Downregulation of intestinal multidrug resistance transporter 1 in obese mice: Effect on its barrier function and role of TNF-α receptor 1 signaling.

OBJECTIVES: Multidrug resistance transporter 1 (Mdr-1) is a relevant component of the intestinal transcellular barrier that decreases absorption of oral drugs, thus modulating their bioavailability. Obese patients with metabolic disorders take medications that are subjected to intestinal metabolism and the Mdr-1-dependent barrier. This study evaluated the effect of a high-fat diet (HFD; 40% fat for 16 wk) on Mdr-1 expression and transport activity in C57BL/6 (C57) male mice. Comparable studies were performed in tumor necrosis factor α (TNF-α) receptor 1 knockout mice (R1KO) to delineate a possible role of TNF-α signaling. METHODS: mRNA expression was evaluated by real-time polymerase chain reaction and protein levels by western blotting and immunohistochemistry. Mdr-1 activity was assessed using the everted intestinal sac model, with rhodamine 123 as the substrate. Statistical comparisons were made using the Student t test or one-way analysis of variance followed by the post hoc Tukey test. RESULTS: Mdr-1 protein, as well as its corresponding Mdr1a and Mdr1b mRNA, was decreased in C57-HFD mice compared with controls. Immunohistochemical studies confirmed downregulation of Mdr-1 in situ. These results correlated with a 48% decrease in the basolateral to apical transport of rhodamine 123. In contrast, R1KO-HFD modified neither intestinal Mdr-1 mRNA nor its protein expression or activity. In addition, C57-HFD showed elevated intestinal TNF-α mRNA and protein (enzyme-linked immunosorbent assay) levels, whereas R1KO-HFD was undetectable or had a lower increase, respectively. CONCLUSIONS: This study demonstrated an impairment of the Mdr-1 intestinal barrier function induced by HFD as a consequence of downregulation of both Mdr-1 gene homologues, resulting in impaired Mdr-1 protein expression. Inflammatory response mediated by TNF-α receptor 1 signaling was likely involved.

Broadening the spectrum of ivermectin: Its effect on Trypanosoma cruzi and related trypanosomatids.

Chagas disease is an endemic American parasitosis, caused by Trypanosoma cruzi. The current therapies, benznidazole (BZN) and nifurtimox (NFX), show limited efficacy and multiple side effects. Thus, there is a need to develop new trypanocidal strategies. Ivermectin (IVM) is a broad-spectrum antiparasitic drug with low human and veterinary toxicity with effects against T. brucei and Leishmania spp. Considering this and its relatively low cost, we evaluate IVM as a potential repurposed trypanocidal drug on T. cruzi and other trypanosomatids. We found that IVM affected, in a dose-dependent manner, the proliferation of T. cruzi epimastigotes as well as the amastigotes and trypomastigotes survival. The Selectivity Index for the amastigote stage with respect to Vero cells was 12. The IVM effect was also observed in Phytomonas jma 066 and Leishmania mexicana proliferation but not in Crithidia fasciculata. On the epimastigote stage, the IVM effect was trypanostatic at 50 µM but trypanocidal at 100 µM. The assays of the drug combinations of IVM with BNZ or NFX showed mainly additive effects among combinations. In silico studies showed that classical structures belonging to glutamate-gated Cl channels, the most common IVM target, are absent in kinetoplastids. However, we found in the studied trypanosomatid genomes one copy for putative IMPα and IMPß, potential targets for IVM. The putative IMPα genes (with 76% similarity) showed conserved Armadillo domains but lacked the canonical IMPß binding sequence. These results allowed us to propose a novel molecular target in T. cruzi and suggest IVM as a good candidate for drug repurposing in the Chagas disease context.

Multidrug resistance-associated protein 2 is negatively regulated by oxidative stress in rat intestine via a posttranslational mechanism. Impact on its membrane barrier function.

Oxidative stress (OS) is a key factor in the development of gastrointestinal disorders, in which the intestinal barrier is altered. However, the Multidrug resistance-associated protein 2 (Mrp2) status, an essential component of the intestinal transcellular barrier exhibiting pharmaco-toxicological relevance by limiting the orally ingested toxicants and drugs absorption, has not been investigated. We here evaluated the short-term effect of OS on Mrp2 by treatment of isolated rat intestinal sacs with tert-butyl hydroperoxide (TBH) for 30 min. OS induction by TBH (250 and 500 µM) was confirmed by increased lipid peroxidation end products, decreased reduced glutathione (GSH) content and altered antioxidant enzyme activities. Under this condition, assessment of Mrp2 distribution between brush border (BBM) and intracellular (IM) membrane fractions, showed that Mrp2 protein decreased in BBM and increased in IM, consistent with an internalization process. This was associated with decreased efflux activity and, consequently, impaired barrier function. Subsequent incubation with N-Acetyl-L-Cysteine (NAC, 1 mM) reestablished GSH content and reverted concomitantly the alteration in Mrp2 localization and function induced by TBH. Cotreatment with a specific inhibitor of classic calcium-dependent Protein Kinase C (cPKC) implicated this kinase in TBH-effects. In conclusion, we demonstrated a negative posttranslational regulation of rat intestinal Mrp2 after short-term exposition to OS, a process likely mediated by cPKC and dependent on intracellular GSH content. The concomitant impairment of the Mrp2 barrier function may have implications in xenobiotic absorption and toxicity in a variety of human diseases linked to OS, with notable consequences on the toxicity/safety of therapeutic agents.

Reversion of down-regulation of intestinal multidrug resistance-associated protein 2 in fructose-fed rats by geraniol and vitamin C: Potential role of inflammatory response and oxidative stress.

Intestinal multidrug resistance-associated protein 2 is an ABC transporter that limits the absorption of xenobiotics ingested orally, thus acting as essential component of the intestinal biochemical barrier. Metabolic Syndrome (MetS) is a pathological condition characterized by dyslipidemia, hyperinsulinemia, insulin resistance, chronic inflammation, and oxidative stress (OS). In a previous study we demonstrated that MetS-like conditions induced by fructose in drinking water (10% v/v, during 21 days), significantly reduced the expression and activity of intestinal Mrp2 in rats. We here evaluated the potential beneficial effect of geraniol or vitamin C supplementation, natural compounds with anti-inflammatory and anti-oxidant properties, in reverse fructose-induced Mrp2 alterations. After MetS-like conditions were induced (21 days), animals were cotreated with geraniol or vitamin C or vehicle for another 14 days. Decreased expression of Mrp2 protein and mRNA due to fructose administration was reversed by geraniol and by vitamin C, consistent with restoration of Mrp2 activity evaluated in everted intestinal sacs. Concomitantly, increased intestinal IL-1ß and IL-6 levels induced by fructose were totally and partially counterbalanced, respectively, by geraniol administration. The intestinal redox unbalance generated by fructose was improved by geraniol and vitamin C, as evidenced by decreasing lipid peroxidation products and activity of Superoxide Dismutase and by normalizing glutathione reduced/oxidized glutathione ratio. The restoration effects exhibited by geraniol and vitamin C suggest that local inflammatory response and OS generated under MetS-like conditions represent important mediators of the intestinal Mrp2 down-regulation. Additionally, both agents could be considered of potential therapeutic value to preserve Mrp2 function under MetS conditions.

Intestinal multidrug resistance-associated protein 2 is down-regulated in fructose-fed rats.

Expression and activity of jejunal multidrug resistance-associated protein 2 (Mrp2) and glutathione-S-transferase (GST) were examined in fructose fed Wistar rats, an experimental model of metabolic syndrome. Animals were fed on (a) control diet or (b) control diet plus 10% w/vol fructose in the drinking water. Mrp2 and the α class of GST proteins as well as their corresponding mRNAs were decreased, suggesting a transcriptional regulation by fructose. Confocal microscopy studies reaffirmed down-regulation of Mrp2. Everted intestinal sacs were incubated with 1-chloro-2,4-dinitrobenzene in the mucosal compartment, and the glutathione-conjugated derivative, dinitrophenyl- S-glutathione (DNP-SG; model Mrp2 substrate), was measured in the same compartment to estimate Mrp2 activity. Excretion of DNP-SG was substantially decreased by fructose treatment, consistent with simultaneous down-regulation of Mrp2 and GST. In addition, the effect of fructose on intestinal barrier function exerted by Mrp2 was evaluated in vivo using valsartan, a recognized Mrp2 substrate of therapeutic use. After intraduodenal administration as a bolus, intestinal absorption of valsartan was increased in fructose-drinking animals. Fructose administration also induced oxidative stress in intestinal tissue as demonstrated by significant increases of intestinal lipid peroxidation end products and activity of the antioxidant enzyme superoxide dismutase, by a decreased GSH/GSSG ratio. Moreover, fructose treatment conduced to increased intestinal levels of the proinflammatory cytokines IL-ß1 and IL-6. Collectively, our results demonstrate that metabolic syndrome-like conditions, induced by a fructose-rich diet, result in down-regulation of intestinal Mrp2 expression and activity and consequently in an impairment of its barrier function.

The trypanocidal benznidazole promotes adaptive response to oxidative injury: Involvement of the nuclear factor-erythroid 2-related factor-2 (Nrf2) and multidrug resistance associated protein 2 (MRP2).

Oxidative stress is a frequent cause underlying drug-induced hepatotoxicity. Benznidazole (BZL) is the only trypanocidal agent available for treatment of Chagas disease in endemic areas. Its use is associated with side effects, including increases in biomarkers of hepatotoxicity. However, BZL potential to cause oxidative stress has been poorly investigated. Here, we evaluated the effect of a pharmacologically relevant BZL concentration (200µM) at different time points on redox status and the counteracting mechanisms in the human hepatic cell line HepG2. BZL increased reactive oxygen species (ROS) after 1 and 3h of exposure, returning to normality at 24h. Additionally, BZL increased glutathione peroxidase activity at 12h and the oxidized glutathione/total glutathione (GSSG/GSSG+GSH) ratio that reached a peak at 24h. Thus, an enhanced detoxification of peroxide and GSSG formation could account for ROS normalization. GSSG/GSSG+GSH returned to control values at 48h. Expression of the multidrug resistance-associated protein 2 (MRP2) and GSSG efflux via MRP2 were induced by BZL at 24 and 48h, explaining normalization of GSSG/GSSG+GSH. BZL activated the nuclear erythroid 2-related factor 2 (Nrf2), already shown to modulate MRP2 expression in response to oxidative stress. Nrf2 participation was confirmed using Nrf2-knockout mice in which MRP2 mRNA expression was not affected by BZL. In summary, we demonstrated a ROS increase by BZL in HepG2 cells and a glutathione peroxidase- and MRP2 driven counteracting mechanism, being Nrf2 a key modulator of this response. Our results could explain hepatic alterations associated with BZL therapy.

Pregnane X receptor mediates the induction of P-glycoprotein by spironolactone in HepG2 cells.

We evaluated the effect of spironolactone (SL), a well-known inducer of biotransformation and elimination pathways, on the expression and activity of P-glycoprotein (P-gp/ABCB1/MDR1), a major xenobiotic transporter, in HepG2 cells, as well as the potential mediation of pregnane X nuclear receptor (PXR). Cells were exposed to SL (1, 5, 10, 20 or 50 µM) for 48 h. Expression of P-gp and its mRNA levels were estimated by Western blotting and real time PCR, respectively. P-gp activity was inversely correlated with the ability of the cells to accumulate the model substrate rhodamine 123 (Rh123, 5 µM), in the presence or absence of verapamil (50 µM), a P-gp inhibitor. At the highest dose of SL tested, P-gp and MDR1 mRNA levels were significantly increased (73 and 108%) with respect to control cells. Rh123 accumulation was concomitantly reduced and verapamil was able to abolish this effect, confirming P-gp participation. Additionally, we tested the cytotoxicity of doxorubicin, a model substrate of P-gp, under inducing conditions. HepG2 cells treated with SL exhibited higher viability, i.e. less doxorubicin toxicity, than control cells, consistent with P-gp up-regulation. When HepG2 cells were treated with SL in the presence of ketoconazole (KTZ), a non-specific nuclear receptor inhibitor, the up-regulation of P-gp was suppressed. To further identify the nuclear receptor involved, cells were transfected with a siRNA directed against human PXR, leading to a 74% decrease in PXR protein levels, which totally abolished SL induction of P-gp. We conclude that SL up-regulates P-gp expression, likely at transcriptional level, and its efflux activity in HepG2 cells. This effect is mediated by PXR. Thus, ligands of PXR such as SL may alter the disposition and toxicity of other xenobiotics, including drugs of therapeutic use, that are P-gp substrates.