Age-dependent changes in glutamate oxidation by non-synaptic and synaptic mitochondria from rat brain

Traumatic brain injury induces region-specific glutamate metabolism changes as measured by multiple mass spectrometry methods

The release of excess glutamate following traumatic brain injury (TBI) results in glutamate excitotoxicity and metabolic energy failure. Endogenous mechanisms for reducing glutamate concentration in the brain parenchyma following TBI are poorly understood. Using multiple mass spectrometry approaches, we examined TBI-induced changes to glutamate metabolism. We present evidence that glutamate concentration can be reduced by glutamate oxidation via a "truncated" tricarboxylic acid cycle coupled to the urea cycle. This process reduces glutamate levels, generates carbon for energy metabolism, leads to citrulline accumulation, and produces nitric oxide. Several key metabolites are identified by metabolomics in support of this mechanism and the locations of these metabolites in the injured hemisphere are demonstrated by MALDI-MS imaging. The results of this study establish the advantages of multiple mass spectrometry approaches and provide insights into glutamate metabolism following TBI that could lead to improved treatment approaches.

Proton magnetic resonance spectroscopy of brain metabolic shifts induced by acute administration of 2-deoxy-d-glucose and lipopolysaccharides

In vivo proton magnetic resonance spectroscopy ((1) H MRS) of outbred stock ICR male mice (originating from the Institute of Cancer Research) was used to study the brain (hippocampus) metabolic response to the pro-inflammatory stimulus and to the acute deficiency of the available energy, which was confirmed by measuring the maximum oxygen consumption. Inhibition of glycolysis by means of an injection with 2-deoxy-d-glucose (2DG) reduced the levels of gamma-aminobutyric acid (GABA, p < 0.05, in comparison with control, least significant difference (LSD) test), N-acetylaspartate (NAA, p < 0.05, LSD test) and choline compounds, and at the same time increased the levels of glutamate and glutamine. An opposite effect was found after injection with bacterial lipopolysaccharide (LPS) - a very common pro-inflammatory inducer. An increase in the amounts of GABA, NAA and choline compounds in the brain occurred in mice treated with LPS. Different metabolic responses to the energy deficiency and the pro-inflammatory stimuli can explain the contradictory results of the brain (1) H MRS studies under neurodegenerative pathology, which is accompanied by both mitochondrial dysfunction and inflammation. The prevalence of the excitatory metabolites such as glutamate and glutamine in 2DG treated mice is in good agreement with excitation observed during temporary reduction of the available energy under acute hypoxia or starvation. In turn, LPS, as an inducer of the sickness behavior, which was manifested as depression, sleepiness, loss of appetite etc., shifts the brain metabolic pattern toward the prevalence of the inhibitory neurotransmitter GABA.

Age-related changes in mitochondrial respiration and oxidative damage in the cerebral cortex of the Fischer 344 rat

This study probed possible age-related changes in mitochondrial bioenergetics in naïve Fischer 344 rats. Synaptic and extrasynaptic mitochondria were isolated from the cortex of one hemisphere of young (3-5 months), middle (12-14 months), or aged (22-24 months) rats. Respiration parameters were obtained using a Clarke-type electrode. Aged rats displayed no significant alterations in respiration, indicating mitochondria must be more resilient to the aging process than previously thought. Synaptic mitochondria displayed lower respiration capacities than the extrasynaptic fraction. Aged F344 rats appear capable of normal electron transport chain function without declines in ability to produce ATP. Markers of cortical oxidative damage (3-nitrotyrosine [3-NT], 4-hydroxynonenal [4-HNE], and protein carbonyls [PC]) were collected from the post-mitochondrial supernatant (PMS) from the contralateral hemisphere, and from mitochondrial samples following respiration analysis. Age-related increases in PC and 3-NT levels were found in synaptic mitochondria, whereas significant extrasynaptic elevations were only found in middle aged rats. These findings support an age-related increase in oxidative damage in the cortex, while proposing the two fractions of mitochondria are differentially affected by the aging process. Levels of oxidative damage that accumulates in the cortex with age does not appear to significantly impair cortical mitochondrial respiration of F344 rats.

Treatment with dehydroepiandrosterone (DHEA) stimulates oxidative energy metabolism in the cerebral mitochondria

The content of the neurosteroids, dehydroepiandrosterone (DHEA) in the brain decreases with aging. Also the oxidative energy metabolism is known to decrease with aging. Hence we examined the effects of treatment with DHEA (0.2 or 1.0 mg/kg body weight for 7 days) on oxidative energy metabolism in brain mitochondria from old and young adult rats. State 3 respiration rates in brain mitochondria from old animals were considerably lower than those in young adults. Treatment with DHEA stimulated state 3 and state 4 respiration rates in both the groups of the animals in a dose-dependent manner. In the old rats following DHEA treatment, the state 3 respiration rates became comparable to or increased beyond those of untreated young adults. In contrast to the old rats, stimulatory effect of DHEA treatment was of greater magnitude in the young adults. However, at higher dose (1.0 mg) the effect declined. Cytochrome aa3 content in the brain mitochondria from old rats was significantly low but the content of cytochrome b was unchanged while the content of cytochromes c+c1 had increased. Treatment with DHEA increased the content of cytochrome aa3 and b in old as well as in young adult animals. Higher dose of DHEA (1.0 mg) had adverse effect on the content of cytochrome c+c1. DHEA treatment stimulated ATPase activity in a dose-dependent manner in young adult rats whereas in the old rats the effect on ATPase activity was marginal. Dehydrogenases activities were somewhat lower in the old rats. DHEA treatment stimulated mitochondrial dehydrogenases activities in both the groups. Results of our studies suggest that judicious use of DHEA treatment can improve oxidative energy metabolism parameters in brain mitochondria from young adult as well as old rats.

Dehydroepiandrosterone (DHEA) treatment stimulates oxidative energy metabolism in the cerebral mitochondria from developing rats

Effects of treatment with dehydroepiandrosterone (DHEA) (0.2 or 1.0mg/kg body weight for 7 days) on oxidative energy metabolism in cerebral mitochondria from developing and young adult rats were examined. Treatment with DHEA did not change the body weight of developing rats but resulted in increase in the brain weight in 5 week group. In young adult rats the body weight increased following treatment with 1.0mg DHEA. State 3 and state 4 respiration rates with all the substrates increased following DHEA treatment, the effect being more pronounced in the developing rats. State 4 respiration rates were stimulated to variable extents. Contents of cytochromes aa(3) and b increased following DHEA treatment and once again the effect was more pronounced in the developing rats. DHEA treatment marginally changed the content of cytochromes c+c(1). In the developing rats the ATPase activity and the levels of dehydrogenases increased significantly by DHEA treatment. Results of our studies have shown that treatment with exogenous DHEA accelerates the process of maturation of cerebral mitochondria thus emphasizing the role of DHEA in brain development in postnatal life.

Maintenance of tricarboxylic acid cycle kinetics in Brown-Norway Fischer 344 rats may translate to longevity

Glucose metabolism and tricarboxylic acid cycle (TCA) kinetics have been shown to decline in brain with age in various animal species. This study examined TCA cycle kinetics and age in Brown-Norway Fischer 344 rats. Using [1-(13)C]glucose infused over 10, 30, 60 or 100 min, and following the label through the TCA cycle using (1)H¿(13)C¿ spin-echo difference magnetic resonance spectroscopy, groups of 2 (n=18), 12 (n=16), and 24 (n=16) month old rats were evaluated. Unexpectedly, TCA cycle kinetics did not change with age. Observed decreases in glutamate, glutamine and N-acetyl aspartate levels are consistent with an age-related decrease in neuronal numbers. The possible link between this observation and increased longevity, together with a decreased incidence of neoplasia in the Brown-Norway Fischer 344 rat is discussed.

Age-dependent changes in some aspects of glutamate metabolism in the brain of the teleost, Channa punctatus. I. Ammonia and glutamine contents and glutamate dehydrogenase activity

Age related changes in some aspects of glutamate metabolism were followed in the brain of a short lived species of tropical murrel, Channa punctatus. Both ammonia and glutamine contents of brain increased with advancing age of the murrel. The glutamate dehydrogenase activity of brain increased during maturation phase (year classes 0(+)-3+) followed by a decline in senescence phase (year classes 3(+)-6+). The pattern of age changes in glutamate metabolism in this species of fish shows similarity with the observations made in a majority of mammalian species, thereby suggesting a commonality in a basic metabolic mechanism during aging process in the central nervous system of vertebrates.

Effect of thermal inactivation and ATP on age related changes in hepatic glutamate dehydrogenase activity of male garden lizard

The total glutamate dehydrogenase (GDH) activity of the liver of the male garden lizard did not change during maturation (young to middle-aged) but showed a decline in later phase of the life span (middle-aged to old). On the other hand, the heat stable GDH activity increase during maturation and declined thereafter. The degree of thermal inactivation of the total GDH activity at 45 degrees +/- 1 degree C was not age-dependent. ATP stimulation of total GDH activity was about three times higher in old than in middle-aged lizards.

Cardiolipins and biomembrane function

Evidence is discussed for roles of cardiolipins in oxidative phosphorylation mechanisms that regulate State 4 respiration by returning ejected protons across and over bacterial and mitochondrial membrane phospholipids, and that regulate State 3 respiration through the relative contributions of proteins that transport protons, electrons and/or metabolites. The barrier properties of phospholipid bilayers support and regulate the slow proton leak that is the basis for State 4 respiration. Proton permeability is in the range 10(-3)-10(-4) cm s-1 in mitochondria and in protein-free membranes formed from extracted mitochondrial phospholipids or from stable synthetic phosphatidylcholines or phosphatidylethanolamines. The roles of cardiolipins in proton conductance in model phospholipid membrane systems need to be assessed in view of new findings by Hübner et al. [313]: saturated cardiolipins form bilayers whilst natural highly unsaturated cardiolipins form nonlamellar phases. Mitochondrial cardiolipins apparently participate in bilayers formed by phosphatidylcholines and phosphatidylethanolamines. It is not yet clear if cardiolipins themselves conduct protons back across the membrane according to their degree of fatty acyl saturation, and/or modulate proton conductance by phosphatidylcholines and phosphatidylethanolamines. Mitochondrial cardiolipins, especially those with high 18:2 acyl contents, strongly bind many carrier and enzyme proteins that are involved in oxidative phosphorylation, some of which contribute to regulation of State 3 respiration. The role of cardiolipins in biomembrane protein function has been examined by measuring retained phospholipids and phospholipid binding in purified proteins, and by reconstituting delipidated proteins. The reconstitution criterion for the significance of cardiolipin-protein interactions has been catalytical activity; proton-pumping and multiprotein interactions have yet to be correlated. Some proteins, e.g., cytochrome c oxidase are catalytically active when dimyristoylphosphatidylcholine replaces retained cardiolipins. Cardiolipin-protein interactions orient membrane proteins, matrix proteins, and on the outerface receptors, enzymes, and some leader peptides for import; activate enzymes or keep them inactive unless the inner membrane is disrupted; and modulate formation of nonbilayer HII-phases. The capacity of the proton-exchanging uncoupling protein to accelerate thermogenic respiration in brown adipose tissue mitochondria of cold-adapted animals is not apparently affected by the increased cardiolipin unsaturation; this protein seems to take over the protonophoric role of cardiolipins in other mitochondria. Many in vivo influences that affect proton leakage and carrier rates selectively alter cardiolipins in amount per mitochondrial phospholipids, in fatty acyl composition and perhaps in sidedness; other mitochondrial membrane phospholipids respond less or not at all.(ABSTRACT TRUNCATED AT 400 WORDS)

Age-dependent changes in rat brain mitochondria of synaptic and non-synaptic origins

Synaptic and non-synaptic mitochondria were isolated from the brains of 3- 12-and 28-30-month-old female Fisher 344 rats. Total oxygen consumption and oxygen consumption due to mitochondrial respiration decreases 83% with increasing age in synaptic mitochondria using malate plus glutamate as substrate, but only 33% in non-synaptic mitochondria; succinate-driven activity is not affected. Succinate-driven superoxide generation decreases over 90% in both fractions; malate plus glutamate-driven superoxide generation decreases 50% in synaptic mitochondria only. The amount of c- and a-type cytochromes decreases approximately 50% in synaptic mitochondria. The absorbance wavelength maximum of cytochrome b decreases 2.6 nm in synaptic mitochondria from senescent brains but only 1.6 nm in non-synaptic mitochondria.

Selective alteration of mouse brain neurotransmitter release with age

The release of acetylcholine (ACh), glutamate (GLU) and dopamine (DA) from various brain regions was investigated in young (3 month) and old (30 month) Balb/c mice. Aging increased the basal release of GLU (77%) and DA (29%) in striatum and GLU in hippocampus (94%); the concentrations of these neurotransmitters in the media after K+ stimulation were unaltered by aging. Although the basal release of ACh was not altered by age, K+-stimulated ACh release was reduced in striatum. The age-related increases in basal GLU and DA release may be important in the pathophysiology of cell death during aging.

Age-related changes of glucose metabolism in rat cerebral cortex with reference to glucose-derived amino acids

The parietal cortical slices obtained from 8 week-old (young) and 78 week-old (middle-aged) male Wistar rats were incubated with D-[U-14C]glucose in oxygen-saturated Gey's balanced salt solution. Subsequently, the radioactivities of liberated CO2 and glucose-derived amino acids (alanine, aspartate, GABA, glutamate and glutamine) obtained from the slices were measured. In the middle-aged rats as compared to the young rats, the amount of radioactivity of CO2 (P less than 0.01) and glutamate (P less than 0.05) showed a significant reduction with glutamine unchanged, while that of alanine (P less than 0.01), aspartate (P less than 0.05) and GABA (P less than 0.05) increased significantly. The results indicate that with advancing age the overall glucose oxidation in the cerebral cortex declines but the metabolic pathway to form amino acids is not uniformly suppressed. Therefore, the above characteristic glucose metabolism could be related to the development of heterogeneous enzyme activities associated with aging in the brain.

Impairment of glutamate uptake and absence of alterations in the energy-transducing ability of old rat brain mitochondria

The proton electrochemical gradient has been measured in old brain mitochondria isolated from 2- or 24-month-old rats with the use of different respiratory substrates. With succinate as substrate, neither the respiratory rate, membrane potential or delta pH varied with age, indicating that the dielectric strength of the mitochondrial membrane was unaltered in old animals. The ohmic behavior of the membrane was tested in experiments in which the respiratory rate was partially inhibited by malonate, and was found to be unchanged with age. When glutamate plus malate were used as substrates, the respiratory rate was substantially reduced, and a drastic decrease in glutamate uptake was observed in old rat brain mitochondria.

Effects of procaine on the oxidative phosphorylation of brain mitochondria from senescent rats

Senescence affects cerebral metabolic functions. Various drugs have been tested to counteract the effects of aging on the brain. In this paper, we studied the influence of treatment using procaine, 1 mg per 100 g body weight, injected over a period of 3 days, to both young and old rats, on the phosphorylative oxidation properties of cerebral mitochondria. Respiratory activity decreased significantly in the brain of old rats. This reduction of oxygen consumption measured in the presence of glutamate, reached 31% in state 4, 25% in state 3 and, in the presence of succinate, 23% in state 4 without significant changes in state 3. The injection of procaine into young rats induced a significant increase of oxygen consumption rate with both glutamate and succinate as substrates. The same treatment administered to old rats was followed by a rise in respiratory activity, with values close to those observed in young control rats. Although the mechanism of action of procaine is not yet clear, there is some evidence that it interacts with membrane phospholipid sites. Therefore, it may be concluded that procaine facilitates oxygen transport towards the mitochondrial matrix by modifying the membrane structure in both old and young rats, although, in the latter case, this increase is not intended to improve the energetic properties of the mitochondrion.

Influence of pathological concentrations of ammonia on metabolic fate of 14C-labeled glutamate in astrocytes in primary cultures

Rates of glutamine formation and of carbon dioxide production (as an indication of oxidative deamination of glutamate) were determined in primary cultures of astrocytes exposed to 50 microM labeled glutamate in the absence or presence of added ammonia (0.1-3 mM). Glutamine formation (1.7 nmol/min/mg protein) was unaffected by all concentrations of added ammonia. This probably reflects the presence of a low content of ammonia (0.1-0.2 mM), originating from degradation of glutamine, in the cells even in the absence of added ammonia, and it shows that pathophysiological concentrations of ammonia do not increase the formation of glutamine from exogenous glutamate. The carbon dioxide production rate was 5.9 nmol/min/mg protein, i.e., three to four times higher than the rate of glutamine formation. It was significantly reduced (to 3.5 nmol/min/mg protein) in the presence of 1 mM or more of ammonia. This is in keeping with suggestions by others that toxic levels of ammonia affect oxidative metabolism.

Age-dependent changes in pyruvate uptake by nonsynaptic and synaptic mitochondria from rat brain

Changes in the uptake of pyruvate by nonsynaptic and synaptic mitochondria from brains of young adult and old rats were investigated. An age-dependent decrease in State 3 respiration in the presence of pyruvate plus malate as substrate was observed in cerebral mitochondrial populations but not in liver mitochondria. Addition of exogenous cytochrome c to nonsynaptic and synaptic mitochondria enhanced the rate of State 3 respiration but the age-dependent decrease in State 3 respiration persisted in both types of mitochondria. A decrease in the uptake of pyruvate as measured by the inhibitor-stop and rapid centrifugation techniques was observed in both nonsynaptic and synaptic mitochondria from 24-month-old rats compared to 3-month-old rats. The results suggest that the decrease in the uptake of pyruvate may be one of the factors responsible for the observed reduction in State 3 respiration in the presence of pyruvate plus malate by both nonsynaptic and synaptic mitochondria from brains of senescent rats compared to young adults.

Aging decreases oxidative metabolism and the release and synthesis of acetylcholine

Acetylcholine (ACh) synthesis in vivo is known to decrease during the aging process (senescence). To elucidate the molecular mechanism(s) of this age-related decline, we studied brain slices from 3-, 10-, and 30-month-old mice of two strains (C57B1 and Balb/c). In low K+ media, oxidative metabolism as measured by 14CO2 production decreased with aging from 100% (3 months) to 85% (10 months) or 71% (30 months) whether [U-14C]glucose, [3,4-14C]glucose, or [1-14C]pyruvate was the substrate. In the aged brain (30 months) the increase in 14CO2 production with K+ stimulation was about twofold higher than in the young brain (3 months). Thus, in high K+ media, only slight decreases (less than 10%) in oxidative metabolism occurred with aging. Changes in ACh synthesis paralleled the decreases in 14CO2 production. Synthesis of [14C]ACh from [U-14C]glucose in low K+ media declined from 100% (3 months) to 85% (10 months) or 66% (30 months), while in high K+ media only slight decreases (less than 10.5%) occurred with aging. The Ca2+-dependent, K+-stimulated release of [14C]ACh declined from 100% (3 months) to 58% (10 months) or 25% (30 months). Only the decrease in he release of ACh declined to the same extent as the reduced in vivo synthesis of ACh with aging. The results suggest that decreases in oxidative metabolism, ACh synthesis, and in the release of ACh contribute to a reduction in cholinergic function in senescent brain.

Neurotransmitter and carbohydrate metabolism during aging and mild hypoxia

Alterations in the metabolism of the glucose derived neurotransmitters may underlie some of the deficits in brain function that can accompany aging. We examined the whole brain syntheses of acetylcholine (ACh), alanine, aspartate, glutamate, gamma-aminobutyrate (GABA), glutamine and serine in two strains (C57BL and BALB/c) of aged mice (3, 10 and 30 months). ACh synthesis in C57BL and BALB/c mice declined 41 and 44% at 10 months and 64 and 75% by 30 months. Incorporation of [U-14C]glucose into amino acids generally decreased with aging, but it was not depressed as much as ACh formation. The only significant reductions in the amino acids in the 30 month old mice of both strains were in the syntheses of GABA (46 and 32%) and glutamine (44 and 55%). These changes may make the aged brain more vulnerable to metabolic insults, since mild anemic hypoxia decreased the syntheses of all the neurotransmitters at all ages even further. ACh synthesis in hypoxic 30 month old mice was only 9-11% of the 3 month old nonhypoxic mice, whereas amino acid formation ranged from 18-55% of the 3 month old nonhypoxic mice. Carbohydrate metabolism and its response to metabolic insults was also altered by age in both strains. The 30 month old mice had higher brain lactate concentrations than the 3 month old mice. The combination of hypoxia and aging further depressed oxidative metabolism, since a greater increase in brain lactates occurred in the aged hypoxilism and its response to metabolic insults was also altered by age in both strains. The 30 month old mice had higher brain lactate concentrations than the 3 month old mice. The combination of hypoxia and aging further depressed oxidative metabolism, since a greater increase in brain lactates occurred in the aged hypoxilism and its response to metabolic insults was also altered by age in both strains. The 30 month old mice had higher brain lactate concentrations than the 3 month old mice. The combination of hypoxia and aging further depressed oxidative metabolism, since a greater increase in brain lactates occurred in the aged hypoxic mice than in young hypoxic mice. Thus, aging may reduce the ability of the brain to adapt to metabolic insults.