Undifferentiated HepaRG cells show reduced sensitivity to the toxic effects of M8OI through a combination of CYP3A7-mediated oxidation and a reduced reliance on mitochondrial function.

The methylimidazolium ionic liquid M8OI (1-octyl-3-methylimidazolium chloride, also known as [C8mim]Cl) has been detected in the environment and may represent a hazard trigger for the autoimmune liver disease primary biliary cholangitis, based in part on studies using a rat liver progenitor cell. The effect of M8OI on an equivalent human liver progenitor (undifferentiated HepaRG cells; u-HepaRG) was therefore examined. u-HepaRG cells were less sensitive (>20-fold) to the toxic effects of M8OI. The relative insensitivity of u-HepaRG cells to M8OI was in part, associated with a detoxification by monooxygenation via CYP3A7 followed by further oxidation to a carboxylic acid. Expression of CYP3A7 - in contrast to the related adult hepatic CYP3A4 and CYP3A5 forms - was confirmed in u-HepaRG cells. However, blocking M8OI metabolism with ketoconazole only partly sensitized u-HepaRG cells. Despite similar proliferation rates, u-HepaRG cells consumed around 75% less oxygen than B-13 cells, reflective of reduced dependence on mitochondrial activity (Crabtree effect). Replacing glucose with galactose, resulted in an increase in u-HepaRG cell sensitivity to M8OI, near similar to that seen in B-13 cells. u-HepaRG cells therefore show reduced sensitivity to the toxic effects of M8OI through a combination of metabolic detoxification and their reduced reliance on mitochondrial function.

Potential for cardiac toxicity with methylimidazolium ionic liquids.

Methylimidazolium ionic liquids (MILs) are solvent chemicals used in industry. Recent work suggests that MILs are beginning to contaminate the environment and lead to exposure in the general population. In this study, the potential for MILs to cause cardiac toxicity has been examined. The effects of 5 chloride MIL salts possessing increasing alkyl chain lengths (2 C, EMI; 4 C, BMI; 6 C; HMI, 8 C, M8OI; 10 C, DMI) on rat neonatal cardiomyocyte beat rate, beat amplitude and cell survival were initially examined. Increasing alkyl chain length resulted in increasing adverse effects, with effects seen at 10-5 M at all endpoints with M8OI and DMI, the lowest concentration tested. A limited sub-acute toxicity study in rats identified potential cardiotoxic effects with longer chain MILs (HMI, M8OI and DMI) based on clinical chemistry. A 5 month oral/drinking water study with these MILs confirmed cardiotoxicity based on histopathology and clinical chemistry endpoints. Since previous studies in mice did not identify the heart as a target organ, the likely cause of the species difference was investigated. qRT-PCR and Western blotting identified a marked higher expression of p-glycoprotein-3 (also known as ABCB4 or MDR2) and the breast cancer related protein transporter BCRP (also known as ABCG2) in mouse, compared to rat heart. Addition of the BCRP inhibitor Ko143 - but not the p-glycoproteins inhibitor cyclosporin A - increased mouse cardiomyocyte HL-1 cell sensitivity to longer chain MILs to a limited extent. MILs therefore have a potential for cardiotoxicity in rats. Mice may be less sensitive to cardiotoxicity from MILs due in part, to increased excretion via higher levels of cardiac BCRP expression and/or function. MILs alone, therefore may represent a hazard in man in the future, particularly if use levels increase. The impact that MILs exposure has on sensitivity to cardiotoxic drugs, heart disease and other chronic diseases is unknown.

Hydroxychloroquine antiparkinsonian potential: Nurr1 modulation versus autophagy inhibition.

The nuclear orphan receptor (Nurr1) has recently received a perceivable solicitude as a target for the therapeutic intervention against PD. Meanwhile, the dysregulation of autophagy, along with other processes is believed to contribute massively to PD pathophysiology. Hydroxychloroquine, a hydroxy derivative of chloroquine, is an antimalarial agent which is also used as an anti-rheumatic drug. The neuroprotective potential of hydroxychloroquine and chloroquine remained controversial until recently a study showed that chloroquine exhibited an antiparkinsonian activity through Nurr1 modulation. The aim of this work is to identify whether the less toxic derivative, hydroxychloroquine, could show a similar pattern. In rat rotenone model, hydroxychloroquine effectively boosted Nurr-1 expression, exhibited an anti-inflammatory effect as verified by hindering certain pro-inflammatory cytokines and successfully reduced GSK-3ß activity. Consequently, an increase in the striatal tyrosine hydroxylase content, as well as improved locomotion and muscle coordination was shown. However, this improvement was opposed by hydroxychloroquine induced autophagic inhibition as manifested by enhancing both LC3-II and P62 levels possibly through the prominent decline in sirtuin 1 level and elevated apoptotic biomarkers. In conclusion, hydroxychloroquine successfully ameliorated PD motor dysfunction in spite of the fact that both autophagy and apoptosis were deregulated through Nurr1 modulation.

Cilostazol Mediated Nurr1 and Autophagy Enhancement: Neuroprotective Activity in Rat Rotenone PD Model.

Nuclear receptor related 1 (Nurr1) orphan receptor has emerged as a promising contender in ameliorating Parkinson's disease; thus, finding a suitable activator of Nurr1 receptor is an attracting target for treating PD. Cilostazol, a phosphodiesterase-3 inhibitor, recently showed a favorable neuroprotective activity in multiple devastating central disorders, yet the possible antiparkinsonian activity of the drug has not been fully elucidated. Thus, the aim of this study is to explore the neuroprotective effect of cilostazol in rotenone-induced PD model in rats. Cilostazol successfully upregulated Nurr1 expression in PD rats, which resulted in successful preservation of the dopaminergic neuron functionality and integrity as verified by the marked improvement of motor performance in rotarod and open field tests, as well as the increased striatal tyrosine hydroxylase content. Moreover, cilostazol revealed an anti-inflammatory activity as manifested by hampering the global controller of inflammatory signaling pathway, nuclear factor-kappa B, together with its downstream pro-inflammatory cytokines, namely tumor necrosis factor-alpha and interleukin-1 beta, via Nurr-1 upregulation and glycogen synthase kinase 3 beta GSK-3ß inhibition. In turn, the increase in GSK-3ß inhibited form suppressed the measured downstream apoptotic biomarkers, viz. cytochrome C and caspase-3. Remarkably, cilostazol enhanced autophagy as depicted by hampering both LC3-II and P62 levels possibly through the prominent rise in sirtuin 1 level. In conclusion, cilostazol could be a promising candidate for PD treatment through modulating Nurr1 expression, as well as SIRT-1/autophagy, and GSK-3ß/apoptosis cross-regulation. Graphical Abstract In the rat rotenone model of Parkinson's disease (PD), Nurr1 expression was downregulated, GSK-3ß was activated, and autophagic flux was inhibited. Those deleterious effects were associated with deteriorated motor functions, striatal TH content, enhanced inflammatory state, and apoptotic cascade. Cilostazol, a phosphodiesterase-3 inhibitor, exerted a potential protective effect against PD through Nurr1 enhancement, GSK-3ß/apoptosis modulation, and SIRT-1/autophagy enhancement. Nurr1 nuclear receptor related 1, TH tyrosine hydroxylase, NF-κB nuclear factor κB, TNFα tumor necrosis factor alpha, ILs interleukins, GSK-3ß glycogen synthase kinase 3 beta, SIRT-1 sirtuin 1.