Parabens enhance the calcium-dependent testicular mitochondrial permeability transition: Their relevance on the reproductive capacity in male animals.

Parabens, alkyl ester derivatives from p-hydroxybenzoic acid, are extensively used as antimicrobial preservatives. Nonetheless, due to its widespread and massive employment, several studies highlighted the association between parabens and alterations in the reproductive system. This study aimed to relate the adverse effect of the most commonly used parabens in testis mitochondria with male fertility. From all the parabens used, propyl and butyl were the ones that most negatively decreased the respiratory control ratio. In the case of butyl, inhibitions of 20% and 60% were observed, respectively, at the lowest and highest concentration, when compared to the control group. The membrane potential was only significantly affected by propyl (14%) and butyl (31%), and at a concentration of 250 µM. Succinate dehydrogenase, cytochrome c oxidase, and ATPase activities showed a nonsignificant decrease. Cytochrome c reductase, on the other hand, showed statistically significant inhibitions for both propyl (56%) and butylparaben (55%). The susceptibility to the mitochondrial permeability transition pore (MPTP) opening was increased by all parabens, although this increase was markedly significant for propyl and butyl. These results show that the susceptibility of mitochondria to parabens is dependent on the alkyl chain length and parabens hydrophobicity, and the main mitochondrial target is Complex II-III and MPTP. Hence, this study demonstrates the contribution of parabens exposition to the inhibition of testis mitochondrial function and their putative noxious effect on the male reproductive system.

Propofol affinity to mitochondrial membranes does not alter mitochondrial function.

The molecular mechanisms of hepatotoxicity after propofol anaesthesia have not been fully elucidated, although there is a relation with mitochondrial dysfunction. The action of propofol on mitochondrial hepatic functions in a rat model was evaluated by infusion for 4h with 25 and 62.5mg/kg/h propofol or 3.125ml/kg/h (vehicle). Liver mitochondrial respiratory rates were evaluated as well as mitochondrial transmembrane potential (ΔΨ), calcium fluxes, mitochondrial enzymatic activities (Complex I-V) and oxidative stress biomarkers (superoxide dismutase, catalase, glutathione reductase, glutathione S-transferase, lipid peroxidation and the oxidised/reduced glutathione ratio). Biophysical interactions with membrane models were also performed. The mitochondrial transmembrane potential was decreased and the opening time of the mitochondrial permeability transition pore was slightly reduced for the highest dose. The activity of complex II was stimulated by propofol, which also causes fluctuations on some respiratory parameters, whereas the antioxidant system was affected in a nonspecific manner. Fluorescence quenching studies suggested that propofol is preferably located in deeper regions of the bilayer and has a high affinity to mitochondrial membranes. It is suggested that propofol interacts with liver mitochondrial membranes with mild modification in mitochondrial function.

Carvedilol exacerbate gentamicin-induced kidney mitochondrial alterations in adult rat.

Gentamicin is an aminoglycoside antibiotic widely used to treat many types of bacterial infections. Although its properties, his clinical use is limited due to the occurrence of nephrotoxicity, which has been related to mitochondrial dysfunction. Carvedilol, an antihypertensive drug with strong antioxidant properties, has been tested in order to prevent gentamicin nephrotoxicity. This study aimed to test this hypothesis using a rat model of gentamicin-induced nephrotoxicity. Animals were treated subcutaneously with DMSO (control) (0.4%/kg/24h bw) for 11days; with carvedilol (2mg/kg/24h bw) for 11days; with gentamicin (60mg/kg/24h bw) for the last 8days and with carvedilol (2mg/kg/24h bw) for 11days and with gentamicin (60mg/kg/24h bw) for the last 8days. Estimations of urine creatinine, urine carboxylic acids, blood urea, serum creatinine and glomerular filtration rate were carried out after the last administered dose of gentamicin. Mitochondria functionality was analyzed by monitoring its bioenergetics function and cardiolipin oxidized products were analyzed by ESI-MS. The kidneys were also examined for morphological changes. Gentamicin caused marked nephrotoxicity and mitochondrial dysfunction as evidenced by several mitochondrial parameters. Carvedilol did not induce significant changes while the co-treatment exacerbated the negative effect of gentamicin although maintaining ATP levels and membrane potential. Kidneys from gentamicin treated rats, with and without carvedilol, showed necrosis of tubular cells in renal cortex. Higher values on relative abundance of cardiolipin oxidation products identified as [M-2H]2- ions, at m/z 771 were observed in the groups treated with gentamicin. The observed effects were associated to a possible interaction of carvedilol with F1F0-ATP synthase that merit further investigation. In conclusion, carvedilol may contribute to the exacerbation of renal dysfunction induced by gentamicin, at least in some physiological and biochemical parameters. From a clinical perspective, and until further conclusions, cautious use of both drugs in combination is advised with particular emphasis in patients presenting mitochondrial disorders.

Mitochondrial and liver oxidative stress alterations induced by N-butyl-N-(4-hydroxybutyl)nitrosamine: relevance for hepatotoxicity.

The most significant toxicological effect of nitrosamines like N-butyl-N-(4-hydroxybutyl)nitrosamine (BBN) is their carcinogenic activity, which may result from exposure to a single large dose or from chronic exposure to relatively small doses. However, its effects on mitochondrial liver bioenergetics were never investigated. Liver is the principal organ responsible for BBN metabolic activation, and mitochondria have a central function in cellular energy production, participating in multiple metabolic pathways. Therefore any negative effect on mitochondrial function may affect cell viability. In the present work, ICR male mice were given 0.05% of BBN in drinking water for a period of 12 weeks and were sacrificed one week later. Mitochondrial physiology was characterized in BBN- and control-treated mice. Transmembrane electric potential developed by mitochondria was significantly affected when pyruvate-malate was used, with an increase in state 4 respiration observed for pyruvate-malate (46%) and succinate (38%). A decrease in the contents of one subunit of mitochondrial complex I and in one subunit of mitochondrial complex IV was also observed. In addition, the activity of both complexes I and II was also decreased by BBN treatment. The treatment with BBN increases the susceptibility of liver mitochondria to the opening of the mitochondrial permeability transition pore. This susceptibility could be related with the increase in the production of H2 O2 by mitochondria and increased oxidative stress confirmed by augmented susceptibility to lipid peroxidation. These results lead to the conclusion that hepatic mitochondria are one primary target for BBN toxic action during liver metabolism.

Mitochondrial toxicity of the phyotochemicals daphnetoxin and daphnoretin--relevance for possible anti-cancer application.

Daphnetoxin is a daphnane type orthoester diterpene found exclusively in plants of the family Thymelaeaceae while daphnoretin, a bis-coumarin derivative that is the major constituent of the bark of some plants of this family, can also be found in Leguminosae and Rutaceae. These two compounds are recognized to have different biological effects, including a possible anti-cancer activity. The subject of the present research was to compare their mitochondrial toxicity and also investigate a possible selectivity towards tumor cell lines. Wistar rat liver mitochondria and three distinct cell lines were used to investigate compound-induced toxicity. The results indicate that both test compounds are toxic to isolated mitochondrial fractions, especially when used at concentrations higher than 100 microM. However, daphnetoxin presented the highest toxicity including increased proton leak in the inner mitochondrial membrane, increased induction of the mitochondrial permeability transition pore, inhibition of ATP synthase and inhibition of the mitochondrial respiratory chain. Both compounds also inhibited cell proliferation, regardless of the cell line used. Up to the maximal concentration tested in cells, no mitochondrial effects were detected by vital epifluorescence imaging, indicating that inhibition of cell proliferation may also originate from mitochondrial-independent mechanisms. The results warrant careful assessment of toxicity vs. pharmacology benefits of both molecules.

Parabens in male infertility-is there a mitochondrial connection?

Parabens are widely used as preservatives in many foods, cosmetics, toiletries, and pharmaceuticals due to their relatively low toxicity profile and to a long history of safe use. Parabens are alkyl esters of p-hydroxybenzoic acid and typically include methylparaben, ethylparaben, propylparaben, butylparaben, isobutylparaben, isopropylparaben and benzylparaben. These compounds are known to have a null or very weak estrogenic activity in estrogen receptor assays in vitro. In recent years, an increasing concern has emerged regarding possible adverse effects of chemicals in food and in cosmetics on human reproduction outcomes. In developed countries about 15% of human couples are affected by infertility, almost half of these cases attributed to men, through low sperm motility or/and sperm count. It is known that a significant number of cases of male infertility results from exposure to xenobiotics, and also that testis mitochondria are particularly affected by drug-induced toxicity. The present review discusses evidence that parabens may not be as safe as initially thought, and suggests that the interaction between parabens and mitochondrial function in the testis may be key in explaining the contribution of parabens for a decrease in reproductive potential.