Enhanced Endogenous Amino Acids and Energy Metabolism Level for cAMP Biosynthesis by Arthrobacter sp. CCTCC 2013431 with Citrate as Cosubstrate

Objectives In our previous study, citrate was used as auxiliary energy substance for improving cAMP fermentation performance, however, the regulation mechanism of citrate on improved cAMP contents was not clear. To elucidate the regulation mechanism, cAMP fermentations with/without citrate addition were conducted in a 7 L fermentor using Arthrobacter sp. CCTCC 2013431 and assays on key enzymes activities, energy metabolism level, amino acids contents and peroxidation level were performed. Results With 3 g/L-broth sodium citrate added, cAMP concentration and conversion yield from glucose reached 4.34 g/L and 0.076 g/g which were improved by 30.7% and 29.8%, respectively, when compared with those of control. Citrate changed carbon flux distribution among different routes and more carbon flux was directed into pentose phosphate pathway beneficial to cAMP synthesis. Meanwhile, energy metabolism together with precursor amino acids levels were improved significantly owing to strengthened metabolic intensity of tricarboxylate cycle by exogenous citrate utilization which provided energy and substance basis for cAMP production. Moreover, higher glutamate synthesis and oxidative stress caused by citrate addition consumed excessive NADPH derived from pentose phosphate pathway by which feedback suppression for pentose phosphate pathway was relieved efficiently.Conclusion Citrate promoted cAMP fermentation production by Arthrobacter sp. CCTCC2013431 due to enhanced precursor amino acids, energy metabolism level and relieved feedback suppression for pentose phosphate pathway.

Altered pyruvate dehydrogenase control and mitochondrial free Ca2+ in hearts of cardiomyopathic hamsters

The fraction of total pyruvate dehydrogenase in the active, dephosphorylated form is much lower in the glucose-perfused isolated hearts of two myopathic strains of Syrian hamster (BIO 14.6 and TO-2) than in the hearts of healthy control animals (F1B). The myopathic hearts also develop significantly less pressure under these conditions. Experiments with isolated myocytes from the BIO 14.6 heart reveal that intramitochondrial free Ca2+ ([Ca2+]m), a positive effector of pyruvate dehydrogenase interconversion, rises much less in response to a protocol of increased frequency of electrical stimulation and adrenergic stimulation than does [Ca2+]m in cells from the healthy control animals (viz from 248 +/- 15 to 348 +/- 44 nM in BIO 14.6 vs. from 241 +/- 35 to 830 +/- 124 nM in F1B, at 4 Hz). As the concentration of Ca2+ that produces half-maximal activation of pyruvate dehydrogenase within mitochondria is 650 nM, this difference between strains is likely the mechanism of the altered enzyme interconversion. The lesser response of [Ca2+]m to electrical stimulation in the BIO 14.6 cells probably results mainly from smaller systolic transients in cytosolic free Ca2+ in response to excitation of single myocytes from the BIO 14.6 animal. Lowered values of [Ca2+]m within the range described would compromise not only pyruvate dehydrogenase activity, but also flux through the tricarboxylate cycle in the myopathic heart, owing to the sensitivity of 2-oxoglutarate dehydrogenase to Ca2+. This may explain the decreased activity of oxidative phosphorylation and performance of work in the myopathic heart.

Effect of micromolar concentrations of free calcium ions on the reduction of heart mitochondrial NAD(P) by 2-oxoglutarate

1. The reduction of mitochondrial NAD(P) by 2-oxoglutarate was monitored as a measure of 2-oxoglutarate dehydrogenase activity in its intramitochondrial locale. In the absence of ADP, steady-state reduction of NAD(P) by 0.5 mM-2-oxoglutarate in the presence of 0.5 mM-L-malate was markedly increased by extramitochondrial Ca2+, with 50% activation at pCa 6.58, when the Na+ concentration was 10 mM, the Pi concentration ws 5 mM and the added Mg2+ concentration was 1 mM. Omission of Pi resulted in 50% activation at pCa 6.77; omission of Mg2+ resulted in 50% activation at pCA greater than or equal to 7.3. 2. The activation of 2-oxoglutarate dehydrogenase could be reversed on addition of an excess of EGTA. The rate of inactivation was dependent on the concentration of Na+, with K0.5 2.5 mM, which is consistent with the rate of withdrawal of Ca2+ from the mitochondria being the limiting factor. 3. The steady-state reduction of cytochrome c by 2-oxoglutarate (0.5 mM) also showed a marked dependence on pCa in the absence of ADP; in the presence of an excess of ADP, no such effect of Ca2+ was detectable. 4. Mitochondria from the hearts of senescent rats showed an undiminished rate of dehydrogenase activation by Ca2+ but a rate of inactivation by excess EGTA that was diminished by 40%. Direct studies of Ca2+ egress with Arsenazo III confirmed a decrement in rate with old age. 5. Studies of 2-oxoglutarate dehydrogenase activity as a function of the mitochondrial context of Ca2+, as measured by atomic-absorption spectrophotometry, showed half-maximal activation at a mitochondrial content of 1.0 nmol of Ca2+/mg of protein, and saturation at 3 nmol/mg. 6. These findings support the model advanced by Denton, Richards & Chin [(1978) Biochem. J. 176, 899-906], of a control of the tricarboxylate cycle by intramitochondrial Ca2+, and demonstrate the range of mitochondrial Ca2+ content over which this may occur. In addition, they raise the possibility of a disturbance of this control mechanism in old age.

Purification by affinity chromatography of a membrane dicarboxylate binding protein from Bacillus subtilis

Membrane vesicles of Bacillus subtilis W23 actively transport the C4 and C5 dicarboxylates of the tricarboxylate cycle by system(s) of relatively high affinity for their requisite substrates (Km 4–53 μM). Glutamate and succinate binding activities were readily solubilized from membrane vesicles by nonionic detergents, particularly by Lubrol WX. From this extract, glutamate binding activity was highly enriched by affinity chromatography on phloroglucinol-expanded Sepharose-6B to which L-aspartate was coupled via divinylsulfone. Another protein (41 000 molecular weight), which bound both L-glutamate and L-malate, was purified from affinity columns to which either L-glutamate or L-malate had been coupled via bisdiglycidyl ether. This protein bound labelled L-malate as well as L-glutamate with affinities similar to those seen with membrane vesicles (Kd's 8 μML-malate and 52 μML-glutamate).

The nature and control of the tricarboxylate cycle in beetle flight muscle

The only exogenous substrates oxidized by mitochondria isolated from the flight muscle of the Japanese beetle (Popillia japonica) are proline, pyruvate and glycerol 3-phosphate. The highest rate of oxygen consumption is obtained with proline. The oxidation of proline leads to the production of more NH3 than alanine, indicating a functioning glutamate dehydrogenase (EC 1.4.1.2). Studies of mitochondrial extracts confirm the presence of a very active glutamate dehydrogenase, and this enzyme is found to be activated by ADP and inhibited by ATP. These extracts also show high alanine aminotransferase activity (EC 2.6.1.2) and a uniquely active “malic’ enzyme (EC 1.1.1.39). The “malic’ enzyme is activated by succinate and inhibited by ATP and by pyruvate. It is suggested that the input of tricarboxylate-cycle intermediate from proline oxidation is balanced by the formation of pyruvate from malate, and the complete oxidation of the majority of the pyruvate. Studies of the steady-state concentrations of mitochondrial CoASH and CoA thioesters during proline oxidation show a high succinyl (3-carboxypropionyl)-CoA content which falls on activating respiration with ADP. There is a concomitant rise in CoASH. However, the reverse transition, from state-3 to state-4 respiration, causes only very slight changes in acylation. The reasons for this are discussed. Studies of the mitochondrial content of glutamate, 2-oxoglutarate, malate, pyruvate, citrate and isocitrate during the same phases of proline oxidation give results consistent with control at the level of glutamate dehydrogenase and isocitrate dehydrogenase during proline oxidation, with the possibility of further control at “malic’ enzyme. During the oxidation of pyruvate all of the tricarboxylate-cycle intermediates and NAD(P)H follow the pattern of changes described in the blowfly (Johnson & Hansford, 1975; Hansford, 1974) and isocitrate dehydrogenase is identified as the primary site of control.?2OAuthor