SkQThy, a novel and promising mitochondria-targeted antioxidant.

Since thymoquinone (2-isopropyl-5-methylbenzoquinone) isolation from Nigella sativa in 1963, various studies have reported on its diverse pharmacological properties. However, despite its versatile healing abilities, clinical trials involving the use of thymoquinone have not been initiated due to its poor bioavailability. Many attempts have been made to improve the therapeutic efficacy of thymoquinone by synthesizing analogs, as well as by developing nanotechnology-based delivery systems. We hypothesized that some of the issues with thymoquinone delivery and bioavailability could be resolved by targeted delivery to mitochondria of thymoquinone derivatives conjugated to the penetrating lipophilic cationic triphenylphosphonium fragment. As mitochondria are the major site of reactive oxygen species generation in the cell, such a membranotropic thymoquinone derivative can act as an efficient antioxidant or prooxidant depending on the concentration used. Based on these theoretical considerations, a novel mitochondria-targeted compound, SkQThy, was synthesized and its effects on rat liver mitochondria and yeast cells were examined. SkQThy was found to exhibit pronounced antioxidant activity in mammalian mitochondria and yeast cells, decreasing hydrogen peroxide production in mitochondria, as well as preventing prooxidant-induced oxidative stress and mitochondrial fragmentation in yeast cells and increasing cell viability. Moreover, SkQThy proved itself to be the most efficient mitochondria-targeted antioxidant within the SkQs family, showing good therapeutic potential.

New Data on Effects of SkQ1 and SkQT1 on Rat Liver Mitochondria and Yeast Cells.

Mitochondria are involved in many processes in eukaryotic cells. They play a central role in energy conservation and participate in cell metabolism and signaling pathways. Mitochondria are the main source of reactive oxygen species, excessive generation of which provokes numerous pathologies and cell death. One of the most promising approaches to the attenuation of oxidative stress in mitochondria is the use of targeted (i.e., transported exclusively into mitochondria) lipophilic cationic antioxidants. These compounds offer advantages over conventional water-soluble antioxidants because they induce the so-called "mild uncoupling" and can prevent collapse of the membrane potential in low, nontoxic concentrations. A novel mitochondria-targeted antioxidant, SkQT1, was synthesized and tested within the framework of the research project guided by V. P. Skulachev. The results of these experiments were initially reported in 2013; however, one publication was not able to accommodate all the data on the SkQT1 interactions with isolated mitochondria and cells. Here, we examined comparative effects of SkQT1 and SkQ1 on rat liver mitochondria (with broader spectrum of energy parameters being studied) and yeast cells. SkQT1 was found to be less effective uncoupler, depolarizing agent, inhibitor of respiration and ATP synthesis, and "opener" of a nonspecific pore compared to SkQ1. At the same time SkQ1 exhibited higher antioxidant activity. Both SkQT1 and SkQ1 prevented oxidative stress and mitochondria fragmentation in yeast cells exposed to t-butyl hydroperoxide and promoted cell survival, with SkQT1 being more efficient than SkQ1. Together with the results presented in 2013, our data suggest that SkQT1 is the most promising mitochondria-targeted antioxidant that can be used for preventing various pathologies associated with the oxidative stress in mitochondria.

More about Interactions of Rhodamine 19 Butyl Ester with Rat Liver Mitochondria.

Oxidative stress is one of the major factors underlying mitochondrial dysfunctions. One of the most promising approaches for alleviating or preventing oxidative stress is the use of cationic uncouplers that accumulate in mitochondria in accordance to the level of the membrane potential, producing "mild" uncoupling. Based on this theoretical background, cationic rhodamine 19 butyl ester (C4R1) was synthesized and tested within the framework of the research project guided by V. P. Skulachev. The results of these tests were presented (Khailova et al. (2014) Biochim. Biophys. Acta, 1837, 1739-1747), but one publication could not accommodate all data on interactions of C4R1 with isolated mitochondria. In addition to previously presented data, we found that the effect of C4R1 on the rate of oxygen uptake is subject to temporal variations, which probably reflects variable rates of C4R1 entry into the mitochondria. Consequently, transient stimulation of respiration can be followed by inhibition. C4R1 was found not to shunt electron flow from complex I of the respiratory chain; it largely acted as an inhibitor of complex I in the respiratory chain and showed antioxidant activity. C4R1 taken at low, non-uncoupling concentrations enhanced the uncoupling activity of fatty acids (e.g. palmitate). Relatively low C4R1 concentrations stimulated opening of a nonspecific Ca2+/Pi-dependent pore. ATP synthesis and hydrolysis were substantially inhibited by C4R1 at low concentrations that had no appreciable effects on respiration in states 4 and 3 and only slightly decreased the membrane potential. Besides, conditions were revealed allowing correct evaluation of the membrane potential generated at the inner mitochondrial membrane with safranin O upon oxidation of both succinate and NAD-dependent substrates in the presence of C4R1.

Mechanisms of sensing and adaptive responses to low oxygen conditions in mammals and yeasts.

Oxygen is required for effective production of ATP and plays a key role in the maintenance of life for all organisms, excepting strict anaerobes. The ability of aerobic organisms to sense and respond to changes in oxygen level is a basic requirement for their survival. Eukaryotes have developed adaptive mechanisms to sense and respond to decreased oxygen concentrations (hypoxia) through adjustment of oxygen homeostasis by upregulating hypoxic and downregulating aerobic nuclear genes. This review summarizes recent data on mechanisms of cells sensing and responding to changes in oxygen availability in mammals and in yeasts. In the first part of the review, prominence is given to functional regulation and stabilization of hypoxia-inducible factors (HIFs), HIF-mediated regulation of electron transport flux and repression of lipogenesis, as well as to hypoxia-induced mitochondrial permeability transition (pore) opening, cell death, and autophagy. In the second part of the review emphasis is placed on oxygen sensing in nonpathogenic yeasts by heme, unsaturated fatty acids, and sterols, as well as on responses to hypoxia in fungal pathogens.

Alternative oxidase: distribution, induction, properties, structure, regulation, and functions.

The respiratory chain in the majority of organisms with aerobic type metabolism features the concomitant existence of the phosphorylating cytochrome pathway and the cyanide- and antimycin A-insensitive oxidative route comprising a so-called alternative oxidase (AOX) as a terminal oxidase. In this review, the history of AOX discovery is described. Considerable evidence is presented that AOX occurs widely in organisms at various levels of organization and is not confined to the plant kingdom. This enzyme has not been found only in Archaea, mammals, some yeasts and protists. Bioinformatics research revealed the sequences characteristic of AOX in representatives of various taxonomic groups. Based on multiple alignments of these sequences, a phylogenetic tree was constructed to infer their possible evolution. The ways of AOX activation, as well as regulatory interactions between AOX and the main respiratory chain are described. Data are summarized concerning the properties of AOX and the AOX-encoding genes whose expression is either constitutive or induced by various factors. Information is presented on the structure of AOX, its active center, and the ubiquinone-binding site. The principal functions of AOX are analyzed, including the cases of cell survival, optimization of respiratory metabolism, protection against excess of reactive oxygen species, and adaptation to variable nutrition sources and to biotic and abiotic stress factors. It is emphasized that different AOX functions complement each other in many instances and are not mutually exclusive. Examples are given to demonstrate that AOX is an important tool to overcome the adverse aftereffects of restricted activity of the main respiratory chain in cells and whole animals. This is the first comprehensive review on alternative oxidases of various organisms ranging from yeasts and protists to vascular plants.

[Molecular characteristics of transporters of C4-dicarboxylates and mechanism of translocation].

Transport of C4-dicarboxylate (C4-DCB) plays an important role in cell metabolism. In particular, they are intermediates of the citrate cycle. Transport of succinate across the mitochondrial membrane provides correlation between metabolism in peroxysomes and in mitochondrial. Transport of C4-DCB across all kinds of energy-transforming membranes of animal, plant, fungal, and bacterial cells is known. The review summarizes molecular characteristics of the C4-DCB transporters. Of particular interest are primary structures for carries with the known kinetic mechanism and kinetic transport parameters. For each studied group of organisms, the number of transmembrane segments in the carried molecule or the character of specificity do not correlate with a certain transport mechanism--antiport, symport with proton or symport with cation. The review describes perspective methodical approaches allowing association of peculiarities of structure with transport mechanism for individual transporters, obtaining of functional hybrid transporters--"protein chimeras", scanning of transporter transmembrane segments with the help of "cystein mutagenesis", study of transporter kinetic parameters with point mutations for essential amino acids, probing of the transporter active center with the help of alkyl and acyl substrate derivatives used to obtain the "lipophilic profile" of the channel of the C4-DCB transporter. It is recommended to use these approaches to one transporter with small sizes and large substrate specificity.

Topography of the active site of the Saccharomyces cerevisiae plasmalemmal dicarboxylate transporter studied using lipophilic derivatives of its substrates.

2-Alkylmalonates and O-acyl-L-malates have been found to competitively inhibit the dicarboxylate transporter of Saccharomyces cerevisiae cells, and the substrate derivatives chosen did not penetrate across the plasmalemma under the experiment conditions. Probing of the active site of this transporter has revealed a large lipophilic area stretching between the 0.72 to 2.5 nm from the substrate-binding site. Itaconate inhibited the transport fivefold more effectively than L-malate. This suggests the existence of a hydrophobic region immediately near the dicarboxylate-binding site (to 0.72 nm). The yeast plasmalemmal transporter was different from the rat liver mitochondrial dicarboxylate transporter. An area with variable lipophilicity adjoining the substrate-binding site has been revealed in the latter by a similar method. This area is mainly hydrophobic at distances up to 1.76 nm from the binding site and is separated by a hydrophilic region from 0.38 to 0.88 nm. Fumarate but not maleate competitively inhibited succinate transport into the S. cerevisiae cells. It is suggested that the plasmalemmal transporter binds the substrate in the trans-conformation. The prospects of the proposed approach for scanning lipophilic profiles of channels of different transporters are discussed.

Properties of yeast Saccharomyces cerevisiae plasma membrane dicarboxylate transporter.

Transport of succinate into Saccharomyces cerevisiae cells was determined using the endogenous coupled mitochondrial succinate oxidase system. The dependence of succinate oxidation rate on the substrate concentration was a curve with saturation. At neutral pH the K(m) value of the mitochondrial "succinate oxidase" was fivefold less than that of the cellular "succinate oxidase". O-Palmitoyl-L-malate, not penetrating across the plasma membrane, completely inhibited cell respiration in the presence of succinate but not glucose or pyruvate. The linear inhibition in Dixon plots indicates that the rate of succinate oxidation is limited by its transport across the plasmalemma. O-Palmitoyl-L-malate and L-malate were competitive inhibitors (the K(i) values were 6.6 +/- 1.3 microM and 17.5 +/- 1.1 mM, respectively). The rate of succinate transport was also competitively inhibited by the malonate derivative 2-undecyl malonate (K(i) = 7.8 +/- 1.2 microM) but not phosphate. Succinate transport across the plasma membrane of S. cerevisiae is not coupled with proton transport, but sodium ions are necessary. The plasma membrane of S. cerevisiae is established to have a carrier catalyzing the transport of dicarboxylates (succinate and possibly L-malate and malonate).

Study of active site topography of rat liver mitochondrial dicarboxylate transporter using lipophilic substrate derivatives.

Earlier it has been demonstrated that the active site (substrate-binding site + active site channel) of rat liver mitochondrial dicarboxylate transporter is characterized by rather complex topography. Probing the active site with 2-monoalkylmalonates revealed the existence of internal and external lipophilic areas separated by a polar region. A two substrate-binding site model of the transporter has been supposed. The correctness of this model has been evaluated by probing the active site with O-acyl-L-malates differing from 2-monoalkylmalonates by 0.23 nm longer distance from the anion groups to the aliphatic chain. Changes in the polar group of the probe did not prevent its binding and showed the same variable lipophilicity pattern for the transporter channel. Probing with alpha,omega-alkylene dimalonates did not reveal the second substrate-binding site at the active site. The substrate-binding site did not show any differences in affinity to O-acyl-derivatives of L-malate and D-malate, except L-malate binds more effectively than D-malate. This suggests involvement of the L-malate hydroxyl group in substrate binding and stereospecific behavior of the transporter substrate-binding site. A modified one substrate-binding site model of the dicarboxylate transporter is discussed.

Specific features of changes in levels of endogenous respiration substrates in Saccharomyces cerevisiae cells at low temperature.

The rate of endogenous respiration of Saccharomyces cerevisiae cells incubated at 0 degrees C under aerobic conditions in the absence of exogenous substrates decreased exponentially with a half-period of about 5 h when measured at 30 degrees C. This was associated with an indirectly shown decrease in the level of oxaloacetate in the mitochondria in situ. The initial concentration of oxaloacetate significantly decreased the activity of succinate dehydrogenase. The rate of cell respiration in the presence of acetate and other exogenous substrates producing acetyl-CoA in mitochondria also decreased, whereas the respiration rate on succinate increased. These changes were accompanied by an at least threefold increase in the L-malate concentration in the cells within 24 h. It is suggested that the increase in the L-malate level in the cells and the concurrent decrease in the oxaloacetate level in the mitochondria should be associated with a deceleration at 0 degrees C of the transport of endogenous respiration substrates from the cytosol into the mitochondria. This deceleration is likely to be caused by a high Arrhenius activation energy specific for transporters. The physiological significance of L-malate in regulation of the S. cerevisiae cell respiration is discussed.

[Isolation of cell membranes from Saccharomyces cerevisiae for evaluation of the protein composition]. / Poluchenie kletochnykh obolochek Saccharomyces cerevisiae s tsel'iu opredeleniia ikh belkovogo sostava.

We describe a simple method for the isolation of membrane fractions from Saccharomyces cerevisiae yeasts, containing the complex of plasma membranes and cell walls. The method is based on cell disruption on an INBI flow disintegrator. This device spares subcellular structures, which simplifies the isolation of cell membranes. The membrane fraction obtained by this method was suitable for studies of protein composition of these structures by means of two-dimensional electrophoresis.

[Comparative study of some parameters of energy metabolism in two strains of Saccharomyces cerevisiae]. / Sravnitel'noe izuchenie nekotorykh parametrov énergeticheskogo obmena dvukh shtammov Saccharomyces cerevisiae.

A comparative study of energy metabolism in two strains Saccharomyces cerevisiae (the initial strain N 73 and laser-irradiated mutant strain Y-503) was performed. In all growth phases, the rates of oxygen consumption by cells of Y-503 were higher than in the initial strain. The maximum (threefold) increase in the rate of oxygen consumption was observed in the linear phase. The effects of respiratory chain inhibitors rotenone, antimycin A, and cyanide on cellular and mitochondrial respiration were identical. There are two sites of energy coupling in the respiratory chain of mitochondria in S. cerevisiae N 73 and Y-503, and electron flow mainly is mainly mediated by cytochrome oxidase. The data suggest that a higher respiratory activity of S. cerevisiae Y-503 cells in comparison with N 73 is associated with greater amounts of mitochondria and total surface area of coupling mitochondrial membranes, which appears to be a factor contributing to a high physiological and biochemical activity of this strain.

[Morphological and biochemical characteristics of new isolates Saccharomyces cerevisiae U-503]. / Morfologicheskie i biokhimicheskie svoistva novogo shtamma Saccharo myces cerevisiae Y-503.

Compared with S. cerevisiae N73, its laser irradiation-induced mutant S. cerevisiae U-503 exhibited a significantly higher respiration rate. Electron microscopic changes consistent with this finding were found in the mitochondrial system of mutant cells. The mutant strain retained its physiological and biochemical properties over a nine-year storage period.

[Quantitative determination of total mitochondrial protein with Coomassie]. / Kolichestvennoe opredelenie obshchego belka mitokhondrii s kumassi.

The mechanism of Coomassie interaction with proteins was being studied. Under certain conditions the range of detectible polypeptides can be wider. For protein analysis in mitochondria we have suggested a new component ratio for the Bradford reagent. A correction for mitochondrial protein was determined, which should be made on using bovine serum albumin as a standard.