Effects of the calcium channel blocker verapamil and sulphydryl reducing agent dithiothreitol on atractyloside toxicity in precision-cut rat renal cortical and liver slices.

The effects of dithiothreitol (DTT), a sulfhydryl-containing agent and verapamil (VRP), a calcium channel blocker as possible cytoprotectants against the atractyloside-induced toxicity were characterized in rat kidney and liver slices in vitro using multiple markers of toxicity. Precision-cut slices (200 microM thick) were either incubated with atractyloside (2 mM) or initially preincubated with either DTT (5 mM) or VRP (100 microM) for 30 min followed by exposure to atractyloside (2 mM) for 3 h at 37 degrees C on a rocker platform rotated at approximately 3 rpm. All of the toxicity parameters were sensitive to exposure to atractyloside, but treatment with DTT or VRP alone did not provide any indication of damage to the tissues. Preincubation of slices containing either DTT or VRP for 30 min provided total protection against atractyloside-induced increase in LDH leakage in both kidney and liver slices. Increased induction of lipid peroxidation by atractyloside in liver slices was completely abolished by DTT and VRP. Both DTT and VRP provided partial protection against atractyloside-induced inhibition of gluconeogenesis in both kidney and liver slices. Atractyloside-induced ATP depletion in both kidney and liver slices was partially abolished by VRP but not DTT. The significant depletion of GSH in the kidney slices by atractyloside was completely reversed by DTT only, while VRP alone reversed the same process in liver slices. Decreased MTT reductive capacity and significant increase in ALT leakage caused by atractyloside in liver slices was partially reversed. Complete protection was achieved with both DTT and VRP against atractyloside-induced inhibition of PAH uptake in kidney slices. These findings suggest that both DTT and VRP exert cytoprotective effects in atractyloside-induced biochemical perturbation, effects that differ in liver and kidney. The effect of these agents on atractyloside has provided us with a further understanding of the molecular mechanism of its action.

Adenine nucleotide and calpain inhibitor I protect against atractyloside-induced toxicity in rat renal cortical slices in vitro.

Atractyloside is a compound with a documented nephrotoxicity. It induces renal tubular necrosis at high doses and apoptosis at lower doses. This study investigates the potential protective effect of some chemical agents against atractyloside-induced nephrotoxicity in vitro using the precision-cut rat renal cortical slices obtained from kidneys of Wistar rats. For co-incubation experiments, slices were incubated for 3 h at 37 degrees C on a rocker platform with various chemical agents: ADP (5 mM), calpain inhibitor I (CPI, 1 mM), stevioside (STV, 2.5 mM) or probenecid (PRB, 2.5 mM) in the presence or absence of atractyloside (2 mM). For pre-incubation experiments, slices were incubated with the same chemical agents for 1 h before exposure to atractyloside. The nephrotoxic effects of atractyloside (2 mM) alone were manifested in several ways: by a marked increase in lactate dehydrogenase (LDH) and alkaline phosphatase (ALP) leakage, significant inhibition of p-aminohippurate (PAH) accumulation, marked depletion of intracellular ATP and reduced glutathione (GSH), and a significant reduction in pyruvate-stimulated gluconeogenesis. Co-incubation of slices with ADP or CPI and atractyloside completely blocked atractyloside-induced increase in LDH leakage, but not ALP leakage. Atractyloside-induced depletion of ATP and reduced gluconeogenesis was prevented by co-incubation with ADP or CPI. Furthermore, co-incubation of slices with STV and atractyloside, but not PRB, completely abolished atractyloside-induced depletion of ATP and decreased gluconeogenesis in the slices. Pre-incubation of slices with either ADP or CPI protected against atractyloside-induced increase in LDH leakage, reduced ATP and decreased gluconeogenesis. PAH uptake in the slices was inhibited by atractyloside and PRB in a time-dependent manner. While ADP and CPI were found to exert complete protection against atractyloside-induced toxicity irrespective of treatment schedule, STV is effective only under certain conditions, and PRB offer no protection at all. The results of this study demonstrate the usefulness of renal cortical slices as toxicology tool for evaluating and screening compounds for their potential protective effects, and are supportive of a role of adeninine nucleotide (ADP) and protease inhibitor (CPI) in protecting against atractyloside-induced cell injury.

Cadmium-induced changes in avian renal morphology.

The effects of i.m. administered cadmium on growth rate and nephromorphology were studied in young pullets. The growth rate of pullets treated with 0.6 mg Cd2+/kg at 48-h intervals was severely retarded, reaching only 50% of normal growth by 21 days. Such a decrease in growth rate was prevented when cadmium was given with either ferric or magnesium EDTA chelate. Electron micrographs of kidney tissue from cadmium intoxicated birds revealed massive intracellular disorganisation of proximal tubular cells, showing increased vacuolation and dilated endoplasmic reticulum. Mitochondria were few and swollen with reduced cristae. Some disorganisation was noted in the group treated with MgEDTA in conjunction with cadmium, with normal morphology observed in the group treated with FeEDTA plus cadmium. In general, glomerular morphology of intoxicated pullets appeared normal, except that a 25% increase in thickness of the glomerular basement membrane was evident. No such membrane thickening was observed in any of the chelate treated groups. These findings indicate that both chelates can provide certain levels of protection, in terms of growth rate and morphology, from cadmium intoxication. The possible mechanisms by which chelates offer protection have been discussed, but many questions remain unanswered.

The survival and implantation of mouse blastocysts at varying degrees of reduced atmospheric pressure.

Pregnant mice were exposed to reduced atmospheric pressures ranging from 630 to 390 mm Hg during the pre-implantation and implantation periods and the numbers of embryos surviving 85 hours post coitum compared with those in litter-mate controls. Even at a pressure of 630 mm Hg (= 1,550 mm Hg) there was a significant fall in numbers of normal blastocysts and rise in abnormal forms before implantation, and implantation sites were reduced in number. The numbers of abnormal forms increased and implantation sites decreased at lower pressures, suggesting strongly that the hypoxia of reduce atmospheric pressure was responsible for the abnormalities observed. The pre-implantation period appears to be one during which the fertilised ovum is at particular risk, both of hypoxic damage and of failure to implant. Implantation may afford a degree of protection against hypoxia.