Substrate Competition Studies Demonstrate Oxidative Metabolism of Glucose,Glutamate, Glutamine,Lactate and 3-Hydroxybutyrate in Cortical Astrocytes from Rat Brain

Neurochemical Research - It is well established that astrocytes can utilize many substrates to support oxidative energy metabolism; however, use of energy substrates in the presence of other...     

Energy uncoupling inhibits aerobic granulation

Although aerobic granulation has been intensively studied, the possible mechanism of this cell-to-cell self-immobilization phenomenon still remains unclear. Aerobic granulation in the absence and presence of a chemical uncoupler, 3,3′,4′,5-tetrachlorosalicylanilide (TCS), which can dissipate the proton gradient and further disrupt ATP synthesis, was investigated. Upon exposure to TCS, precultivated mature aerobic granules underwent disintegration, indicating that the stability and integrity of aerobic granules would be associated with microbial energy metabolism. It was also shown that the formation of aerobic granules in the presence of TCS was completely inhibited as compared with the control free of TCS. These results, for the first time, reveal that aerobic granulation is energy metabolism dependent, and possible reasons are also discussed.     

A new role of anandamide in human sperm: Focus on metabolism

The endocannabinoid system and the presence of CB1 receptor (CB1‐R) target of the anandamide were identified in human sperm, however the anandamide action in this context needs to be further elucidated. At this purpose we analyzed the effects of anandamide on human sperm capacitation and motility. Afterwards, we focused on lipid and glucose sperm metabolism and also investigated the interrelationship between anandamide and insulin secretion by sperm. By intracellular free Ca²⁺ content assay and proteins tyrosine phosphorylation, we evidenced that anandamide did not induce capacitation process and a negative effect was obtained on sperm motility. The blockage of CB1‐R by the specific antagonist SR141716 increased both capacitation and sperm motility suggesting an involvement of the CB1‐R in the acquisition of sperm fertilizing activity. The evaluation of the triglycerides content, lipase and acyl‐CoA dehydrogenase activities, suggest that anandamide exerts a lipogenetic effect on human sperm lipid metabolism. Concerning the glucose metabolism, anandamide increases GSK3 phosphorylation indicating that it is involved in the accumulation of energy substrates. G6PDH activity was not affected by anandamide. Interestingly, AEA is involved in insulin secretion by sperm. As insulin had been demonstrated to be an autocrine factor that triggers capacitation, the endocannabinoid might be inserted in the signaling cascade that induces this process. Altogether these findings highlight a pivotal involvement of the CB1‐R in the control of sperm energy homeostasis and propose a new site of action for endocannabinoids in the control of energy metabolism. J. Cell. Physiol. 221: 147–153, 2009. © 2009 Wiley‐Liss, Inc     

IDH knockdown alters foraging behavior in the termite Odontotermes formosanus in different social contexts

Foraging, as an energy-consuming behavior, is very important for colony survival in termites. How energy metabolism related to glucose decomposition and adenosine triphosphate (ATP) production influences foraging behavior in termites is still unclear. Here, we analyzed the change in energy metabolism in the whole organism and brain after silencing the key metabolic gene isocitrate dehydrogenase (IDH) and then investigated its impact on foraging behavior in the subterranean termite Odontotermes formosanus in different social contexts. The IDH gene exhibited higher expression in the abdomen and head of O. formosanus. The knockdown of IDH resulted in metabolic disorders in the whole organism. The dsIDH-injected workers showed significantly reduced walking activity but increased foraging success. Interestingly, IDH knockdown altered brain energy metabolism, resulting in a decline in ATP levels and an increase in IDH activity. Additionally, the social context affected brain energy metabolism and, thus, altered foraging behavior in O. formosanus. We found that the presence of predator ants increased the negative influence on the foraging behavior of dsIDH-injected workers, including a decrease in foraging success. However, an increase in the number of nestmate soldiers could provide social buffering to relieve the adverse effect of predator ants on worker foraging behavior. Our orthogonal experiments further verified that the role of the IDH gene as an inherent factor was dominant in manipulating termite foraging behavior compared with external social contexts, suggesting that energy metabolism, especially brain energy metabolism, plays a crucial role in regulating termite foraging behavior.     

The physiological function of nitrate reduction in Clostridium perfringens.

Fermentation-balance studies have been carried out on Clostridium perfringens grown in the presence and absence of nitrate in the medium. Nitrate is able to serve as an electron acceptor for these bacteria, permitting increased growth yields over those obtained in its absence. This increase is due to an increase in the proportion of metabolite molecules which can participate in substrate-level phosphorylation reactions when an inorganic acceptor is available. The nitrate reduction can be regarded as a primitive form of anaerobic respiration in these bacteria, since it is clearly coupled to their energy metabolism and is not assimilative in function. We believe that the existence of this kind of energy metabolism in these bacteria has significant evolutionary implications.     

Cardiac metabolism in the Myxinidae: physiological and phylogenetic considerations

Cardiac muscle hearts of Atlantic hagfish continuously function under hypoxic conditions that would lead to cardiac failure in most other vertebrates. Contractile performance of hagfish systemic hearts is resistant to anoxia and respiratory poisons but shows a significant decrement when carbohydrate catabolism is blocked by 0.5 mM iodoacetic acid. Enzyme activity profiles of hagfish ventricle reveal a robust capacity for glycolysis of carbohydrate in comparison to that for general aerobic metabolism and catabolism of alternate metabolic fuels. Isolated working hagfish ventricles preferentially oxidize radiolabeled glucose even when fatty acid fuels are present in the incubation medium. Work output of the isolated ventricular preparation is maintained only in the presence of exogenous glucose. The results indicate that energy metabolism of the hagfish myocardium is predominantly carbohydrate-based and that energy demand of the tissue can be sustained by anaerobic glycolysis during extended periods of extreme hypoxia. Cardiac metabolism of this primitive species is compared with that of hearts from higher vertebrates and an evolutionary hypothesis relating cardiac workload to preferred metabolic fuel is discussed.     

Myoglobin content and the activities of enzymes of energy metabolism in red and white fish hearts

Summary The myoglobin content of representative red and white coloured fish hearts was quantitated. It was confirmed that the macroscopic difference in appcarance is due to the presence or absence of myoglobin. Thereafter, the cytochrome c content as well as the maximal activities of key enzymes of energy metabolism were assessed in myoglobin-rich sea raven (Hemitripterus americanus) and myoglobin-poor ocean pout (Macrozoarces americanus) hearts. Both species are sluggish benthic dwellers that occur in similar habitats in the North Atlantic Ocean. The activities of enzymes associated with aerobic metabolism were similar in sea raven and ocean pout hearts, but far in excess of activities observed from white skeletal muscle. The two hearts also displayed comparable activities of enzymes associated with anaerobic energy metabolism. It therefore appears that the capacity to produce reducing equivalents for the electron transport system is similar in two selected fish hearts despite great differences in myoglobin content.     

Microglia-Specific Metabolic Changes in Neurodegeneration

The high energetic demand of the brain deems this organ rather sensitive to changes in energy supply. Therefore, even minor alterations in energy metabolism may underlie detrimental disturbances in brain function, contributing to the generation and progression of neurodegenerative diseases. Considerable evidence supports the key role of deficits in cerebral energy metabolism, particularly hypometabolism of glucose and mitochondrial dysfunction, in the pathophysiology of brain disorders. Major breakthroughs in the field of bioenergetics and neurodegeneration have been achieved through the use of in vitro and in vivo models of disease as well as sophisticated neuroimaging techniques in patients, yet these have been mainly focused on neuron and astrocyte function. Remarkably, the subcellular metabolic mechanisms linked to neurodegeneration that operate in other crucial brain cell types such as microglia have remain obscured, although they are beginning to be unraveled. Microglia, the brain-resident immune sentinels, perform a diverse range of functions that require a high-energy expenditure, namely, their role in brain development, maintenance of the neural environment, response to injury and infection, and activation of repair programs. Interestingly, another key mechanism underlying several neurodegenerative diseases is neuroinflammation, which can be associated with chronic microglia activation. Considering that many brain disorders are accompanied by changes in brain energy metabolism and sustained inflammation, and that energy metabolism has a strong influence on the inflammatory responses of microglia, the emerging significance of microglial energy metabolism in neurodegeneration is highlighted in this review.     

Compartmentalized neurotransmitter and amino acid synthesis in vivo studied by high field MRS

There is strong evidence that the brain can use multiple substrates for energy including glucose, lactate, ketone bodies, glutamate and glutamine. Competition studies show that certain substrates are preferentially used for energy by synaptic terminals even when other substrates are available. It has recently been shown that synaptosomes can use both glutamine and glutamate for energy and synthesis of amino acids; however, these substrates yield very different patterns of 13C-labelling of end products. These findings provide evidence of differential compartmentalisation of the metabolism of glutamate taken up from the extracellular milieu as compared to the glutamate produced from glutamine within synaptic terminals. This compartmentalisation is related to the specific role(s) of glutamate vs. glutamine in synaptic terminals as well as the metabolism of these amino acids in either partial or complete TCA cycles for energy. The presence of glucose, which provides a source of acetyl-CoA, can greatly modulate both the metabolic fate of other substrates and the pool size of amino acids such as glutamate and GABA. The differential localization of the enzymes glutamate dehydrogenase and aspartate aminotransferase contribute to this compartmentalisation as does the necessity that synaptic terminals balance their energy needs with the requirement to synthesize neurotransmitters.     

Proton motive force generation by citrolactic fermentation in Leuconostoc mesenteroides.

In Leuconostoc mesenteroides subsp. mesenteroides 19D, citrate is transported by a secondary citrate carrier (CitP). Previous studies of the kinetics and mechanism of CitP performed in membrane vesicles of L. mesenteroides showed that CitP catalyzes divalent citrate HCit2-/H+ symport, indicative of metabolic energy generation by citrate metabolism via a secondary mechanism (C. Marty-Teysset, J. S. Lolkema, P. Schmitt, C. Divies, and W. N. Konings, J. Biol. Chem. 270:25370-25376, 1995). This study also revealed an efficient exchange of citrate and D-lactate, a product of citrate/carbohydrate cometabolism, suggesting that under physiological conditions, CitP may function as a precursor/product exchanger rather than a symporter. In this paper, the energetic consequences of citrate metabolism were investigated in resting cells of L. mesenteroides. The generation of metabolic energy in the form of a pH gradient (delta pH) and a membrane potential (delta psi) by citrate metabolism was found to be largely dependent on cometabolism with glucose. Furthermore, in the presence of glucose, the rates of citrate utilization and of pyruvate and lactate production were strongly increased, indicating an enhancement of citrate metabolism by glucose metabolism. The rate of citrate metabolism under these conditions was slowed down by the presence of a membrane potential across the cytoplasmic membrane. The production of D-lactate inside the cell during cometabolism was shown to be responsible for the enhancement of the electrogenic uptake of citrate. Cells loaded with D-lactate generated a delta psi upon dilution in buffer containing citrate, and cells incubated with citrate built up a pH gradient upon addition of D-lactate. The results are consistent with an electrogenic citrate/D-lactate exchange generating in vivo metabolic energy in the form of a proton electrochemical gradient across the membrane. The generation of metabolic energy from citrate metabolism in L. mesenteroides may contribute significantly to the growth advantage observed during cometabolism of citrate and glucose.     

The role of glucose metabolism and insulin resistance in cardiac remodelling induced by cigarette smoke exposure

The aim of this study is to evaluate whether the alterations in glucose metabolism and insulin resistance are mechanisms presented in cardiac remodelling induced by the toxicity of cigarette smoke. Male Wistar rats were assigned to the control group (C; n = 12) and the cigarette smoke-exposed group (exposed to cigarette smoke over 2 months) (CS; n = 12). Transthoracic echocardiography, blood pressure assessment, serum biochemical analyses for catecholamines and cotinine, energy metabolism enzymes activities assay; HOMA index (homeostatic model assessment); immunohistochemistry; and Western blot for proteins involved in energy metabolism were performed. The CS group presented concentric hypertrophy, systolic and diastolic dysfunction, and higher oxidative stress. It was observed changes in energy metabolism, characterized by a higher HOMA index, lower concentration of GLUT4 (glucose transporter 4) and lower 3-hydroxyl-CoA dehydrogenase activity, suggesting the presence of insulin resistance. Yet, the cardiac glycogen was depleted, phosphofructokinase (PFK) and lactate dehydrogenase (LDH) increased, with normal pyruvate dehydrogenase (PDH) activity. The activity of citrate synthase, mitochondrial complexes and ATP synthase (adenosine triphosphate synthase) decreased and the expression of Sirtuin 1 (SIRT1) increased. In conclusion, exposure to cigarette smoke induces cardiac remodelling and dysfunction. The mitochondrial dysfunction and heart damage induced by cigarette smoke exposure are associated with insulin resistance and glucose metabolism changes.     

Workshop 4: Compartmentation of Neuronal Metabolism. Compartmentation of energy metabolism and amino acid synthesis in synaptosomes

There is strong evidence that the brain can use multiple substrates for energy including glucose, lactate, ketone bodies, glutamate and glutamine. Competition studies show that certain substrates are preferentially used for energy by synaptic terminals even when other substrates are available. It has recently been shown that synaptosomes can use both glutamine and glutamate for energy and synthesis of amino acids; however, these substrates yield very different patterns of 13C‐labelling of end products. These findings provide evidence of differential compartmentalisation of the metabolism of glutamate taken up from the extracellular milieu as compared to the glutamate produced from glutamine within synaptic terminals. This compartmentalisation is related to the specific role(s) of glutamate vs. glutamine in synaptic terminals as well as the metabolism of these amino acids in either partial or complete TCA cycles for energy. The presence of glucose, which provides a source of acetyl‐CoA, can greatly modulate both the metabolic fate of other substrates and the pool size of amino acids such as glutamate and GABA. The differential localization of the enzymes glutamate dehydrogenase and aspartate aminotransferase contribute to this compartmentalisation as does the necessity that synaptic terminals balance their energy needs with the requirement to synthesize neurotransmitters.     

Effect of phosphorylation on glycolysis in the cells of assimilating millet leaf tissues

The effect of phosphorylation on glycolysis reactions was studied in respect with the rate of 1-14C-glucose metabolization and the composition of synthesized labelled products in isolated cells of assimilating millet leave tissues incapable to reassimilation of respiratory CO2. Data on oxygen metabolism in mesophyll protoplasts and in cells of parenchymal facing of vascular bundle sheaths in the absence and in the presence of electron acceptors (3,5-dichlorophenolindophenol and methylviologen) show that they retain adenylate pool and energy charge characteristic of photosynthetizing tissues. The glycolysis rate decreased in illuminated cells, which did not remove carbon products from chloroplasts. Analysis of compounds produced from 1-14C-glucose exogenous ADP effect on their ration and the change of adenylate energy charge in the presence of methylviologen demonstrates that the acting factor is a decrease of Pi and ADP concentrations in cytoplasm because of their use chloroplast phosphorylation. It is suggested, that a short-cut chain of glycolysis reactions may take place in intact cells assimilating CO2 in photosynthesis, and the capacity of this chain is determined by the type of carbon metabolism and photorespiration mechanism.     

Cometabolism of Citrate and Glucose by Enterococcus faecium FAIR-E 198 in the Absence of Cellular Growth

Citrate metabolism by Enterococcus faecium FAIR-E 198, an isolate from Greek Feta cheese, was studied in modified MRS (mMRS) medium under different pH conditions and glucose and citrate concentrations. In the absence of glucose, this strain was able to metabolize citrate in a pH range from constant pH 5.0 to 7.0. At a constant pH 8.0, no citrate was metabolized, although growth took place. The main end products of citrate metabolism were acetate, formate, acetoin, and carbon dioxide, whereas ethanol and diacetyl were present in smaller amounts. In the presence of glucose, citrate was cometabolized, but it did not contribute to growth. Also, more acetate and less acetoin were formed compared to growth in mMRS medium and in the absence of glucose. Most of the citrate was consumed during the stationary phase, indicating that energy generated by citrate metabolism was used for maintenance. Experiments with cell-free fermented mMRS medium indicated that E. faecium FAIR-E 198 was able to metabolize another energy source present in the medium.     

Effects of NH4+ and K+ on the energy metabolism in Sp2/0-Ag14 myeloma cells

Potassium ions decrease the transport rate of ammonium ions into myeloma and hybridoma cells, one effect of the involved transport processes being an increased energy demand (Martinelle and Häggström, 1993; Martinelle et al., 1998b). Therefore, the effects of K+ and NH4+ on the energy metabolism of the murine myeloma cell line, Sp2/0-Ag14, were investigated. Addition of NH4Cl (10 mM) increased the metabolism via the alanine transaminase (alaTA) pathway, without increasing the consumption of glutamine. As judged by the alanine production, the energy formation from glutamine increased by 155%. The presence of elevated concentrations of KCl (10 mM) was positive, resulting in a decreased uptake of glutamine (45%), and an even larger suppression of ammonium ion formation (70%), while the same throughput via the alaTA pathway (and energy production from glutamine) was retained as in the control culture. However, the simultaneous presence of 10 mM K+ and 10 mM NH4+ was more inhibitory than NH4Cl alone; an effect that could not be ascribed to increased osmolarity. Although the culture with both K+ and NH4+ consumed 60% more glutamine than the culture with NH4+ alone, the energy generation from glutamine could not be increased further, due to the suppression of the glutamate dehydrogenase pathway. Furthermore, the data highlighted the importance of evaluating the metabolism via different energy yielding pathways, rather than solely considering the glutamine consumption for estimating energy formation from glutamine.     

Role of oxytocin in energy metabolism

The basic mechanisms that lead obesity are not fully understood; however, several peptides undoubtedly play a role in regulating body weight. Obesity, a highly complex metabolic disorder, involves central mechanisms that control food intake and energy expenditure. Previous studies have shown that central or peripheral oxytocin administration induces anorexia. Recently, in an apparent discrepancy, rodents that were deficient in oxytocin or the oxytocin receptor were shown to develop late-onset obesity without changing their total food intake, which indicates the physiological importance of oxytocin to body metabolism. Oxytocin is synthesized not only within magnocellular and parvocellular neurons but also in several organs, including the ovary, uterus, placenta, testis, thymus, kidney, heart, blood vessels, and skin. The presence of oxytocin receptors in neurons, the myometrium and myoepithelial cells is well recognized; however, this receptor has also been identified in other tissues, including the pancreas and adipose tissue. The oxytocin receptor is a typical class I G protein-coupled receptor that is primarily linked to phospholipase C-β via Gq proteins but can also be coupled to other G proteins, leading to different functional effects. In this review, we summarize the present knowledge of the effects of oxytocin on controlling energy metabolism, focusing primarily on the role of oxytocin on appetite regulation, thermoregulation, and metabolic homeostasis.     

Effects of L-glutamate, D-aspartate, and monensin on glycolytic and oxidative glucose metabolism in mouse astrocyte cultures: further evidence that glutamate uptake is metabolically driven by oxidative metabolism

The hypothesis was tested that oxidative metabolism, mainly fueled by glutamate itself, provides the energy for active, Na(+),K(+)-ATPase-catalyzed Na(+) extrusion following glutamate uptake in conjunction with Na(+). This hypothesis was supported by the following observations: (i) glutamate had either no effect or caused a slight reduction in glycolytic rate, measured as deoxyglucose phosphorylation; (ii) D-aspartate, which is accumulated by the L-glutamate carrier, but cannot be metabolized by the cells, caused an increase in glycolytic rate; (iii) monensin which, like D-aspartate, stimulates the intracellular, Na(+)-activated site of the Na, K-ATPase and thus energy metabolism, but provides no metabolic substrate, stimulated both glycolysis and glucose oxidation; and (iv) oxidation of glucose was potently inhibited by glutamate, although glutamate is known to stimulate oxygen consumption in primary cultures of astrocytes, a combination showing that oxidation of a non-glucose substrate is increased in the presence of glutamate. These findings should be considered in attempts to understand metabolic interactions between neurons and astrocytes and regulation of energy metabolism in brain.     

Biochemistry and Evolution of Anaerobic Energy Metabolism in Eukaryotes

Summary: Major insights into the phylogenetic distribution, biochemistry, and evolutionary significance of organelles involved in ATP synthesis (energy metabolism) in eukaryotes that thrive in anaerobic environments for all or part of their life cycles have accrued in recent years. All known eukaryotic groups possess an organelle of mitochondrial origin, mapping the origin of mitochondria to the eukaryotic common ancestor, and genome sequence data are rapidly accumulating for eukaryotes that possess anaerobic mitochondria, hydrogenosomes, or mitosomes. Here we review the available biochemical data on the enzymes and pathways that eukaryotes use in anaerobic energy metabolism and summarize the metabolic end products that they generate in their anaerobic habitats, focusing on the biochemical roles that their mitochondria play in anaerobic ATP synthesis. We present metabolic maps of compartmentalized energy metabolism for 16 well-studied species. There are currently no enzymes of core anaerobic energy metabolism that are specific to any of the six eukaryotic supergroup lineages; genes present in one supergroup are also found in at least one other supergroup. The gene distribution across lineages thus reflects the presence of anaerobic energy metabolism in the eukaryote common ancestor and differential loss during the specialization of some lineages to oxic niches, just as oxphos capabilities have been differentially lost in specialization to anoxic niches and the parasitic life-style. Some facultative anaerobes have retained both aerobic and anaerobic pathways. Diversified eukaryotic lineages have retained the same enzymes of anaerobic ATP synthesis, in line with geochemical data indicating low environmental oxygen levels while eukaryotes arose and diversified.     

Urban Metabolism and the Energy Stored in Cities

Using the city of Toronto as a case study, this article examines impacts of energy stocks and flexible demand in the urban metabolism on the resilience of the city, including discussion of directions for further study of the resiliency of the urban metabolism. An important element developed is the nominal residence time of the energy stocks. This value defines how long an energy stock lasts under typical patterns of energy use. The findings suggest that the residence times of many sources of energy overcome vulnerability when energy supply shocks last on the order of hours or a few days, but that the measure is limited to assessing only certain types of commonly used energy sources in aggregate terms. Discussion is included on the uncertainty of this measure and on the metabolic and resiliency implications of new technologies intended to reduce energy use and improve sustainability of cities and the use of the urban metabolism as a means of comparison. The methodology employed highlights how waste energy could be used to increase the resiliency of the city's water supply, but also how the study of the urban metabolism would benefit from a more disaggregate form in the study of sustainable and resilient cities.     

In vivo 31P and 13C nuclear magnetic resonance studies of acetate metabolism in Chromatium vinosum

31P and 13C nuclear magnetic resonance (NMR) experiments were performed on suspensions of the phototrophic bacterium Chromatium vinosum incubated anaerobically in the dark. 31P NMR spectra revealed that during prolonged dark incubation high ATP levels are maintained. This phenomenon was independent of the presence of the energy reserves polyglucose and polyphosphate. 13C NMR experiments revealed that the amino acids glutamate, aspartate, and alanine are the major products of acetate incorporation in the dark. Apart from these amino acids, poly-beta-hydroxybutyrate was also formed. Acetate metabolism was markedly stimulated by the presence of polyglucose. The specific 13C activity of glutamate C-2 was approximately 50% that of glutamate C-4. The idea is discussed that this difference is the consequence of the maintenance of redox balance during entry of acetate into cell metabolism.