N. I. Fedotcheva

Effect of phenolic acids of microbial origin on production of reactive oxygen species in mitochondria and neutrophils

BackgroundSeveral low-molecular-weight phenolic acids are present in the blood of septic patients at high levels. The microbial origin of the most of phenolic acids in the human body was shown previously, but pathophysiological role of the phenolic acids is not clear. Sepsis is associated with the excessive production of reactive oxygen species (ROS) in both the circulation and the affected organs. In this work the influence of phenolic acids on ROS production in mitochondria and neutrophils was investigated.MethodsROS production in mitochondria and neutrophils was determined by MCLA- and luminol-dependent chemiluminescence. The rate of oxygen consumption by mitochondria was determined polarographically. The difference of electric potentials on the inner mitochondrial membrane was registered using a TPP+-selective electrode. The formation of phenolic metabolites in monocultures by the members of the main groups of the anaerobic human microflora and aerobic pathogenic bacteria was investigated by the method of gas chromatography–mass spectrometry.ResultsAll phenolic acids had impact on mitochondria and neutrophils, the main producers of ROS in tissues and circulation. Phenolic acids (benzoic and cinnamic acids) producing the pro-oxidant effect on mitochondria inhibited ROS formation in neutrophils. Their effect on mitochondria was abolished by dithiothreitol (DTT). Phenyllactate and p-hydroxyphenyllactate decreased ROS production in both mitochondria and neutrophils. Bifidobacteria and lactobacilli produced in vitro considerable amounts of phenyllactic and p-hydroxyphenyllactic acids, Clostridia s. produced great quantities of phenylpropionic and p-hydroxyphenylpropionic acids, p-hydroxyphenylacetic acid was produced by Pseudomonas aeruginosa and Acinetobacter baumanii; and benzoic acid, by Serratia marcescens.ConclusionsThe most potent activators of ROS production in mitochondria are phenolic acids whose effect is mediated via the interaction with thiol groups. Among these are benzoic and cinnamic acids. Some phenolic acids, in particular phenyllactate and p-hydroxyphenyllactate, which decrease ROS production in mitochondria and neutrophils, can play a role of natural antioxidants. The results indicate that low-molecular weight phenolic acids of microbial origin participate in the regulation of the ROS production in both the circulation and tissues, thereby affecting the level of oxidative stress in sepsis.

Toxic effects of microbial phenolic acids on the functions of mitochondria

Low-molecular-weight phenolic acids (PhAs) phenylacetate, phenyllactate, phenylpropionate, p-hydroxyphenyllactate, and p-hydroxyphenylacetate are essentially the products of the degradation of aromatic amino acids and polyphenols by the intestinal microflora. In sepsis, the concentrations of some of these acids in the blood increase tens of times. Assuming that these compounds can cause the mitochondrial dysfunction in sepsis, we examined their effects on respiration, the induction of pore opening, and the production of reactive oxygen species (ROS) in mitochondria. It was found that phenylpropionate and phenylacetate produce a more toxic effect on mitochondria than the other phenolic acids. At concentrations 0.01-0.1 mM they decreased the rate of oxidation of NAD-dependent substrates and activated the Ca2+- and menadione-induced opening of the cyclosporin A-sensitive pore and the production of ROS. The disturbances caused by these PhAs are similar to those observed in mitochondria in sepsis, and hence the rise in their level may be one of the causes of mitochondrial dysfunctions. Phenyllactate, p-hydroxyphenyllactate, and p-hydroxyphenylacetate inhibited the production of ROS and pore opening, acting as antioxidants. Thus, the ability of PhAs to affect the mitochondrial functions, as well as an increase in their concentrations in sepsis (the total concentration of these PhAs in the blood is close to 0.1 mM), suggests that PhAs can be directly involved in the development of mitochondrial failure.

Burst of succinate dehydrogenase and α-ketoglutarate dehydrogenase activity in concert with the expression of genes coding for respiratory chain proteins underlies short-term beneficial physiological stress in mitochondria.

Conditions for the realization in rats of moderate physiological stress (PHS) (30-120 min) were selected, which preferentially increase adaptive restorative processes without adverse responses typical of harmful stress (HST). The succinate dehydrogenase (SDH) and α-ketoglutarate dehydrogenase (KDH) activity and the formation of reactive oxygen species (ROS) in mitochondria were measured in lymphocytes by the cytobiochemical method, which detects the regulation of mitochondria in the organism with high sensitivity. These mitochondrial markers undergo an initial 10-20-fold burst of activity followed by a decrease to a level exceeding the quiescent state 2-3-fold by 120 min of PHS. By 30-60 min, the rise in SDH activity was greater than in KDH activity, while the activity of KDH prevailed over that of SDH by 120 min. The attenuation of SDH hyperactivity during PHS occurs by a mechanism other than oxaloacetate inhibition developed under HST. The dynamics of SDH and KDH activity corresponds to the known physiological replacement of adrenergic regulation by cholinergic during PHS, which is confirmed here by mitochondrial markers because their activity reflects these two types of nerve regulation, respectively. The domination of cholinergic regulation provides the overrestoration of expenditures for activity. In essence, this phenomenon corresponds to the training of the organism. It was first revealed in mitochondria after a single short-time stress episode. The burst of ROS formation was congruous with changes in SDH and KDH activity, as well as in ucp2 and cox3 expression, while the activity of SDH was inversely dependent on the expression of the gene of its catalytic subunit in the spleen. As the SDH activity enhanced, the expression of the succinate receptor decreased with subsequent dramatic rise when the activity was becoming lower. This article is part of a Directed Issue entitled: Bioenergetic dysfunction, adaption and therapy.

Effect of progesterone and its synthetic analogues on the activity of mitochondrial permeability transition pore in isolated rat liver mitochondria

The influence of progesterone and its synthetic analogues on the induction of the Ca(2+)-dependent mitochondrial permeability transition pore (MPTP) has been studied. The novel synthetic analogue of progesterone 17a-acetoxy-3b-butanoyloxy-6-methyl-pregna-4,6-diene-20-on (buterol) was compared with progesterone and medroxyprogesterone acetate (MPA). It was found that progesterone and buterol have opposite effects on the induction of MPTP opening by calcium ions. By contrast to progesterone, which decreased the calcium ion concentration necessary for pore opening, and MPA, which also, although at a lesser extent, activated the pore induction, buterol at a concentration of 20-100 microM blocked the pore opening and increased the calcium retention capacity of mitochondria more than twofold. The action of buterol is specific to the pore since it did not affect the respiration, whereas progesterone completely inhibited NAD-dependent respiration. MPA acted similar to progesterone but less effectively. The inhibitory effect of buterol was eliminated in the presence of carboxyatractyloside, which selectively binds the thiol groups of adenylate translocase and prevents the adenine nucleotide binding. These data indicate that buterol interacts with thiol groups, which explains its inhibitory effect not only on the mitochondrial pore but also on the transport system of xenobiotics in tumor cells in which buterol reduces the multidrug resistance.

Role of mitochondrial thiols of different localization in the generation of reactive oxygen species

The role of thiols of the outer and the inner membranes of mitochondria in the regulation of generation of reactive oxygen species (ROS) has been studied. It was found that N-ethylmaleimide (NEM), which penetrates through the mitochondrial membrane and binds thiols to form thioesters, at concentrations from 20 to 250 μM activates the production of superoxide anion and hydrogen peroxide during the oxidation of the substrates of complexes I and II of the respiratory chain. 5′,5′-Dithiobis-(2-nitrobenzoate) (DTNB), which does not penetrate into mitochondria and binds thiols to form disulfides, weakly activates hydrogen peroxide production during the oxidation of NAD-dependent substrates and inhibits the ROS production upon succinate oxidation. DTNB is particularly effective in inhibiting the menadione-induced formation of ROS. The differences in the ROS formation by these reagents are explained by the fact that they influence different thiol-containing proteins and enzymes. As distinct from NEM, which inhibits complex I of the respiratory chain, DTNB has no effect on the respiratory chain of mitochondria but can bind the SH-groups of NADH-quinone oxidoreductase, which is localized in the outer mitochondrial membrane and participates in the redox cycle of menadione. It was also shown that the ability to inhibit the ADP-stimulated respiration, a feature inherent in both reagents, does not significantly contribute to ROS production.

States of succinate dehydrogenase in the organism: Dormant vs. hyperactive (pushed out of equilibrium)

Using an original cytobiochemical method to study oxidation in mitochondria, preserving their native network organization within cells in a blood smear, we have revealed a hyperactive state of succinate dehydrogenase that arises in the organism under physiological stress. This is generally consistent with the notion of non-equilibrium state of enzymes during their activity. The mechanism moderating the succinate dehydrogenase hyperactivity is based on full-fledged functioning of α-ketoglutarate dehydrogenase, sup-ported by oxidation of isocitrate.

Participation of phenolic acids of microbial origin in the dysfunction of mitochondria in sepsis

The role of low-molecular-weight phenolic acids of microbial origin in the mitochondrial dysfunction observed in sepsis has been studied. It was shown that microbial phenolic acids formed during fermentation of aromatic amino acids and polyphenols have an effect on mitochondrial functions, whose magnitude depends on the structure of a particular phenolic acid. The anaerobic metabolites cinnamic and benzoic acids and, to a lesser extent, phenylpropionic and phenylacetic acids at concentrations of 0.02–0.1 mM inhibited the NAD-dependent respiration, decreased the Ca2+-retention capacity of mitochondria, and oxidized the thiol groups. Their effects were partially abolished by menadione and dithiothreitol. Hydroxylated phenolic acids, 2,4-dihydroxybenzoic, 2,3-dihydroxyphenylpropionic, and other phenolic acids formed in aerobic metabolism of bacteria, when used at the same concentrations, did not affect these processes. During the catabolism of phenolic acids by clinically important bacteria, these compounds undergo anaerobic interconversions. The data obtained suggest that they contribute to the mitochondrial dysfunction in sepsis, and this contribution increases under hypoxic conditions.

Glutamate contributes to alcohol hepatotoxicity by enhancing oxidative stress in mitochondria

Chronic alcohol intoxication is associated with increased oxidative stress. However, the mechanisms by which ethanol triggers an increase in the production of reactive oxygen species (ROS) and the role of mitochondria in the development of oxidative stress has been insufficiently studied. The biochemical and proteomic data obtained in the present work suggest that one of the main causes of an increase in ROS generation is enhanced oxidation of glutamate in response to long-term alcohol exposure. In the course of glutamate oxidation, liver mitochondria from alcoholic rats generated more superoxide anion and H2O2 than in the presence of other substrates and more than control organelles. In mitochondria from alcoholic rats, rates of H2O2 production and NAD reduction in the presence of glutamate were almost twice higher than in the control. The proteomic study revealed a higher content of glutamate dehydrogenase in liver mitochondria of rats subjected to chronic alcohol exposure. Simultaneously, the content of mitochondrial catalase decreased compared to control. Each of these factors stimulates the production of ROS in addition to ROS generated by the respiratory chain complex I. The results are consistent with the conclusion that glutamate contributes to alcohol hepatotoxicity by enhancing oxidative stress in mitochondria.

[Redox-dependent ferric oxide nanoparticles loaded with doxorubicin and their influence on the functions of mitochondria].

The spectral, fluorescent and functional properties of ferric oxide and ferric hydroxide nanoparticles loaded with doxorubicin and stabilized with citric acid or lysine were studied in comparison with free doxorubicin. Their effect on the opening of calcium-induced mitochondrial pore and the possibility of controlled release of doxorubicin under the influence of redox stimuli were investigated. The data show that the effect of nanoparticles on mitochondria depends on the type of stabilizer. The spectral and fluorescence methods used allow us to estimate the presence or absence of free doxorubicin in solution of nanoparticles and the concentration of bound doxorubicin. It is shown that dithiothreitol and glutathione increase the amplitude of absorption and fluorescence of doxorubicin during incubation with nanoparticles. It is assumed that this effect may be associated with the reduction of oxidized iron by thiols with subsequent release of doxorubicin.

Anaerobic Microorganisms from Human Microbiota Produce Species-Specific Exometabolites Important in Heath and Disease

Potential role of small molecules of microbial origin (SMOMs) in human homeostasis is under intensive research. Today the data on chemical structure of microbiota’s metabolites are still limited as well as their mechanisms of participation in the systemic inflammation and regulatory processes in health and disease. We have previously shown that in sepsis the levels of some phenolic acids in the blood increase tens of times, while some other metabolites are reduced or entirely disappear. It is known that various diseases, especially critical ill state, usually associated with maximal shifts in the composition of indigenous anaerobic microflora. In this study the attempt was made to evaluate the potential input of pure culture of different species anaerobic bacteria in “in vitro” setting in human metabolome. The main objective of the present study was to determine individual contributions of anaerobes in the cumulative pool of lowmolecular-weight phenolic and carboxylic acids. The production of these metabolites by predominant species of human anaerobic flora has been studied by gas chromatography–mass spectrometry (GC–MS) analysis. It was demonstrated that, along with lactate, bifidobacteria and lactobacilli produced in vitro considerable amounts of phenyllactic and phydroxyphenyllactic acids. Clostridium spp. produced lactic and phenyllactic acids, as well as 2-hydroxybuturic acid. C. sporogenes, alternatively to C. perfringens, produced great quantities of phenylpropionic and phydroxyphenylpropionic acids. Bacteroides spp. turned to be powerful producers of succinic and fumaric acids and greatly contributed to the production of lactic acid. Eubacterium lentum produced lactic, phenyllactic, and succinic acids at high concentrations. The species-specific differences in the selective production of particular metabolites between indigenous and conventionally pathogenic human anaerobes may be useful for determining the composition of biocenosis and microbial associations, and can be used as well as in the design of novel probiotics.