The oxidation of choline by liver slices and mitochondria during liver development in the rat

Betaine is the major oxidation product of [Me-¹⁴C] choline produced by rat liver slices. Liver slices from adult rats rapidly oxidize [Me-¹⁴C] choline to betaine and the bulk of the betaine produced is recovered in the incubation medium. Considerably more choline is oxidized to betaine than is phosphorylated to phosphorylcholine. The rate of phosphorylation of choline appears to be independent of the rate of choline oxidation. Liver slices from fetal and young rats oxidize choline to betaine at a lower rate than adult liver slices.The ability of mitochondria to oxidize [Me-¹⁴C] choline to betaine aldehyde and betaine is considerably lower in fetal liver than in adult liver. The major product with both fetal and adult mitochondria is betaine aldehyde. Choline oxidation by mitochondria begins to increase 1 day prior to birth and increases progressively to adult levels by 18 days. The developmental pattern for choline oxidation is similar to the pattern for succinic dehydrogenase activity.     

A possible mechanism for the increased oxidation of choline after chronic ethanol ingestion.

An attempt has been made to determine the location of the site at which the metabolism of ethanol interacts with that of choline to produce an increase in the oxidation of choline. The first enzyme in the oxidation pathway for choline, choline dehydrogenase, was assayed using a newly developed spectrophotometric assay and freshly isolated intact rat liver mitochondria. No changes were observed in either 'apparent' V or the 'apparent' Km values of choline dehydrogenase for choline after ethanol ingestion. However, when the choline oxidase system was assayed, a 28% decrease in 'apparent' Km for choline and a 53% increase in 'apparent' V was observed. The effects of ATP on choline oxidase were studied further, and a 29.4% decrease was observed in mitochondrial ATP levels from freshly isolated mitochondria from the ethanol-treated rats. In vitro aging of mitochondria further decreased the level of ATP, and the rate of decrease was considerably faster during the first hour in the mitochondria from the ethanol-treated animals. The decreases in ATP from both control and experimental mitochondria were accompanied by increases in choline oxidase activity. The initial decrease in ATP was correlated with an increase in mitochondrial ATPase activity which may be related to an increase in mitochondria Mg2+. Because chronic ethanol ingestion has resulted in decreased oxidation rates of succinate and beta-hydroxybutyrate while at the same time increasing the oxidation rates of choline, the studies reported here suggest that the effect of chronic ethanol ingestion is primarily on a step that is unique to choline and which probably exists prior to the electron transport chain.     

Transport and oxidation of choline by liver mitochondria

1. Rapid choline oxidation and the onset of P(i)-induced swelling by liver mitochondria, incubated in a sucrose medium at or above pH7.0, required the addition of both P(i) and an uncoupling agent. Below pH7.0, P(i) alone was required for rapid choline oxidation and swelling. 2. Choline oxidation was inhibited by each of several reagents that also inhibited P(i)-induced swelling under similar conditions of incubation, including EGTA, mersalyl, Mg(2+), the Ca(2+)-ionophore A23187, rotenone and nupercaine. None of these reagents had any significant effect on the rate of choline oxidation by sonicated mitochondria. There was therefore a close correlation between the conditions required for rapid choline oxidation and for P(i)-induced swelling to occur, suggesting that in the absence of mitochondrial swelling the rate of choline oxidation is regulated by the rate of choline transport across the mitochondrial membrane. 3. Respiratory-chain inhibitors, uncoupling agents (at pH6.5) and ionophore A23187 caused a loss of endogenous Ca(2+) from mitochondria, whereas nupercaine and Mg(2+) had no significant effect on the Ca(2+) content. Inhibition of choline oxidation and mitochondrial swelling by ionophore A23187 was reversed by adding Ca(2+), but not by Mg(2+). It is concluded that added P(i) promotes the Ca(2+)-dependent activation of mitochondrial membrane phospholipase activity in respiring mitochondria, causing an increase in the permeability of the mitochondrial inner membrane to choline and therefore enabling rapid choline oxidation to occur. Nupercaine and Mg(2+) appear to block choline oxidation and swelling by inhibiting phospholipase activity. 4. Choline was oxidized slowly by tightly coupled mitochondria largely depleted of their endogenous adenine nucleotides, suggesting that these compounds are not directly concerned in the regulation of choline oxidation. 5. The results are discussed in relation to the possible mechanism of choline transport across the mitochondrial membrane in vivo and the influence of this process on the pathways of choline metabolism in the liver.     

Uncoupler-stimulated oxidation of choline by rat-liver mitochondria

The main product of uncoupler-stimulated oxidation of choline by rat-liver mitochondria is betaine, which is found almost exclusively extramitochondrially. The uncoupled oxidation of choline is stimulated by intramitochondrial phosphate. The effect of intramitochondrial phosphate is to induce adenine nucleotide efflux, which in its turn allows the efflux of betaine from the mitochondria.     

A possible mechanism for the increased oxidation of choline after chronic ethanol ingestion

An attempt has been made to determine the location of the site at which the metabolism of ethanol interacts with that of choline to produce an increase in the oxidation of choline. The first enzyme in the oxidation pathway for choline, choline dehydrogenase, was assayed using a newly developed spectro-photometric assay and freshly isolated intact rat liver mitochondria. No changes were observed in either the ‘apparent’ V or the ‘apparent’ K_m values of choline dehydrogenase for choline after ethanol ingestion. However, when the choline oxidase system was assayed, a 28% decrease in ‘apparent’ K_m for choline and a 53% increase in ‘apparent’ V was observed. The effects of ATP on choline oxidase were studied further, and a 29.4% decrease was observed in mitochondrial ATP levels from freshly isolated mitochondria from the ethanoltreated rats. In vitro aging of mitochondria further decreased the level of ATP, and the rate of decrease was considerably faster during the first hour in the mitochondria from the ethanol-treated animals. The decreases in ATP from both control and experimental mitochondria were accompanied by increases in choline oxidase activity. The initial decrease in ATP was correlated with an increase in mitochondrial ATPase activity which may be related to an increase in mitochondrial Mg²⁺. Because chronic ethanol ingestion has resulted in decreased oxidation rates of succinate and β-hydroxybutyrate while at the same time increasing the oxidation rates of choline, the studies reported here suggest that the effect of chronic ethanol ingestion is primarily on a step that is unique to choline and which probably exists prior to the electron transport chain.     

Influence of ubiquinone on the inhibitory effect of adriamycin on mitochondrial oxidative phosphorylation.

The inhibition of succinate oxidation in both heart and liver mitochondria by the cardiotoxic anticancer antibiotic adriamycin in vitro was reversed to a large extent by exogenous ubiquinone-45. Inhibition of the oxidation of NAD+-linked substrates in heart and liver mitochondria responded differently to ubiquinone, the inhibition being reversed only in liver organelles. Administration of adriamycin inhibited oxidative phosphorylation in rat heart, kidney and liver mitochondria, the inhibition being highest in the heart organelles (about 50% for both NAD+-linked substrates and succinate). Exogenous addition of ubiquinone to mitochondria isolated from drug-treated animals did not reverse the inhibition. Administration of ubiquinone along with adriamycin did not change effectively the pattern of drug-mediated decrease in oxidative activity of the organelles, particularly in the heart.     

Control of choline oxidation by rat-liver mitochondria

The steady-state concentrations of choline and its reaction products in intact rat-liver mitochondria were determined under different conditions. From these measurements, it is concluded that in a sucrose medium choline dehydrogenation and betaine aldehyde dehydrogenation are the rate-limiting steps in overall choline oxidation under “State-3” or uncoupled conditions, respectively.Ageing of the mitochondria leads to changes in the mitochondrial membrane, resulting in a markedly different pattern of oxidation products. This finding explains why rotenone inhibits oxygen uptake with choline as substrate in fresh but not in aged mitochondria.     

Control of choline oxidation by rat-liver mitochondria.

The steady-state concentrations of choline and its reaction products in intact rat-liver mitochondria were determined under different conditions. From these measurements, it is concluded that in a sucrose medium choline dehydrogenation and betaine aldehyde dehydrogenation are the rate-limiting steps in overall choline oxidation under "State-3" or uncoupled conditions, respectively. Ageing of the mitochondria leads to changes in the mitochondrial membrane, resulting in a markedly different pattern of oxidation products. This finding explains why rotenone inhibits oxygen uptake with choline as substrate in fresh but not in aged mitochondria.     

Choline oxidation and choline dehydrogenase

The oxidation of choline by both freshly prepared and aged rat liver mitochondria is inhibited by amytal. Whereas rotenone inhibits choline-cytochromec reductase only in the case of freshly prepared mitochondria, the extent of inhibition is influenced by preincubation, but the inhibition is not secondary to the inhibited oxidation of betaine aldehyde, the product of choline oxidation. Evidence shows that rotenone is able to inhibit the swelling of rat liver mitochondria and the inhibition of choline-cytochromec reductase by rotenone is related to the inhibition of mitochondrial swelling. Nine inhibitors of choline dehydrogenase have been reported. Among those, some belong to the category of acetylcholine esterase inhibitor. In view of the structure of those inhibitors, it seems quite likely that there is an anionic site at the active center of choline dehydrogenase. Purification of choline dehydrogenase in its native form has been accomplished by solubilization with Lubrol WX, hydroxyapatite, and DEAE-Sepharose chromatography and sucrose gradient ultracentrifugation. The preparation is pure as judged by SDS-PAGE and Ultrogel AcA 34 column chromatography. The molecular weight determined by SDS-PAGE is approximately 61,000. There is 0.23 mg phospholipid/mg protein and the Stokes' radius of protein-Lubrol-phospholipid mixed micelles is about 59 A.     

Acetylcholine activation of alpha-ketoglutarate oxidation in liver mitochondria

Activation of alpha-ketoglutarate oxidation in the rat liver mitochondria takes place 15 and 30 min after intraperitoneal injection of acetyl choline. This mediator in doses of 25, 50 and 100 micrograms per 100 g of body weight causes a pronounced stimulation of phosphorylation respiration rate and calcium capacity of mitochondria with alpha-ketoglutarate oxidation. Acetyl choline is found to have a moderate inhibitory action on oxidation of lower (physiological) concentrations of succinate. Its stimulating action on alpha-ketoglutarate oxidation is associated with activation of M-cholinoreceptors; atropine, a choline-blocker, removes completely this effect. It is supposed that alpha-ketoglutarate and succinate are included into the composition of two reciprocal hormonal-substrate nucleotide systems.     

Control of choline oxidation in rat kidney mitochondria

Choline is a quaternary amino cationic organic alcohol that is oxidized to betaine in liver and kidney mitochondria. Betaine acts as an intracellular organic osmolyte in the medulla of the kidney. Evidence is provided that kidney mitochondria have a choline transporter in their inner membrane. The transporter has a Km of 173 ± 64 μM and a Vmax of 0.4 ± 0.1 nmol/min/mg mitochondrial protein (at 10 °C). Uptake of choline is not coupled to betaine efflux. Transporter activity demonstrates a dependence on membrane potential and choline transport is inhibited by hemicholinium-3. Steady-state oxygen consumption due to choline oxidation in kidney mitochondria was measurable at 37 °C (125 ± 6 pmolO₂/min/mg mitochondrial protein), in the absence of other mitochondrial electron transport chain substrates and the choline transporter was shown to be the major site of control (96 ± 4%) over choline oxidation flux in isolated kidney mitochondria. We conclude that the choline transporter in rat kidney mitochondria is the major site of control over the production of the organic osmolyte, betaine.     

Choline and betaine aldehyde oxidation by rat liver mitochondria

1. The question of the ability or inability of rat liver mitochondria to oxidize externally added or internally generated betaine aldehyde has been reexamined. Well washed mitochondria were demonstrated to contain approx. 7% of the post-nuclear betaine aldehyde dehydrogenase as an integral component. The enzyme is approximately equally distributed between the inner membrane and the intermembrane plus matrix fractions. Significantly, none was found in the outer membrane fraction. The mitochondrial enzyme was shown to be functional under all the conditions tested; betaine aldehyde generated within the mitochondria by choline oxidation or added externally was oxidized to betaine in significant amounts.

2. The stoichiometry for the complete oxidation of choline or externally added betaine aldehyde was confirmed to be 2 and 1 moles, respectively, of O₂ utilized per mole of substrate added. Depending on the reaction conditions employed, considerable variation in the relative amount of choline oxidase and betaine aldehyde oxidase activities of mitochondria was observed when they were allowed to oxidize only a portion of the choline added. The necessity of measuring the contribution of betaine aldehyde oxidase in studies of choline oxidase is discussed.

3. Reasons for the discrepancies in the literature concerning the ability of mitochondria to oxidize betaine aldehyde are discussed.     

Free-living nematodes Caenorhabditis elegans possess in their mitochondria an additional rhodoquinone, an essential component of the eukaryotic fumarate reductase system.

The respiratory chain of Caenorhabditis elegans was characterized in mitochondria isolated from aerobically grown nematodes. Nematode mitochondria contain ubiquinone-9 as a major component and rhodoquinone-9 as a minor component. The ratio of ubiquinone-9/rhodoquinone-9 is higher in C. elegans mitochondria than in mitochondria from second-stage larvae of Ascaris suum, the free-living stage of porcine gut-dwelling nematode. The individual oxidoreductase activities comprising succinate oxidase and the amount of substrate-reducible cytochromes are comparable to those of mitochondria from second-stage larvae of A. suum. The specific activity of fumarate reductase is lower in C. elegans mitochondria than in mitochondria from second-stage larvae of A. suum, but still higher than in mammalian mitochondria. These results indicate that the free-living nematode C. elegans is capable of synthesizing rhodoquinone, as distinguished from aerobic mammalian species, although its mitochondria appear more aerobic than A. suum larval mitochondria.     

The reaction of choline dehydrogenase with some electron acceptors.

1. The choline dehydrogenase (EC 1.1.99.1) WAS SOLUBILIZED FROM ACETONE-DRIED POWDERS OF RAT LIVER MITOCHONDRIA BY TREATMENT WITH Naja naja venom. 2. The kinetics of the reaction of enzyme with phenazine methosulphate and ubiquinone-2 as electron acceptors were investigated. 3. With both electron acceptors the reaction mechanism appears to involve a free, modified-enzyme intermediate. 4. With some electron acceptors the maximum velocity of the reaction is independent of the nature of the acceptor. With phenazine methosulphate and ubiquinone-2 as acceptors the Km value for choline is also independent of the nature of the acceptor molecule. 5. The mechanism of the Triton X-100-solubilized enzyme is apparently the smae as that for the snake venom solubilized enzyme.     

Restoration of respiratory electron-transport reactions in quinone-depleted particle preparations from Anacystis nidulans.

Electron transport from H2, NADPH, NADH and succinate to O2 or ferricytochrome c in respiratory particles isolated from Anacystis nidulans in which hydrogenase had been induced was abolished after extraction of the membranes with n-pentane; oxidation of ascorbate plus NNN'N'-tetramethyl-p-phenylenediamine remained unaffected. Incorporation of authentic ubiquinone-10, plastoquinone-9, menaquinone-7 and phylloquinone (in order of increasing efficiency) restored the electron-transport reactions. ATP-dependent reversed electron flow from NNN'N'-tetramethyl-p-phenylenediamine to NADP+ or, via the membrane-bound hydrogenase, to H+ was likewise abolished by pentane extraction and restored by incorporation of phylloquinone. Participation of the incorporated quinones in the respiratory electron-transport reactions of reconstituted particles was confirmed by measuring the degree of steady-state reduction of the quinones. Isolation and identification of the quinones present in native Anacystis membranes yielded mainly plastoquinone-9 and phylloquinone; neither menaquinone nor alpha-tocopherolquinone could be detected. Together with the results from reconstitution experiments this suggests that phylloquinone might function as the main respiratory quinone in Anacystis nidulans.     

Ubiquinone-1 Induces External Deamino-NADH Oxidation in Potato Tuber Mitochondria

The addition of ubiquinone-1 (UQ-1) induced Ca2+-independent oxidation of deamino-NADH and NADH by intact potato (Solanum tuberosum L. cv Bintje) tuber mitochondria. The induced oxidation was coupled to the generation of a membrane potential. Measurements of NAD+-malate dehydrogenase activity indicated that the permeability of the inner mitochondrial membrane to NADH and deamino-NADH was not altered by the addition of UQ-1. We conclude that UQ-1-induced external deamino-NADH oxidation is due to a change in specificity of the external rotenone-insensitive NADH dehydrogenase. The addition of UQ-1 also induced rotenone-insensitive oxidation of deamino-NADH by inside-out submitochondrial particles, but whether this was due to a change in the specificity of the internal rotenone-insensitive NAD(P)H dehydrogenase or to a bypass in complex I could not be determined.     

The uptake of choline by rat liver mitochondria.

1. Rat liver mitochondria can accumulate choline against a concentration gradient. Maximally about 30 nmol choline per mg mitochondrial protein are found in the matrix space. 2. The process of choline uptake is biphasic. After a rapid uptake of 1.5-15 nmol per mg protein, a slower uptake occurs if an energy supply is present. In the absence of energy, only the rapid uptake is found. 3. The inhibition of uncoupler-stimulated choline oxidation by cations is the result of an inhibition of choline uptake.     

Identification of the quinone species in cyanide-sensitive and cyanide-insensitive mitochondria of Moniliella tomentosa.

Moniliella tomentosa was investigated for the presence of different quinones that might be involved in the cyanide-sensitive and/or cyanide-insensitive electron-transport pathways. The naturally occurring quinone in Moniliella tomentosa was found to be ubiquinone-45. Other quinone species could not be detected. The concentration of ubiquinone-45 in mitochondria is not related to the presence or absence of the alternative oxidase activity.     

Choline transport into rat liver mitochondria. Characterization and kinetics of a specific transporter.

Rat liver mitochondria possess a specific choline transporter in the inner membrane. The transporter shows saturable kinetics at high membrane potential with a Km of 220 microM and a Vmax of 0.4 nmol/mg of protein/min at pH 7.0 and 25 degrees C. At physiological concentrations of choline, the rate of choline uptake by the transporter shows a linear dependence on membrane potential; uptake is distinct from the nonspecific cation diffusion process. Hemicholinium-3, hemicholinium-15, quinine, and quinidine, all analogues of choline, are high affinity competitive inhibitors of choline transport with Ki values of 17, 55, 15, and 127 microM, respectively. The choline transporter is distinct from other known mitochondrial transporters. Rat heart mitochondria do not appear to possess a choline transporter. Evidence suggests that the transporter is an electrophoretic uniporter. Analogue studies have shown that the hydroxyl and the quaternary ammonium groups of choline are necessary for binding to the transporter. A comparison of molecular models of choline and the high affinity inhibitors has provided evidence for the preferred conformation of choline for binding to the transporter. The presence of a choline transporter in the mitochondrial inner membrane provides a potential site for control of choline oxidation and hence supply of endogenous betaine.     

Antioxidative effect of ubiquinones on mitochondrial membranes.

Peroxidation of mitochondria occurs extensively in ubiquinone-depleted membranes. Reincorporation into the membranes of either the physiological ubiquinone or a short-chain homologue protects mitochondria against peroxidation. The ability to prevent this phenomenon is more evident in mitochondria that have incorporated ubiquinone-3 and might be ascribed to an ordering structural effect on the lipid bilayer.