The Fusarium mycotoxins enniatins and beauvericin cause mitochondrial dysfunction by affecting the mitochondrial volume regulation, oxidative phosphorylation and ion homeostasis.

The mechanisms of cell toxicity of mycotoxins of the enniatin family produced by Fusarium sp. enniatin B, a mixture of enniatin homologues (3% A, 20% A(1), 19% B, 54% B1) and beauvericin, were investigated. In isolated rat liver mitochondria, exposure to submicromolar concentrations of the enniatin mycotoxins depleted the mitochondrial transmembrane potential, uncoupled oxidative phosphorylation, induced mitochondrial swelling and decreased calcium retention capacity of the mitochondria. The mitochondrial effects were strongly connected with the potassium (K(+)) ionophoric activity of the enniatins. The observed enniatins induced K(+) uptake by mitochondria. This shows that the enniatins acted as ionophores highly selective for potassium ions. The effects were observed in potassium containing media whereas less or no effect remained to be observed when K(+) was partially or totally replaced by isomolar concentrations of Na(+). The rank order of enniatin induced mitochondrial impairment was beauvericin>enniatin mixture>enniatin B. Exposure to the enniatins depleted the mitochondrial membrane potential also in intact human neural (Paju), murine insulinoma (Min-6) cells as well as boar spermatozoa. Exposure to enniatin B in media with physiological (4mM) or low (<1mM) but not in high (60mM) external concentration of K(+) induced hyperpolarization of the spermatozoal plasma membrane indicating enniatin that catalysed efflux of the cytosolic K(+) ions. These results indicate that the cellular toxicity targets of the enniatin mycotoxins are the mitochondrion and the homeostasis of potassium ions.

Diversity of neurodegenerative processes in the model of brain cortex tissue ischemia.

Stroke is known to induce massive cell death in the ischemic brain. Either necrotic or apoptotic types of cell death program were observed in neurons in zone of ischemia. We suggest that spatial heterogeneity of glucose and oxygen distribution plays a crucial role in this phenomenon. In order to elucidate the role of glucose and oxygen in ischemic neurons choice of cell death pathway, conditions corresponding to different areas of insult were reproduced in vitro in the model of surviving brain cortex tissue slices. Three zones were modeled in vitro by varying glucose and oxygen concentration in surviving slices incubation media. Modeled ischemic area I (MIA I) was corresponded to the center of suggested ischemic zone where the levels of glucose and oxygen were considered to be extremely low. MIA II was assigned as intermediate area where oxygen concentration was still very low but glucose was present (this area was also divided into two sub-areas MIA IIa and MIA IIb with physiologically low (5mM) and normal (10mM) level of glucose respectively). MIA III was considered as a periphery area where glucose concentration was close to physiological level and high level of ROS production had been induced by reoxygenation after anoxia. Analysis of molecular mechanisms of cell death in MIA I, IIa, IIb and III was carried out. Cell death in MIA I was found to proceed by necrotic manner. Apoptosis characterized by cyt c release, caspase 3 activation and internucleosomal DNA fragmentation was observed in MIA III. Cell death in MIA II was accompanied by several (not all) hallmarks of apoptosis. Mechanisms of cell death in MIA IIa and MIA IIb were found to be different. Internucleosomal DNA fragmentation in MIA IIa but not in MIA IIb was sensitive to glycine (5mM), inhibitor of NMDA receptor MK-801 (10microM) and PTP inhibitor cyclosporine A (10microM). Activation of caspase 3 was detected in MIA IIb but not in MIA IIa. However cytochrome c release was observed neither in MIA IIa nor in MIA IIb. In MIAs II-III apoptosis was accompanied by uncoupling of oxidative phosphorylation, which was induced by rise of intracellular Ca(2+) and intensive ROS production. Results obtained in present study allow us to propose existence of at least four molecular pathways of cell death development in brain ischemic zone. The choice of cell death pathway is determined by oxygen and glucose concentration in the particular area of the ischemic zone.

Bafilomycin A1 is a potassium ionophore that impairs mitochondrial functions.

Novel activities of bafilomycin A1, a macrolide antibiotic known as an inhibitor of V-ATPases, were discovered. Bafilomycin A1 induced uptake of potassium ions by energized mitochondria and caused mitochondrial swelling, loss of membrane potential, uncoupling of oxidative phosphorylation, inhibition of the maximal respiration rates, and induced pyridine nucleotide oxidation. The mitochondrial effects provoked by nanomolar concentrations of bafilomycin A1 were connected to its activity as a potent, K(+)-specific ionophore. The K(+) ionophoric activity of bafilomycin A1 was observed also in black lipid membranes, indicating that it was an inherent property of the bafilomycin A1 molecule. It was found that bafilomycin A1 is a K(+) carrier but not a channel former. Bafilomycin A1 is the first and currently unique macrolide antibiotic with K(+) ionophoric properties. The novel properties of bafilomycin A1 may explain some of the biological effects of this plecomacrolide antibiotic, independent of V-ATPase inhibition.

The higher toxicity of cereulide relative to valinomycin is due to its higher affinity for potassium at physiological plasma concentration.

Valinomycin and cereulide are bacterial toxins with closely similar chemical structure and properties but different toxic effects. Emetic poisoning is induced by cereulide but not by valinomycin. Both are specific potassium ionophores. Such compounds may affect mitochondrial functions. Both compounds cause a potassium-dependent drop in the transmembrane inner membrane potential due to the uptake of K+ as positively charged ionophore complex. Valinomycin is more potent than cereulide at high [K+] (>80 mM), whereas cereulide in contrast to valinomycin is active already at <1 mM. With cereulide, there is a substantial lag, while valinomycin acts without lag. Both ionophores induce mitochondrial swelling in the presence of K+, in the case of cereulide with a lag. These toxins strongly inhibited respiration at the level of complex IV when used at higher concentrations than that used for detection of ionophoretic transport of K+. At high [KCl] (120 mM), valinomycin was more potent than cereulide both as ionophore and inhibitor, but at low [KCl] (2.5 mM), cereulide was much more potent. Thus, valinomycin needed 20-30 mM KCl for substantial effects, cereulide only 1-3 mM K+, which is close to its level in blood serum. This explains the higher toxicity of cereulide at low concentrations with the positively charged potassium complex being accumulated in the cell by transport through the plasma membrane driven by the membrane potential. Furthermore, with similar concentrations, the final concentration of cereulide in the cells may become higher than that of valinomycin.