Effects of fusaric acid on respiration in maize root mitochondria

The effects of fusaric acid, a phytotoxin produced byFusarium pathogens, on the metabolism of isolated maize root mitochondria and on maize seed germination and seedling growth were investigated. The phytotoxin inhibited basal and coupled respiration when succinate and α-ketoglutarate were the substrates. Coupled respiration dependent on NADH was inhibited, but basal respiration was not. Consistently, succinate cytochromec oxidoreductase activity was decreased whereas NADH cytochromec oxidoreductase was not affected. The ATPase activities of carbonyl cyanide p-trifluoro-methoxyphenyl hydrazone stimulated mitochondria and of freeze-thawing disrupted mitochondria were inhibited. These results indicate that the phytotoxin impairs the respiratory activity of maize mitochondria by at least three mechanisms: (1) it inhibits the flow of electrons between succinate dehydrogenase and coenzyme Q, (2) it inhibits ATPase/ATP-synthase activity and (3) it possibly inhibits α-ketoglutarate dehydrogenase. Seed germination and seedling growth were also affected by fusaric acid with the most pronounced effect on root development. These effects can possibly contribute to the diseases ofFusarium- infected plants     

Growth hormone and liver mitochondria. Effects on cytochromes and some enzymes.

A reliable and reproducible assay was developed for measuring mitochondrial α-keto acid decarboxylase activity using ferricyanide as the electron acceptor. This method permitted the functional isolation and investigation of the decarboxylase step of the branched-chain α-keto acid dehydrogenases in rat liver mitochondria. Pyruvate and α-ketoglutarate decarboxylases are known to be separate and distinct enzymes from the branched-chain α-keto acid decarboxylases and were studied as controls. The relative specific activities of rat liver mitochondrial decarboxylases as measured by the ferricyanide assay showed that pyruvate and α-ketoglutarate were decarboxylated twice as rapidly as α-ketoisovalerate and four to ten times as fast as α-keto-β-methylvalerate and α-ketoisocaproate. The three branched-chain α-keto acids individually inhibit pyruvate and α-ketoglutarate decarboxylases. Inactivation of mitochondrial branched-chain α-keto acid decarboxylase activity by freezing and thawing and by prolonged storage resulted in a proportional decrease in decarboxylase activity toward each of the three branched-chain α-keto acids. However, hypophysectomy was found to increase decarboxylase activity with α-keto-β-methylvalerate to four times normal and with α-ketoisovalerate to three times normal, but the activity with α-ketoisocaproate was not changed. Hypophysectomy did not alter mitochondrial decarboxylase activity with pyruvate, α-ketoglutarate, or α-ketovalerate. The finding that hypophysectomy differentially alters the mitochondrial decarboxylase activity with the three branched-chain α-keto acids suggests either that there is more than one substrate-specific enzyme with branched-chain α-keto acid decarboxylase activity or that there is a modification of one enzyme such that the catalytic activity is selectively altered toward the three substrates.     

The effect of three α-keto acids on 3-mercaptopyruvate sulfurtransferase activity

3-Mercaptopyruvate sulfurtransferase catalyzes the transfer of sulfur from 3-mercaptopyruvate to several possible acceptor molecules, one of which is cyanide. Because the transsulfuration of cyanide is the primary in vivo mechanism of detoxification, 3-mercaptopyruvate sulfurtransferase may function in the enzymatic detoxification of cyanide in vivo. Three α-keto acids (α-ketobutyrate, α-ketoglutarate, and pyruvate) have previously been demonstrated to be cyanide antidotes in vivo, and it has been suggested that this is due to the nonenzymatic binding of cyanide by the α-keto acid. However, it has also been proposed that α-keto acids may increase the activity of enzymes involved in the transsulfuration of cyanide. Thus, the effect of these three α-keto acids on the enzyme 3-mercaptopyruvate sulfurtransferase was examined. All three α-keto acids inhibited 3-mercaptopyruvate sulfurtransferase in a concentration-dependent manner and were determined to be uncompetitive inhibitors of MST with respect to 3-mercaptopyruvate. The inhibitor constant K_i was estimated by two methods for each inhibitor and ranged from 4.3 to 6.3 mM. The I₅₀, which is the inhibitor concentration that produces 50% inhibition, was calculated for all three α-keto acids and ranged between 9.5 and 13.7 mM. These observations add further support to the hypothesis that the mechanisms of the α-keto acid antidotes is the nonenzymatic binding of cyanide, not stimulation of enzymes involved in the transsulfuration of cyanide to thiocyanate. © 1996 John Wiley & Sons, Inc.     

Functional significance of aromatic amino acid: aromatic keto acid aminotransferases in rat brain and liver: competition for tryptophan between aminotransferases and tryptophan hydroxylase in vitro.

Using low concentrations of substrates and cofactors, a comparison was made of the relative rates by which aminotransferases catalysed transaminations between aromatic amino acids and aromatic or aliphatic keto acids. Tryptophan aminotransferase in homogenates of rat midbrain and liver transaminated phenylpyruvate at a rate 70 to 150-fold greater than the rate with α-ketoglutarate at low concentrations of substrates. Phenylalanine aminotransferase in liver and midbrain also was more active with aromatic keto acids than with aliphatic keto acids. However, tyrosine aminotransferase in dialysed homogenates of midbrain transaminated α-ketoglutarate and phenylpyruvate at approximately equal rates. Fresh homogenates of midbrain contained an inhibitor which markedly decreased tyrosine aminotransferase activity with α-ketoglutarate but not with phenylpyruvate. Tyrosine aminotransferase in homogenates of rat liver transaminated α-ketoglutarate and phenylpyruvate at equal rates below 10 μM keto acid, but above 10 μM, transamination of α-ketoglutarate was favoured. With homogenates of liver, transamination of α-ketoglutarate, but not phenylpyruvate, by tyrosine was increased 650% by exogenous pyridoxal phosphate. Since tryptophan aminotransferase in the brain may compete with tryptophan hydroxylase for available tryptophan, a comparison was made of the relative activities of tryptophan hydroxylase and tryptophan aminotransferase. At concentrations above 7.5 μM phenylpyruvate, transamination was 8 to 17-fold greater than the rate of hydroxylation of 50 μM tryptophan.     

α-KETOGLUTARATE UPTAKE IN HUMAN FIBROBLASTS

Glutamine requirements are increased during injury, in particular to sustain the needs of rapidly growing cells. This includes fibroblasts involved in wound healing. α-Ketoglutarate (α-KG) has been proved to be a potent precursor of glutamine. However, little is known about the process of its cell uptake. Since this first step could be crucial in α-KG metabolism, we have characterized α-ketoglutarate uptake in fibroblasts. Total uptake of α-ketoglutarate was linear up to 1mmol and temperature independent. Rate of uptake was independent of the presence of Na⁺in the medium. Competition studies with another ketoacid demonstrated the non-specificity of α-ketoglutarate uptake. In addition, 4-hydroxy-α-cyanocinnamate, a known inhibitor of anion transport, was ineffective on α-ketoglutarate uptake. Taken as a whole, these data provide evidence that α-ketoglutarate uptake in fibroblast occurs by an unmediated diffusion process. This suggests that α-ketoglutarate uptake is not the controlling step in fibroblasts, i.e. only the availability of extracellular α-ketoglutarate. This could be an advantage since during injury, cell membrane depolarization and dissipation of Na⁺gradient may limit cellular glutamine uptake.     

Complex Formation of Starch with Organic Substances

Cell free extracts of Hansenula miso IFO 0146 contained an enzyme which catalyzed acyloin condensation of acetaldehyde and α-ketoglutarate to form 5～hydroxy-4-ketohexanoic acid (HKH). The enzyme was specific for acetaldehyde and α-ketoglutarate. Condensation could not be demonstrated between α-ketoglutarate and other aldehydes tested (formaldehyde, propionaldehyde or butyraldehyde). No reaction occurred when boiled enzyme was used. The apparent Km values (at pH 7.5) for acetaldehyde and α-ketoglutarate are 24.4 mM and 3.2 mM, respectively. TPP and Mg²⁺ were not required for the reaction. The optimum pH of the reaction was 7.5～8.5. The reaction was inhibited by EDTA, PCMB and PMS. The enzyme forming HKH was different from that forming acetoin because the latter required TPP and was repressed when cells were grown in lactate medium while the former did not require TPP and was formed independently of its substrate. The product of this condensing reaction was isolated and identified as HKH from its chemical properties.     

Glutamine and α-ketoglutarate as glutamate sources for glutathione synthesis in human erythrocytes

Glutathione (GSH) is an intracellular antioxidant synthesized from glutamate, cysteine and glycine. The human erythrocyte (red blood cell, RBC) requires a continuous supply of glutamate to prevent the limitation of GSH synthesis in the presence of sufficient cysteine, but the RBC membrane is almost impermeable to glutamate. As optimal GSH synthesis is important in diseases associated with oxidative stress, we compared the rate of synthesis using two potential glutamate substrates, α-ketoglutarate and glutamine. Both substrates traverse the RBC membrane rapidly relative to many other metabolites. In whole RBCs partially depleted of intracellular GSH and glutamate, 10 mm extracellular α-ketoglutarate, but not 10 mm glutamine, significantly increased the rate of GSH synthesis (0.85 ± 0.09 and 0.61 ± 0.18 μmol·(L RBC)(-1) ·min(-1), respectively) compared with 0.52 ± 0.09 μmol·(L RBC)(-1) ·min(-1) for RBCs without an external glutamate source. Mathematical modelling of the situation with 0.8 mm extracellular glutamine returned a rate of glutamate production of 0.36 μmol·(L RBC)(-1) ·min(-1), while the initial rate for 0.8 mM α-ketoglutarate was 0.97 μmol·(L RBC)(-1) ·min(-1). However, with normal plasma concentrations, the calculated rate of GSH synthesis was higher with glutamine than with α-ketoglutarate (0.31 and 0.25?μmol·(L RBC)(-1) ·min(-1), respectively), due to the substantially higher plasma concentration of glutamine. Thus, a potential protocol to maximize the rate of GSH synthesis would be to administer a cysteine precursor plus a source of α-ketoglutarate and/or glutamine.     

Differences in properties between aromatic amino acid: Aromatic keto acid aminotransferases and aromatic amino acid: α-ketoglutarate aminotransferases

Homogenates of rat liver transaminate phenylpyruvate (PP), as well as α-ketoglutarate (α-KG), in the presence of L-tyrosine, 3,4-dihydroxyphenylalanine (L-DOPA) or L-tryptophan. Aminotransferase activity with phenylpyruvate and DOPA, but not with tyrosine, was inhibited by excess phenylpyruvate. Tyrosine and DOPA aminotransferase activities with phenylpyruvate were more heat stable than the corresponding activities with α-ketoglutarate. Aminotransferase activities with phenylpyruvate were not significantly induced following intraperitoneal injections of cortisol, glucagon or serotonin, compared with a 3 to 7-fold increase in the aminotransferase activities with α-ketoglutarate. Tyrosine:phenylpyruvate aminotransferase activity rose 40% at night, compared with a 300% increase in tyrosine:α-ketoglutarate aminotransferase activity. The results suggest that aminotransferases catalysing transfers between aromatic keto acids and aromatic amino acids are separate enzymes from those utilizing α-ketoglutarate as the acceptor keto acid.     

Resistance of tropoelastin and elastin peptides to degradation by alpha 2-macroglobulin-protease complexes

When α-ketoglutarate is the substrate, malate is a considerably more effective inhibitor of glutamate dehydrogenase than glutamate, oxalacetate, aspartate, or glutarate. Malate is a considerably poorer inhibitor when glutamate is the substrate. Malate is competitive with α-ketoglutarate, uncompetitive with TPNH, and noncompetitive with glutamate. The above, plus the fact that malate is a considerably more potent inhibitor when TPNH rather than TPN is the coenzyme, indicates that malate is predominantly bound to the α-ketoglutarate site of the enzyme-TPNH complex and has a considerably lower affinity for the enzyme-TPN complex. Ligands which decrease binding of TPNH to the enzyme such as ADP and leucine markedly decrease inhibition by malate. Conversely, GTP, which increases binding of TPNH to the enzyme also enhances inhibition by malate. Malate also decreases interaction between mitochondrial aspartate aminotransferase and glutamate dehydrogenase. This effect of malate on enzyme-enzyme interaction is enhanced by DPNH and GTP which also increase inhibition of glutamate dehydrogenase by malate and is decreased by TPN, ADP, ATP, α-ketoglutarate, and leucine which decrease inhibition of glutamate dehydrogenase by malate. These results indicate that malate could decrease α-ketoglutarate utilization by inhibiting glutamate dehydrogenase and retarding transfer of α-ketoglutarate from the aminotransferase to glutamate dehydrogenase. These effects of malate would be most pronounced when the mitochondrial level of α-ketoglutarate is low and the level of malate and reduced pyridine nucleotide is high.     

Properties of Wheat Mitochondria. Study of Substrates, Cofactors and Inhibitors

Isolated mitochondria of wheat shoots oxidize α- ketoglutarate, DL-malate succinate and NADH with good relative respiration control and ADP: O ratio. They have high affinity for α-ketoglutarate and NADH as substrates and utilize malate and succinate with a respiration ratio of about one-half of α-ketoglutarate. The average ADP : O ratios approach the expected theoretical values, i.e., 3.6 ± 0.2 for α-ketoglutarate, 1.8 ± 0.2 for succinate, and 2.8 ± 0.2 for malate. The ADP: O ratio with NADH is 1.8 ± 0.2. The maximum coupling of oxidation and phosphorylation is obtained at concentrations of 10 mM, 2 mM, 10 mM and 8 mM for α-ketoglutarate, NADH, malate and succinate, respectively. — Wheat mitochondria have little or no dependence on added cofactors. Mitochondria prepared by our procedure apparently retain sufficient amounts of endogenous cofactors required for NAD-linked systems. FAD⁺ is found to improve succinate oxidation. Cytochrome c does not have any significant effect on respiratory parameters of wheat mitochondria. — Wheat mitochondria are some -what resistant to DNP at 1.7 × 10^-5M. Malonate seems to improve coupling of α-ketoglutarate oxidation. Other Krebs cycle intermediates have been tested on three major substrates of TCA cycle, i.e., α-ketoglutarate, malate and succinate.     

Studies on the apparent instability of bovine kidney alpha-ketoglutarate dehydrogenase complex

The α-ketoglutarate dehydrogenase complex in extracts of bovine kidney and liver mitochondria is inactivated rapidly at 25 °C. This inactivation is not accompanied by loss of activity of the three component enzymes of the complex. This inactivation can be prevented by extensive washing of the mitochondria with dilute phosphate buffer prior to rupturing the mitochondria by freezing and thawing. Evidence is presented that the washings contain a protease which cleaves a peptide bond or bonds in the dihydrolipoyl transsuccinylase component of the α-ketoglutarate dehydrogenase complex, and this limited proteolysis results in dissociation of α-ketoglutarate dehydrogenase and dihydrolipoyl dehydrogenase from the transsuccinylase.The protease appears to be specific for the transsuccinylase component of the mammalian α-ketoglutarate dehydrogenase complex. It does not affect the activity of the mammalian pyruvate dehydrogenase complex or the Escherichia coli α-ketoglutarate dehydrogenase complex. The protease has been purified about 100-fold from extracts of unwashed mitochondria from bovine kidney. It requires a thiol for activity and it is not affected by treatment with diisopropyl phosphorofluoridate or phenylmethyl sulfonylfluoride.A component has been detected in highly purified preparations of the bovine kidney α-ketoglutarate dehydrogenase complex by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, which is present in trace amounts, if at all, in purified preparations of the bovine heart α-ketoglutarate dehydrogenase complex. This component is tightly bound to the transsuccinylase.     

Amaranth seed oil: Effect of oral administration on energetic functions of rat liver mitochondria activated with adrenaline

Respiration parameters of liver mitochondria (MCh) in rats fed with amaranth seed oil for 3 weeks have been evaluated. Thirty minutes before decapitation, adrenaline was injected intraperitoneally at a low dose (350 μg/kg body weight) to both control and experimental animals. It was shown that in animals that were injected with adrenaline and did not receive oil, the rate of phosphorylating respiration increased by 32% and phosphorylation time decreased by 22% upon oxidation of succinate; upon oxidation of α-ketoglutarate in the presence of the succinate dehydrogenase inhibitor malonate, phosphorylating respiration was activated by 23%. The respiration of MCh upon oxidation of succinate + glutamate and α-ketoglutarate in the absence of malonate was not affected by adrenaline. The intake of oil markedly activated almost all parameters of mitochondrial respiration in experimental rats upon oxidation of all above-listed substrates in both coupled and uncoupled MCh. However, phosphorylation time was close to the control value (upon oxidation of succinate) or increased (upon oxidation of α-ketoglutarate in the presence and absence of malonate). The injection of adrenaline to animals receiving oil did not affect the oil-activated respiration of MCh oxidizing the substrates used; however, phosphorylation time in all groups of animals decreased. Ca²⁺ capacity of MCh in rats receiving amaranth oil did not change. Thus, our data show that feeding of rats with amaranth oil activates mitochondrial respiration and prevents MCh hyperactivation induced by adrenaline.     

Malate oxidation, rotenone-resistance, and alternative path activity in plant mitochondria

The effect of cyanide and rotenone on malate (pH 6.8), malate plus glutamate (pH 7.8), citrate, α-ketoglutarate, and succinate oxidation by cauliflower (Brassica oleracea L.) bud, sweet potato (Ipomoea batatis L.) tuber, and spinach (Spinacia oleracea and Kalanchoë daigremontiana leaf mitochondria was investigated. Cyanide inhibited all substrates equally with the exception of malate plus glutamate; in this case, inhibition of O₂ uptake was more severe due to an effect of cyanide on aspartate aminotransferase. Azide and antimycin A gave similar inhibitions with all substrates. Subsequent addition of NAD had no effect with any substrate. Providing that oxalacetate accumulation was prevented, rotenone inhibited all NAD-linked substrates equally and caused ADP:O ratios to decrease by one-third. Addition of succinate to mitochondria oxidizing malate stimulated oxygen uptake, but adding citrate and α-ketoglutarate did not. These results indicate that there is no direct link between malic enzyme and the rotenone- and cyanide-resistant respiratory pathways, and that there is no need to postulate separate compartmentation of malic enzyme and the other NAD-linked enzymes in the matrix.     

Accumulation of α-Keto Acids as Essential Components in Cyanide Assimilation by Pseudomonas fluorescens NCIMB 11764

Pyruvate (Pyr) and α-ketoglutarate (αKg) accumulated when cells of Pseudomonas fluorescens NCIMB 11764 were cultivated on growth-limiting amounts of ammonia or cyanide and were shown to be responsible for the nonenzymatic removal of cyanide from culture fluids as previously reported (J.-L. Chen and D. A. Kunz, FEMS Microbiol. Lett. 156:61–67, 1997). The accumulation of keto acids in the medium paralleled the increase in cyanide-removing activity, with maximal activity (760 μmol of cyanide removed min⁻¹ ml of culture fluid⁻¹) being recovered after 72 h of cultivation, at which time the keto acid concentration was 23 mM. The reaction products that formed between the biologically formed keto acids and cyanide were unambiguously identified as the corresponding cyanohydrins by ¹³C nuclear magnetic resonance spectroscopy. Both the Pyr and α-Kg cyanohydrins were further metabolized by cell extracts and served also as nitrogenous growth substrates. Radiotracer experiments showed that CO₂ (and NH₃) were formed as enzymatic conversion products, with the keto acid being regenerated as a coproduct. Evidence that the enzyme responsible for cyanohydrin conversion is cyanide oxygenase, which was shown previously to be required for cyanide utilization, is based on results showing that (i) conversion occurred only when extracts were induced for the enzyme, (ii) conversion was oxygen and reduced-pyridine nucleotide dependent, and (iii) a mutant strain defective in the enzyme was unable to grow when it was provided with the cyanohydrins as a growth substrate. Pyr and αKg were further shown to protect cells from cyanide poisoning, and excretion of the two was directly linked to utilization of cyanide as a growth substrate. The results provide the basis for a new mechanism of cyanide detoxification and assimilation in which keto acids play an essential role.     

The effect of cosubstrates on tricarboxylic acid cycle dynamics during pyruvate oxidation: the formation of alpha-ketoglutarate and utilization of glutamate by mitochondria from rabbit brain.

—Data comparing tricarboxylic acid cycle dynamics in mitochondria from rabbit brain using [2- or 3-¹⁴C]pyruvate with and without cosubstrates (malate, α-ketoglutarate, glutamate) are reported. With a physiological concentration of an unlabelled cosubstrate, from 90-99% of the isotope remained in cycle intermediates. However, the liberation of ¹⁴CO₂ and the presence of ¹⁴C in the C-1 position of α-ketoglutarate indicated that multiple turns of the cycle occurred. Entry of pyruvate into the cycle was greater with malate than with either α-ketoglutarate or glutamate as cosubstrate. With malate as cosubstrate for [¹⁴C]pyruvate the amount of [¹⁴C]citrate which accumulated averaged 30nmol/ml or 23% of the pyruvate utilized while α-ketoglutarate averaged 45 nmol/ml or 35% of the pyruvate utilized. With α-ketoglutarate as cosubstrate for [¹⁴C]pyruvate, the average amount of [¹⁴C]citrate which accumulated decreased to 8 nmol/ml or 10% of the pyruvate utilized while [¹⁴C]α-ketoglutarate increased slightly to 52 nmol/ml or an increase to 62%, largely due to a decrease in pyruvate utilization. The percentage of ¹⁴C found in α-ketoglutarate was always greater than that found in malate, irrespective of whether α-ketoglutarate or malate was the cosubstrate for either [2- or 3-¹⁴C]pyruvate. The fraction of ¹⁴CO₂ produced was slightly greater with α-ketoglutarate as cosubstrate than with malate. This observation and the fact that malate had a higher specific activity than did α-ketoglutarate when α-ketoglutarate was the cosubstrate, indicated a preferential utilization of α-ketoglutarate formed within the mitochondria. When l -glutamate was a cosubstrate for [¹⁴C]pyruvate the principal radioactive product was glutamate, formed by isotopic exchange of glutamate with [¹⁴C] α-ketoglutarate. If malate was also added, [¹⁴C]citrate accumulated although pyruvate entry did not increase. Due to retention of isotope in glutamate, little [¹⁴C]succinate, malate or aspartate accumulated. When [U-¹⁴C]l -glutamate was used in conjunction with unlabelled pyruvate more ¹⁴C entered the cycle than when unlabelled glutamate was used with [¹⁴C]pyruvate and led to α-ketoglutarate, succinate and aspartate as the major isotopic products. When in addition, unlabelled malate was added, total and isotopic α-ketoglutarate increased while [¹⁴C]aspartate decreased. The increase in [¹⁴C]succinate when [¹⁴C] glutamate was used indicated an increase in the flux through α-ketoglutarate dehydrogenase and was accompanied by a decrease of pyruvate utilization as compared to experiments when either α-ketoglutarate or glutamate were present at low concentration. It is concluded that the tricarboxylic acid cycle in brain mitochondria operates in at least three open segments, (1) pyruvate plus malate (oxaloacetate) to citrate; (2) citrate to α-ketoglutarate and; (3) α-ketoglutarate to malate, and that at any given time, the relative rates of these segments depend upon the substrate composition of the environment of the mitochondria. These data suggest an approach to a steady state consistent with the kinetic properties of the tricarboxylic acid cycle within the mitochondria.     

Cellular localization of α-ketoglutarate: Glyoxylate carboligase in rat tissues

α-Ketoglutarate : glyoxylate carboligase activity has been reported by other laboratories to be present in mitochondria and in the cytosol of mammalian tissues; the mitochondrial activity is associated with the α-ketoglutarate decarboxylase moiety of the α-ketoglutarate dehydrogenase complex. The cellular distribution of the carboligase has been re-examined here using marker enzymes of known localization in order to monitor the composition of subcellular fractions prepared by differential centrifugation. Carboligase activity paralleled the activity of the mitochondrial matrix enzyme citrate synthase in subcellular fractions prepared from rat liver, heart and brain as well as from rabbit liver. Whole rat liver mitochondria upon lysis released both carboligase and citrate synthase. The activity patterns of several other extramitochondrial marker enzymes differed significantly from that of carboligase in rat liver. In addition, the distribution pattern of carboligase was similar to that of α-ketoglutarate decarboxylase and of α-ketoglutarate dehydrogenase complex.The data indicate that α-ketoglutarate : gloxylate carboligase activity is located exclusively within the mitochondria of the rat and rabbit tissues investigated. There is no evidence for a cytosolic form of the enzyme. Thus the report from another laboratory that the molecular etiology of the human genetic disorder hyperoxaluria type I is a deficiency of cytosolic carboligase must be questioned.     

Indole-3-Pyruvic Acid as an Intermediate in the Conversion of Tryptophan to Indole-3-Acetic Acid. I. Some Characteristics of Tryptophan Transaminase from Mung Bean Seedlings

Seedlings of mung bean (Phaseolus aureus) contain a soluble enzyme capable of converting l-tryptophan to indole-3-pyruvic acid by transamination. The concentration of the enzyme is highest in the stem meristem and primary leaves and lowest in the roots. The enzyme was purified 28.6 fold by ammonium sulphate precipitation, Sephadex G-200 filtration, and electrophoresis. The isoelectric point of the enzyme protein was pH 6.6. The optimum pH and temperature for the catalytic conversion were ca. 8.5 and 53°C respectively. Using l -tryptophan and α-ketoglutarate as substrates Km was found to be 3.3 × 10^?4 M and the activation energy 18,270 cal per mole. The enzyme converted only the l -form of tryptophan, phenylalanine, tyrosine, and histidine. Out of 13 other l -amino acids tested 8 could be transaminated. Eight α-keto acids tested could all be used as substrates. High efficiency of an α-keto acid as an amino group acceptor agreed usually with high efficiency of the corresponding amino acid as a donor. The pari ß-methyl-α-ketoisovaleric acid and isoleucine was an exception to that rule. Addition of pyridoxalphosphate to the reaction mixture was not needed. The indole-3-pyruvic acid formed in the reaction was trapped and partly stabilized as its borate complex and measured spectrophotometrically at 327 nm. The keto acid formed was further identified by chromatography of its 2,4-dinitrophenylhydrazone in 4 solvent systems. When using α-keto-glutaric acid as a substrate, the glutamic acid produced was determined by the glutamate dehydrogenase method. The sensitivity of the assay permits enzyme determinations in extracts from 5 mg leaves or 100 mg roots.     

Using substrate analogues to probe the kinetic mechanism and active site of Escherichia coli MenD

MenD catalyzes the thiamin diphosphate-dependent decarboxylative carboligation of α-ketoglutarate and isochorismate. The enzyme is essential for menaquinone biosynthesis in many bacteria and has been proposed to be an antibiotic target. The kinetic mechanism of this enzyme has not previously been demonstrated because of the limitations of the UV-based kinetic assay. We have reported the synthesis of an isochorismate analogue that acts as a substrate for MenD. The apparent weaker binding of this analogue is advantageous in that it allows accurate kinetic experiments at substrate concentrations near K(m). Using this substrate in concert with the dead-end inhibitor methyl succinylphosphonate, an analogue of α-ketoglutarate, we show that MenD follows a ping-pong kinetic mechanism. Using both the natural and synthetic substrates, we have measured the effects of 12 mutations of residues at the active site. The results give experimental support to previous models and hypotheses and allow observations unavailable using only the natural substrate.     

Inhibition of p-nitroanisole O-demethylation in perfused rat liver by potassium cyanide

The effect of potassium cyanide on p-nitroanisole O-demethylation in perfused rat livers has been examined. Cyanide (2 mm), an inhibitor of cytochrome oxidase, diminished p-nitroanisole O-demethylation by 50–75% in perfused livers from normal and phenobarbital-treated rats, but had much less effect on hepatic microsomal p-nitroanisole O-demethylation. The inhibition was also observed in livers where the activity of the pentose phosphate shunt was abolished by pretreatment with 6-aminonicotinamide. Cyanide infusion decreased hepatic $\text{ATP}\text{ADP}$ ratios and cellular concentrations of glutamate, α-ketoglutarate, and isocitrate, but caused an increase in the $\text{NADPV}{}^{\mathrm{+}}\text{NADPH}$ ratio. Rates of NADPH generation via the pentose phosphate shunt were unchanged by cyanide, and hepatic concentrations of glucose 6-phosphate were markedly increased by cyanide. Thus, inhibition of p-nitroanisole metabolism could not be explained solely by a direct interaction of cyanide with mixed-function oxidases or diminished NADPH generation via the pentose cycle. These data indicate that cyanide inhibits mixed-function oxidation in intact cells by diminishing the generation of NADPH from sources other than the pentose cycle. Further, these data are consistent with the hypothesis that some NADPH for mixed-function oxidation arises from cyanidesensitive mitochondrial sources.     

Ionic control of renal gluconeogenesis IV. Effect of extracellular phosphate concentration

Isolated rat renal tubules from glucose from pyruvate, malate, glycerol and α-ketoglutarate. The rate of glucose formation from all but glycerol is enhanced by an increase in Ca²⁺ concentration. Because changes in inorganic phosphate concentrations influence the uptake and retention of calcium by isolated cells, the effect of changes in phosphate concentration upon renal gluconeogenesis was examined. It was found that changing phosphate concentration altered the metabolism of isolated rat renal tubules in three ways which dependend upon the Ca²⁺ concentration. In the absence of Ca²⁺, increasing phosphate concentration from 0.07 to 1.2 mM led to a stimulation of the decarboxylation of [U-¹⁴C]malate, [1-14C]pyruvate, [2-¹⁴C]-pyruvate, α-keto[5-¹⁴C]glutarate and [1,3-¹⁴C₂]glycerol, and to an increase in ATP concentration but had no effect upon the rate of glucose formation from malate, pyruvate, α-ketoglutarate but a slight stimulation of glucose production from glycerol. A further increase in phosphate above 1.2 mM had no effect on any of these parameters. In the presence of either low (0.2 mM) or high (2.0 mM) Ca²⁺, changing phosphate concentration had no effect upon the decarboxylation of any of these substrates except glycerol whose decarboxylation was stimulated by increasing medium phosphate concentration. In the presence of calcium, increasing phosphate concentration led to an inhibition of glucose formation from malate, pyruvate and α-ketoglutarate but not from glycerol. Also in the presence of calcium both parathyroid hormone and cyclic AMP stimulated glucose formation, and under these conditions increasing phosphate concentration led to an inhibition of glucose formation. In tubules treated with parathyroid hormone an increase in phosphate concentration from 0.07 to 6.0 mM led to a significant increase in cyclic AMP concentration even though the rate of glucose formation decreased.Analysis of metabolite concentrations and rates of substrates decarboxylations, under a variety of conditions, revealed that P_i altered renal gluconeogenesis at a site different from those controlled by changes in Ca²⁺ concentration. The P_i-control site was tentatively identified as the glyceraldehyde phosphate dehydrogenase-glycerate kinase reaction sequence. However, the effect of changing P_i concentration upon parathyroid hormone-induced alterations in cyclic AMP concentration could not be explained by this action of P_i, and was probably due to an effect of P_i upon cellular calcium distribution. Thus, changes in P_i concentration appear to have two cellular effects, only one of which is related to a change in cellular calcium metabolism.