Regulation of malate oxidation in isolated mung bean mitochondria: I. Effects of oxaloacetate, pyruvate, and thiamine pyrophosphate

Regulation by Magnesium of Potato Tuber Mitochondrial Respiratory Activities

Dehydrogenase activities of potato tuber mitochondria and corresponding phosphorylation rates were measured for the dependence on external and mitochondrial matrix Mg2+. Magnesium stimulated state 3 and state 4 respiration, with significantly different concentrations of matrix Mg2+ required for optimal activities of the several substrates. Maximal stimulation of respiration with all substrates was obtained at 2-mM external Mg2+. However, respiration of malate, citrate, and alpha-ketoglutarate requires at least 4-mM Mg2+ inside mitochondria for maximization of dehydrogenase activities. The phosphorylation system, requires a low level of internal Mg2+ (0.25 mM) to reach high activity, as judged by succinate-dependent respiration. However, mitochondria respiring on citrate or alpha-ketoglutarate only sustain high levels of phosphorylation with at least 4-mM matrix Mg2+. Respiration of succinate is active without external and matrix Mg2+, although stimulated by the cation. Respiration of alpha-ketoglutarate was strictly dependent on external Mg2+ required for substrate transport into mitochondria, and internal Mg2+ is required for dehydrogenase activity. Respiration of citrate and malate also depend on internal Mg2+ but, unlike alpha-ketoglutarate, some activity still remains without external Mg2+. All the substrates revealed insensitive to external and internal mitochondrial Ca2+, except the exogenous NADH dehydrogenase, which requires either external Ca2+ or Mg2+ for detectable activity. Calcium is more efficient than Mg2+, both having cumulative stimulation. Unlike Ca2+, Mn2+ could substitute for Mg2+, before and after addition of A23, showing its ability to regulate phosphorylation and succinate dehydrogenase activities, with almost the same efficiency as Mg2+.

On the Metabolic Relationship between the Calvin Cycle and the Tricarboxylic Acid Cycle: IV. A Plant Survey for Anomalous Acetyl Coenzyme A

Leaves of 10 randomly selected plants representing eight dicotyledonous families were exposed to (14)CO(2) for a 10-minute period in the light. Citrate and alanine were isolated, purified isotopically, and degraded to obtain the (14)C-isotope distribution of corresponding carbon atoms, i.e. citrate (C-1,2) and alanine (C-2,3). The cited carbon atoms of alanine were equally labeled as is typical of a 3-carbon intermediate derived from photosynthetic 3-phosphoglycerate. The carbon atoms of citrate, equivalent to acetyl-CoA, were unequally labeled. The citrate (C-1,2) isotope ratio ranged from 1.20 to 1.78 for the various plants compared to a ratio of unity in the uniformly labeled control. The results infer that 3-phosphoglycerate produced in the chloroplast is not the singular precursor of mitochondrial citrate.

Regulation of plant pyruvate dehydrogenase complex by phosphorylation

The ATP-dependent inactivation of the pyruvate dehydrogenase complex (PDC) was examined using ruptured mitochondria and partially purified pyruvate dehydrogenase complex isolated from broccoli and cauliflower (Brassica oleracea) bud mitochondria. The ATP-dependent inactivation was temperature- and pH-dependent. [(32)P]ATP experiments show a specific transphosphorylation of the gamma-PO(4) of ATP to the complex. The phosphate attached to the PDC was labile under mild alkaline but not under mild acidic conditions. The inactivated-phosphorylated PDC was not reactivated by 20 mm MgCl(2), dialysis, Sephadex G-25 treatment, apyrase action, or potato acid phosphatase action. However, partially purified bovine heart PDC phosphatase catalyzed the reactivation and dephosphorylation of the isolated plant PDC. The ATP-dependent inactivation-phosphorylation of the PDC was inhibited by pyruvate. It is concluded that the ATP-dependent inactivation-phosphorylation of broccoli and cauliflower mitochondrial PDC is catalyzed by a PDC kinase. It is further concluded that the PDC from broccoli and cauliflower mitochondria is capable of interconversion between an active (dephosphorylated) and an inactive (phosphorylated) form.

Citric Acid cycle activity in mitochondria isolated from mung bean hypocotyls

Citric acid cycle activity in mitochondria from mung bean (Phaseolus aureus var. Jumbo) hypocotyls were examined by surveying (a) characteristics of oxidation of cycle intermediates; (b) activities of cycle enzymes in mitochondrial extracts; (c) contents of cycle intermediates and electron transport components in isolated mitochondria; and (d) time-course changes of products formed during oxidation of succinate, malate, and citrate. Isolated mitochondria are deficient in thiamine pyro-phosphate and somewhat so in adenylates, but apparently sufficient in CoA, NAD, and electron transport carriers. Cycle activity in the mitochondria is not directly correlated with the activities of the enzymes measured in extracts. These studies led to the conclusion that the region between malate and citrate is an important regulatory area in citric acid cycle functioning in isolated mung bean mitochondria.

Regulation of Malate Oxidation in Isolated Mung Bean Mitochondria: II. Role of Adenylates

Effects of ADP and ATP on products of malate oxidation in the presence or absence of respiratory inhibitors and an uncoupler were investigated in mitochondria isolated from mung bean (Phaseolus aureus var. Jumbo) hypocotyls. Changes in levels of products from malate oxidation generally correlated directly with changes in oxygen uptake. Effects of ADP and ATP were indistinguishable from each other when respiratory chain activity was limited. We concluded that adenylates indirectly act on malate oxidation via the oxidation-reduction status of the pyridine nucleotides which are linked to the respiratory chain. The possibility of allosteric action of ADP and ATP on malate dehydrogenase activity was examined in both intact mitochondria and a partially purified enzyme preparation. Although small inhibition, 16% with 500 muM ATP and 8% with 500 muM ADP, was observed at pH 9.5, this effect was abolished by the addition of magnesium ions or by lowering the pH to 7.2. We concluded that these adenylate effects are probably not a significant factor in regulation under physiological conditions. Furthermore, the equilibrium constant of malate dehydrogenase (to 1.5 x 10(-5)) in both mitochondria and the partially purified enzyme calculated from the steady state level of NADH formed suggested that the enzyme functions in an equilibrium manner in intact mitochondria.