Progesterone as an Anti-Inflammatory Drug and Immunomodulator: New Aspects in Hormonal Regulation of the Inflammation

The specific regulation of inflammatory processes by steroid hormones has been actively studied in recent years, especially by progesterone (P₄) and progestins. The mechanisms of the anti-inflammatory and immunomodulatory P₄ action are not fully clear. The anti-inflammatory effects of P₄ can be defined as nonspecific, associated with the inhibition of NF-κB and COX, as well as the inhibition of prostaglandin synthesis, or as specific, associated with the regulation of T-cell activation, the regulation of the production of pro- and anti-inflammatory cytokines, and the phenomenon of immune tolerance. The specific anti-inflammatory effects of P₄ and its derivatives (progestins) can also include the inhibition of proliferative signaling pathways and the antagonistic action against estrogen receptor beta-mediated signaling as a proinflammatory and mitogenic factor. The anti-inflammatory action of P₄ is accomplished through the participation of progesterone receptor (PR) chaperones HSP90, as well as immunophilins FKBP51 and FKBP52, which are the validated targets of clinically approved immunosuppressive drugs. The immunomodulatory and anti-inflammatory effects of HSP90 inhibitors, tacrolimus and cyclosporine, are manifested, among other factors, due to their participation in the formation of an active ligand–receptor complex of P₄ and their interaction with its constituent immunophilins. Pharmacological agents such as HSP90 inhibitors can restore the lost anti-inflammatory effect of glucocorticoids and P₄ in chronic inflammatory and autoimmune diseases. By regulating the activity of FKBP51 and FKBP52, it is possible to increase or decrease hormonal signaling, as well as restore it during the development of hormone resistance. The combined action of immunophilin suppressors with steroid hormones may be a promising strategy in the treatment of chronic inflammatory and autoimmune diseases, including endometriosis, stress-related disorders, rheumatoid arthritis, and miscarriages. Presumably, the hormone receptor- and immunophilin-targeted drugs may act synergistically, allowing for a lower dose of each.

New Properties and Mitochondrial Targets of Polyphenol Agrimoniin as a Natural Anticancer and Preventive Agent

Agrimoniin is a polyphenol from the group of tannins with antioxidant and anticancer activities. It is assumed that the anticancer action of agrimoniin is associated with the activation of mitochondria-dependent apoptosis, but its mitochondrial targets have not been estimated. We examined the direct influence of agrimoniin on different mitochondrial functions, including the induction of the mitochondrial permeability transition pore (MPTP) as the primary mechanism of mitochondria-dependent apoptosis. Agrimoniin was isolated from Agrimonia pilosa Ledeb by multistep purification. The content of agrimoniin in the resulting substance reached 80%, as determined by NMR spectroscopy. The cytotoxic effect of purified agrimoniin was confirmed on the cultures of K562 and HeLa cancer cells by the MTT assay. When tested on isolated rat liver mitochondria, agrimoniin at a low concentration (10 µM) induced the low-amplitude swelling, which was inhibited by the MPTP inhibitors ADP and cyclosporine A, activated the opening of MPTP by calcium ions and stimulated the respiration supported by succinate oxidation. Also, agrimoniin reduced the electron acceptor DCPIP in a concentration-dependent manner and chelated iron ions. Owing to all these properties, agrimoniin can stimulate apoptosis or activate mitochondrial functions, which can be helpful in the prevention and elimination of stagnant pathological states.

Progestins as Anticancer Drugs and Chemosensitizers, New Targets and Applications

Progesterone and its synthetic analogues, progestins, participate in the regulation of cell differentiation, proliferation and cell cycle progression. Progestins are usually applied for contraception, maintenance of pregnancy, and hormone replacement therapy. Recently, their effectiveness in the treatment of hormone-sensitive tumors was revealed. According to current data, the anticancer activity of progestins is mainly mediated by their cytotoxic and chemosensitizing influence on different cancer cells. In connection with the detection of previously unknown targets of the progestin action, which include the membrane-associated progesterone receptor (PR), non-specific transporters related to the multidrug resistance (MDR) and mitochondrial permeability transition pore (MPTP), and checkpoints of different signaling pathways, new aspects of their application have emerged. It is likely that the favorable influence of progestins is predominantly associated with the modulation of expression and activity of MDR-related proteins, the inhibition of survival signaling pathways, especially TGF-β and Wnt/β-catenin pathways, which activate the proliferation and promote MDR in cancer cells, and the facilitation of mitochondrial-dependent apoptosis. Biological effects of progestins are mediated by the inhibition of these signaling pathways, as well as the direct interaction with the nucleotide-binding domain of ABC-transporters and mitochondrial adenylate translocase as an MPTP component. In these ways, progestins can restore the proliferative balance, the ability for apoptosis, and chemosensitivity to drugs, which is especially important for hormone-dependent tumors associated with estrogen stress, epithelial-to-mesenchymal transition, and drug resistance.

Protectors of the Mitochondrial Permeability Transition Pore Activated by Iron and Doxorubicin

AIM

The study is aimed at examining of action of iron, DOX, and their complex on the Mitochondrial Permeability Transition Pore (MPTP) opening and detecting of possible protectors of MPTP in the conditions close to mitochondria-dependent ferroptosis.

BACKGROUND

The Toxicity of Doxorubicin (DOX) is mainly associated with free iron accumulation and mitochondrial dysfunction. DOX can provoke ferroptosis, iron-dependent cell death driven by membrane damage. The Mitochondrial Permeability Transition Pore (MPTP) is considered as a common pathway leading to the development of apoptosis, necrosis, and, possibly, ferroptosis. The influence of DOX on the Ca²⁺ -induced MPTP opening in the presence of iron has not yet been studied.

OBJECTIVE

The study was conducted on isolated liver and heart mitochondria. MPTP and succinate- ubiquinone oxidoreductase were studied as targets of DOX in mitochondria-dependent ferroptosis. The iron chelator deferoxamine (DFO), the lipid radical scavenger butyl-hydroxytoluene (BHT), and rutenium red (Rr), as a possible inhibitor of ferrous ions uptake in mitochondria, were tested as MPTP protectors. The role of medium alkalization was also examined.

METHODS

Changes of threshold calcium concentrations required for MPTP opening were measured by a Ca²⁺ selective electrode, mitochondrial membrane potential was registered by tetraphenylphosphonium (TPP+)-selective electrode, and mitochondrial swelling was recorded as a decrease in absorbance at 540 nm. The activity of Succinate Dehydrogenase (SDH) was determined by the reduction of the electron acceptor DCPIP.

CONCLUSION

MPTP and the respiratory complex II are identified as the main targets of the iron-dependent action of DOX on the isolated mitochondria. All MPTP protectors tested abolished or weakened the effect of iron and a complex of iron with DOX on Ca²⁺ -induced MPTP opening, acting in different stages of MPTP activation. These data open new approaches to the modulation of the toxic influence of DOX on mitochondria with the aim to reduce their dysfunction.

The mitochondrial NO-synthase/guanylate cyclase/protein kinase G signaling system underpins the dual effects of nitric oxide on mitochondrial respiration and opening of the permeability transition pore

The available data on the involvement of nitric oxide (NO) and mitochondrial calcium-dependent NO synthase (mtNOS) in the control of mitochondrial respiration and the permeability transition pore (mPTP) are contradictory. We have proposed that the mitochondrial mtNOS/guanylate cyclase/protein kinase G signaling system (mtNOS-SS) is also implicated in the control of respiration and mPTP, providing the interplay between NO and mtNOS-SS, which, in turn, may result in inconsistent effects of NO. Therefore, using rat liver mitochondria, we applied specific inhibitors of the enzymes of this signaling system to evaluate its role in the control of respiration and mPTP opening. Steady-state respiration was supported by pyruvate, glutamate, or succinate in the presence of hexokinase, glucose, and ADP. When applied at low concentrations, l-arginine (to 500 µm) and NO donors (to 50 µm) activated the respiration and increased the threshold concentrations of calcium and d,l-palmitoylcarnitine required for the dissipation of the mitochondrial membrane potential and pore opening. Both effects were eliminated by the inhibitors of NO synthase, guanylate cyclase, and kinase G, which denotes the involvement of mtNOS-SS in the activation of respiration and deceleration of mPTP opening. At high concentrations, l-arginine and NO donors inhibited the respiration and promoted pore opening, indicating that adverse effects induced by an NO excess dominate over the protection provided by mtNOS-SS. Thus, these results demonstrate the opposite impact of NO and mtNOS-SS on the respiration and mPTP control, which can explain the dual effects of NO.

Substrate-Specific Reduction of Tetrazolium Salts by Isolated Mitochondria, Tissues, and Leukocytes

Tetrazolium salts are commonly used in cytochemical and biochemical studies as indicators of metabolic activity of cells. Formazans, formed by reduction of tetrazolium salts, behave as pseudo-solutions during initial incubation, which allows monitoring their optical density throughout incubation. The criteria and conditions for measuring oxidative activity of mitochondria and dehydrogenase activity in reduction of nitroblue tetrazolium (NBT) and methyl thiazolyl tetrazolium (MTT) in suspensions of isolated mitochondria, tissue homogenates, and leukocytes were investigated in this work. We found that the reduction of these two acceptors depended on the oxidized substrate - NBT was reduced more readily during succinate oxidation, while MTT - during oxidation of NAD-dependent substrates. Reduction of both acceptors was more sensitive to dehydrogenase inhibitors that to respiratory chain inhibitors. The reduction of NBT in isolated mitochondria, in leukocytes in the presence of digitonin, and in liver and kidney homogenates was completely blocked by succinate dehydrogenase inhibitors - malonate and TTFA. Based on these criteria, activation of succinate oxidation was revealed from the increase in malonate-sensitive fraction of the reduced NBT under physiological stress. The effect of progesterone and its synthetic analogs on oxidation of NAD-dependent substrates by mitochondria was investigated using MTT. Both acceptors are also reduced by superoxide anion; the impact of this reaction is negligible or completely absent under physiological conditions, but can become detectable on generation of superoxide induced by inhibitors of individual enzyme complexes or in the case of mitochondrial dysfunction. The results indicate that the recording of optical density of reduced NBT and MTT is a highly sensitive method for evaluation of metabolic activity of mitochondria applicable for different incubation conditions, it offers certain advantages in comparison with other methods (simultaneous incubation of a large set of probes in spectral cuvettes or plates); moreover, it allows determination of activity of separate redox-dependent enzymes when selective inhibitors are available.

[Influence of Microbial Metabolites of Phenolic Nature on the Activity of Mitochondrial Enzymes]

The aim of this work was to study the effect of microbial metabolites of phenolic nature on the activity of enzymes of the tricarboxylic acid cycle in isolated mitochondria, and determine metabolites of the tricarboxylic acid cycle as potential biomarkers of mitochondrial dysfunction in the blood of patients with sepsis. It is shown that microbial metabolites of phenolic nature have an inhibitory effect on the activity of dehydrogenases, determined by the reduction of dichlorophenolindophenol and nitroblue tetrazolium in liver mitochondria and liver homogenates. This effect is more pronounced in oxidation of the NAD-dependent substrates than succinate oxidation, and at lower concentrations of microbial metabolites than inhibition of respiration. By gas chromatography-mass spectrometry it was found that the content of the tricarboxylic acid cycle metabolites in the blood of patients with sepsis decreased compared to healthy donors. The data obtained show that the microbial phenolic acids can contribute significantly to the dysfunction of mitochondria and suppression of general metabolism, characteristic of these pathologies.

[Changes in lymphocytes under influence of oxidative substrates]

Blood lymphocytes of children with oncology diseases were studied in smears compared with healthy ones examined from the closely selected group. The following two methods were used: the traditional in hematology method of smear staining for detection of blood formula and lymphocyte indices and the staining with novel cytobiochemical method including 60-min incubation in biochemical medium for estimation of the activity of succinate dehydrogenase, lactate dehydrogenase and their ratio, that can serve as a measure of respiration and glycolysis--Warburg effect, typical of tumor. The great increase in lymphocyte size by addition of lactate was found in blood smears of patients with tumors. This effect was not pronounced by addition of succinate and in cells of healthy persons. Changes in the structure of the cells in patients were also related to the changes in the activity of enzymes studied. These changes can be considered as transition of metabolism and the structure of cells to the state in tumor. Cytobiochemical method allows for higher diagnostic sensitivity of patient examination and efficiency of medical care of patients with oncological diseases.

[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 the 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 a 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 the dithiotreitol 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 the oxidized iron by thiols with subsequent release of doxorubicin.

Mitochondrial models of pathologies with oxidative stress. Efficiency of alkalization to reduce mitochondrial damage

Previously, we developed a method to monitor the development of oxidative stress in isolated liver mitochondria. The method is based on recording of membrane potential changes in response to sequential introduction of low concentrations (5-20 μM) of tert-butyl hydroperoxide (tBHP). It allows monitoring of the extent of amplification or attenuation of oxidative stress caused by external influences (changes in incubation conditions, additions of biologically active substances). Based on this method, we created a mitochondrial model for the study and improvement of treatment of pathologies associated with oxidative stress. The following two processes were simulated in the experiments: 1) introduction of desferal for treatment of serious diseases caused by cell overload with iron (high desferal concentrations were shown to suppress mitochondrial energetics); 2) efficiency of alkalization to reduce mitochondrial damage induced by oxidative stress. The experiments have shown that even a small increase in pH (alkalization) increases the amount of tBHP that can be added to mitochondria before the MPTP ("mitochondrial permeability transition pore") is induced. The effect of alkalization was shown to be close to the effect of cyclosporin A in the pH range 7.2-7.8. The mechanism of the similarities of these effects in the organism and in mitochondrial suspensions is explained by the increase in toxic reactive oxygen species in both systems under oxidative stress.

[State of succinate dehydrogenase in the organism--"unbalanced" or hyperactive]

Through the use of the original cytobiochemical method to study oxidation in mitochondria, preserving their native organization in network within cells in a blood smear, we revealed hyperactive state of succinate dehydrogenase, which is realized in the organism under physiological stress. It is consistent with the view of the non-equilibrium state of enzymes during activity. The mechanism of the succinate dehydrogenase hyperactivity moderation is based on the full functioning of alpha-ketoglutarate dehydrogenase, supported by oxidation of isocitric acid.

[Effect of steroid hormones on production of reactive oxygen species in mitochondria]

Among the targets of the steroid hormones are mitochondria, which as the main source of reactive oxygen species (ROS) in the cell play a central role in the development of various pathologies. We studied the effect of progesterone and its synthetic analogues on mitochondrial ROS production. It was found that progesterone activates the formation of superoxide anion and hydrogen peroxide in mitochondria during oxidation of complex I substrates of the respiratory chain and exerts no influence on production of ROS during oxidation of succinate, complex II substrate of the respiratory chain. Synthetic analogues of progesterone - medroxyprogesterone acetate, buterol, acetomepregenol, megestrol acetate, have different effects on ROS production, depending on their chemical structure. By the effectiveness of impact on ROS production in mitochondria all the steroids tested can be classified in the descending order as follows: progesterone > buterol > or = atsetomepregenol > medroxyprogesterone acetate > megestrol acetate. Activation of ROS production by progesterone and buterol has different mechanisms: progesterone acts as an inhibitor of NAD-dependent respiration, while buterol and acetomepregenol form noncovalently associated complexes by hydrogen bonds between the ester carbonyl at C3 and SH-groups of the respective targets.

[The role of thiol antioxidants in restoring mitochondrial functions, modified by microbial metabolites]

The effects of phenolic acids of microbial origin on mitochondrial functions and the possibility of removing their effects by thiol antioxidants dithiotreitol and N-acethylcysteine were studied. The action of some phenolic acids on the redox state of NADH, the membrane potential and calcium capacity of mitochondria is due to their interaction with thiol groups. The partial restoration of mitochondrial functions occurred in the presence of dithiotreitol and N-acethylcysteine, the full recovery (short-term duration) was promoted by the combined action of dithiotreitol and menadione (vitamin K3). It was found that the protective effect of thiol antioxidants became prooxidant one, if the medium contained free iron and compounds with a quinone structure, capable of entering into a redox cycle with thiols. It is shown that the interaction of thiols with iron and menadione is accompanied by absorption of oxygen to form superoxide anion. Prooxidant effect of thiol antioxidants may explain the absence of the protective effect at the later stages of sepsis and systemic inflammatory syndrome.

[Exometabolites of some anaerobic microorganisms of human microflora]

Some exometabolites produced by basic representatives of human anaerobic microflora were investigated, detected by gas chromatography-mass spectrometry (GC-MS). In vitro besides lactic acid Bifidobacterium and Lactobacillus generate substantial amounts of phenyllactic and p-hydroxyphenyllactic acids. Clostridium produced 2-hydroxybutyric acid and to a lesser extent lactic and phenyllactic acids. In contrast to C. perfringens, C. sporogenes generates substantial amount of phenylpropionic and p-hydroxyphenylpropionic acids and less p-hydroxyphenyllactic acid. C. perfringens produced minor amounts of 2-hydroxyglutaric acid. Bacteroids are potent producers of succinic and fumaric acids; they also contribute to production of significant portion of lactic acid. E. lentum generate lactic, phenyllactic and succinic acids and form a characteristic only for ones (from studied microorganisms) 2-hydroxyhexanic and 2-hydroxy-3-methylbutyric acids.

Mitochondrial metabolites in tissues as indicators of metabolic alterations during hibernation

The decrease in metabolism is one of mechanisms for hibernating animals to resist hypoxia and oxidative stress. Assuming that the inhibition of mitochondria; respiration in torpor and its activation upon arousal are accompanied by changes in the content of mitochondrial substrates, we estimated the levels of endogenous metabolites of the tricarboxylic acid (TCA) cycle in the liver, brown adipose tissue, and the brain of the arctic ground squirrels as possible indicators of mitochondrial processes. The level of lactate in the same tissues and serum was determined as marker of hypoxia. It was found that the isocitrate (ISC) concentration in all tissues was one order of magnitude higher than that of alpha-ketoglutarate (KGL), while succinate was not detected in any of tissues, indicating the inhibition at the initial stages of the TCA cycle. During the torpor, the concentrations of ISC, KGL and lactate predominantly decreased in tissues. Serum lactate decreased five-fold in torpor and was restored in a temperature-dependent manner with a long period of persistence of stable concentration in the range of body temperature between 12 and 27°C upon arousal. The data obtained indicate the development of metabolic depression rather than hypoxia in these tissues.

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.

Increase in the contribution of transamination to the respiration of mitochondria during arousal

The involvement of transamination in the respiration of liver mitochondria in ground squirrels during hibernation and arousal has been studied. It was shown by HPLC that, in the presence of glutamate and malate, the formation of alpha-ketoglutarate (KGL), a transamination marker, and fumarate, a product of succinate oxidation, takes place. During arousal, the formation of KGL increased fourfold, and the respiration sensitive to the inhibitor of aspartate transaminase aminooxyacetate (AOA) increased threefold. The function of transamination upon arousal is related to the elimination of oxaloacetate, an endogenous inhibitor of succinate dehydrogenase. In addition, being more resistant to oxidative stress than oxidation, transamination is probably involved in the antioxidant defense required during the rapid rise of body temperature upon arousal. Our experiments showed an increase in the concentration of malonic dialdehyde (MDA), an end product of lipid peroxidation, in liver mitochondria in this state, which can reduce the activity of the enzymes of the tricarboxylic acids cycle. Under these conditions, the transamination contributes to the maintenance of a high respiration rate necessary for arousal.

Nonezymatic formation of succinate in mitochondria under oxidative stress

The products of the reactions of mitochondrial 2-oxo acids with hydrogen peroxide and tert-butyl hydroperoxide (tert-BuOOH) were studied in a chemical system and in rat liver mitochondria. It was found by HPLC that the decarboxylation of alpha-ketoglutarate (KGL), pyruvate (PYR), and oxaloacetate (OA) by both oxidants results in the formation of succinate, acetate, and malonate, respectively. The two latter products do not metabolize in rat liver mitochondria, whereas succinate is actively oxidized, and its nonenzymatic formation from KGL may shunt the tricarboxylic acid (TCA) cycle upon inactivation of alpha-ketoglutarate dehydrogenase (KGDH) under oxidative stress, which is inherent in many diseases and aging. The occurrence of nonenzymatic oxidation of KGL in mitochondria was established by an increase in the CO(2) and succinate levels in the presence of the oxidants and inhibitors of enzymatic oxidation. H(2)O(2) and menadione as an inductor of reactive oxygen species (ROS) caused the formation of CO(2) in the presence of sodium azide and the production of succinate, fumarate, and malate in the presence of rotenone. These substrates were also formed from KGL when mitochondria were incubated with tert-BuOOH at concentrations that completely inhibit KGDH. The nonenzymatic oxidation of KGL can support the TCA cycle under oxidative stress, provided that KGL is supplied via transamination. This is supported by the finding that the strong oxidant such as tert-BuOOH did not impair respiration and its sensitivity to the transaminase inhibitor aminooxyacetate when glutamate and malate were used as substrates. The appearance of two products, KGL and fumarate, also favors the involvement of transamination. Thus, upon oxidative stress, nonenzymatic decarboxylation of KGL and transamination switch the TCA cycle to the formation and oxidation of succinate.

Evidence of the glyoxylate cycle in the liver of newborn rats

RESULTS

BACKGROUND

It is generally accepted that the glyoxylate cycle exists in microorganisms and higher plants but absent in higher animals. the hypodhesis of the glyoxylate cycle in the tissues of higher animals with a high level of physiological activity was first proposed by Kondrashova and Rodionova in 1971. The goal of this work was yo verifv this in newborn rats, which possess a 2.5-fold hygher physiological activity and oxygen consumption rate than adult rats.

MATERIAL/METHODS

Newborn (7-day-old) anradult 1 ats were used for this experiment. The activities of the key enzymes of the glyoxylate cocle (isecitrate lyse and nmalate synthase) were measured by HPLC and spectroscopic methods. The activities of isocitrate lyase and malate synthase were found in the liver homogenates prepared from newborn rats, but not from adult rats. The activities of the enzymes common to both the Krebs cycle and the glyoxylate cycle (citrate synthase, aconitase, and malate dehydrogenase) were 20-40% higher in newborn than in adult rats.

CONCLUSIONS

These data indicate the existence of the glyoxylate cycle in animal tissues.

Preservation of native properties of mitochondria in rat liver homogenate

A protocol is developed for preparation of concentrated rat liver homogenate preserving assemblies of mitochondria in isotonic KCl under 0 and 15 degrees C. Assemblies preserve ability for self-organization during storage in homogenate. All key energy functions of mitochondria can be investigated in such a homogenate. Oxidative phosphorylation and membrane potential are stable for 5-7 h and can be still observed on the next day. Substrate-level phosphorylation is better pronounced for mitochondria in KCl than in sucrose medium while Ca2+ capacity is greater and lipid peroxidation is much lower. Sucrose addition impairs these functions. The rate of phosphorylating respiration is lower in large assemblies and higher in small. Transition from large to small assemblies corresponds to the transition from quiescent state of animal to adrenaline induced active state. The proposed method is particularly convenient for clinical investigations with small bioptates.

[Monoamine oxidase activity in rat liver in vitamin B12 deficiency]

Changes in the activity of monoamine oxidase (MAO-B) in liver homogenates and mitochondria from normal and vitamin B12-deficient rats have been studied in various functional states of the mitochondria. Preincubation of liver preparation at 32 degrees C increased the MAO affinity for benzylamine in samples of normal (but not vitamin B12-deficient rats). Succinate added to the incubation medium decreased Km and increased Vmax in both normal and vitamin B12-deficient animals. A correlation was found between the decline of MAO-B activity under vitamin B12 deficiency, deceleration of succinate oxidation and reduction of the transmembrane potential.

[Effect of GDP and carboxyatractylate on potassium ion transport in brown fat mitochondria]

It has been shown that the increase of the membrane potential in uncoupled brown fat mitochondria after addition of 1-2 mM GDP to a medium containing potassium acetate is accompanied by swelling of mitochondria which occurs in two phases. The first swelling phase is due to the electrogenic transport of K+ ions, while the second one is activated by carboxyatractylate and carnitine. The swelling is practically completely inhibited by a further rise of the GDP concentration irrespective of high values of the membrane potential. Unlike K+ transport, the potential-dependent transport of Na+ ions occurs more rapidly, is monophasic and insensitive to carboxyatractylate and carnitine. It is suggested that regulation of K+ ion transport in brown fat mitochondria is mediated by the action of nucleotides and fatty acid esters on the uncoupling protein and ADP/ATP antiporter.

[Metabolites of the propionate pathway as regulators of fatty and dicarboxylic acid oxidation in liver mitochondria]

The functioning of the propionate pathway of oxidation substrate metabolism in the norm and under vitamin B12 deficiency has been studied. This pathway has been shown to play an important role in oxidative processes occurring in normal organisms, for its inhibition in B12-deficient animals is associated with a reduction of respiration as well as with noticeable decreases in palmitoylcarnitine and succinate oxidation rates and oxidation phosphorylation coupling. Succinate, the end product of the propionate pathway, normalizes the respiration and restores the rate of palmitoylcarnitine oxidation in B12-deficient animals, which is suggestive of its crucial role in the propionate pathway. In vivo propionate inhibits, whereas methyl malonate stimulates palmitoylcarnitine respiration, however only in intact animals. In B12-deficient animals the sensitivity to these metabolites is decreased.

[Effect of propionate pathway metabolites on the oxidative activity of liver mitochondria under normal conditions and in vitamin B12 deficiency]

We performed a comparative investigation in vivo and in vitro of the propionate and methylmalonate effect on oxidative activity of liver mitochondria in control and vitamin B12-deficient rats and found that efficiency of the effects were less pronounced in vitamin B12-deficient rats. It is also shown that the rates of respiration and phosphorylation decreased in liver mitochondria of vitamin B12-deficient rats.

[The effect of metabolites of the propionate pathway on the oxidative activity of liver mitochondria]

Methylmalonate and propionate, the major metabolites of the propionate pathway of fatty and amino acid metabolism used at 1-4 mM cause selective inhibition of succinate and palmitoyl carnitine oxidation in liver mitochondria. Methylmalonate is more specific towards succinate, whereas propionate--towards palmitoyl carnitine oxidation. Methylmalonate is transported to mitochondria at a high rate with no effect on succinate transport. Being injected intramusculary methylmalonate has no inhibiting effect on the oxidative activity of mitochondria but is able to activate succinate and palmitoyl carnitine oxidation. The inhibiting effect of propionate on palmitoyl carnitine oxidation is a long-term one. Injections of these metabolites precursors, isoleucine, methionine and valine, produce an activating effect on succinate oxidation. Thus, propionate pathway metabolites may participate in the regulation of lipid-carbohydrate metabolism.

[Effect of antibodies against mitochondrial K+-transporting protein on K+ transport in rat liver mitochondria]

The K+ transport in rat liver mitochondria was studied by the immunochemical method. Antibodies to mitochondrial K+-transporting protein with molecular weight 60 kDa were obtained and used as possible inhibitor or K+ transport. Antibodies depressed the DNP-induced K+ efflux and energy-dependent swelling by 50% without causing changes in respiration and oxidative phosphorylation.

[Effect of the outer mitochondrial membrane fraction on mitoplast respiration]

Additions of the fraction of outer mitochondrial membranes to the mitoplast suspension is shown to bring about an increase of the ADP-stimulated respiration rate, indices of respiration control and uncoupled respiration. This effect is not a result of the cytochrome c presence in the fraction of outer membranes. In the glycerol-containing medium which causes dissociation of intermembrane contacts the coupling effect of outer membranes on mitoplast respiration is not revealed. It is concluded that the outer membrane in contact with the inner one takes part in realization of the mitochondrial coupling.

[Potential activity of the external pathway of NADH oxidation in mitochondria]

High rate of exogenic NADH oxidation (up to 200 mg-at. oxygen for 1 min per 1 mg of protein and higher) along the rothenone, antimycin-nonsensitive pathway is observed under interaction of mitoplasts with the external membrane and cytochrome c. In the medium with low ionic strength the interaction of external and internal membranes is not a sufficient condition for activating the external pathway of the NADH oxidation: the presence of exogenic cytochrome c is also necessary. With saturated cytochrome c concentrations the addition of outer membranes leads to further stimulation of the NADH oxidation. In the medium with high ionic strength external membranes stimulate oxidation of NADH when exogenic cytochrome c is absent; the subsequent addition of cytochrome c stimulates the NADH oxidation in this medium to a greater extent than in the medium with the low ionic strength. Under the nonlimited interaction of external and internal membranes and cytochrome c the potential activity of the outer pathway of NADH oxidation in the liver mytoplasts of hybernating gophers is lower than in the liver mytoplasts of rats.

[Changes in K+ transport in the liver mitochondria of gophers in hibernation]

Liver mitochondria of awake and hibernating squirrels maintain the same amount of K+ due to a decrease of K+-permeability during hibernation. The rates of DNP-stimulated K+-efflux and respiration-dependent K+-influx in mitochondria are diminished during hibernation. A two-fold increasing of K+-content and activation of K+-transport are observed at the arousing. Variations of K+-transport in mitochondria correspond to the changes in the channel-formed activity of K+-transporting protein isolated from the liver of this animals. This activity is maximal during arousal and is least during hibernation.

[Protein from beef heart mitochondria inducing the potassium channel conductivity of bilayer lipid membrane]

Protein (M. m. 60 000) inducing selective potassium conductance of bilayer lipid membranes (BLM) was isolated from mitochondria and homogenate of the beef heart. This protein was obtained by means of alcohol (ethanol) extraction and was purified by gel-filtration on Sephadex G-15 and G-50 followed by electrophoresis in the 10% polyacrylamide gel. 6-10 g/ml of the protein produced the conductivity channels on BLM with amplitude divisible of 24 +/- 4 pmho. The channels of 175 +/- 7 pmho were the most typical ones. The modification of BLM by K+-transport in protein under the conditions of potassium gradient resulted in the appearance of the membrane potential close to the theoretical Nernst potential.