S-adenosyl-L-methionine reverses the cholestatic effect of ethinylestradiol in rat hepatocytes by increasing its catabolism

In this study, ethinylestradiol inhibited the uptake of taurocholate by cultured rat hepatocytes, increasing the K_m1 while leaving the V_max unchanged. S-AdenosylL-methionine (SAMe) had no effect on taurocholate uptake or release, but was able to reverse the competitive inhibition induced by ethinylestradiol. S-Adenosyl-L-homocysteine did not reverse this inhibition, which suggests that the methyl group of SAMe affects its activity. Several possible mechanisms for the action of SAMe were investigated. The methylation of cell membrane phospholipids was eliminated as a possible mechanism. The presence of SAMe greatly increased the catabolism of ethinylestradiol by hepatocytes and reduced its covalent binding to hepatocyte macromolecules. In culture supernatants, both highly polar (conjugated) and non-conjugated metabolites could be detected. Moreover, most of the metabolites were methylated. This suggests that SAMe may revert the effects of ethinylestradiol of taurocholate uptake by increasing its catabolic rate by hepatocytes.Abbreviations SAMe, S-adenosyl-L-methionine - EE, 17-ethinylestradiol     

Driving forces in hepatocellular uptake of phalloidin and cholate

Active uptake of phalloidin and cholate in isolated rat liver cells depends upon both Na⁺ gradient and membrane potential. Omission of Na⁺ or inhibition of the (Na⁺ + K⁺)-ATPase diminished both phalloidin and cholate uptake. Dissipation of the sodium, potassium or proton gradient by monensin, nigericin, gramicidin and valinomycin blocked phalloidin uptake and also caused reduction of cholate transport. Chelation of Ca²⁺ and Mg²⁺ by EGTA or incubation of liver cells with NH₄Cl neither influenced phalloidin nor cholate uptake. Hyperpolarization of liver cells by the lipophilic anions NO₃⁻ or SCN⁻ enhanced phalloidin but reduced cholate uptake. Depolarization induced by a reversed K⁺ gradient reduced both kinds of transport. The results indicate that sodium ions and the membrane potential are driving forces for phalloidin and cholate uptake in hepatocytes.     

A functional, active transport system for methotrexate in freshly isolated hepatocytes.

Methotrexate transport was studied in isolated rat liver cells. The process was found to be saturable with a K_t of 2.3 × 10^?3M and Vmax of 282 nmol/g wet wt. min. The system showed a requirement for sodium ions and it was sensitive to ouabain. Metabolic inhibitors, e.g., 2,4-dinitrophenol, anaerobic conditions, and deprivation of glucose, suppressed the uptake rate. Folic acid, but not folinic acid, was slightly inhibitory. It is suggested that methotrexate is transported in isolated hepatocytes by an active, sodium dependent process.     

Effect of a phenyl group in quaternary ammonium compounds on thiamine uptake in isolated rat hepatocytes

The inhibitory effect of a phenyl group in quaternary ammonium compounds on thiamine uptake in isolated rat hepatocytes was investigated. The phenyltrimethylammonium ion was a more potent inhibitor than the tetramethylammonium ion, while the dibenzyldimethylammonium ion was the most potent inhibitor of thiamine uptake among those compounds examined. A kinetic study showed that this compound was a competitive inhibitor. The cetyltrimethylammonium ion was a less effective inhibitor than the benzyltrimethylammonium ion, and the palmitoylcholine ion was a weak inhibitor. These results indicate that the lipophilicity of a quaternary ammonium compound is not always correlated with its affinity for thiamine-carrier binding, but the presence of a phenyl group plays a significant role in affinity. The inhibitory effect of the series of (CH₃)₃N⁺(CH₂)_nC₆H₅ (n = 0−6) compounds on thiamine uptake in isolated rat hepatocytes was studied. The maximal inhibitory activity occurred at n = 5. These results suggest that the phenyl group in a quaternary ammonium compound has a specific interaction with the thiamine-binding site in rat liver plasma membrane.     

Active transport of alpha-aminoisobutyric acid in freshly prepared rat hepatocytes

The transport of alpha-aminoisobutyric acid in freshly prepared rat liver cells was saturable and exhibited a K_t of 13.9 × 10^?3M and a_max of 28.6 umoles/ml intracellular fluid/30 min. The system required the presence of sodium and was sensitive to ouabain. Anaerobiosis, 2,4-dinitrophenol and low temperature suppressed the uptake of the amino acid. Efflux studies also indicated that the majority of the intracellular amino acid was rapidly exchangeable and therefore probably present in the cell water in a free state. It is suggested that alpha-aminoisobutyric acid is transported into isolated rat hepatocytes by an active carrier system.     

Glucose handling by hepatocytes from obese Zucker rats

Hepatocytes isolated from obese Zucker rats showed a significantly higher rate of both [U-¹⁴C]glucose and [U-¹⁴C]lactate incorporation into [¹⁴C]lipid than those from their lean counterparts. This was associated with a marked increase in the lipogenic rate measured by the incorporation of³H₂O into the cell esterified fatty acids. Although there were no changes in the incorporation of the tracer into either [¹⁴C]glycogen or¹⁴CO₂, the [¹⁴C] total uptake was significantly higher in the obese animals. The high rate of [¹⁴C]lipid synthesis from glucose was observed both at 15 and 30 mM substrate concentrations and was linked to an enhanced uptake of the tracer into the cell as measured using the decarboxilation of [1-¹⁴C]glucose in the presence of phenazine methosulphate. The presence of insulin in the incubation medium had no effect on the uptake of glucose by the liver cells. However, the large uptake of glucose by the hepatocytes from the obese animals was not related to an enhanced rate of transport as measured using 3-O-methyl[U-¹⁴C]glucose. The activity of glucose-6-phosphate dehydrogenase together with a higher [1-¹⁴C]glucose/[U-¹⁴C]glucose descarboxylation ratio indicate a predominant very active pentose phosphate pathway which may be responsible for the enhanced glucose uptake observed in the hepatocytes from the obese animals.     

Na+-dependence of 45Ca2+ uptake in adult rat isolated cardiac cells

We developed a technique that yields isolated adult rat myocytes, 70% of which are elongated and morphologically similar to intact tissue. Electrophysiological studies showed most of these cells were quiescent, Ca²⁺-tolerant and exhibited normal action potentials accompanied by contractions. We analyzed ⁴⁵Ca²⁺ uptake data in terms of instantaneous, fast and slow compartments. 69% of total exchangeable Ca²⁺ was found in the slow compartment; the rest was almost equally divided between the instantaneous and fast compartments. Replacement of extracellular Na⁺ by Li⁺ or Tris increased ⁴⁵Ca²⁺ uptake by the fast compartment; high [K⁺]_o increased this uptake further. These increases appeared to be related also to internal concentrations of Na⁺. This conclusion was supported by experiments with digitonin-treated cells. Our results indicate that the way Na⁺-dependent ⁴⁵Ca²⁺ uptake is affected by [Na⁺]_o, [Na⁺]_i and [K⁺]_o is compatible with the Na⁺-Ca²⁺ exchange mechanism. Our preparation should prove useful in studies of regulation of Ca²⁺ transport in cardiac muscles.     

Cytochrome c oxidase: the mechanistic significance of structural H+ in energy transduction

Changes in the bulk-phase concentration of O₂ and H⁺ associated with the reduction of O₂ to water are simultaneously determined in reactions catalyzed by fully reduced cytochrome c oxidase both isolated and embedded in liposomes. Consistent with the polyphasic kinetics of electron transfer through the oxidase, the time course of O₂ consumption and H⁺ translocation exhibit the following novel characteristics: (1) The uptake of scalar protons (H_m ⁺), the ejection of vectorial protons (H⁺ _v), and the consumption of O₂, all proceed in a kinetically polyphasic process. (2) During the first phase of the reaction the rates of O₂ uptake and H⁺ transfer are extremely fast and compatible with the rates of electron flow through the oxidase. (3) The K_m of the oxidase for O₂ is close to 75 M, the same for O₂ consumption and scalar H⁺ uptake. The V_max of O₂ reduction to water in reactions catalyzed by the isolated enzyme is, at least, 0.5 × 10⁴ s^–1. (4) The extent of vectorial H⁺ ejection by cytochrome c oxidase embedded in liposomes is an exponential function dependent on both enzyme concentration and extent of O₂ consumption. (5) The H⁺/O stoichiometry of H⁺ ejection is a variable that may reach a maximum value of 4.0 only when the enzyme undergoes net oxidation at extremely high enzyme/O₂ molar ratios. It is postulated that the generation of useful energy at the level of cytochrome c oxidase depends not only on the number of molecules of O₂ reduced to water but also on the extent and state of reduction and/or protonation of the enzyme.     

S-adenosylmethionine exerts a protective effect against thioacetamide-induced injury in primary cultures of rat hepatocytes

S-adenosylmethionine (SAMe) has been shown to protect hepatocytes from toxic injury, both experimentally-induced in animals and in isolated hepatocytes. The mechanisms by which SAMe protects hepatocytes from injury can result from the pathways of SAMe metabolism. Unfortunately, data documenting the protective effect of SAMe against mitochondrial damage from toxic injury are not widely available. Thioacetamide is frequently used as a model hepatotoxin, which causes in vivo centrilobular necrosis. Even though thioacetamide-induced liver necrosis in rats was alleviated by SAMe, the mechanisms of this protective effect remain to be verified. The aim of our study was to determine the protective mechanisms of SAMe on thioacetamide-induced hepatocyte injury by using primary hepatocyte cultures. The release of lactate dehydrogenase (LDH) from cells incubated with thioacetamide for 24 hours, was lowered by simultaneous treatment with SAMe, in a dose-dependent manner. The inhibitory effect of SAMe on thioacetamide-induced lipid peroxidation paralleled the effect on cytotoxicity. A decrease in the mitochondrial membrane potential, as determined by Rhodamine 123 accumulation, was also prevented. The attenuation by SAMe of thioacetamide-induced glutathione depletion was determined after subsequent incubation periods of 48 and 72 hours. SAMe protects both cytoplasmic and mitochondrial membranes. This effect was more pronounced during the development of thioacetamide-induced hepatocyte injury that was mediated by lipid peroxidation. Continuation of the SAMe treatment then led to a reduction in glutathione depletion, as a potential consequence of an increase in glutathione production, for which SAMe is a precursor.     

Transferrin binding and iron uptake in mouse hepatocytes

Methods were developed for obtaining highly viable mouse hepatocytes in single cell suspension and for maintaining the hepatocytes in adherent static culture. The characteristics of transferrin binding and iron uptake into these hepatocytes was investigated. (1) After attachment to culture dishes for 18–24 h hepatocytes displayed an accelerating rate of iron uptake with time. Immediately after isolation mouse hepatocytes in suspension exhibited a linear iron uptake rate of 1.14·10⁵molecules/cell per min in 5 μM transferrin. Iron uptake also increased with increasing transferrin concentration both in suspension and adherent culture. Pinocytosis measured in isolated hepatocytes could account only for 10–20% of the total iron uptake. Iron uptake was completely inhibited at 4°C. (2) A transferrin binding component which saturated at 0.5 μM diferric transferrin was detected. The number of specific, saturable diferric transferrin binding sites on mouse hepatocytes was 4.4·10⁴±1.9·10⁴ for cells in suspension and 6.6·10⁴±2.3·10⁴ for adherent cultured cells. The apparent association constants were 1.23·10⁷ 1·mol^?1 and 3.4·10⁶ 1·mol^?1 for suspension and cultured cells respectively. (3) Mouse hepatocytes also displayed a large component of non-saturable transferrin binding sites. This binding increased linearly with transferrin concentration and appeared to contribute to iron uptake in mouse hepatocytes. Assuming that only saturable transferrin binding sites donate iron, the rate of iron uptake is about 2.5 molecules iron/receptor per min at 5 μM transferrin in both suspension and adherent cells and increases to 4 molecules iron/receptor per min at 10 μM transferrin in adherent cultured cells. These rates are considerably greater than the 0.5 molcules/receptor per min observed at 0.5 μM transferrin, the concentration at which the specific transferrin binding sites are fully occupied. The data suggest that either the non-saturable binding component donates some iron or that this component stimulates the saturable component to increase the rate of iron uptake. (4) During incubations at 4°C the majority of the transferrin bound to both saturable and nonsaturable binding sites lost one or more iron atoms. Incubations including 2 mM α,α′-dipyridyl (an Fe¹¹ chelator) decreased the cell associated ⁵⁹Fe at both 4 and 37°C while completely inhibiting iron uptake within 2–3 min of exposure at 37°C. These observations suggest that most if not all iron is loosened from transferrin upon interaction of transferrin with the hepatocyte membrane. There is also greater sensitivity of ⁵⁹Fe uptake compared to transferrin binding to pronase digestion, suggesting that an iron acceptor moiety on the cell surface is available to proteolysis.     

Spontaneous51Cr release by isolated rat hepatocytes: An indicator of membrane damage

Summary Radiochromium uptake and release by isolated rat hepatocytes in suspension was monitored under continuous-labeling conditions. Cell protein remained unchanged during the absorption phase, whereas the release of⁵¹Cr correlated well with the loss of cell viability and release of cytoplasmic protein. The results suggest that under equilibrium conditions,⁵¹Cr release represents an efflux of label from damaged or dying preparations and not an elution of radioisotope from intact cells.     

Rat Liver Catechol-O-Methyltransferase Kinetics and Assay Methodology

Abstract

In mammals, catechol-O-methyltransferase (COMT) is distributed throughout various organs, the highest activities being found in the liver and kidney. However, comparisons of the kinetic parameters are difficult to perform, since the experimental procedures in the enzyme assay vary quite considerably. The present work was aimed at studying the optimal liver COMT assay conditions for determining the kinetics of the enzyme. The COMT assay was performed with liver homogenates from 60 days old male Wistar rats with adrenaline (AD) as the substrate. Time course experiments using 100 μM S-adenosyl-L-methionine (SAMe) and 300 μM AD showed linearity of O-methylation reaction upto 10min. Using 100μM SAMe, V_max (nmol mg protein' h^?1) and K_m (μM) values progressively decreased respectively from 22.1 and 104.8 at 5mindown to 5.8 and 24.62 at 60 min incubation periods. This decrease was not due to end-product inhibition. Using 2500 μM AD, K_m values (μM) for the methyl donor SAMe increased progressively from 174 at 5 min upto 1192.5 at 60 min; upto 30 min of incubation F_max values did not change. When a 5 min incubation period and 500 μM SAMe were used, V_max and K_m values for liver COMT were 63.4 nmol mg protein^?1h^?1 and 261.1 μM, respectively. It is concluded that an incubation period of 5 min and a SAMe concentration of 500 μM provide optimal conditions for the liver homogenate COMT assay.     

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     

Metabolic activation and hepatotoxicity. Effect of cysteine, N-acetylcysteine, and methionine on glutathione biosynthesis and bromobenzene toxicity in isolated rat hepatocytes.

Freshly isolated rat hepatocytes contained a high level (30–40 nmol/10⁶ cells) of reduced glutathione (GSH) which decreased steadily upon incubation in an amino acid containing medium lacking cysteine and methionine. This decrease in GSH level was prevented, and turned into a slight increase, when either cysteine, N-acetylcysteine, or methionine was also present in the medium. The amino acid uptake into hepatocytes was more rapid with cysteine than with methionine. Cystine was not taken up, or taken up very slowly, by the cells and could not be used to prevent the decrease in GSH level which occurred in the absence of cysteine and methionine. The level of GSH in hepatocytes freshly isolated from rats pretreated with diethylmaleate was markedly decreased (to ~5 nmol/10⁶ cells) but increased rapidly upon incubation of the cells in a medium containing amino acids including either cysteine, N-acetylcysteine, or methionine. Again, cysteine was taken up into the cells more rapidly than methionine. The rate of uptake of cysteine was moderately enhanced in hepatocytes with a lowered level of intracellular GSH as compared to cells with normal GSH concentration. Exclusion of glutamate and/or glycine from the medium did not markedly affect the rate of resynthesis of GSH by hepatocytes incubated in the presence of exogenously added cysteine or methionine. Incubation of hepatocytes with bromobenzene in an amino acid-containing medium lacking cysteine and methionine resulted in accelerated cell damage. Addition of either cysteine, N-acetylcysteine, or methionine to the medium caused a decrease in bromobenzene toxicity. The protective effect was dependent, however, on the time of addition of the amino acid to the incubate; e.g., the effect on bromobenzene toxicity was greatly reduced when either cysteine or methionine was added after 1 h of preincubation of the hepatocytes with bromobenzene as compared to addition at zero time. This decrease in protective effect in bromobenzene-exposed cells was related to a similar decrease in the rate of uptake of cysteine and methionine into hepatocytes preincubated with bromobenzene. The rate of uptake, and incorporation into cellular protein, of leucine was also markedly inhibited in hepatocytes preincubated with bromobenzene. In contrast, there was no measurable change in the rate of release of leucine from cellular protein as a result of incubation of hepatocytes with bromobenzene. It is concluded that the presence of cysteine, N-acetylcysteine, or methionine in the medium protects hepatocytes from bromobenzene toxicity by providing intracellular cysteine for GSH biosynthesis and suggested that an inhibitory effect on amino acid uptake may contribute to the cytotoxicity of bromobenzene in hepatocytes.     

Comparative studies of protein biosynthesis: the main experimental parameters in pulse and pulse-chase experiments must be standardized

Summary— The influence of experimental conditions was investigated in pulse and pulse-chase experiments involving ^l-[³⁵s]methionine incorporation by isolated rat hepatocytes. The incorporation of the labelled amino acid must be linear as a function of dose and time, and similar hepatocyte densities should be used to compare radioactive uptake. High hepatocyte densities give greater precision. In pulse-chase experiments, it was shown that a pool of free radioactivity moves progressively during the chase phase from the intracellular compartment. Protein-associated radioactivity must therefore be expressed as a function of both total radioactive uptake and total labelled protein.     

Radioenzymatic estimation of S-adenosylmethionine in rat brain regions and subcellular fractions

A rapid, sensitive, and specific method for the analysis of S-adenosyl-l-methionine (SAMe) in tissues is described. The assay is based on the measurement of the conversion of SAMe and [³H]dopamine to 3-[³H]methoxytyramine in the presence of catechol-O-methyltransferase (COMT). The linearity of the quantitative measurement is greatly improved by including an internal standard of [¹⁴C]SAMe in each test. Using the described technique, nanogram quantities of SAMe can be measured in tissue. SAMe is distributed relatively evenly throughout the anatomical regions of the brain. Studies of its subcellular distribution indicate that while SAMe is located primarily in the soluble fraction, a considerable amount is also associated with the synaptosomal fraction.     

Intracellular signalling of epinephrine in rat hepatocytes during fetal development and hepatic regeneration

The changes in intracellular calcium concentration and IP₃ production after the addition of epinephrine were analysed in adult, fetal (20th–22nd day of intrauterine life), and regenerating rat hepatocytes (4 h–24 h after partial hepatectomy) to determine whether the signal transduction is the same in quiescent proliferating and differentiating cells.The epinephrine treatment causes a significative cytosolic calcium transient in hepatocytes isolated in the last day of fetal life (22-day old) and in the early stage of regeneration (4 h). This effect is not significant in the previous stage of fetal life (20-day old) and at the onset of M phase of cell cycle after partial hepatectomy (24 h).[³H]myo inositol incorporation into IP₃ and IP₄ is higher in 20 day fetal and regenerating hepatocytes with respect to the control. In these cells the epinephrine does not affect basal level of IP₃ and IP₄, while it causes a substantial increase of these inositol phosphates in adult hepatocytes.[³H]myo inositol incorporation into PIP₂ is very low at the 20th day of fetal life. Epinephrine has no effect on this parameter in fetal and regenerating hepatocytes.Our results show that the epinephrine signal is mediated differently in proliferating and in quiescent hepatocytes.     

Isolation and culture of hepatocytes from human liver of immediate autopsy

Summary Human livers were removed at immediate autopsy (IA) from brain death patients within 1 h after cessation of cardiac function. Viable hepatocytes were isolated successfully from these IA livers by perfusion of an intack lobe with collagenase or by digestion of a small tissue wedge with collagenase-dispase. The yields of hepatocytes ranged from 1 to 3 × 10⁶ cells/g liver in the five cases studied. Approximately 70 to 90% of the cells excluded trypan blue dye. In the isolated hepatocytes, 632 pmol/mg protein of cytochromep ₄₅₀ and 536. pmol/mg protein cytochromeb ₅ were measured. The cells attached to the dishes in 4 h and produced monolayer cultures with a high success rate. The cells maintained in primary cultures for several days and developed ultrastructural features characteristic of human hepatocytes in vivo. The cultured hepatocytes can hydroxylate benzo[a]pyrene, conjugate the metabolites, and have a benzo[a]pyrene hydroxylase activity of 48.7 pmol/mg DNA per h, which is comparable to that of rat hepatocytes. The liver cells repaired DNA damage caused by exposures to aminofluorene and acetylaminofluorene in culture. This work was supported by EPA Grants R-809835-01-1, R-809599010 and DOE Contract DE-A505-83ER60158. Cobtribution no. 1762 from the Cellular Pathobiology Laboratory, University of Maryland School of Medicine.     

LACK OF ENHANCEMENT OF DIMETHYLTRYPTAMINE FORMATION IN RAT BRAIN AND RABBIT LUNG IN VIVO BY METHIONINE OR S-ADENOSYLMETHIONINE

In vivo conversion of intracisternally administered [¹⁴C]tryptamine to [¹⁴C]N,N-dimethyl-tryptamine (DMT) in rat brain, even in the presence of an excess of substrate and methyl donor appeared to be insignificant, although enzymatically synthesized [¹⁴C]DMT was recovered readily after intracranial injection. Authenticity of [¹⁴C]DMT was demonstrated by cocrystallization with authentic DMT and oxalic acid to constant specific radioactivity after chromatographic separation of [¹⁴C]DMT. In rabbit lung, the apparent K_m for S-adenosylmcthionine (SAMe) (29 μM) with indolethylamine-N-methyltransferase was found to be close to endogenous levels of SAMe (34 μM) that are not likely to saturate the enzyme normally. Nevertheless. large doses of L-methioninc or SAMe failed to increase the in vivo conversion of [¹⁴C]N-methyltryptamine to [¹⁴C]DMT in this tissue. The production of [¹⁴]DMT was instead markedly irihihitrd by this treatment. possibly due to an effect of S-adeno-sylhomocysteine. Our results fail to support the hypothesis that psychotropic effects of methionine or SAMe are due to increased accumulations of pharmacologically active methylated indoleamines.     

Pitfalls in the measurement of membrane potential in yeast cells using tetraphenylphosphonium

The uptake of the lipophilic cation tetraphenylphosphonium (Ph₄P⁺) by Saccharomyces cerevisiae was measured using yeast grown on glucose and harvested either at the logarithmic or at the stationary phase of growth. When yeast was collected at the stationary phase, Ph₄P⁺ uptake proceeded steadily during several hours until an equilibrium was reached. When yeast was collected in the logarithmic phase of growth, a biphasic uptake was observed. The second phase of uptake began when the glucose of the incubation medium had been exhausted. From experiments in the presence of cycloheximide or chloramphenicol it is concluded that the second phase of Ph₄P⁺ uptake is dependent on the synthesis of some protein(s) repressed by glucose but unrelated with the existence of functional mitochondria. The addition of compounds which collapse the membrane potential provokes an efflux from the yeast cells of the Ph₄P⁺ accumulated both during the first phase and the second phase of uptake. It is concluded that accumulation of Ph₄P⁺ in yeast cells is a complex process and that Ph₄P⁺ cannot be used to give a quantitative measure of the yeast plasma membrane potential.