related to the pathogenesis of diabetes mellitus. Characterization of exposure was determined by quantifying the concentration of PCB126 in liver and lung (GC-MS) and by the increased expression of aryl hydrocarbon receptor (AhR) in kidney, liver, lung, and adipose tissue (Western blot). The immunosuppressive effect of PCB126 was evidenced by impairment of cell production in the bone marrow and thus the total number of cells in the circulation. In addition, the interference of the pollutant in the activation pathway mediated by G-protein coupled receptors (GPCRs), in particular in neutrophils, was observed by changing important functions of these cells such as the expression of adhesion molecules, reactive oxygen species generation, and migration. Among the metabolic changes observed, we highlight the increased levels of triglycerides and serum cholesterol, increased release of free fatty acids; increased gamma glutamyl transferase hepatic enzyme activity; increased insulin resistance and increased generation of nitric oxide by the islets of Langerhans, these data possibly related to the impairment of beta cells (ß) pancreatic function, suggested by the increased expression of GLUT4 in adipose tissue, increased serum insulin concentration and increased oxidative stress in the islets of Langerhans. Altogether, these results highlight important changes caused by intranasal exposure to PCB126, suggesting participation of the pollutant in the genesis of diabetes mellitus type II

Synthesis and preliminary biological evaluation of a compound library of triazolylcyclitols.

A small library of compounds was prepared by a combination of toluene dioxygenase (TDO)-catalyzed enzymatic dihydroxylation and copper(I)-catalyzed Hüisgen cycloaddition. Some compounds were obtained by coupling an alkyne and a conduritol derivative, while more complex structures were obtained by a double Hüisgen reaction of a dialkyne and two molecules of the cyclitol. The compounds were fully characterized and subjected to preliminary biological screening.

Anacardic acids from cashew nuts ameliorate lung damage induced by exposure to diesel exhaust particles in mice.

Anacardic acids from cashew nut shell liquid, a Brazilian natural substance, have antimicrobial and antioxidant activities and modulate immune responses and angiogenesis. As inflammatory lung diseases have been correlated to environmental pollutants exposure and no reports addressing the effects of dietary supplementation with anacardic acids on lung inflammation in vivo have been evidenced, we investigated the effects of supplementation with anacardic acids in a model of diesel exhaust particle- (DEP-) induced lung inflammation. BALB/c mice received an intranasal instillation of 50 µ g of DEP for 20 days. Ten days prior to DEP instillation, animals were pretreated orally with 50, 150, or 250 mg/kg of anacardic acids or vehicle (100 µ L of cashew nut oil) for 30 days. The biomarkers of inflammatory and antioxidant responses in the alveolar parenchyma, bronchoalveolar lavage fluid (BALF), and pulmonary vessels were investigated. All doses of anacardic acids ameliorated antioxidant enzyme activities and decreased vascular adhesion molecule in vessels. Animals that received 50 mg/kg of anacardic acids showed decreased levels of neutrophils and tumor necrosis factor in the lungs and BALF, respectively. In summary, we demonstrated that AAs supplementation has a potential protective role on oxidative and inflammatory mechanisms in the lungs.

In vivo hydroquinone exposure impairs MCP-1 secretion and monocyte recruitment into the inflamed lung.

Alveolar macrophages (AMs) are important cells in the resolution of the inflammatory process and they come into direct contact with inhaled pollutants. Hydroquinone (HQ) is an environmental pollutant and a component of cigarette smoke that causes immunosuppressive effects. In the present work, we showed that mice exposed to low levels of aerosolized HQ (25 ppm; 1 h/day/5 days) presented impaired mononuclear cell migration to the lipopolysaccharide (LPS)-inflamed lung. This may have been due to reduced monocyte chemoattractant protein-1 (MCP-1) secretion into bronchoalveolar lavage fluid (BALF), and it was not related to alterations to mononuclear cell mobilization into the blood or adhesion molecules expression on mononuclear cell membranes. Corroborating the actions of HQ on MCP-1 secretion, reduced MCP-1 concentrations were also found in the supernatant of ex vivo AM and tracheal tissue collected from HQ-exposed mice. A direct action of HQ on MCP-1 secretion, resulting from impaired gene synthesis, was verified by in vitro incubation of naive AMs or tracheal tissue with HQ. The role of reduced levels of MCP-1 in the BALF on monocyte migration was analysed in the human monocytic lineage THP-1 in in vitro chemotaxis assays, which showed that the reduced concentrations of MCP-1 found in the BALF or cell supernatants from HQ-exposed mice impaired cell migration. Considering the fact that MCP-1 presents a broad spectrum of actions on pathophysiological conditions and that resident mononuclear cells are involved in lung tissue homeostasis and in immune host defence, the mechanism of HQ toxicity presented herein might be relevant to the genesis of infectious lung diseases in smokers and in inhabitants of polluted areas.

In vivo hydroquinone exposure causes tracheal hyperresponsiveness due to TNF secretion by epithelial cells.

Hydroquinone (HQ) is the main oxidative substance in cigarette smoke and a toxic product of benzene biotransformation. Although the respiratory tract is an inlet pathway of HQ exposure, its effect on airway muscle responsiveness has not been assessed. We thus investigated the effects of low dose in vivo HQ-exposure on tracheal responsiveness to a muscarinic receptor agonist. Male Swiss mice were exposed to aerosolised 5% ethanol/saline solution (HQ vehicle; control) or 0.04 ppm HQ (1h/day for 5 days) and tracheal rings were collected 1h after the last exposure. HQ exposure caused tracheal hyperresponsiveness to methacholine (MCh), which was abolished by mechanical removal of the epithelium. This hyperresponsiveness was not dependent on neutrophil infiltration, but on tumour necrosis factor (TNF) secretion by epithelial cells. This conclusion was based on the following data: (1) trachea from HQ-exposed mice presented a higher amount of TNF, which was abrogated following removal of the epithelium; (2) the trachea hyperresponsiveness and TNF levels were attenuated by in vivo chlorpromazine (CPZ) treatment, an inhibitor of TNF synthesis. The involvement of HQ-induced TNF secretion in trachea mast cell degranulation was also demonstrated by the partial reversion of tracheal hyperresponsiveness in sodium cromoglicate-treated animals, and the in vivo HQ-exposure-induced degranulation of trachea connective tissue and mucosal mast cells, which was reversed by CPZ treatment. Our data show that in vivo HQ exposure indirectly exacerbates the parasympathetic-induced contraction of airway smooth muscle cells, mediated by TNF secreted by tracheal epithelial cells, clearly showing the link between environmental HQ exposure and the reactivity of airways.

In vivo hydroquinone exposure alters circulating neutrophil activities and impairs LPS-induced lung inflammation in mice.

Hydroquinone (HQ) is an environmental contaminant which causes immune toxicity. In this study, the effects of exposure to low doses of HQ on neutrophil mobilization into the LPS-inflamed lung were investigated. Male Swiss mice were exposed to aerosolized vehicle (control) or 12.5, 25 or 50ppm HQ (1h/day for 5 days). One hour later, oxidative burst, cell cycle, DNA fragmentation and adhesion molecules expressions in circulating neutrophils were determined by flow cytometry, and plasma malondialdehyde (MDA) levels were measured by HPLC. Also, 1h later the last exposures, inflammation was induced by LPS inhalation (0.1mg/ml/10min) and 3h later, the numbers of leukocytes in peripheral blood and in the bronchoalveolar lavage fluid (BALF) were determined using a Neubauer chamber and stained smears; adhesion molecules expressed on lung microvessel endothelial cells were quantified by immunohistochemistry; myeloperoxidase (MPO) activity was measured in the lung tissue by colorimetric assay; and cytokines in the BALF were determined by ELISA. In vivo HQ exposure augmented plasma MDA levels and oxidative activity of neutrophils, but did not cause alterations in cell cycle and DNA fragmentation. Under these conditions, the number of circulating leukocytes was not altered, but HQ exposure reduced LPS-induced neutrophil migration into the alveolar space, as these cells remained in the lung tissue. The impaired neutrophil migration into BALF may not be dependent on reduced cytokines secretions in the BALF and lung endothelial adhesion molecules expressions. However, HQ exposure increased the expression of ß(2) and ß(3) integrins and platelet-endothelial cell adhesion molecule-1 (PECAM-1) in neutrophils, which were not further enhanced by fMLP in vitro stimulation, indicating that HQ exposure activates circulating neutrophils, impairing further stimulatory responses. Therefore, it has been shown, for the first time, that neutrophils are target of lower levels of in vivo HQ exposure, which may be considered in host defense in infectious diseases.