Molecular and functional characterization of choline transporter in rat renal tubule epithelial NRK-52E cells

Homeostatic regulation of the plasma choline concentration depends on the effective functioning of a choline transporter in the kidney. However, the nature of the choline transport system in the kidney is poorly understood. In this study, we examined the molecular and functional characterization of choline uptake in the rat renal tubule epithelial cell line NRK-52E. Choline uptake was saturable and mediated by a single transport system, with an apparent Michaelis-Menten constant (K_m) of 16.5 μM and a maximal velocity (V_max) of 133.9 pmol/mg protein/min. The V_max value of choline uptake was strongly enhanced in the absence of Na⁺ without any change in K_m values. The increase in choline uptake under Na⁺-free conditions was inhibited by Na⁺/H⁺ exchanger (NHE) inhibitors. Choline uptake was inhibited by the choline uptake inhibitor hemicholinium-3 (HC-3) and organic cations, and was decreased by acidification of the extracellular medium and by intracellular alkalinization. Collapse of the plasma membrane H⁺ electrochemical gradient by a protonophore inhibited choline uptake. NRK-52E cells mainly express mRNA for choline transporter-like proteins (CTL1 and CTL2), and NHE1 and NHE8. CTL1 protein was recognized in both plasma membrane and mitochondria. CTL2 protein was mainly expressed in mitochondria. The biochemical and pharmacological data indicated that CTL1 is functionally expressed in NRK-52E cells and is responsible for choline uptake. This choline transport system uses a directed H⁺ gradient as a driving force, and its transport functions in co-operation with NHE8. Furthermore, the presence of CTL2 in mitochondria provides a potential site for the control of choline oxidation.     

Effect of external high potassium and pH on the uptake of choline in glial and neuronal cells in culture

TheV _max of the uptake of choline was increased in nerve cell cultures by lowering (from 7.4 to 6.5) or increasing (from 7.4 to 8.1) the pH. In neurons no effect was observed on the value of theK _m's of the uptake of either the apparent high or low affinity components. In glial cells only a low affinity component was measured at pH 6.5 and diffusion was observed at pH 8.1. An excess of K⁺ ions in the incubation medium reproduced the increase inV _max observed with changes in pH suggesting a possible dependence of the uptake of choline upon the H⁺ and OH^– gradients. Taking into account the characteristics already known of the transport of choline into nerve cells, such a dependence adds new insight in the mechanisms underlying the transport and indicates another possible regulation of choline entry, eventually directed towards the synthesis of acetylcholine.     

Transport of valproate and its effects on GABA uptake in astroglial primary culture

The antiepileptic drug Na⁺-valproate (VPA) is a broadspectrum anticonvulsant. It has been proposed to be involved in the inhibitory mechanisms of GABA-ergic systems. In this study, transport of the drug and possible influence on the GABA uptake were investigated in primary astroglial cell cultures from newborn rat cerebral cortex. The results show a Na⁺ and K⁺ independent high affinity uptake for VPA, withK _m andV _max not significantly different from those observed for the GABA uptake. In the presence of the drug, the K_m-value of the GABA uptake increased. The GABA uptake inhibitors guvacine, (RS)-Cis-4-OH-nipecotic acid and 4,5,6,7-tetrahydroisoxazolo (4,5-c) pyridin-3-ol (THPO) did not influence upon the uptake of VPA, suggesting a transport mechanism for the drug, separated from the GABA uptake carrier.     

Sodium-dependent and -independent Choline Uptake by Type II Epithelial Cells from Rat Lung

The uptake of ³H-labeled choline by a suspension of isolated type II epithelial cells from rat lung has been studied in a Ringer medium. Uptake was linear for 4 min at both 0.1 μm and 5.0 μm medium choline; at 5 μm, only 10% of the label was recovered in a lipid fraction. Further experiments were conducted at the low concentration (0.1 μm), permitting characterization of the properties of high-affinity systems. Three fractions of choline uptake were detected: (i) a sodium-dependent system that was totally inhibited by hemicholinium-3 (HC-3); (ii) a sodium-independent uptake, when Na⁺ was replaced by Li⁺, K⁺ or Mg²⁺, inhibited by HC-3; (iii) a residual portion persisting in the absence of Na⁺ and unaffected by HC-3. Choline uptake was sigmoidally related to the medium Na⁺ concentration. Kinetic properties of the uptake of 0.1 μm ³H-choline in the presence and absence of medium Na⁺ were examined in two ways. (a) Inhibition by increasing concentrations of unlabeled choline (0.5–100 μm) was consistent with the presence of two Michaelis-Menten-type systems in the presence of Na⁺; a Na⁺-dependent portion (a mean of 0.52 of the total) had a K _m for choline of 1.5 μm while K _m in the absence of Na⁺ (Li⁺ substituting) was 18.6 μm. (b) Inhibition by HC-3 (0.3–300 μm) gave K_i values of 1.7 μm and 5.0 μm HC-3 for the Na⁺-dependent and -independent fractions. The apparent K _m of the Na⁺-dependent uptake is lower than that reported previously for lung-derived cells and is in the range of the K _m values reported for high-affinity, Na⁺-dependent choline uptake by neuronal cells. Received: 18 February 1997/Revised: 7 December 1997     

Alpha-aminoisobutyric acid uptake in primary cultures of astrocytes

Homotypically pure cultures of rat brain astrocytes were used to examine some aspects of non-neuronal A-system (alanine preferring) amino acid uptake. The Asystem specific probe, alpha-aminoisobutyric acid is transported rapidly, and a steady state distribution ratio of 9–25 is reached after 30 minute incubations. Kinetic estimates derived from uptake progress curves indicated aK _m of 1.35 mM and aV _max of 133 nmol/min/mg protein. Uptake is reduced in the absence of either Na⁺ or K⁺. Elevations in extracellular K⁺, a putative metabolic modulator of neuroglia, did not affect uptake.     

Changes of sodium and ATP affinities of the cardiac (Na,K)-ATase during and after nitric oxide deficient hypertension

In the cardiovascular system, NO is involved in the regulation of a variety of functions. Inhibition of NO synthesis induces sustained hypertension. In several models of hypertension, elevation of intracellular sodium level was documented in cardiac tissue. To assess the molecular basis of disturbances in transmembraneous transport of Na⁺, we studied the response of cardiac (Na,K)-ATPase to NO-deficient hypertension induced in rats by NO-synthase inhibition with 40 mg/kg/day N^G-nitro-L-arginine methyl ester (L-NAME) for 4 four weeks. After 4-week administration of L-NAME, the systolic blood pressure (SBP) increased by 36%. Two weeks after terminating the treatment, the SBP recovered to control value. When activating the (Na,K)-ATPase with its substrate ATP, no changes in K_m and V_max values were observed in NO-deficient rats. During activation with Na⁺, the V_max remained unchanged, however the K_Na increased by 50%, indicating a profound decrease in the affinity of the Na⁺-binding site in NO-deficient rats. After recovery from hypertension, the activity of (Na,K)-ATPase increased, due to higher affinity of the ATP-binding site, as revealed from the lowered K_m value for ATP. The K_Na value for Na⁺ returned to control value. Inhibition of NO-synthase induced a reversible hypertension accompanied by depressed Na⁺-extrusion from cardiac cells as a consequence of deteriorated Na⁺-binding properties of the (Na,K)-ATPase. After recovery of blood pressure to control values, the extrusion of Na⁺ from cardiac cells was normalized, as revealed by restoration of the (Na,K)-ATPase activity. (Mol Cell Biochem 000: 000-000, 1999)     

Requirement of Glycogenolysis for Uptake of Increased Extracellular K+ in Astrocytes: Potential Implications for K+ Homeostasis and Glycogen Usage in Brain

The importance of astrocytic K⁺ uptake for extracellular K⁺ ([K⁺]_e) clearance during neuronal stimulation or pathophysiological conditions is increasingly acknowledged. It occurs by preferential stimulation of the astrocytic Na⁺,K⁺-ATPase, which has higher K_m and V_max values than its neuronal counterpart, at more highly increased [K⁺]_e with additional support of the cotransporter NKCC1. Triggered by a recent DiNuzzo et al. paper, we used administration of the glycogenolysis inhibitor DAB to primary cultures of mouse astrocytes to determine whether K⁺ uptake required K⁺-stimulated glycogenolysis. KCl was increased by either 5 mM (stimulating only the Na⁺,K⁺-ATPase) or 10 mM (stimulating both transporters) in glucose-containing saline media prepared to become iso-osmotic after the addition. DAB completely inhibited both uptakes, the Na⁺,K⁺-ATPase-mediated by preventing Na⁺ uptake for stimulation of its intracellular Na⁺-activated site, and the NKCC1-mediated uptake by inhibition of depolarization- and L-channel-mediated Ca²⁺ uptake. Drugs inhibiting the signaling pathways involved in either of these processes also abolished K⁺ uptake. Assuming similar in vivo characteristics, partly supported by literature data, K⁺-stimulated astrocytic K⁺ uptake must discontinue after normalization of extracellular K⁺. This will allow Kir1.4-mediated release and reuptake by the less powerful neuronal Na⁺,K⁺-ATPase.     

CHOLINE UPTAKE BY CHOLINERGIC NEURON CELL SOMAS

The cellular compartments of ciliary ganglia take up choline by a single, saturable process with K_m=7.1 × 10^?5 M and V_max= 4.66 pmol/min per ganglion: Denervation of the ganglia and the resultant degeneration of nerve terminals caused no significant decrease of the rate of accumulation of choline by the ganglia. This indicates that the measured uptake is by the postganglionic ncurons and nonneural elements (NNE: glial and connective tissue cells) in the ganglia. This uptakc is not dependent on metabolic energy and is not affectcd by lowcring Na⁺ or raising K⁺ concentrations in the incubating mcdia but is depressed in the presence of ouabain and hemicholinium-3. The presence or Na⁺-dependent. rapidly saturable uptake in the preganglionic nerve terminals which is not detectablc kinetically is, however, inferred from a decrease in ACh synthesis in dcncrvatcd prcparations and a similar decrcasc in intact ganglia incubated in low Na+ solution.     

Ontogenetic studies on tryptophan transport into plasma membrane vesicles derived from rat brain synaptosomes: Effect of thyroid hormones

The uptake of tryptophan at various stages of development was examined in plasma membrane vesicles derived from rat brain. The total uptake has two components Na⁺-dependent and Na⁺-independent respectively. The Na⁺-dependent component of the transport system appears around the 5th postnatal day and increases with the age. TheK _m value of the system does not vary during development. The V_max increases five-fold between 14 and 35 day of postnatal life. Plasma membrane vesicles derived from T₃-treated rats are able to accumulate nearly three-fold more tryptophan than nontreated rats. The results support the idea that thyroid hormones at the earlier stages of life, promote the establishment of neurotransmission in the developing nervous system.     

l-serine and GABA uptake by synaptosomes during postnatal development of rat

Postnatal development changes in mechanisms of synaptosomal amino acid transport have been studied in rat cerebral cortex. Specific uptake of radiolabeled l-serine was examined and compared with that of radiolabeled GABA using synaptosomes-enriched fractions freshly prepared from cerebral cortex at different postnatal days from the birth to young adulthood. The preparations were incubated with 10 nM of [³H]l-serine and 10 nM of [³H]-GABA in either the presence or absence of NaCl, KCl or choline chloride, at 2 and 30 °C, for different periods up to 30 min. The uptake of [³H]l-serine was temperature dependent in synaptosomal fractions prepared from cerebral cortex of rats in postnatal days 5, 7, 13 and 21, but stronger dependence was observed in adult brain, irrespective of the presence of Na⁺, K⁺ or choline ions. At all postnatal ages studied, [³H]-GABA uptake showed a high activity in the presence of Na⁺ ions and at 30 °C. The values of K_m were 90–489 μM in l-serine uptake. However, in the uptake of GABA the values of K_m were 80–150 μM. The highest values of V_max were obtained at 5 and 21 postnatal days for both transport systems. These results indicate that the uptake of l-serine and GABA are regulated differentially during postnatal development.     

Transport of L-alanine in cultured human fibroblasts: Evidence for two kinetically distinguishable systems

The transport of L-alanine in human diploid fibroblasts was investigated. Transport measurements were performed on subcultures between the third and eighth passages with subconfluent cells growing on glass coverslips. Kinetic analysis of approximate initial rates of transport at substrate concentrations from 0.05 to 10 mmole/liter indicate the presence of two distinguishable systems. The high affinity system has a K_m of 0.24 mmole/liter and a V_max of 6.4 nmole/100 μg protein/2 min. For the low affinity system, the contribution of the high affinity system to the uptake must absolutely be taken into account. The K_m and V_max values, obtained by using a computer program, are a K_m of 15.0 mmole/liter and a V_max of 14.7 nmole/100 μg protein/2 min. For alanine concentrations below 1 mmole/liter, the contribution of the Na⁺-independent uptake is less than 10%, and the kinetic constants of the high affinity system are in the same range if this contribution is taken into account. On the contrary the influence of a diffusion-like process is more significant on the low affinity system whose K_m is about 49 mmole/liter after subtraction of the Na⁺-independent uptake from the experimental velocities. Inhibition studies were performed with NCH₃-alanine. They permitted us first to confirm the existence of system A in cultured human fibroblasts in agreement with two recent works and second to show how this system contributes to L-alanine uptake. This contribution seems very small in low concentrations but it rises as the concentrations increase.     

Uptake of ethanolamine in neuronal and glial cell cultures

The uptake of radioactive ethanolamine has been studied in exclusively neuronal and glial cell cultures from dissociated cerebral hemispheres of chick embryos. Both cell types show saturable kinetics; neurons have an apparentK _m of 6.7 M,V _max 41.4 pmol mg prot.^–1 min^–1 and glial cells aK _m of 119.6 M,V _max 3,917 pmol mg prot^–1 min^–1. The lower affinity of the transport and the 100 fold increase inV _max observed in glial cells correlated with a more important accumulation of free ethanolamine found in glial cells and with a higher degree of phosphorylation of ethanolamine. The uptake appeared to be temperature and Na⁺ ions dependent but was not affected by CN^– or ouabain. Monomethyl-, dimethylethanolamine and choline were effective in inhibiting the uptake. Little or no effect was observed with serine, methionine, carnitine, alanine or glutamate.     

Salt tolerance in suspension cultures of sugar beet : induction of na/h antiport activity at the tonoplast by growth in salt

Cell suspension cultures of sugar beet were grown at various salinities (0-200 millimolar NaCl). Their tolerance to Na⁺ was comparable to that of the intact plant. Tonoplast vesicles were prepared by sucrose density gradient centrifugation of microsomal membranes and shown to be highly purified. The vesicles were subjected to a pH jump in the presence of acridine orange and the rate of recovery of fluorescence after addition of Na⁺ was used as a measure of Na⁺-dependent H⁺ efflux. In the presence of K⁺ and valinomycin, the Na⁺/H⁺ antiport showed saturation kinetics. Increasing Na⁺ in the growth medium did not change the apparent K_m for Na⁺, but increased V_max to about twice the control value, suggesting a specific induction of antiport synthesis by salt.     

Leucine transport in Xenopus laevis oocytes: Functional and morphological analysis of different defolliculation procedures

l-leucine uptake in stage V Xenopus laevis oocytes was affected by the specific methods used to remove the follicle cells. In the presence of 100 mM NaCl, l-leucine uptake was reduced by 67.5%±5.7 when defolliculation was performed enzymatically by collagenase treatment, whereas the reduction was 30.5%±6.4 after mechanical defolliculation. The Na⁺-dependent uptake of 0.1 mM l-leucine was 18.6±4.6 pmol oocyte⁻¹ 40 min⁻¹ in folliculated oocytes and 5.6±1.9 in collagenase defolliculated oocytes (means±SE). l-leucine uptake was not affected by the removal of the follicular layer if defolliculation occurred after the transport period; radiolabeled l-leucine is therefore not taken up into a compartment that is removed by the defolliculation process. The different l-leucine uptake rates observed in folliculated and defolliculated oocytes were not due to non-specific l-leucine binding to membranes. l-leucine kinetics showed that the l-leucine V_max and K_m values were lower in oocytes deprived of the follicular layer than in control oocytes enveloped in intact follicular layers. The V_max and K_m values of Na⁺-dependent l-leucine transport, calculated from data obtained the day after defolliculation by collagenase treatment, were: 16±1.5 pmol oocyte⁻¹ 40 min⁻¹ and 57±21 μmol (mean±SD). The Na⁺-activation curve of 0.1 mM l-leucine was hyperbolic in folliculated oocytes and sigmoidal in defolliculated oocytes. The morphological analysis performed in parallel with the transport experiments showed that after defolliculation, the fibers forming the vitelline membrane tended to be arranged in a more regular orthogonal array, and the number of oocyte microvilli was reduced after collagenase treatment. Mechanical defolliculation did not appreciably affect the oocyte microvilli, however this procedure did not completely remove all follicle cells. The damage to collagenase treated oocytes was reversible, and the functional and structural features of most oocytes improved upon subsequent in vitro incubation. The recovery process seemed to involve protein synthesis in view of the increased value of l-leucine V_max, and microscopic observation showing recovery of the microvillar apparatus.     

Transport Pathways for Therapeutic Concentrations of Lithium in Rat Liver

Although both amiloride- and phloretin-sensitive Na⁺/Li⁺ exchange activities have been reported in mammalian red blood cells, it is still unclear whether or not the two are mediated by the same pathway. Also, little is known about the relative contribution of these transport mechanisms to the entry of therapeutic concentrations of Li⁺ (0.2–2 mm) into cells other than erythrocytes. Here, we describe characteristics of these transport systems in rat isolated hepatocytes in suspension. Uptake of Li⁺ by hepatocytes, preloaded with Na⁺ and incubated in the presence of ouabain and bumetanide, comprised three components. (a) An amiloride-sensitive component, with apparent K _m 1.2 mm Li⁺, V _max 40 μmol · (kg dry wt · min)⁻¹, showed increased activity at low intracellular pH. The relationship of this component to the concentration of intracellular H⁺ was curvilinear suggesting a modifier role of [H⁺] _i . This system persisted in Na⁺-depleted cells, although with apparent K _m 3.8 mm. (b) A phloretin-sensitive component, with K _m 1.2 mm, V _max 21 μmol · (kg · min)⁻¹, was unaffected by pH but was inactive in Na⁺-depleted cells. Phloretin inhibited Li⁺ uptake and Na⁺ efflux in parallel. (c) A residual uptake increased linearly with the external Li⁺ concentration and represented an increasing proportion of the total uptake. The results strongly suggest that the amiloride-sensitive and the phloretin-sensitive Li⁺ uptake in rat liver are mediated by two separate pathways which can be distinguished by their sensitivity to inhibitors and intracellular [H⁺]. Received: 8 April 1999/Revised: 19 July 1999     

Discrimination of single transport systems. The Na plus-sensitive transport of neutral amino acids in the Ehrlich cell

Uptake of methionine, α-aminoisobutyric acid, and α-(methyl-amino)-isobutyric acid has been shown to occur by at least two transport systems, one sensitive and the other insensitive to the Na⁺ concentration. For α-aminoisobutyric acid and its N-methyl derivative, the Na⁺-insensitive uptake is not concentrative and its rate increases almost linearly with concentration within the range examined. In contrast, the Na⁺-insensitive uptake of methionine is concentrative and subject to inhibition by such amino acids as phenylalanine, leucine, and valine, although not in a manner to indicate that the uptake is mediated by a single agency. This component is not produced by a residual operation of the Na⁺-requiring transport system, handicapped by the absence of Na⁺ or by its having combined with α-aminoisobutyric acid. The increase in the rate of methionine uptake is linear with concentration only above about 16 mM methionine. The Na⁺-sensitive uptakes of methionine, α-aminoisobutyric, and α-(methylamino)-isobutyric acid appear to occur by the same population of transport-mediating sites. Both K_m and V _max of the Na⁺-sensitive uptake of these three amino acids change with changes in the concentration of Na⁺, an effect which is shown to have a theoretical basis. A similarity in the values of Vmax for ten amino acids entering principally by the Na⁺-sensitive agency indicates that differences in their K_m values probably measure differences in their affinities for that transport-mediating system.     

In Vitro Effects of Arachidonic and L-Glutamic Acids on the High-Affinity Choline Transport in Rat Hippocampus

A second messenger role for arachidonic acid (AA) in the regulation of the high-affinity choline uptake (HACU) was suggested. It was repotted that micromolar concentrations of AA applied in vitro decreased the HACU values and increased the specific binding of [³H]hemicholinium-3 ([³H]HCh-3). It was published that L-glutamic acid (GA) applied in vivo produced a fall in the HACU values. In addition, GA liberates free AA. In this study, an ability of GA to influence in vitro the activity of presynaptic cholinergic nerve terminals via its effect on the release of AA is investigated in hippocampal synaptosomes of young Wistar rats. Millimolar concentrations of GA decrease both the high- and low-affinity choline uptake, the specific as well as nonspecific binding of [³H]HCh-3 and the activity of Na⁺,K⁺-ATPase. Kinetic analysis (Lineweaver-Burk and Scatchard plots) reveals a change in V_max and B_max, but not in K_M and K_D. It appears very likely that under normal conditions GA applied in vitro is not able to change markedly the choline transport via its effect on the release of AA. Results confirm the hypothesis about an indirect inhibitory role for glutamatergic receptors on cholinergic cells.     

Changes in membrane properties of chick embryonic hearts during development

The electrophysiological properties of embryonic chick hearts (ventricles) change during development; the largest changes occur between days 2 and 8. Resting potential (E_m) and peak overshoot potential (+E _max) increase, respectively, from -35 mv and +11 mv at day 2 to -70 mv and +28 mv at days 12–21. Action potential duration does not change significantly. Maximum rate of rise of the action potential (+V _max) increases from about 20 v/sec at days 2–3 to 150 v/sec at days 18–21; + V _max of young cells is not greatly increased by applied hyperpolarizing current pulses. In resting E_m vs. log [K⁺]_o curves, the slope at high K⁺ is lower in young hearts (e.g. 30 mv/decade) than the 50–60 mv/decade obtained in old hearts, but the extrapolated [K⁺]_i values (125–140 mM) are almost as high. Input resistance is much higher in young hearts (13 MΩ at day 2 vs. 4.5 MΩ at days 8–21), suggesting that the membrane resistivity (R_m) is higher. The ratio of permeabilities, P _Na/P _K, is high (about 0.2) in young hearts, due to a low P _K, and decreases during ontogeny (to about 0.05). The low K⁺ conductance (g _K) in young hearts accounts for the greater incidence of hyperpolarizing afterpotentials and pacemaker potentials, the lower sensitivity (with respect to loss of excitability) to elevation of [K⁺]_o, and the higher chronaxie. Acetylcholine does not increase g _K of young or old ventricular cells. The increase in (Na⁺, K⁺)-adenosine triphosphatase (ATPase) activity during development tends to compensate for the increase in g _K. +E _max and + V _max are dependent on [Na⁺]_o in both young and old hearts. However, the Na⁺ channels in young hearts (2–4 days) are slow, tetrodotoxin (TTX)-insensitive, and activated-inactivated at lower E_m. In contrast, the Na⁺ channels of cells in older hearts (> 8 days) are fast and TTX-sensitive, but they revert back to slow channels when placed in culture.     

OPOSSUM KIDNEY CELLS TAKE UP L-DOPA THROUGH AN ORGANIC CATION POTENTIAL-DEPENDENT AND PROTON-INDEPENDENT TRANSPORTER

The present work was aimed at studying the kinetics and nature of the l-DOPA transporter in opossum kidney (OK) cells. Saturation experiments were performed in OK cells incubated for 6 min with increasing concentrations of l-DOPA (10 to 2500 μm); non-linear analysis of the saturation curve revealed for l-DOPA aK_mof 129 μm (114, 145) and aV_maxof 30.0±0.4 nmol mg protein^?16 min^?1The uptake of l-DOPA (250 μm) was inhibited in a concentration-dependent manner by cyanine 863, an organic cation inhibitor, with aK_ivalue of 638 (430, 947) μmthe organic anion inhibitor 4,4′-diisothiocyanostilbene-2,2′-disulphonic acid (DIDS), was devoid of effect upon the uptake of l-DOPA. The uptake of l-DOPA (250 μm) was significantly (P<0.02) decreased (25% reduction) when cells were incubated in the presence of 137 mm K⁺plus 5 mm Na⁺when compared with the control condition (137 mm Na⁺plus 5 mm K⁺); substitution of NaCl by choline chloride (137 mm) did not affect l-DOPA uptake. Similarly, inwardly or outwardly directed proton gradients of 0.5 pH units (7.9, 7.4, 6.9, 6.4 and 5.9) were found not to change l-DOPA uptake. In conclusion, the l-DOPA uptake system in OK cells has the characteristics of an organic cation potential-dependent and proton-independent transporter.     

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.