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Monensin, a well known ionophore antibiotic, may cause severe damage in neuronal cells by altering Na+/K+-ATPase and Ca2+-ATPase. We investigated whether IRFI-042, a synthetic analogue of vitamin E, may block lipid peroxidation in neuronal cells and protect against monensin neurotoxicity in chicks. Monensin toxicity was induced in chicks by once-daily administration (150 mg/kg by oral gavages), for 8 days. Sham animals received a saline solution and were used as controls. All animals were randomized to receive either IRFI-042 (20 mg/kg) or its vehicle. Survival rate, brain lipid peroxidation, mRNA for neuronal and inducible nitric oxide synthases (nNOS and iNOS) and brain histological evaluations, including immunohistochemical expression of nNOS and iNOS were performed. Monensin administration decreased survival rate, induced behavioural changes, increased brain lipid peroxidation, reduced brain nNOS mRNA and immunostaining and enhanced iNOS mRNA and immunostaining in the brain in chicks. IRFI-042 significantly improved the survival rate and counteracted monensin-induced changes in chick brains. Our data suggest that monensin is responsible of neurotoxicity in chicks by inducing oxidative stress/lipid peroxidation and that IRFI-042 might represent a useful pharmacological approach to protect against the neuronal damage induced by this monovalent carboxylic ionophorous polyether antibiotic.

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Monensin, a well-known ionophore antibiotic, may cause severe damage in myocardial cells. We investigated whether IRFI 042, a new analogue of vitamin E, may block lipid peroxidation in myocardial cells and in turn protect against monensin toxicity. Monensin toxicity was induced by repeated daily administration of the ionophore antibiotic (150 mg/kg/day for 7 days). Sham animals received by oral gavages only a saline solution and were used as controls. All animals were randomized to receive concomitantly by oral gavages IRFI 042 (20 mg/kg) or its vehicle. The experiment lasted 8 days. Survival rate, heart lipid peroxidation, studied by means of thiobarbituric acid-reactive substances (TBARs) levels, cardiac expression of endothelial nitric oxide (e-NOS) and histological analysis of the heart were performed. Monensin administration caused a decrease in survival rate. Mortality appeared following the second monensin injection and at day 7 caused a survival rate of 20%. Thereafter, no further mortality was observed. IRFI 042 administration improved survival rate. Injection of the ionophore antibiotic resulted in a marked cardiac lipid peroxidation and in a significant reduction in cardiac e-NOS message and protein expression. IRFI 042 decreased heart TBARs levels (Monensin + vehicle = 6.5 +/- 0.8 nmol/mg; Monensin + IRFI 042 = 3.2 +/- 1.1 nmol/mg; P < 0.001) and increased e-NOS message and protein expression. Histological analysis showed that IRFI 042 improved myocardial cells damage and enhanced the depressed e-NOS expression in chick heart samples following monensin administration. Our data suggest that IRFI 042 is a promising drug to reduce monensin cardio-toxicity in chicks.

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NG108-15 cells extend "rapid-onset" neurites vigorously within the first hour after plating in minimal serum-free medium on Petri dishes coated with polylysine and laminin (1 ng/mm2). We recently reported that the initial rates of neurite formation and cell translocation are further accelerated in this system when non-specific substratum attachment sites are partially blocked by polyglutamate, bovine serum albumin, or polyethylene glycol polymers [Smalheiser, N. R. (1991): Dev. Brain Res. 62:81-89]. When cells were plated in the presence of the monovalent cation ionophore monensin (1-5 microM) or hypertonic sucrose (50-100 mM), the initial rate of outgrowth on laminin/polylysine-treated Petri dishes was not affected, yet the acceleration produced by polyglutamate was strongly inhibited. These data indicate that monensin-sensitive intracellular events can regulate neurite extension on laminin indirectly, through modulating the effects exerted on cells by nonspecific substratum sites. Although the critical events affected by monensin remain to be identified, movements of laminin receptors (their clustering, internalization, and recycling) are likely targets for further study.

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Glibenclamide, a second generation sulfonylurea, is an oral hypoglycemic drug. It seems to act mainly on the ATP-driven K(+)- channels of the beta-cells of pancreas determining insulin secretion. Because monensin, a Na+/H+ antiport, is able when administered to rats in vivo to inhibit insulin secretion, the action of glibenclamide is studied on glycemia and insulinemia to verify if it can antagonize the action of monensin. The results show that glibenclamide is able to partly reverse ionophore induced hyperglycemia and the inhibition of insulin secretion. These results might be interpreted as if glibenclamide only reverses the ATP-driven K(+)- channel dependent insulin secretion. Moreover the antagonist action of glibenclamide is slightly delayed when both drugs are administered together. The role of Na+/H+ antiport in basal insulin secretion is discussed.

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The immortalized septal cell line, SN56 B5 G4, generated by the fusion of mouse septal area cells and neuroblastoma cells, was used to determine if nimodipine, an antagonist of voltage sensitive calcium 'L' channels, might act in a neuroprotective fashion when intracellular calcium levels were raised by incubation in ouabain and monensin. Fluorescent indicator dyes and the automated spectrofluorometer, the CytoFluor 2300, were used to analyze specific cellular targets and functions affected by ouabain and monensin and possible protection by prior incubation with nimodipine. Ouabain and monensin were used together to create a time- and dose-dependent toxic episode. Increases in the emission intensity of Fluo3-AM demonstrated that the concentration of intracellular calcium was monotonically increased by increasing levels of ouabain-monensin. The calcein-AM fluorescent probe indicated that there were no changes in plasma membrane permeability during the toxic episode. Lysosomal integrity decreased as indicated by decreases in neutral red retention. The concentration of free radicals increased as shown by the increase in emission intensity of 2',7'-dichlorfluorescein. Nimodipine pretreatment of the cells incubated with ouabain and monensin resulted in apparent protection of lysosomes and a reduction in the level of free radicals. While nimodipine, by itself, produced a small decrease in intracellular calcium, it actually augmented the ouabain-monensin induced increase in intracellular calcium. The data suggest that in immortalized septal cells, (a) nimodipine offers protection to certain of the responses induced by ouabain-monensin, (b) the protection offered by nimodipine may be independent of antagonism of voltage sensitive calcium channels, and (c) that the protective changes can occur at the same time that intracellular calcium is increasing. These latter observations question the hypothesis that the protection against cell death and dysfunction offered by nimodipine is due solely to maintaining calcium homeostasis.

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Vacuole formation around the Golgi and immunotoxin enhancement induced by low doses of the ionophore monensin were inhibited by 50% human plasma (final concentration), whereas the lysosomal pH increase remained unaffected. Immunotoxin enhancement by the Ca2+ antagonist perhexiline was also inhibited by plasma. The inhibiting factor was present in different species and highly concentration-dependent. After purification on DEAE- and CM-Sepharose it showed a heterogeneous distribution between 45 and 50 kDa, in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, an extreme isoelectric point near 3.5, and binding to wheat germ agglutinin-Sepharose. Maximum inhibition was found in the lower molecular mass fraction of 45 kDa. The 50-kDa fraction, although showing immunological identity reactions, remained almost inactive. The simultaneous inhibition of morphological alterations and the enhancement of immunotoxin activity by the highly enriched protein provides a first direct link between both events. Apart from a role of this serum glycoprotein on in vivo inhibition of immunotoxin enhancement, its ability to maintain normal intracellular trafficking in the presence of blocking agents, such as monensin and perhexiline, suggests a more fundamental role in the regulation of these mechanisms.

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Ninety-six commercial broiler chicks housed in battery brooders were exposed to experimental diets varying in monensin (50, 250 mg/kg) and sodium selenite (0, 10 mg/kg) levels from their 10th to 25th day of age. Feed and water were supplied ad libitum. There were 4 replications of each experimental treatment, each with 6 birds/replication. The data on bird weights showed a significant treatment effect for monensin, sodium selenite, and an interaction between the 2. High levels of monensin and sodium selenite decreased weight, the combination exacerbating this response. The residue data showed that chicks accumulated significantly higher concentrations of selenium in their tissues when on diets high in sodium selenite. Chicks also accumulated significantly higher concentrations of monensin in their tissues when on diets high in monensin. An interactive effect was observed in terms of the selenium residue data, high levels of dietary monensin decreased the selenium residue concentration in the liver, kidney and cardiac muscle tissues when on high sodium selenite diets. No interactive effect was observed in terms of the monensin residue data. Pathological lesions, which were expected but not observed, may also indicate an interaction between these compounds.

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