Restricted permeability of rat liver for glutamate and succinate

Why succinate? Physiological regulation by a mitochondrial coenzyme Q sentinel

Metabolites once considered solely in catabolism or anabolism turn out to have key regulatory functions. Among these, the citric acid cycle intermediate succinate stands out owing to its multiple roles in disparate pathways, its dramatic concentration changes and its selective cell release. Here we propose that succinate has evolved as a signaling modality because its concentration reflects the coenzyme Q (CoQ) pool redox state, a central redox couple confined to the mitochondrial inner membrane. This connection is of general importance because CoQ redox state integrates three bioenergetic parameters: mitochondrial electron supply, oxygen tension and ATP demand. Succinate, by equilibrating with the CoQ pool, enables the status of this central bioenergetic parameter to be communicated from mitochondria to the rest of the cell, into the circulation and to other cells. The logic of this form of regulation explains many emerging roles of succinate in biology, and suggests future research questions.

Acute Succinate Administration Increases Oxidative Phosphorylation and Skeletal Muscle Explosive Strength via SUCNR1

Endurance training and explosive strength training, with different contraction protein and energy metabolism adaptation in skeletal muscle, are both beneficial for physical function and quality of life. Our previous study found that chronic succinate feeding enhanced the endurance exercise of mice by inducing skeletal muscle fiber-type transformation. The purpose of this study is to investigate the effect of acute succinate administration on skeletal muscle explosive strength and its potential mechanism. Succinate was injected to mature mice to explore the acute effect of succinate on skeletal muscle explosive strength. And C2C12 cells were used to verify the short-term effect of succinate on oxidative phosphorylation. Then the cells interfered with succinate receptor 1 (SUCNR1) siRNA, and the SUCNR1-GKO mouse model was used for verifying the role of SUCNR1 in succinate-induced muscle metabolism and expression and explosive strength. The results showed that acute injection of succinate remarkably improved the explosive strength in mice and also decreased the ratio of nicotinamide adenine dinucleotide (NADH) to NAD⁺ and increased the mitochondrial complex enzyme activity and creatine kinase (CK) activity in skeletal muscle tissue. Similarly, treatment of C2C12 cells with succinate revealed that succinate significantly enhanced oxidative phosphorylation with increased adenosine triphosphate (ATP) content, CK, and the activities of mitochondrial complex I and complex II, but with decreased lactate content, reactive oxygen species (ROS) content, and NADH/NAD⁺ ratio. Moreover, the succinate's effects on oxidative phosphorylation were blocked in SUCNR1-KD cells and SUCNR1-KO mice. In addition, succinate-induced explosive strength was also abolished by SUCNR1 knockout. All the results indicate that acute succinate administration increases oxidative phosphorylation and skeletal muscle explosive strength in a SUCNR1-dependent manner.

Succinate Can Shuttle Reducing Power from the Hypoxic Retina to the O2-Rich Pigment Epithelium

When O₂ is plentiful, the mitochondrial electron transport chain uses it as a terminal electron acceptor. However, the mammalian retina thrives in a hypoxic niche in the eye. We find that mitochondria in retinas adapt to their hypoxic environment by reversing the succinate dehydrogenase reaction to use fumarate to accept electrons instead of O₂. Reverse succinate dehydrogenase activity produces succinate and is enhanced by hypoxia-induced downregulation of cytochrome oxidase. Retinas can export the succinate they produce to the neighboring O₂-rich retinal pigment epithelium-choroid complex. There, succinate enhances O₂ consumption by severalfold. Malate made from succinate in the pigment epithelium can then be imported into the retina, where it is converted to fumarate to again accept electrons in the reverse succinate dehydrogenase reaction. This malate-succinate shuttle can sustain these two tissues by transferring reducing power from an O₂-poor tissue (retina) to an O₂-rich one (retinal pigment epithelium-choroid).

pH-Gated Succinate Secretion Regulates Muscle Remodeling in Response to Exercise

In response to skeletal muscle contraction during exercise, paracrine factors coordinate tissue remodeling, which underlies this healthy adaptation. Here we describe a pH-sensing metabolite signal that initiates muscle remodeling upon exercise. In mice and humans, exercising skeletal muscle releases the mitochondrial metabolite succinate into the local interstitium and circulation. Selective secretion of succinate is facilitated by its transient protonation, which occurs upon muscle cell acidification. In the protonated monocarboxylic form, succinate is rendered a transport substrate for monocarboxylate transporter 1, which facilitates pH-gated release. Upon secretion, succinate signals via its cognate receptor SUCNR1 in non-myofibrillar cells in muscle tissue to control muscle-remodeling transcriptional programs. This succinate-SUCNR1 signaling is required for paracrine regulation of muscle innervation, muscle matrix remodeling, and muscle strength in response to exercise training. In sum, we define a bioenergetic sensor in muscle that utilizes intracellular pH and succinate to coordinate tissue adaptation to exercise.

Accumulation of succinate controls activation of adipose tissue thermogenesis

Thermogenesis by brown and beige adipose tissue, which requires activation by external stimuli, can counter metabolic disease¹. Thermogenic respiration is initiated by adipocyte lipolysis through cyclic AMP-protein kinase A signalling; this pathway has been subject to longstanding clinical investigation^2-4. Here we apply a comparative metabolomics approach and identify an independent metabolic pathway that controls acute activation of adipose tissue thermogenesis in vivo. We show that substantial and selective accumulation of the tricarboxylic acid cycle intermediate succinate is a metabolic signature of adipose tissue thermogenesis upon activation by exposure to cold. Succinate accumulation occurs independently of adrenergic signalling, and is sufficient to elevate thermogenic respiration in brown adipocytes. Selective accumulation of succinate may be driven by a capacity of brown adipocytes to sequester elevated circulating succinate. Furthermore, brown adipose tissue thermogenesis can be initiated by systemic administration of succinate in mice. Succinate from the extracellular milieu is rapidly metabolized by brown adipocytes, and its oxidation by succinate dehydrogenase is required for activation of thermogenesis. We identify a mechanism whereby succinate dehydrogenase-mediated oxidation of succinate initiates production of reactive oxygen species, and drives thermogenic respiration, whereas inhibition of succinate dehydrogenase supresses thermogenesis. Finally, we show that pharmacological elevation of circulating succinate drives UCP1-dependent thermogenesis by brown adipose tissue in vivo, which stimulates robust protection against diet-induced obesity and improves glucose tolerance. These findings reveal an unexpected mechanism for control of thermogenesis, using succinate as a systemically-derived thermogenic molecule.

Amino acid homeostasis and signalling in mammalian cells and organisms

Cells have a constant turnover of proteins that recycle most amino acids over time. Net loss is mainly due to amino acid oxidation. Homeostasis is achieved through exchange of essential amino acids with non-essential amino acids and the transfer of amino groups from oxidised amino acids to amino acid biosynthesis. This homeostatic condition is maintained through an active mTORC1 complex. Under amino acid depletion, mTORC1 is inactivated. This increases the breakdown of cellular proteins through autophagy and reduces protein biosynthesis. The general control non-derepressable 2/ATF4 pathway may be activated in addition, resulting in transcription of genes involved in amino acid transport and biosynthesis of non-essential amino acids. Metabolism is autoregulated to minimise oxidation of amino acids. Systemic amino acid levels are also tightly regulated. Food intake briefly increases plasma amino acid levels, which stimulates insulin release and mTOR-dependent protein synthesis in muscle. Excess amino acids are oxidised, resulting in increased urea production. Short-term fasting does not result in depletion of plasma amino acids due to reduced protein synthesis and the onset of autophagy. Owing to the fact that half of all amino acids are essential, reduction in protein synthesis and amino acid oxidation are the only two measures to reduce amino acid demand. Long-term malnutrition causes depletion of plasma amino acids. The CNS appears to generate a protein-specific response upon amino acid depletion, resulting in avoidance of an inadequate diet. High protein levels, in contrast, contribute together with other nutrients to a reduction in food intake.

Tumor microenvironment promotes dicarboxylic acid carrier-mediated transport of succinate to fuel prostate cancer mitochondria

Prostate cancer cells reprogram their metabolism, so that they support their elevated oxidative phosphorylation and promote a cancer friendly microenvironment. This work aimed to explore the mechanisms that cancer cells employ for fueling themselves with energy rich metabolites available in interstitial fluids. The mitochondria oxidative phosphorylation in metastatic prostate cancer DU145 cells and normal prostate epithelial PrEC cells were studied by high-resolution respirometry. An important finding was that prostate cancer cells at acidic pH 6.8 are capable of consuming exogenous succinate, while physiological pH 7.4 was not favorable for this process. Using specific inhibitors, it was demonstrated that succinate is transported in cancer cells by the mechanism of plasma membrane Na(+)-dependent dycarboxylic acid transporter NaDC3 (SLC13A3 gene). Although the level of expression of SLC13A3 was not significantly altered when maintaining cells in the medium with lower pH, the respirometric activity of cells under acidic condition was elevated in the presence of succinate. In contrast, normal prostate cells while expressing NaDC3 mRNA do not produce NaDC3 protein. The mechanism of succinate influx via NaDC3 in metastatic prostate cancer cells could yield a novel target for anti-cancer therapy and has the potential to be used for imaging-based diagnostics to detect non-glycolytic tumors.

Abolition of the inhibitory effect of ethanol oxidation on gluconeogenesis from lactate by asparagine or low concentrations of ammonia

When isolated hepatocytes from fasted rats were incubated with 10 mM lactate, the [lactate]/[pyruvate] ratio measured at the beginning of the incubation was raised above 70:1 but declined to a steady level of about 8:1 within 40 min. The rate of gluconeogenesis from lactate was initially slow but gradually increased over the incubation period becoming maximal by 30 min. The simultaneous addition of lactate and ethanol resulted in an initial [lactate]/[pyruvate] ratio above 250:1 which by 60 min had declined to a new steady-state level of approx. 60:1. The lactate, ethanol combination also brought about a prolongation of the lag phase before glucose synthesis became maximal; however, by 40 min the rate of gluconeogenesis was independent of the presence of ethanol. Thus the inhibitory effect of ethanol on glucose synthesis was manifest only over the early portion of the incubation period. When asparagine, a precursor of malate/aspartate components, was added to the incubation mixture, the lag before maximal rates of glucose formation from lactate in the absence or presence of ethanol was almost abolished. The presence of asparagine also rapidly lowered the [lactate]/[pyruvate] ratio of hepatocytes incubated with lactate plus ethanol establishing a steady-state level of 15:1 within 10-15 min. Asparagine enhanced the rate of lactate-stimulated ethanol oxidation, particularly during the early part of the incubation. In endeavouring to elucidate which of the products of asparagine catabolism (i.e. ammonia and aspartate) were responsible for these effects, we found that a small and constant level of ammonia, formed by the degradation of urea by urease, almost reproduced the effects of asparagine on the [lactate]/[pyruvate] ratio, glucose synthesis and ethanol oxidation. A bolus addition of 10 mM aspartate or 4 mM ammonia to cells metabolising lactate and ethanol were less effective than a steady-state low ammonia concentration, generated from urea/urease. Our studies suggest that asparagine or a low concentration of ammonia, by providing components of the malate/aspartate shuttle, can ameliorate some of the metabolic effects of ethanol on the liver.

Regulation of urea and citrulline synthesis under physiological conditions

Information on the regulation of urea synthesis in vivo was obtained by examining the relationship between ureagenesis in vivo, citrulline synthesis in vitro, and two factors currently hypothesized to exert short-term regulation of this pathway: the liver mitochondrial content of N-acetylglutamate (NAG) and substrate availability. Rats meal-fed for 4 h every day (4-20 schedule) or for 8 h every other day (8-40 schedule) were used. (1) The citrulline-synthesizing capacity of mitochondria from livers of rats on the 8-40 schedule exceeded the corresponding velocity of urea synthesis in vivo at all time points studied. (2) Mitochondrial NAG in these livers increased from 127 +/- 32 pmol/mg of protein at 0 h to 486 +/- 205 pmol/mg at 3 h after the start of a meal, and decreased thereafter, but the correlation between NAG content and the velocity of citrulline synthesis was not simple, suggesting that NAG is not the only determinant of the state of activation of carbamoyl phosphate synthase I. (3) In rats on the 4-20 schedule killed 1 h after the start of the meal, the liver content of ornithine, citrulline, arginine, glutamate, alanine and urea increased 2.1-12-fold with respect to the values at 0 h; glutamine decreased by 39%. (4) The combined findings indicate that in vivo, moment-to-moment control of the velocity of urea synthesis is exerted by substrate availability. (5) Digestion limits the supply of substrate to the liver, and prevents its ureagenic capacity from being overwhelmed following a protein-containing meal.

Metabolic zonation of the liver: regulation and implications for liver function

Liver parenchyma shows a remarkable heterogeneity of the hepatocytes along the porto-central axis with respect to ultrastructure and enzyme activities resulting in different cellular functions within different zones of the liver lobuli. According to the concept of metabolic zonation, the spatial organization of the various metabolic pathways and functions forms the basis for the efficient adaptation of liver metabolism to the different nutritional requirements of the whole organism in different metabolic states. The present review summarizes current knowledge about this heterogeneity, its development and determination, as well as about its significance for the understanding of all aspects of liver function and pathology, especially of intermediary metabolism, biotransformation of drugs and zonal toxicity of hepatotoxins.

Control of hepatic proteolysis by amino acids. The role of cell volume

1. Proteolysis in isolated perfused rat liver was monitored as [3H]leucine release into effluent perfusate after in vivo labeling by intraperitoneal injection of [3H]leucine about 16 h prior to the perfusion experiment. Exposure of the livers to hypotonic perfusion media (175-295 mOsmol.l-1) increased liver mass due to cell swelling and inhibited [3H]leucine release. The extent of inhibition of [3H]leucine release was linearly related to the liver-mass increase, regardless of whether livers from fed or 24-h-starved rats were studied. 2. Infusion of glycine (0.5-3 mmol.l-1) or glutamine (0.5-3 mmol.l-1) during normotonic perfusions (305 mOsmol.l-1) led to a concentration-dependent increase of liver mass and inhibition of [3H]leucine release. The inhibition of [3H]leucine release was again strongly dependent upon the increase of liver mass, regardless of whether cell swelling was induced by glutamine or glycine in normotonic perfusions, by exposure of the liver to hypotonic media or whether amino-acid-induced cell swelling was modified by the nutritional state. The effects of glutamine and glycine on [3H]leucine release were additive to the same extent as that found when the liver-mass increase was observed. 3. Alanine, serine and proline inhibited [3H]leucine release in parallel to the extent of amino-acid-induced liver-mass increase; however, the inhibition of [3H]leucine release was about twice that found when comparable degrees of cell swelling were induced either by hypotonic exposure or by addition of glutamine or glycine. The relationship between alanine-induced liver-mass increase and the inhibition of [3H]leucine release was also maintained in presence of aminooxyacetate (0.2 mmol.l-1). 4. Infusion of an amino acid mixture, roughly mimicking the concentrations found in portal venous blood, to livers from 24-h-starved or fed rats inhibited [3H]leucine release by 56.0 +/- 2.4% (n = 6) or 31.1 +/- 2.3% (n = 3), respectively, and increased liver mass by 5.0 +/- 0.1% (n = 6) or 2.2 +/- 0.3% (n = 3), respectively. Regardless of the nutritional state, there was a close relationship between the amino-acid-mixture-induced (and also phenylalanine-induced) increase of liver mass and the degree of inhibition of [3H]leucine release; however, the inhibition of [3H]leucine release was about fourfold higher than that found when comparable degrees of cell swelling were induced by hypotonic exposure.(ABSTRACT TRUNCATED AT 400 WORDS)

Benzoate stimulates glutamate release from perfused rat liver

In isolated perfused rat liver, benzoate addition to the influent perfusate led to a dose-dependent, rapid and reversible stimulation of glutamate output from the liver. This was accompanied by a decrease in glutamate and 2-oxoglutarate tissue levels and a net K+ release from the liver; withdrawal of benzoate was followed by re-uptake of K+. Benzoate-induced glutamate efflux from the liver was not dependent on the concentration (0-1 mM) of ammonia (NH3 + NH4+) in the influent perfusate, but was significantly increased after inhibition of glutamine synthetase by methionine sulphoximine or during the metabolism of added glutamine (5 mM). Maximal rates of benzoate-stimulated glutamate efflux were 0.8-0.9 mumol/min per g, and the effect of benzoate was half-maximal (K0.5) at 0.8 mM. Similar Vmax. values of glutamate efflux were obtained with 4-methyl-2-oxopentanoate, ketomethionine (4-methylthio-2-oxobutyrate) and phenylpyruvate; their respective K0.5 values were 1.2 mM, 3.0 mM and 3.8 mM. Benzoate decreased hepatic net ammonia uptake and synthesis of both urea and glutamine from added NH4Cl. Accordingly, the benzoate-induced shift of detoxication from urea and glutamine synthesis to glutamate formation and release was accompanied by a decreased hepatic ammonia uptake. The data show that benzoate exerts profound effects on hepatic glutamate and ammonia metabolism, providing a new insight into benzoate action in the treatment of hyperammonaemic syndromes.

Mitochondrial membrane potential in living cells: evidence from studies with rhodamine 6 G as fluorescent probe

Rhodamine 6 G as a cationic permeant fluorophore is demonstrated to be selectively accumulated by mitochondria of living pancreatic acinar cells from guinea pigs. The accumulation of the fluorescent dye was studied by means of the application of electron transport inhibitors in the respiratory chain, ionophores and some hydrogen donors. Besides, some unspecific staining processes were excluded. Using this technique, it becomes possible to estimate the energy state of living cells under various conditions of energy supply and demand.

Acidic amino acid transport in animal cells and tissues

1. The occurrence and characterization of acidic amino acid transport in the plasma membrane of a variety of cells and tissues of a number of organisms is reviewed. 2. Several cell types, especially in brain, possess both high- and low-affinity transport systems for acidic amino acids. 3. High-affinity systems in brain may function to remove neurotransmitter amino acid from the extracellular environment. 4. Many cell systems for acidic amino acid transport are energized by an inwardly directed Na+ gradient. Moreover, certain cell types, such as rat brain neurons, human placental trophoblast and rabbit and rat kidney cortex epithelium, respond to an outwardly directed K+ gradient as an additional source of energization. This simultaneous action may account for the high accumulation ratios seen with acidic amino acids. 5. Rabbit kidney has been found to have a glutamate-H+ co-transport system which is subject to stimulation by protons in the medium. 6. Acidic amino acid transport in rat brain neurons occurs with a stoichiometric coupling of 1 mol of amino acid to 2 mol of Na+. For rabbit intestine, one Na+ is predicted to migrate for each mol of amino acid. 7. Uptake in rat kidney cortex and in high-K+ dog erythrocytes is electrogenic. However, uptake in rabbit and newt kidney and in rat and rabbit intestine is electroneutral. 8. Na+-independent acidic amino acid transport systems have been described in the mouse lymphocyte, the human fibroblast, the mouse Ehrlich cell and in rat hepatoma cells. 9. In a number of cell systems, D-acidic amino acids have substantial affinity for transport; D-glutamate, in a number of systems, however, appears to have little reactivity. 10. Acidic amino acid transport in some cell systems appears to occur via the "classical" routes (Christensen, Adv. Enzymol. Relat. Areas Mol. Biol. 49, 41-101, 1979). For example, uptake in the Ehrlich cell is partitioned between the Na+-dependent A system (which transports a wide spectrum of neutral amino acids), the Na+-dependent ASC system (which transports alanine, serine, threonine, homoserine, etc.), and the Na+-independent L system (which shows reactivity centering around neutral amino acids such as leucine and phenylalanine). Also, a minor component of uptake in mouse lymphocytes occurs by a route resembling the A system. 11. Human fibroblasts possess a Na+-independent adaptive transport system for cystine and glutamate that is enhanced in activity by cystine starvation.(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of hepatic ammonia metabolism: the intercellular glutamine cycle

In the liver acinus, urea synthesis and glutaminase activity are predominantly localized in the periportal area, whereas glutamine synthetase activity is perivenous. Because ammonium ions at low concentrations are effectively removed by glutamine synthetase, but not by urea synthesis, the two pathways of ammonia detoxication in the liver acinus represent the sequence of a low-affinity, but high-capacity system (ureogenesis) and a perivenous high-affinity system (glutamine synthesis). In agreement with these findings, obtained in experiments with the metabolically and structurally intact perfused rat liver, perivenous glutamine synthesis was almost completely inhibited after induction of perivenous liver cell necrosis by carbon tetrachloride, whereas periportal urea synthesis was not affected. The structural and functional organization of hepatic ammonium and glutamine metabolism and the metabolic interactions of different subacinar hepatocyte populations provide a new understanding of hepatic nitrogen metabolism under physiological and pathological conditions. Periportal glutaminase and perivenous glutamine synthetase are simultaneously active, resulting in an intercellular (as opposed to intracellular) glutamine cycle, being under complex metabolic and hormonal control. The intercellular glutamine cycle provides an effective means for almost complete conversion of portal ammonium ions into urea without accompanying net glutamine formation. This is achieved by additional substrate feeding into the urea cycle by the glutaminase reaction, both pathways being localized in the periportal compartment, and the perivenous resynthesis of glutamine from ammonium ions which escaped periportal urea synthesis. This complete conversion of portal ammonium ions into urea by means of glutamine cycling represents the situation of a well-balanced pH homeostasis. Because urea synthesis, in contrast to glutamine synthesis, is a major pathway for removal of bicarbonate, the switching of hepatic ammonium detoxication from urea synthesis to glutamine synthesis in acidosis points to an important role of the liver in maintaining pH homeostasis. The acid-base-induced changes of the route of hepatic ammonium detoxication and therefore bicarbonate removal are performed by the regulatory properties of the enzymes of the intercellular glutamine cycle.

Oxygen deprivation-induced injury to isolated rabbit kidney tubules

The utility of freshly isolated suspensions of rabbit tubules enriched in proximal segments for studying the pathogenesis of oxygen deprivation-induced renal tubular cell injury was evaluated. Oxygenated control preparations exhibited very good stability of critical cell injury-related metabolic parameters including oxygen consumption, cell cation homeostasis, and adenine nucleotide metabolism for periods in excess of 2 h. Highly reproducible models of oxygen deprivation-induced injury and recovery were developed and alterations of injury-related metabolic parameters in these models were characterized in detail. When oxygen deprivation was produced under hypoxic conditions, tubules sustained widespread lethal cell injury and associated metabolic alterations within 15-30 min. However, when oxygen deprivation was produced under simulated ischemic conditions, tubules tolerated 30-60 min with only moderate amounts of lethal cell injury occurring, a situation similar to that seen with ischemia in vivo. Like ischemia in vivo, simulated ischemia in vitro was characterized by a fall in pH during oxygen deprivation. No such fall in pH occurred in the hypoxic model. To test whether this fall in pH could contribute to the protection seen during simulated ischemia in vitro, tubules were subjected to hypoxia at medium pHs ranging from 7.45 to 6.41. Striking protection from hypoxic injury was seen as pH was reduced with maximal protection occurring in tubules made hypoxic at pHs below 7.0. Measurements of injury-associated metabolic parameters suggested that the protective effect of reduced pH may be mediated by pH-induced alterations of tubule cell Ca++ metabolism. This study has, thus, defined and characterized in detail a new and extremely versatile model system for the study of oxygen deprivation-induced cell injury in the kidney and has established that pH alterations play a major role in modulating such injury.

Interference by ethanol of coupling between gluconeogenesis and ureagenesis from proline in isolated hepatocytes

Proline stimulated equally the production of glucose and urea by isolated hepatocytes. Ethanol suppressed glucose production much more strongly than urea synthesis. The proline-derived carbon not reaching glucose was found as lactate. Inhibition of phosphoenolpyruvate synthesis with 3-mercaptopicolinate blocked gluconeogenesis, but was without effect on lactate production. Acetate was formed from endogenous sources, as well as from ethanol. Its accumulation from ethanol was enhanced both by proline and lactate. The differential effect of ethanol on gluconeogenesis and ureagenesis appears to be related to its effect on the redox state of the cell.

Regulation of hepatic glutamate metabolism. Role of 2-oxoacids in glutamate release from isolated perfused rat liver

In isolated perfused rat liver, addition of the oxoanalogues of leucine, isoleucine, methionine and phenylalanine is followed by a rapid and reversible stimulation of glutamate release. This is not observed with the corresponding amino acids or 2-oxoisovalerate, 2-oxoglutarate or oxaloacetate. The increased glutamate release by the liver is accompanied by a decrease in the tissue contents of 2-oxoglutarate and glutamate by about 25% and 50%, respectively. During the metabolism of glutamine, i.e. conditions with elevated tissue glutamate concentrations, 2-oxoacid-induced glutamate release is stimulated. In the presence of glutamine (5 mM), 2-oxoisocaproate, 2-oxo-4-methylvalerate and 2-oxo-4-methylthiobutyrate were found to be most effective and glutamate release by the liver increased linearly from about 80 nmol g-1 min-1 to 600 nmol g-1 min-1 at increasing 2-oxoacid concentrations up to 1 mM. When glutamate tissue levels were decreased by phenylephrine, stimulation of glutamate release by 2-oxoisocaproate was markedly diminished. 2-Oxoacid-stimulated glutamate release is independent of oxoacid metabolism, indicating that the effect is probably not explained by a 2-oxoacid/glutamate exchange across the liver plasma membrane. 2-Oxoacid-induced glutamate export predominantly occurs in a sodium-independent way. At low concentrations of 2-oxoisocaproate (below 0.2 mM), the increased glutamate release was accompanied by a slight inhibition of 14CO2 production from added [14C]glutamate, indicating a simultaneous glutamate uptake and release also under these conditions. Stimulation of glutamate release by 2-oxoisocaproate is followed by a decreased rate of urea and glutamine synthesis from portal ammonia, as a consequence of an increased glutamate release.

Hepatocyte heterogeneity in glutamate uptake by isolated perfused rat liver

Glutamate is simultaneously taken up and released by perfused rat liver, as shown by 14CO2 production from [1-14C]glutamate in the presence of a net glutamate release by the liver, turning to a net glutamate uptake at portal glutamate concentrations above 0.3 mM. 14CO2 production from portal [1-14C]glutamate is decreased by about 60% in the presence of ammonium ions. This effect is not observed during inhibition of glutamine synthetase by methionine sulfoximine. 14CO2 production from [1-14C]glutamate is not influenced by glutamine. Also, when glutamate accumulates intracellularly during the metabolism of glutamine (added at high concentrations, 5 mM), 14CO2 production from [1-14C]glutamate is not affected. If labeled glutamate is generated intracellularly from added [U-14C]proline, stimulation of glutamine synthesis by ammonium ions did not affect 14CO2 production from [U-14C]proline. After induction of a perivenous liver cell necrosis by CCL4, i.e. conditions associated with an almost complete loss of perivenous glutamine synthesis but no effect on periportal urea synthesis, 14CO2 production from [1-14C]glutamate is decreased by about 70%. The results are explained by hepatocyte heterogeneity in glutamate metabolism and indicate a predominant uptake of glutamate (that reaches the liver by the vena portae) by the small perivenous population of glutamine-synthesizing hepatocytes, whereas glutamate production from glutamine or proline is predominantly periportal. In view of the size of the glutamine synthetase-containing hepatocyte pool [Gebhardt, R. and Mecke, D. (1983) EMBO J. 2, 567-570], glutamate transport capacity of these hepatocytes would be about 20-fold higher as compared to other hepatocytes.

Glutamate uptake by cultured rat hepatocytes is mediated by hormonally inducible, sodium-dependent transport systems

Glutamate uptake by rat hepatocytes in primary monolayer culture was found to be mediated by a Na+-independent and by two Na+-dependent transport systems of high and low affinity. Inhibition studies with cysteate and other model amino acids rules out the participation of the neutral amino acid transport systems A, ASC, and N and revealed that the Na+-dependent agencies represent unequivocally anionic transport systems. Na+-dependent uptake of glutamate in isolated hepatocytes was slow compared to the Na+-independent portion, but increased spontaneously during cultivation. In the presence of dexamethasone it was stimulated about 10-fold at the second day of cultivation.

Inhibition of glutamate-aspartate transaminase by beta-methylene-DL-aspartate

beta-Methylene-DL-aspartate, a new beta, gamma-unsaturated amino acid, is an irreversible inhibitor of soluble pig heart glutamate-aspartate transaminase (Ki approximately 3 mM with respect to the L-form; limiting rate constant for inactivation approximately 0.4 min-1). The new amino acid is the most specific inhibitor of glutamate-aspartate transaminase thus far studied. It does not inactivate pig heart glutamate-alanine transaminase, soluble rat kidney glutamine transaminase K, gamma-aminobutyrate transaminase (from Pseudomonas fluorescens), glutamate decarboxylase (Escherichia coli), snake venom L-amino acid oxidase, or hog kidney D-amino acid oxidase. In addition, the following enzymes were not inhibited by beta-methylene-DL-aspartate in rat tissue homogenates: gamma-aminobutyrate transaminase (brain), tyrosine transaminase (liver), glutamine transaminase L (liver), asparagine, transaminase (liver), ornithine transaminase (liver) or branch-chain transaminase(s) (kidney). Intraperitoneal injection of beta-methylene-DL-aspartate into mice decreased kidney and liver glutamate-aspartate transaminase activities but had no effect on liver glutamate-alanine transaminase activity.

Effect of chlorpromazine on isolated rat hepatocytes

The effect of chlorpromazine hydrochloride (CPZ) (1-500 microM) on plasma membrane permeability and mitochondrial respiratory function of isolated rat hepatocytes was studied. The endogenous oxygen consumption stimulated by 1 mM succinate was increased significantly by 5 microM CPZ, whereas the ability to exclude trypan blue (TB) was decreased significantly by 100 microM CPZ. The release of a cytosomal enzyme, lactate dehydrogenase (LDH), was increased significantly by 50 microM CPZ, whereas the release of glutamic-opalacetic transaminase (GOT) was increased significantly by 100 microM. The endogenous oxygen consumption was decreased significantly by 150 microM CPZ. The respiration control ratio by 2 microM carbonylcyanide-m-chlorphenyl hydrazon (CCP) showed significant decreases at all concentrations of CPZ studied; and this might be attributable to the suppression by CPZ of the respiratory stimulation induced by CCP. The results indicated that CPZ at a low concentration (5 microM) first produced a significant change in plasma membrane permeability to low molecular substances such as succinate and then at higher concentrations (50-100 microM) produced significant release of the cytosomal and mitochondrial enzymes, LDH and GOT. They also indicated that the concentrations of CPZ which produced significant effects on respiratory function were higher (above 150 microM) than those which produced significant changes in plasma membrane permeability of hepatocytes.

Abnormalities of volume regulation and membrane integrity in myocardial tissue slices after early ischemic injury in the dog: effects of mannitol, polyethylene glycol, and propranolol

The authors used an in vitro myocardial tissue slice technique to quantitate the transmural distribution of alterations in cell volume regulation and membrane integrity following early ischemic injury and to evaluate directly the effects of therapeutic interventions in a system not subjects to influences of coronary blood flow. Left circumflex coronary occlusion was produced in 57 dogs for 30 or 60 minutes. After in vitro incubation in Krebs-Ringer-phosphate-succinate medium containing trace 14C-inulin, typical values (ml H2O/g dry weight) for control nonischemic myocardial slices were 3.68 +/- 0.07 (SEM) for total tissue water, 2.67 +/- 0.07 for inulin impermeable space, and 1.01 +/- 0.04 for inulin diffusible space. Ischemic myocardial slices exhibited an impaired response to cold shock (0 C for 60 minutes) and rewarming (37 C for 60 minutes). After 60 minutes coronary occlusion, respective increases in total tissue water, inulin-impermeable space and inulin-diffusible space of ischemic slices were 25.5 +/- 2.6%, 6.2 +/- 4.9% and 84.4 +/- 12.5% for papillary muscle, 22.2 +/- 2.1%, 10.4 +/- 4.2% and 52.5 %/- 10.3% for subendocardium and 9.1 +/- 1.5%, 7.2 +/- 2.3% and 15.8 +/- 5.5% for subepicardium. Significant but usually less marked alterations occurred after 30 minutes of coronary occlusion. Propranolol treatment in vivo (2 mg/kg) and/or in vitro (0.01 mg/ml medium) produced no significant changes in tissue water or inulin spaces of ischemic slices, compared with saline controls. Incubation in hyperosmolar mediums resulted in significant reductions in total tissue water and inulin-impermeable space with little change in inulin-diffusible space of both ischemic and control slices. Fifty milliosmolar polyethylene glycol (MW 6000) produced a greater reduction in tissue water and ultrastructural evidence of cell swelling than did either 40 or 100 milliosmolar mannitol (MW 182). The major effect of hyperosmolar incubation appeared to be a selective reduction in edema of cells with structurally intact membranes. Thus, in vitro studies, with myocardial tissue slices provide evidence of widespread alterations of membrane integrity after 30--60 minutes of in vivo coronary artery occlusion. In vitro abnormalities of cell volume regulation can be partially reversed by direct osmotic effects on myocardial cells.

Viability control and special properties of isolated rat hepatocytes

The need for quick viability tests is stressed. Aas these should achieve more than statically categorizing dead or non-dead cells, several procedures are suggested that picture the energetic state of the cells. The almost classical criterion of this category, namely stimulation of respiration by succinate, must be questioned on the basis of the present results. It is shown, that restricted respiration by succinate is not due to limited permeability of the plasma membrane, but to competition by endogenous substrates for uptake into mitochondria. Distribution equilibria for succinate appear to be according to (delta pH)2 with regard to cytoplasm. They are attained within 5-20 s or faster. Uptake is in part regulated by the surface charge density. Permeability changes caused by effectors of surface charge, such as amphiphilic ions, are examplified for succinate, chloride, phosphate, Na+, K+, and Ca2+. Such changes repeatedly also occur after pulses of BSP. They are counterregulated by the cell within a minute in a manner dependent on BSP concentration and the state of the cells. During the preincubation phase, that is the time of readaptation after transfer of cells from 0 degree C to higher temperature, a special labile state transiently occurs, where cyclic permeability changes for Ca2+, Na+, K+ can be caused by substrate addition, especially succinate, and/or ATP. The extent of these changes and their sequence again depend on the energetic state of the cells. In a probably narrow energetic window a sequence of cation movements reminding of that after depolarization of an excitable cell, is observed. Manipulation of the Na+/K+-ratio by variation of preincubation time and by ouabain shows that this is not simply the denominator for reversible calcium uptake. As the surface charge appears to reflect the energetic state, ANS fluorescence is applied to monitor the state of the plasma membrane, though difficulties arising from a slow ANS permeation are not yet solved.

Comparative study of the effect of amino acids on ethanol oxidation in isolated hepatocytes from starved and fed rats

The effects of the various naturally occurring amino acids on ethanol oxidation in hepatocytes from 18-hrs starved and fed rats were studied. In order to minimize the non-ADH pathways and to avoid interference with the liver amino acid uptake the ethanol concentration used was 4 mM, the amino acids being added at the same concentration. In hepatocytes from starved rats, asparagine, serine, ornithine, hydroxyproline, histidine, cysteine, alanine, glycine, glutamate, glutamine, aspartate and arginine significantly increase ethanol consumption. The stimulatory effect of glutamine being much less pronounced than the asparagine one and proline being devoid of action, the influence of ammonium chloride addition on ethanol consumption in the presence of these amino acids was studied. Ammonium chloride determines an enhancement of ethanol oxidation, the results showing, contrarily to previous data, no apparent correlation between intracellular glutamate concentration and ethanol oxidation rate but rather a relation with aspartate concentration. In hepatocytes from fed rats alanine, asparagine, cysteine, glycine, hydroxyproline, ornithine and serine still increase ethanol oxidation, although to a lesser extent than in cells from starved rats. It appears that only amino acids which are precursors of either pyruvate or aspartate or glutamate are able to activate the ethanol oxidation. Pyruvate, aspartate and glutamate supply malate-aspartate shuttle components especially in cells from starved rats, pyruvate allowing direct cytosolic reoxidation of NADH in cells from fed rats as well as from starved rats. The relative strengths of the stimulatory effect could be roughly dependent on energy demand for glucose synthesis in starved rats and for urea synthesis in fed rats.

Transient 45Ca uptake and release in isolated rat-liver cells during recovery from deenergized states

1. Aerobic incubation of isolated rat liver cells--after dilution from the anaerobic stock suspension--transiently brings about a state, during which a reversible calcium uptake can be observed on addition of a respiratory substrate. Uptake varies greatly and can reach more than 50 nmol/mg protein, but declines to zero on prolonged preincubation, especially at higher temperature. Repeated additions of succinate or 3-hydroxybutyrate evoke new calcium transients. If ATP is simultaneously added, if greatly potentiates succinate-initiated reversible uptake. 2. If rotenone is present during the preincubation phase, calcium transients are strongly enhanced. Uptake is blocked by uncouplers and respiratory inhibitors, indicating the involvement of mitochondria. 3. Calcium uptake is not accompanied by increased oxygen consumption. The actual respiration cannot account sufficiently for the energy need of calcium uptake. Participation of cytoplasmic ATP is likely, as inhibitors of adenine nucleotide translocase affect uptake. 4. Lanthanum enhances calcium uptake in contrast to its action on mitochondria. 5. Pulse-labeling experiments indicate that the calcium taken up is removed from a rapidly exchangeable calcium pool by withdrawal into the mitochondria as a deep compartment. 6. Calcium uptake is accelerated either by increasing the phosphate level or by high temperature. It is prolonged by low temperature, high pH or high ATP concentration. Calcium release accelerates with increasing temperature, decreasing pH and a further rise in phosphate concentration. 7. The dependency on phosphate and temperature reveals a delicately poised equilibrium of uptake and release. At ambient temperature, phosphate increases uptake up to a concentration of 0.5 mM. Higher concentrations accelerate both uptake and release. At lower temperature, the accelerating effect on uptake predominates. A temperature shift during incubation results in adaptation of the calcium equilibrium to the new temperature, i.e. release of calcium at high temperature, uptake at low temperature. 8. Oxidizing metabolites inhibit succinate-stimulated calcium uptake and promote release of previously accumulated calcium. An increased sensitivity to phosphate is established. 9. With respect to isolated mitochondria, isolated liver cells appear to be a more realistic model for studying the physiological mechanism of mitochondrial calcium release, since compartmental constraints and regulations are maintained.

The transport of L-cysteinesulfinate in rat liver mitochondria

1. The mechanism of L-cysteinesulfinate permeation into rat liver mitochondria has been investigated. 2. Mitochondria do not swell in ammonium or potassium salts of L-cysteinesulfinate in all the conditions tested, including the presence of valinomycin and/or carbonylcyanide p-trifluoromethoxyphenylhydrazone. 3. The activation of malate oxidation by L-cysteinesulfinate is abolished by aminooxyacetate, an inhibitor of the intramitochondrial aspartate aminotransferase, it is not inhibited by high concentrations of carbonylcyanide p-trifluoromethoxyphenylhydrazone (in contrast to the oxidation of malate plus glutamate) and it is decreased on lowering the pH of the medium. 4. All the aspartate formed during the oxidation of malate plus L-cysteinesulfinate is exported into the extramitochondrial space. 5. Homocysteinesulfinate, cysteate and homocysteate, which are all good substrates of the mitochondrial aspartate aminotransferase, are unable to activate the oxidation of malate. Homocysteinesulfinate and homocysteate have no inhibitory effect on the L-cysteinesulfinate-induced respiration, whereas cysteate inhibits it competitively with respect to L-cysteinesulfinate. 6. In contrast to D-aspartate, D-cysteinesulfinate and D-glutamate, L-aspartate inhibits the oxidation of malate plus L-cysteinesulfinate in a competitive way with respect to L-cysteinesulfinate. Vice versa, L-cysteinesulfinate inhibits the influx of L-aspartate. 7. Externally added L-cysteinesulfinate elicits efflux of intramitochondrial L-aspartate or L-glutamate. The cysteinesulfinate analogues homocysteinesulfinate, cysteate and homocysteate and the D-stereoisomers of cysteinesulfinate, aspartate and glutamate do not cause a significant release of internal glutamate or aspartate, indicating a high degree of specificity of the exchange reactions. External L-cysteinesulfinate does not cause efflux of intramitochondrial Pi, malate, malonate, citrate, oxoglutarate, pyruvate or ADP. The L-cysteinesulfinate-aspartate and L-cysteinesulfinate-glutamate exchanges are inhibited by glisoxepide and by known substrates of the glutamate-aspartate carrier. 8. The exchange between external L-cysteinesulfinate and intramitochondrial glutamate is accompanied by translocation of protons across the mitochondrial membrane in the same direction as glutamate. The L-cysteinesulfinate-aspartate exchange, on the other hand, is not accompanied by H+ translocation. 9. The ratios delta H+/delta glutamate, delta L-cysteinesulfinate/delta glutamate and delta L-cysteinesulfinate/delta aspartate are close to unity. 10. It is concluded that L-cysteinesulfinate is transported by the glutamate-aspartate carrier of rat liver mitochondria. The present data suggest that the dissociated form of L-cysteinesulfinate exchanges with H+-compensated glutamate or with negatively charged aspartate.

[Effect of natural amino acids on ethanol oxidation in isolated rat hepatocytes]

The effects of the various naturally occurring amino acids on ethanol oxidation in hepatocytes from starved rats was systematically studied. In order to minimize the non ADH pathways, the ethanol concentration used was 4 mmol/litre, the amino acids being added at the same concentration. In hepatocytes from fasted rats, alanine, arginine, asparagine, aspartate, citrulline, cysteine, glutamate, glutamine, glycine, histidine, hydroxyproline, ornithine and serine increase significantly ethanol consumption. The stimulatory effect of glutamine being much less pronounced than the asparagine one and proline being devoid of action, the influence of ammonium chloride addition on ethanol consumption in the presence of these amino acids was studied. Ammonium chloride determines an enhancement of ethanol oxidation in these conditions, the results showing no apparent correlation between intracellular glutamate concentration and ethanol oxidation rate, contrarily to previous data. In hepatocytes from fed rats, only alanine, asparagine, cysteine, glycine, hydroxyproline, ornithine and serine increase ethanol oxidation, although to a lesser extent than in cells from starved rats.

Prolone metabolism in isolated rat liver cells

The metabolism of proline was studied in liver cells isolated from starved rats. The following observations were made. 1. Consumption of proline could be largely accounted for by production of glucose, urea, glutamate and glutamine. 2. At least 50% of the total consumption of oxygen was used for proline catabolism. 3. Ureogenesis and gluconeogenesis from proline could be stimulated by partial uncoupling of oxidative phosphorylation. 4. Addition of ethanol had little effect on either proline uptake or oxygen consumption, but strongly inhibited the production of both urea and glucose and caused further accumulation of glutamate and lactate. Accumulation of glutamine was not affected by ethanol. 5. The effects of ethanol could be overcome by partial uncoupling of oxidative phosphorylation. 6. The apparent K(m) values of argininosuccinate synthetase (EC 6.3.4.5) for aspartate and citrulline in the intact hepatocyte are higher than those reported for the isolated enzyme. 7. 3-Mercaptopicolinate, an inhibitor of phosphoenolpyruvate carboxykinase (EC 4.1.1.32), greatly enhanced cytosolic aspartate accumulation during proline metabolism, but inhibited urea synthesis. 8. It is concluded that when proline is provided as a source of nitrogen to liver cells, production of ammonia by oxidative deamination of glutamate is inhibited by the highly reduced state of the nicotinamide nucleotides within the mitochondria. 9. Conversion of proline into glucose and urea is a net-energy-yielding process, and the high state of reduction of the nicotinamide nucleotides is presumably maintained by a high phosphorylation potential. Thus when proline is present as sole substrate, the further oxidation of glutamate by glutamate dehydrogenase (EC 1.4.1.3) is limited by the rate of energy expenditure of the cell.

Inter-organ relationships between glucose, lactate and amino acids in rats fed on high-carbohydrate or high-protein diets

1. Inter-organ relationships between glucose, lactate and amino acids were studied by determination of plasma concentrations in different blood vessels of anaesthetized rats fed on either a high-carbohydrate diet [13% (w/w) casein, 79% (w/w) starch] or a high-protein diet [50% (w/w) casein, 42% (w/w) starch]. The period of food intake was limited (09:00-17:00h), and blood was collected 4h after the start of this period (13:00h). 2. Glucose absorption was considerable only in rats fed on a high-carbohydrate diet. Portal-vein-artery differences in plasma lactate concentration were higher in rats fed on this diet, but not proportional to glucose absorption. Aspartate, glutamate and glutamine were apparently converted into alanine, but when dietary protein intake was high, a net absorption of glutamine occurred. 3. The liver removed glucose from the blood in rats fed on a high-carbohydrate diet, but glucose was released into the blood in rats fed on the high-protein diet, probably as a result of gluconeogenesis. Lactate uptake was very low when amino acid availability was high. 4. In rats on a high-protein diet, increased uptake of amino acids, except for ornithine, was associated with a rise in portal-vein plasma concentrations, and in many cases with a decrease in hepatic concentrations. 5. Hepatic concentrations of pyruvate and 2-oxo-glutarate decreased without a concomitant change in the concentrations of lactate and malate in rats fed on the high-protein diet, in spite of an increased supply of pyruvate precursors (e.g. alanine, serine, glycine), suggesting increased pyruvate transport into mitochondria. 6. High postprandial concentrations of plasma glucose and lactate resulted in high uptakes of these metabolites in peripheral tissues of rats on both diets. Glutamine was released peripherally in both cases, whereas alanine was taken up in rats fed on a high-carbohydrate diet, but released when the amino acid supply increased. 7. It is concluded that: the small intestine is the main site of lactate production, and the peripheral tissues are the main site for lactate utilization; during increased ureogenesis in fed rats, lactate is poorly utilized by the liver; the gut is the main site of alanine production in rats fed on a high-carbohydrate diet and the liver utilizes most of the alanine introduced into the portal-vein plasma in both cases.

Ammonia production and pathways of glutamine utilization in rat kidney slices

Ammonia production from glutamine was studied in slices from non-acidotic and acidotic rat kidneys. Slices from non-acidotic kidneys made 53% as much ammonia from D-glutamine as from L-glutamine during the initial 15 min of incubation. Thereafter the production rate from the L-isomer accelerated while that from the D-isomer remained constant. The accelerated rate of ammonia production from L-glutamine was dependent upon tissue swelling since prevention of swelling reduced the production rate. Swelling activates the mitochondrial glutaminase I pathway as evidenced by the rise in ammonia produced per glutamine utilized ratio as well as by the accelerated rate of CO2 production derived from the oxidative disposal of glutamin's carbon skeleton. Cortical slice swelling activates the mitochondrial pathway in a manner not unlike that seen in vivo during chronic acidosis and may reflect increased permeability to glutamine. Acidotic rat kidneys are not swollen in vivo while cortical slices initially produce 4-fold more ammonia than do non-acidotic slices. After 15 min, this 4-fold difference in total ammonia production drops to only a 2-fold difference due to the swelling-induced activation of the mitochondrial pathway. Consequently, slice swelling obliterates the important fact that ammonia production by the mitochondrial pathway is 15-fold greater in acidotic than in non-acidotic kidneys.