Acid Composition Of Mitochondrial Membranes Research Articles

Adaptogenic Properties of 1-(Germatran-1-il)-Oxyethylamine

Background: Germanium is a biologically active trace element, and it is present in almost all organs and tissues. Its biological activity was revealed in the 20th century. However, the study on the possibility of using germanium for medical purposes was first undertaken by the Japanese scientist Dr. Kazuhiko Asai in 1940. In 1965, academician M.G.Voronkov and colleagues synthesized tricyclic esters of triethanolamine germanium with the general formula XGe(OCH2CH2)3N and studied their biological activity. However, the adaptogenic properties of these compounds have not been sufficiently studied. In this regard, there is an urgent need to study the adaptogenic properties of these drugs. Objective: As the resistance of the organism to stress factors primarily depends on energy metabolism, the aim of our work was to study the influence of stress and 1- (germatran-1-il) –oxyethylamine (GM) on the functional state of mitochondria. Methods: The functional state of mitochondria was studied as per the rate of mitochondria respiration by the level of lipid peroxidation and fatty acid composition of mitochondrial membranes by chromatography technique. Results: It was shown that the drug in concentrations of 10-5, 10-6, and 10-11M reduced the intensity of LPO in the membranes of "aged" mitochondria. This may serve as evidence regarding the presence of anti-stress properties in the drug. Injection of GM at a dose of 10-5 mol/kg to rats prevented the activation of LPO in the membranes of the liver mitochondria in conditions of acute hypobaric hypoxia. Restricting lipid peroxidation, GM prevented changes in the content of C18 and C22 fatty acids in mitochondrial membranes, which probably contributed to maintaining the bioenergetic characteristics of mitochondria at the control level. Conclusion: It is assumed that the anti-stress activity of the drug is associated with its antioxidant properties and its effect on the complex I of the mitochondrial respiratory chain.

Ethoxidol as a Broad-spectrum Adaptogen.

Stress factors lead to a shift in the antioxidant-prooxidant relationship, allowing an increase in the generation of reactive oxygen species (ROS) by mitochondria, which results in the development of oxidative stress. Consequently, it is possible to put forward an assumption that drugs which reduce the excessive generation of ROS by these organelles should increase the body's resistance to stress factors. Antioxidants can be used as such drugs. In this regard, the aim of this work was to study the bioenergetics characteristic of mitochondria under stress conditions and under the action of 2-ethyl-6-methyl-3-hydroxypyridinium hydroxybutanedioate (ethoxidol). The antiradical activity of the drug was evaluated by the chemiluminescent method (CL). The functional state of the mitochondria was studied with reference to the level of lipid peroxidation by the spectrofluorimetry and in terms of fatty acid composition of mitochondrial membranes using the chromatography technique. The study of mitochondrial morphology was performed employing the method of atomic force microscopy. The injection in mice of ethoxidol at a dose of 10-5 mol/kg for 7 days led to the prevention of the stress-induced increase in the intensity of LPO in the membranes of the mitochondria, and swelling of these organelles; it also prevented a decrease in the content of unsaturated fatty acids, containing 18 and 20 carbon atoms. At the same time, ethoxidol increased the life expectancy of mice by 3.0-4.2 times in conditions of various types of hypoxia. The adaptogenic properties of ethoxidol can be attributed to its antiradical and antioxidant properties.

Тетранитрозильный комплекс железа с тиосульфатными лигандами предотвращает дисфункцию митохондрий в условиях стресса

The effect of stress (water deficiency, high-temperature stress) and nitric oxide donor sodium μ2-dithiosulphate-tetranitosyldiferrate tetrahydrate Na2 [Fe2 (S2O3)2 (NO)4]2 × 4H2O (TNIC-thio) on the fatty acid composition and bioenergetic characteristics of 5-day etiolated pea seedling mitochondria was studied. Stressful effects caused the activation of LPO in the mitochondrial membranes. At the same time, significant changes occurred in the content of C18 and C20 fatty acids (FA). A decrease in the content of linoleic and linolenic acids, one of the main FA components of cardiolipin in higher plants, apparently caused a decrease in the maximum rates of oxidation of NAD-dependent substrates. The. treatment of pea seeds with 10-6M TNIC-thio prevented the activation of LPO, changes in the fatty acid composition of mitochondrial membranes, and contributed to the preservation of the bioenergetic characteristics of these organelles. By preventing the decline in energy metabolism, TNIC-thio probably has adaptogenic properties, that were also reflected in physiological parameters, namely, the growth of seedlings. Treatment of pea seeds and seedlings with the studied preparation prevented inhibition of root and shoot growth in conditions of water deficiency. Based on the data obtained, it can be concluded that the protective properties of TNIC-thio are due to its antioxidant activity.

Functional state of mitochondria in chronic respiratory diseases

Introduction. Chronic respiratory diseases are one of the most common types of non-communicable diseases and are an important problem of our time. The induction of oxidative stress, chronic inflammation and hypoxia, which underlie the pathogenesis of chronic diseases of the bronchopulmonary system, can be determined at the cellular and molecular level by impaired mitochondrial functioning.Aim. This review is devoted to the prospects for assessing the functional state of mitochondria as a fine indicator of the course of chronic respiratory diseases.Results. The data of domestic and foreign sources on the most important parameters of mitochondrial functioning in normal and chronic bronchopulmonary pathology were analyzed. It has been shown that mitochondria are highly sensitive to changes in both exogenous and endogenous homeostasis. Functional parameters of mitochondria, the level of mitochondrial reactive oxygen species, mitochondrial membrane potential, and fatty acid composition of mitochondrial membranes can be used as diagnostic and prognostic criteria for chronic respiratory diseases. The data presented in the review indicate the need for further studies of the functional state of mitochondria in chronic bronchopulmonary pathology.

The Influence of Ultra-Low Concentrations of Potassium Anphen on the Bioenergetic Characteristics of Mitochondria

Background: One of the main sources of ROS in stress conditions is the mitochondria. Excessive generation of ROS leads to oxidation of thiol groups of proteins, peroxidation of membrane lipids and swelling of the mitochondria. In this regard, there is a need to search for preparationsadaptogens that increase the body's resistance to stress factors. Perhaps, antioxidants can serve as such adaptogens. This work aims at studying the effect of antioxidant; the potassium anphen in a wide range of concentrations on the functional state of 6 day etiolated pea seedlings mitochondria (Pisum sativum L). Methods: The functional state of mitochondria was studied per rates of mitochondria respiration, by the level of lipid peroxidation and study of fatty acid composition of mitochondrial membranes by chromatography technique. Results: Potassium anphen in concentrations of 10-5 - 10-8 M and 10-13-10-16 prevented the activation of LPO in the mitochondrial membranes of pea seedlings, increased the oxidation rates of NAD-dependent substrates and succinate in the respiratory chain of mitochondria that probably pointed to the anti-stress properties of the drug. Indeed, the treatment of pea seeds with the preparation in concentrations of 10-13 M prevented the inhibition of growth of seedlings in conditions of water deficiency. Conclusion: It is assumed that the dose dependence of the biological effects of potassium anphen and the manifestation of these effects in ultra-low concentrations are due to its ability in water solutions to form a hydrate containing molecular ensembles (structures).

Protective effects of dietary avocado oil on impaired electron transport chain function and exacerbated oxidative stress in liver mitochondria from diabetic rats.

Electron transport chain (ETC) dysfunction, excessive ROS generation and lipid peroxidation are hallmarks of mitochondrial injury in the diabetic liver, with these alterations also playing a role in the development of non-alcoholic fatty liver disease (NAFLD). Enhanced mitochondrial sensitivity to lipid peroxidation during diabetes has been also associated to augmented content of C22:6 in membrane phospholipids. Thus, we aimed to test whether avocado oil, a rich source of C18:1 and antioxidants, attenuates the deleterious effects of diabetes on oxidative status of liver mitochondria by decreasing unsaturation of acyl chains of membrane lipids and/or by improving ETC functionality and decreasing ROS generation. Streptozocin-induced diabetes elicited a noticeable increase in the content of C22:6, leading to augmented mitochondrial peroxidizability index and higher levels of lipid peroxidation. Mitochondrial respiration and complex I activity were impaired in diabetic rats with a concomitant increase in ROS generation using a complex I substrate. This was associated to a more oxidized state of glutathione, All these alterations were prevented by avocado oil except by the changes in mitochondrial fatty acid composition. Avocado oil did not prevented hyperglycemia and polyphagia although did normalized hyperlipidemia. Neither diabetes nor avocado oil induced steatosis. These results suggest that avocado oil improves mitochondrial ETC function by attenuating the deleterious effects of oxidative stress in the liver of diabetic rats independently of a hypoglycemic effect or by modifying the fatty acid composition of mitochondrial membranes. These findings might have also significant implications in the progression of NAFLD in experimental models of steatosis.

Age-dependent biochemical dysfunction in skeletal muscle of triple-transgenic mouse model of Alzheimer`s disease.

The emergence of Alzheimer`s disease as a systemic pathology shifted the research paradigm toward a better understanding of the molecular basis of the disease considering the pathophysiological changes in both brain and peripheral tissues. In the present study, we evaluated the impact of disease progression on physiological relevant features of skeletal muscle obtained from 3, 6 and 12 month-old 3xTg-AD mice, a model of Alzheimer`s disease, and respective agematched nonTg mice. Our results showed that skeletal muscle functionality is already affected in 3-month-old 3xTg-AD mice as evidenced by deficient acetylcholinesterase and catalase activities as well as by alterations in fatty acid composition of mitochondrial membranes. Additionally, an age-dependent accumulation of amyloid-β1-40 peptide occurred in skeletal muscle of 3xTg-AD mice, an effect that preceded bioenergetics mitochondrial dysfunction, which was only detected at 12 months of age, characterized by decreased respiratory control ratio and ADP/O index and by an impairment of complex I activity. HPLC-MS/MS analyses revealed significant changes in phospholipid composition of skeletal muscle tissues from 3xTg-AD mice with 12 months of age when compared with age-matched nonTg mice. Increased levels of lyso-phosphatidylcholine associated with a decrease of phosphatidylcholine molecular species containing arachidonic acid were detected in 3xTg-AD mice, indicating an enhancement of phospholipase A2 activity and skeletal muscle inflammation. Additionally, a decrease of phosphatidylethanolamine plasmalogens content and an increase in phosphatidylinositol levels was observed in 3xTg-AD mice when compared with age-matched nonTg mice. Altogether, these observations suggest that the skeletal muscle of 3xTg-AD mice are more prone to oxidative and inflammatory events.

Making heads or tails of mitochondrial membranes in longevity and aging: a role for comparative studies

Mitochondria play vital roles in metabolic energy transduction, intermediate molecule metabolism, metal ion homeostasis, programmed cell death and regulation of the production of reactive oxygen species. As a result of their broad range of functions, mitochondria have been strongly implicated in aging and longevity. Numerous studies show that aging and decreased lifespan are also associated with high reactive oxygen species production by mitochondria, increased mitochondrial DNA and protein damage, and with changes in the fatty acid composition of mitochondrial membranes. It is possible that the extent of fatty acid unsaturation of the mitochondrial membrane determines susceptibility to lipid oxidative damage and downstream protein and genome toxicity, thereby acting as a determinant of aging and lifespan. Reviewing the vast number of comparative studies on mitochondrial membrane composition, metabolism and lifespan reveals some evidence that lipid unsaturation ratios may correlate with lifespan. However, we caution against simply relating these two traits. They may be correlative but have no functional relation. We discuss an important methodology for body mass and phylogenetic correction in comparative studies.

Omega‐3 supplementation alters mitochondrial membrane composition and respiration kinetics in human skeletal muscle

Studies have shown increased incorporation of omega-3 fatty acids into whole skeletal muscle following supplementation, although little has been done to investigate the potential impact on the fatty acid composition of mitochondrial membranes and the functional consequences on mitochondrial bioenergetics. Therefore, we supplemented young healthy male subjects (n = 18) with fish oils [2 g eicosapentaenoic acid (EPA) and 1 g docosahexanoic acid (DHA) per day] for 12 weeks and skeletal muscle biopsies were taken prior to (Pre) and following (Post) supplementation for the analysis of mitochondrial membrane phospholipid composition and various assessments of mitochondrial bioenergetics. Total EPA and DHA content in mitochondrial membranes increased (P < 0.05) ∼450 and ∼320%, respectively, and displaced some omega-6 species in several phospholipid populations. Mitochondrial respiration, determined in permeabilized muscle fibres, demonstrated no change in maximal substrate-supported respiration, or in the sensitivity (apparent Km) and maximal capacity for pyruvate-supported respiration. In contrast, mitochondrial responses during ADP titrations demonstrated an enhanced ADP sensitivity (decreased apparent Km) that was independent of the creatine kinase shuttle. As the content of ANT1, ANT2, and subunits of the electron transport chain were unaltered by supplementation, these data suggest that prolonged omega-3 intake improves ADP kinetics in human skeletal muscle mitochondria through alterations in membrane structure and/or post-translational modification of ATP synthase and ANT isoforms. Omega-3 supplementation also increased the capacity for mitochondrial reactive oxygen species emission without altering the content of oxidative products, suggesting the absence of oxidative damage. The current data strongly emphasize a role for omega-3s in reorganizing the composition of mitochondrial membranes while promoting improvements in ADP sensitivity.

Fatty acid composition and activity of the mitochondrial respiratory chain complex I of pea seedlings under water deficit

In this work the effect of insufficient watering and plant growth regulator melaphen (melamine salt of bis(oxymethyl)phosphonic acid) on the fatty acid composition and the energy of 5-day etiolated pea seedling mitochondria (Pisum sativum) were studied.Isolation of mitochondria from 5-day sprouts epicotyls was performed by differential centrifugation. The rate of mitochondria respiration was measured with the aid of Clarke oxygen electrodes and LP-7 polarograph (Czech Republic). Fatty acid methyl esters (FAMEs) were produced by acidic methanolysis of mitochondrial membrane lipids and FAMEs quantification was performed using a Kristall 2000M chromatograph (Russia) with flame-ionization detector and quarts capillary column SPB-1 (50 m × 0.32 mm, a nonpolar phase layer – 0.25 μm). It has been shown that insufficient watering results in alteration of fatty acid composition in mitochondrial membranes of seedlings. The ratio of the content of С18 – unsaturated fatty acids to the stearic acid content decreases by 1.5 times. Significant changes are observed in the content of fatty acids with 20 carbon atoms: the ratio of unsaturated fatty acids to saturated fatty acids decreases by 3.3 times. The changes in fatty acid composition of mitochondrial membranes are in correlation with changes in maximum rates of NAD-dependent substrates oxidation (the Pearson’s coefficient of correlation for С18 fatty acids is 0.7651, for С20 fatty acids – 0.963).

Fatty acid composition of mitochondrial membranes of pea seedlings under conditions of insufficient moistening and moderate cooling.

Fatty acid composition of mitochondrial membranes of pea seedlings under conditions of insufficient moistening and moderate cooling.

Effect of Osmolytes on Protein Dynamics in the Lactate Dehydrogenase-Catalyzed Reaction

Laser-induced temperature jump relaxation spectroscopy was used to probe the effect of osmolytes on the microscopic rate constants of the lactate dehydrogenase-catalyzed reaction. NADH fluorescence and absorption relaxation kinetics were measured for the lactate dehydrogenase (LDH) reaction system in the presence of varying amounts of trimethylamine N-oxide (TMAO), a protein-stabilizing osmolyte, or urea, a protein-destabilizing osmolyte. Trimethylamine N-oxide (TMAO) at a concentration of 1 M strongly increases the rate of hydride transfer, nearly nullifies its activation energy, and also slightly increases the enthalpy of hydride transfer. In 1 M urea, the hydride transfer enthalpy is almost nullified, but the activation energy of the step is not affected significantly. TMAO increases the preference of the closed conformation of the active site loop in the LDH·NAD(+)·lactate complex; urea decreases it. The loop opening rate in the LDH·NADH·pyruvate complex changes its temperature dependence to inverse Arrhenius with TMAO. In this complex, urea accelerates the loop motion, without changing the loop opening enthalpy. A strong, non-Arrhenius decrease in the pyruvate binding rate in the presence of TMAO offers a decrease in the fraction of the open loop, pyruvate binding competent form at higher temperatures. The pyruvate off rate is not affected by urea but decreases with TMAO. Thus, the osmolytes strongly affect the rates and thermodynamics of specific events along the LDH-catalyzed reaction: binding of substrates, loop closure, and the chemical event. Qualitatively, these results can be understood as an osmolyte-induced change in the energy landscape of the protein complexes, shifting the conformational nature of functional substates within the protein ensemble.

Fatty acid composition of mitochondrial membranes of pea germs exposed to insufficient watering and treated with organophosphorous plant growth regulator

The influence of insufficient watering and a melamine salt of bis(oxymethyl)-phosphonic acid (melaphen) on fatty acid composition of mitochondrial membrane of pea seedlings has been studied. It is shown that insufficient watering results in a 1.57-fold decrease in the ratio of unsaturated to saturated C18 fatty acids and in a 3.04-fold decrease in the ratio of unsaturated to saturated C20 fatty acids. The modification of fatty acid composition of mitochondrial membranes was associated with the alterations in their functional state: maximal rates of oxidation of NAD-dependent substrates and the rates of electron transport at the end of respiratory chain decreased. A preliminary treatment of the seeds with 3 × 10−9 M melaphen restored the maximal rates of oxidation of NAD-dependent substrates to the control values. We suggest that the alterations of the electron transport rates in respiratory chain in mitochondria are related to the physicochemical state of the membranes of these organelles, as the treatment with melaphen prevented the changes in fatty acid composition of the membranes of seedlings growing under the conditions of insufficient watering.

Mimicking the natural doping of migrant sandpipers in sedentary quails:effects of dietary n-3 fatty acids on muscle membranes and PPAR expression

Wild semipalmated sandpipers (Calidris pusilla) eat n-3 fatty acids to prime their muscles for long migrations. Sedentary bobwhite quails (Colinus virginianus) were used as a model to investigate the mechanisms for this natural doping. Our goal was to characterize the stimulating effects of n-3 eicosapentaenoic acid (EPA) and n-3 docosahexaenoic acid (DHA) on oxidative capacity. Mechanisms linked to changes in membrane composition and in gene expression for peroxisome proliferator-activated receptors (PPAR) were investigated. Dietary n-3 fatty acids stimulated the activities of oxidative enzymes by 58-90% (citrate synthase, cytochrome oxidase, carnitine palmitoyl transferase and hydroxyacyl dehydrogenase), and sedentary quails showed the same changes in membrane composition as sandpipers preparing for migration. EPA and DHA have the same doping effect. The substitution of n-6 arachidonic acid by n-3 EPA in membrane phospholipids plays an important role in mediating the metabolic effects of the diet, but results provide no significant support for the involvement of PPARs (as determined by changes in gene expression). The fatty acid composition of mitochondrial membranes and sarcoplasmic reticulum can be monitored by measuring total muscle phospholipids because all phospholipids are equally affected by diet. Only extreme regimes of endurance training can lead to increments in oxidative capacity matching those induced here by diet. As they prepare for long migrations, semipalmated sandpipers improve their physical fitness by eating! Choosing n-3 fatty acid doping over endurance training strikes us as a better strategy to boost aerobic capacity when rapid storage of energy is critical.

Effects of acclimation temperature on enzymatic capacities and mitochondrial membranes from the body wall of the earthworm Lumbricus terrestris

Many ectotherms respond to low temperature by adjusting capacities of enzymes from energy metabolism, restructuring membrane phospholipids and modulating membrane fluidity. Although much is known about the temperature biology of earthworms, it is not known to what extent earthworms employ compensatory changes in enzymatic capacities and membrane physical properties after exposure to low temperature. We examined activities of enzymes from glycolysis and central oxidative pathways as well as fluidity and phospholipid fatty acid composition of mitochondrial membranes prepared from the body wall of the temperate oligochaete Lumbricus terrestris after a one month acclimation to 5° and 15°C. No compensation occurs in central pathways of oxidative metabolism since activities of cytochrome- c oxidase and citrate synthase, when measured at a common temperature, are similar for 5°C and 15°C-acclimated animals. In contrast, activity of pyruvate kinase is elevated 1.3-fold after acclimation to 5°C. Mitochondrial membranes display inverse compensation with respect to temperature (membranes from 5°C animals are more ordered than membranes from 15°C animals). Our results, in combination with earlier reports, indicate that routine metabolism in L. terrestris may be maintained at reduced temperatures with little or no change in enzymatic capacities and inverse compensation of mitochondrial membranes.

Lipid lateral diffusion and local microviscosity in plant mitochondrial membranes with various length and unsaturation of fatty acids

Two main aspects of the lipid dynamics, local microviscosity and lateral diffusion, were investigated in intact plant mitochondria isolated from different tissues exhibiting large differences in their fatty acids in terms of unsaturation (amount of linoleic and linolenic acids) or length of the hydrocarbon chains. In addition, the same parameters were determined in the outer and inner membranes isolated from cauliflower mitochondria, which differed not only in the fatty acid composition but also by the lipid-to-protein ratio. In intact mitochondria, local microviscosity assayed with anthroyloxy-fatty acids exhibited a transverse gradient from the surface to the center of the bilayer, which was mainly affected by the unsaturation index and the content in linoleic or linolenic acids. In contrast, lipid lateral diffusion increased as the content in linolenic or palmitic acids increased, but was not directly correlated to the unsaturation index. Interestingly, local microviscosity at the membrane surface was higher in the outer membrane than in the inner membrane, whereas no significant difference was found in lipid lateral diffusion. These results indicate that the influence of the fatty acid composition of mitochondrial membranes on the dynamics of the phospholipid bilayer depends on the type of movement considered and suggest that other parameters, such as the protein content of the bilayer, also affect membrane fluidity.

Lipid lateral diffusion and local microviscosity in plant mitochondrial membranes with various length and unsaturation of fatty acids

Two main aspects of the lipid dynamics, local microviscosity and lateral diffusion, were investigated in intact plant mitochondria isolated from different tissues exhibiting large differences in their fatty acids in terms of unsaturation (amount of linoleic and linolenic acids) or length of the hydrocarbon chains. In addition, the same parameters were determined in the outer and inner membranes isolated from cauliflower mitochondria, which differed not only in the fatty acid composition but also by the lipid-to-protein ratio. In intact mitochondria, local microviscosity assayed with anthroyloxy-fatty acids exhibited a transverse gradient from the surface to the center of the bilayer, which was mainly affected by the unsaturation index and the content in linoleic or linolenic acids. In contrast, lipid lateral diffusion increased as the content in linolenic or palmitic acids increased, but was not directly correlated to the unsaturation index. Interestingly, local microviscosity at the membrane surface was higher in the outer membrane than in the inner membrane, whereas no significant difference was found in lipid lateral diffusion. These results indicate that the influence of the fatty acid composition of mitochondrial membranes on the dynamics of the phospholipid bilayer depends on the type of movement considered and suggest that other parameters, such as the protein content of the bilayer, also affect membrane fluidity.

Modulation of cardiac mitochondrial membrane fluidity by age and calorie intake

The aim of the present study was to determine the effects of dietary restriction (DR) on the age-related changes in membrane fluidity, fatty acid composition and free radical damage of mitochondrial membranes obtained from the rat left ventricle. Mitochondrial membrane preparations were obtained from the left ventricles of 6- and 24-month-old, male, Fischer 344 rats that were allowed to eat throughout their life either ad lib (Group A) or only 60% of the amount consumed by the ad lib fed group (Group B). Our results show that the membrane fluidity of the 24 month Group A hearts was less than that of the 6 month group A hearts. No differences in membrane fluidity were observed between the 6 and 24 month DR groups. The fatty acid composition of the mitochondrial membranes of the two ad lib fed groups differed: the long-chain polyunsaturated 22:4 fatty acid was higher in the older group, although linoleic acid (18:2) was lower. DR eliminated the differences. No statistically significant difference in the overall polyunsaturated fatty acid content was noted. However, the peroxidizability index was higher in the membranes of the 24 month Group A hearts but not in the 24 month Group B hearts. Finally, the degree of lipid damage, as assessed in vitro by the induced production of reactive oxygen species, was elevated in the 24 month Group A hearts. No difference was observed between the young and old DR groups. Considered together, these results suggest that DR maintains the integrity of the cardiac mitochondrial membrane fluidity by minimizing membrane damage through modulation of membrane fatty acid profile.

Remodeling of phospholipid fatty acids in mitochondrial membranes of estivating snails.

The effects of estivation on the phospholipid-specific fatty acid composition of mitochondrial membranes in the hepatopancreas of the terrestrial snail Cepaea nemoralis were investigated. The fatty acid composition of all phospholipids was significantly altered in snails estivating for 6 wk, indicating that substantial remodeling occurs. The most profound changes occurred in cardiolipin (CL). CL of estivating snails was 13-fold more saturated, contained 9-fold more monoenes, and had 45% fewer polyenes than in active snails. These differences were due, in part, to a reduction in linoleic acid (1 8:2n-6) content of CL from estivators. As in mammals, CL of active snails appears to preferentially incorporate 18:2n-6, which accounts for 60% of the acyl chains in this phospholipid. This proportion was reduced by 50% in estivators. Changes in the fatty acyl content of other phospholipids of estivating snails included increased monoenes in phosphatidylethanolamine (PE) and phosphatidylinositol, reduced ratios of n-3/n-6 polyenes in PE and phosphatidylcholine (PC), and an increased n-3/n-6 ratio in phosphatidylserine (PS). Arachidonic acid (20:4n-6) levels were reduced in PS but increased in CL and PC. Taken together, these alterations to fatty acid composition are consistent with decreased biological activity of membrane-related processes which occur in conjunction with the reduction of mitochondrial aerobic metabolism observed during estivation.

Lipid peroxidation of mitochondrial membrane induced by D 1: an organic solvent extractable component isolated from a crude extract of burn eschar

D 1, an organic solvent extractable component of an extract from burn eschar was characterized and the mechanism of its inhibitory effect on mitochondrial respiratory functions was investigated. Using silicic acid column chromatography, it was found that D 1 consisted of two parts: a toxic simple lipid and a non-toxic complex lipid. Six subunits were obtained by further silicic acid column chromatography, among them, the no. 4 and no. 6 were toxic. Infrared spectrometric studies showed that no. 4 consisted of esters, while no. 6 were peroxides. D 1 also contained large amounts of malonaldehyde (MDA) and lipid hydroperoxides (ROOH). Vitamin E was found to prevent the inhibitory action of D 1 on mitochondrial function and to reduce the amount of MDA produced. However, if vitamin E was introduced after the addition of D 1, the inhibition could not be prevented, although there was still a reduction in MDA production; therefore, MDA per se was probably not the cuuse of the inhibition. D 1 induced ROOH formation in mitochondrial membranes. Cumene hydroperoxide, an organic hydroperoxide, was capable of inhibiting the mitochondrial function. This inhibitor action was blocked by vitamin E. It is speculated that ROOH in D 1 is probably the element that inhibits mitochondrial function. That D 1 caused lipid peroxidation of membrane lipid was also proved by analysing the fatty acid composition of mitochondrial membranes before and after treatment with D 1. It was found that the amount of polyunsaturated fatty acids decreased and that of saturated fatty acids increased after incubation with D 1, a direct proof that lipid peroxidation has occurred. Lipid peroxidation of the membrane lipid was the result of the action of oxygen free radicals. This process was best shown by a chemilumirtescence study. In this experiment, D 1 induced chemiluminescence which was dose-dependently related to the amount of D 1 used. This was probably the most direct proof that D 1 caused lipid peroxidation of membrane lipid resulting in damage of the mitochondria. Copyright