Partial purification and properties of choline kinase (EC 2. 7. 1. 32) from rabbit brain: measurement of acetylcholine

Headgroup biosynthesis of phosphatidylcholine and phosphatidylethanolamine in seed plants

Phospholipid biosynthesis is crucial for plant growth and development. It involves attachment of fatty acids to a phospho-diacylglycerol backbone and modification of the phospho-group into an amino alcohol. The biochemistry and molecular biology of the former has been well established, but a number of enzymes responsible for the latter have only recently been cloned and functionally characterized in Arabidopsis and some other model plant species. The metabolism involving the polar head groups of phospholipids established by past biochemical studies can now be validated by available gene knockout models. Moreover, gene knockout studies have revealed emerging functions of phospholipids in regulating plant growth and development. This review aims to revisit the old questions of polar headgroup biosynthesis of plant phosphatidylcholine and phosphatidylethanolamine by giving an overview of recent advances in the field and beyond.

Pre-junctional effects of oximes on [3H]-acetylcholine release in rat hippocampal slices during soman intoxication

In this study, the non-reactivating effects of oximes in the hippocampus of the rat are investigated. The potassium (51 mM) evoked release of [(3)H]-acetylcholine and the liberation of [(3)H]-choline were determined in hippocampal slices following in vitro exposure to soman and five oximes (toxogonin, HI-6, HLö-7, P2S and 2-PAM) in separate experiments by superfusion. In the absence of soman, toxogonin and HLö-7 in particular induced a concentration dependent significant increase in the evoked release of [(3)H]-acetylcholine. There was also a significant effect of HI-6, but the effect was much smaller. Two pralidoxime salts, P2S (methanesulfonate salt) and 2-PAM (methiodide salt), had similar but lower effects that were only observed at relatively high concentrations. Experiments performed following complete inhibition of the acetylcholinesterase activity by soman (1.0 microM) showed that HI-6 and HLö-7 induced a significant decrease in the potassium-evoked release of [(3)H]-acetylcholine, while the liberation of [(3)H]-choline increased. Toxogonin, P2S and 2-PAM did not reduce significantly the evoked release of [(3)H]-acetylcholine. Only limited reactivation of the acetylcholinesterase activity was observed in superfusion experiments with toxogonin, HI-6, P2S and 2-PAM following exposure of hippocampal slices to soman. However, HLö-7 was proved to be relatively more effective in reactivating the acetylcholinesterase activity at high concentrations (50 and 200 microM). The acetylcholinesterase activity was reactivated to approximately 12% and 40% of control, respectively. It is concluded that HI-6 and HLö-7 have important non-acetylcholinesterase reactivating properties following soman poisoning, as may be seen by the significant reduction in the evoked release of [(3)H]-acetylcholine effected by these oximes. HLö-7 is of particular interest in view of its ability to additionally improve reactivation of the acetylcholinesterase activity.

Selected pharmacodynamic and biochemical properties of selenonium choline

1. Five minutes after intravenous administration of 50 mg/kg of the novel choline analogue selenonium choline [(CH3)2Se + CH2CH2OH, SeCh], only 8% of the administered dose was accounted for in blood, brain, liver, heart, and kidney tissues. 2. SeCh was acetylated in vivo to acetylselenonium choline (ASeCh) in all of the tissues examined. 3. During postmortem incubation, brain concentrations of SeCh and ASeCh increased to 535% and to 425%, respectively. 4. K(m) and Vmax values for the phosphorylation of SeCh by choline kinase were higher and lower, respectively, compared to the phosphorylation of choline. 5. Acetylation of SeCh was described with K(m) and Vmax values that were both higher than the values for Ch. 6. The data suggest that SeCh is phosphorylated and incorporated into various lipids in brain tissue, and is acetylated to ASeCh by both nonneural and neural tissues.

The effect of trimethyltin on acetylcholine release in the guinea-pig trachea

The purpose of the present work was to characterise the effects of trimethyltin on the release of acetylcholine from parasympathetic nerves and its effect on the postjunctional cholinergic stimulation of a smooth muscle. The guinea-pig trachea has been used as a model. Prejunctionally, trimethyltin (3.0 × 10(-3) M) significantly enhanced in a reversible manner the high K(+) (75 mM) evoked release of endogenous acetylcholine and [(3)H]acetylcholine. The evoked release of endogenous acetylcholine and [(3)H]acetylcholine was released from a pool of acetylcholine being independent of extraneuronal Ca(2+) in the presence, but not in the absence of trimethyltin. The effect of trimethyltin on the release was not inhibited by low Ca(2+) (0 mM and 1.0 × 10(-4) M) or by Ca(2+) channel blockers (verapamil, 1.0 × 10(-4) M, flunarizine, 1.0 × 10(-4) M, ω-conotoxin GVIA, 2.0 × 10(-7) M and ω-agatoxin, 2.0 × 10(-7) M). The present results also demonstrate that trimethyltin induce emptying of a non-vesicular, probably a cytoplasmic storage pool of acetylcholine, since AH5183 (2.0 × 10(-5) M), an inhibitor of the translocation of acetylcholine into synaptic vesicles, and α-latrotoxin (1.0 × 10(-8) M), a toxin from black widow spider venom inducing vesicle depletion, had no inhibitory effects on the release of [(3)H]acetylcholine evoked by trimethyltin (3.0 × 10(-3) M). The release of [(3)H]acetylcholine was moreover enhanced by trimethyltin when the vesicular uptake of [(3)H]acetylcholine was inhibited by AH5183, probably as a result of a higher cytoplasmic concentration of [(3)H]acetylcholine. Trimethyltin also reduced the neuronal uptake of [(3)H]choline and this was probably due to a depolarising effect of trimethyltin on the cholinergic nerve terminals. A similar depolarisation induced by trimethyltin was observed during patch clamping of GH(4) C(1) neuronal cells. Postjunctionally, trimethyltin had no effect by itself or on the carbachol-induced smooth muscle contraction, indicating that trimethyltin did not have a general depolarising effect on smooth muscle cells or an effect on muscarinic receptors. Furthermore, the reduced electrical field-induced contraction and the subsequent increase in the basal smooth muscle tension that was observed by addition of trimethyltin was activity-dependent, and was most probably due to emptying of a nervous non-vesicular storage pool of acetylcholine, followed by rapid hydrolysis of acetylcholine by acetyl- and pseudocholinesterases.

Partial purification of two forms of choline kinase and separation of choline kinase from sphingosine kinase of rat brain

Choline kinase of rat brain was purified approximately 200,000 fold using acid precipitation, ammonium sulphate fractionation, Q-Sepharose, Octyl-Sepharose and AH-Sepharose chromatography. The ability of this enzyme to catalyze the phosphorylation of choline, ethanolamine (Etn), monomethylethanolamine (MeEtn), dimethylethanolamine (Me2Etn) and sphingosine was investigated. Choline kinase was separated from sphingosine kinase. The fraction with highly purified choline kinase had four major polypeptides with different molecular masses and possessed activities towards choline, Etn, MeEtn and Me2Etn. Two forms of choline kinase were obtained when the enzymatically active fractions eluted from the Q-Sepharose column were subjected to a horizontal isoelectrofocusing electrophoresis. One form focused around pH 4.7 and is able to phosphorylate choline, Etn, MeEtn and Me2Etn. The other form focused around pH 10 and possessed only choline kinase activity. The latter form of choline kinase did not display classical Michaelis-Menten's mechanism but revealed a positive co-operative pattern for two choline binding sites. This form was purified to apparent homogeneity with a approximate molecular mass of 14.4 kDa.

Lecithin and choline in human health and disease

Choline is involved in methyl group metabolism and lipid transport and is a component of a number of important biological compounds including the membrane phospholipids lecithin, sphingomyelin, and plasmalogen; the neurotransmitter acetylcholine; and platelet activating factor. Although a required nutrient for several animal species, choline is not currently designated as essential for humans. However, recent clinical studies show it to be essential for normal liver function. Additionally, a large body of evidence from the fields of molecular and cell biology shows that certain phospholipids play a critical role in generating second messengers for cell membrane signal transduction. This process involves a cascade of reactions that translate an external cell stimulus such as a hormone or growth factor into a change in cell transport, metabolism, growth, function, or gene expression. Disruptions in phospholipid metabolism can interfere with this process and may underlie certain disease states such as cancer and Alzheimer's disease. These recent findings may be appropriate in the consideration of choline as an essential nutrient for humans.

Choline metabolism as a basis for the selective vulnerability of cholinergic neurons

The unique propensity of cholinergic neurons to use choline for two purposes--ACh and membrane phosphatidylcholine synthesis--may contribute to their selective vulnerability in Alzheimer's disease and other cholinergic neurodegenerative disorders. When physiologically active, the neurons use free choline taken from the 'reservoir' in membrane phosphatidylcholine to synthesize ACh; this can lead to an actual decrease in the quantity of membrane per cell. Alzheimer's disease (but not Down's syndrome, or other neurodegenerative disorders) is associated with characteristic neurochemical lesions involving choline and ethanolamine: brain levels of these compounds are diminished, while those of glycerophosphocholine and glycerophosphoethanolamine (breakdown products of their respective membrane phosphatides) are increased, both in cholinergic and noncholinergic brain regions. Perhaps this metabolic disturbance and the tendency of cholinergic neurons to 'export' choline--in the form of ACh--underlie the selective vulnerability of the neurons. Resulting changes in membrane composition could abnormally expose intramembraneous proteins such as amyloid precursor protein to proteases.

Purification and properties of choline kinase from rat brain

A blue-dye column separated rat brain choline kinase (EC 2.7.1.32) into two peaks, very likely corresponding to distinct isozymes. The major-peak enzyme was purified 15,000-fold to homogeneity. The final specific activity was approx. 40 mumol.min-1.mg-1. This is 10-times higher than that reported for the enzymes from lung and kidney. The purified enzyme gave a single 44 kDa protein band on sodium dodecyl sulfate polyacrylamide gel electrophoresis. Analytical gel-filtration showed that the native enzyme had a molecular weight of 90,000 and a Stokes radius of 4.2 nm. The sedimentation coefficient was deduced to be 4.8 S and the molecular weight 87,600 by sucrose-density-gradient centrifugation. Hence, the native enzyme appears to be a dimer. The apparent Km values for ATP and choline were 1.0 mM and 14 microM, respectively. At high choline concentrations, the enzyme showed deviation from Michaelis-Menten kinetics. The enzyme was active in a high pH range and utilized a variety of amino alcohols structurally related to choline, including ethanolamine, N-methylethanolamine and N,N-dimethylethanolamine as substrates. Spermine and spermidine stimulated the enzyme by decreasing the apparent Km for ATP and increasing Vmax. Although less efficiently, monovalent cations such as NH4+, K+, Li+ and Na+ and quaternary amines such as carpronium, chlorocholine and acetylcholine were also stimulatory.

Substrate specificity of choline kinase

The substrate specificity of choline kinase (ATP:choline phosphotransferase, EC 2.7.1.32) from brewer's yeast has been examined using multiple analogs of choline, most of which have been reported to be a substrate of one or another choline-using system from other sources. In contrast to many such systems, choline kinase from brewer's yeast has been found to have relatively stringent and straight-forward structural requirements for its substrates. It is hypothesized that there are at least four points of interaction of the substrate with the enzyme--one for the hydroxyalkyl side chain and one for each of the three substituents on the quaternary nitrogen. Of the latter, one site seems relatively more sterically hindered than the other two. Short, single or double alkyl substitutions on the quaternary nitrogen are possible without a large loss of substrate capacity of the analog. Thus N,N-dimethyl-N-propylethanolamine had a relative Vmax of 116% and a relative Vmax 96% that of choline and a Km of 68 +/- 15 microM [nearly four times that of choline itself (18 microM)]. However, N-butyl-N,N-dimethylethanolamine and N,N,N-triethylethanolamine were very poor substrates. Analogs with substituents on the quaternary nitrogen of longer chain length were without activity as were aromatic derivatives. None of the bisquaternary compounds of the general structure HOCH2CH2N+(CH3)2-(CH2)n-N+(CH3)2CH2CH2OH (n = 2-10) showed any substrate capacity, as well. Restrictions on the hydroxyethyl side chain were also severe. One additional methylene group in this chain greatly reduced substrate capacity of the analog and two additional ones eliminated it entirely, as did almost any substituent on the beta carbon. A single (but not a double) substituent on the alpha carbon was moderately tolerated, however. Thus alpha-methylcholine and N-methyl-2-hydroxymethylpiperidine were substrates (although the latter one was a poor one) but beta-methylcholine and N-methyl-3-hydroxypiperidine were not. Such information may be of use toward designing cholinergic probes targeting specific enzyme or metabolic functions.

Choline uptake and metabolism in affinity-purified cholinergic nerve terminals from rat brain

Cholinergic nerve terminals were affinity purified from rat caudate nucleus. These terminals possessed both high- (KT = 2.7 microM) and low- (KT = 58 microM) affinity uptake mechanisms for exogenous [3H]choline. The proportion of [3H]choline acetylated was reduced from 75 to 30% under conditions of anoxia and hypoglycaemia, whereas the phosphorylation of choline increased from 4 to 52%. Choline phosphorylation was also increased when the terminals were preloaded with choline. The affinity-purified terminals were shown to release acetylcholine in a Ca2+-dependent manner on depolarization. The relationship between choline acetylation and phosphorylation in the cholinergic nerve terminal is discussed.

Choline kinase activity in Plasmodium-infected erythrocytes: characterization and utilization as a parasite-specific marker in malarial fractionation studies

Choline kinase (EC 2.7.1.32) was investigated in plasmodium falciparum-infected erythrocytes. Disrupted infected erythrocytes had a choline kinase activity of 1.9 +/- 0.2 nmol phosphorylcholine/10(7) infected cells per h, whereas the activity in normal uninfected erythrocytes was less than 6 pmol/10(7) cells per h. A broad alkaline optimal pH (7.9-9.2) was observed. The Km values for choline and ATP were 79 +/- 20 microM, and 1.3 +/- 0.3 mM, respectively. ATP concentrations higher than 12 mM inhibited choline kinase. Maximal activity was registered with a Mg2+ concentration of 10 mM, whereas its replacement by Mn2+, or other divalent cations, involved a decrease in choline kinase activity of at least 75%. Inhibition by products of the reaction, such as phosphorylcholine and ADP was investigated. In plasmodium knowlesi-infected erythrocytes, choline kinase had similar properties, but with a much higher specific activity of 16.4 +/- 2.1 nmol/10(7) infected cells per h. Subcellular fractionation of P. knowlesi-infected erythrocyte suspensions revealed that choline kinase was located exclusively in the cytosol of the parasite. We show that this enzyme is a useful index of parasite cytosolic content leakage, when infected erythrocytes are fractionated by saponin lysis or nitrogen decompression.

Lipids of nervous tissue: composition and metabolism

As indicated in the Introduction, the many significant developments in the recent past in our knowledge of the lipids of the nervous system have been collated in this article. That there is a sustained interest in this field is evident from the rather long bibliography which is itself selective. Obviously, it is not possible to summarize a review in which the chemistry, distribution and metabolism of a great variety of lipids have been discussed. However, from the progress of research, some general conclusions may be drawn. The period of discovery of new lipids in the nervous system appears to be over. All the major lipid components have been discovered and a great deal is now known about their structure and metabolism. Analytical data on the lipid composition of the CNS are available for a number of species and such data on the major areas of the brain are also at hand but information on the various subregions is meagre. Such investigations may yet provide clues to the role of lipids in brain function. Compared to CNS, information on PNS is less adequate. Further research on PNS would be worthwhile as it is amenable for experimental manipulation and complex mechanisms such as myelination can be investigated in this tissue. There are reports correlating lipid constituents with the increased complexity in the organization of the nervous system during evolution. This line of investigation may prove useful. The basic aim of research on the lipids of the nervous tissue is to unravel their functional significance. Most of the hydrophobic moieties of the nervous tissue lipids are comprised of very long chain, highly unsaturated and in some cases hydroxylated residues, and recent studies have shown that each lipid class contains characteristic molecular species. Their contribution to the properties of neural membranes such as excitability remains to be elucidated. Similarly, a large proportion of the phospholipid molecules in the myelin membrane are ethanolamine plasmalogens and their importance in this membrane is not known. It is firmly established that phosphatidylinositol and possibly polyphosphoinositides are involved with events at the synapse during impulse propagation, but their precise role in molecular terms is not clear. Gangliosides, with their structural complexity and amphipathic nature, have been implicated in a number of biological events which include cellular recognition and acting as adjuncts at receptor sites. More recently, growth promoting and neuritogenic functions have been ascribed to gangliosides. These interesting properties of gangliosides wIll undoubtedly attract greater attention in the future.(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of potassium depolarization and preganglionic nerve stimulation on the metabolism of [3H]-choline in rat isolated sympathetic ganglia

1 The effects of potassium depolarization and preganglionic nerve stimulation on the metabolism of [(3)H]-choline in the isolated superior sympathetic ganglion of the rat have been studied.2 When unstimulated (resting) ganglia were incubated for 10 min with a low concentration (0.1 muM) of [(3)H]-choline (high affinity uptake), approximately 75% of the accumulated radioactivity was present as [(3)H]-phosphorylcholine, 11% was [(3)H]-acetylcholine ([(3)H]-ACh) and the remainder was unchanged [(3)H]-choline.3 Depolarization of the ganglia with K (46 mM) before their incubation with [(3)H]-choline, increased [(3)H]-choline uptake by 70% and increased [(3)H]-ACh synthesis by more than 700%, so that [(3)H]-ACh represented almost 50% of the total radioactivity recovered. In contrast, the proportion of [(3)H]-phosphorylcholine fell to 36% of the total radioactivity recovered.4 The striking effect of K-depolarization on [(3)H]-ACh synthesis in ganglia occurred at a concentration of 30 mM or above, and the maximum effect was seen at 45-50 mM.5 Chronic denervation of the ganglia abolished all the effects of high-K on [(3)H]-choline metabolism. In resting ganglia, [(3)H]-ACh formation was reduced by over 80% but [(3)H]-phosphorylcholine synthesis and the level of unchanged [(3)H]-Ch were not affected by denervation.6 Exposure of the ganglia to low-Na or hemicholinium-3 (HC-3) greatly reduced [(3)H]-ACh synthesis in control resting ganglia and almost abolished the effects of high-K on [(3)H]-ACh synthesis.7 Prevention of transmitter release with high-Mg or low-Ca medium also prevented K-depolarization from stimulating [(3)H]-ACh synthesis.8 Preganglionic nerve stimulation had an effect on [(3)H]-choline metabolism similar to that of K-depolarization. Thus, at all the frequencies studied (1-30 Hz), [(3)H]-ACh synthesis was greatly increased and [(3)H]-phosphorylcholine was reduced, the maximum effects occurring at 3 Hz.9 When ganglia were incubated with a high concentration (100 muM) of [(3)H]-choline (low affinity uptake), a different pattern of metabolism was observed. Most of the radioactivity in resting ganglia was present as unchanged [(3)H]-choline (70%) with [(3)H]-phosphorylcholine and [(3)H]-ACh representing 23% and 6% of the total radioactivity respectively. K-depolarization decreased [(3)H]-choline uptake but increased the proportions of [(3)H]-phosphorylcholine and [(3)H]-ACh to 32% and 24% of the total radioactivity respectively.10 It is concluded that in unstimulated (resting) rat sympathetic ganglia most of the [(3)H]-choline transport and metabolism occurs in postsynaptic structures. However, depolarization of the presynaptic nerve terminals appears to trigger a sodium-dependent, HC-3 sensitive, high-affinity uptake process, and causes a dramatic increase in presynaptic [(3)H]-ACh synthesis together with a fall in postsynaptic [(3)H]-phosphorylcholine synthesis. These changes in choline metabolism cannot be due to the depolarization of the nerve terminals per se, because they were abolished by high-Mg or low-Ca, i.e. when transmitter release was prevented. Thus, the increase in ACh synthesis may be triggered by a fall in the intraterminal concentration of ACh or by the changes in Ca flux induced by depolarization. Our experiments do not provide evidence on these possible mechanisms.

The effects of atropine on [3H]acetylcholine secretion from guinea-pig myenteric plexus evoked electrically or by high potassium

1. The myenteric plexus-longitudinal muscle preparation of the guinea-pig ileum was incubated with [(3)H]choline (1.125-1.5 muM), and then superfused with Tyrode solution containing hemicholinium-3 (10 muM). Secretion of [(3)H]acetylcholine ([(3)H]ACh) was evoked either (a) by electrical field stimulation (0.5-15 Hz, 150 shocks per period, 0.5 msec), used to ;indirectly' depolarize the varicosities of nerve terminals, or (b) by high potassium (40 mM with 1 muM-tetrodotoxin, for 6 min, or 80 mM without tetrodotoxin, for 1 min), to ;directly' depolarize varicosities.2. With these stimulation parameters, which yielded about the same fractional secretion of [(3)H]ACh, and with eserine (10 muM) present in the medium, atropine (1 muM) enhanced the ;indirectly', electrically evoked secretion 3.65+/-0.34 (n = 6) fold, and that caused by 40 mM or 80 mM-potassium 1.82+/-0.06 (n = 6) or 1.55+/-0.09 (n = 10) fold, respectively. Atropine thus enhanced ;indirectly', electrically evoked secretion 4-fold more than that caused by ;direct' depolarization of varicosities with high potassium (P < 0.001).3. This difference is not likely to be caused by depression of the sensitivity of the presynaptic muscarinic receptors to ACh released by nerve stimulation, caused by the hypertonicity of the medium in the potassium stimulation experiments. The medium made hypertonic by addition of Tris-HEPES (80 mM) did lower the binding affinity of membrane preparations of (pre- and post-synaptic) muscarinic receptors, to carbamylcholine, and also the contractile responsiveness of the longitudinal muscle to this agent, in both cases to about one half. But it did not appear to alter the responsiveness of either pre- or post-synaptic muscarinic receptors to endogenous ACh, released by nerve stimulation.4. The results support a dual-mode model for the muscarinic negative feed-back control of ACh secretion from the nerve terminals of this preparation, mainly operating by restriction of the invasion of terminals, and only secondarily by depression of the efficiency of depolarization-secretion coupling in invaded varicosities.5. Since this model has earlier been proposed to apply for the control of secretion of [(3)H]noradrenaline from the micro-anatomically similar nerve terminals of noradrenergic nerves, the present findings suggest that the model may have a wider biological significance, and possibly apply to the control of the secretory activity of boutons-en-passant nerve terminals in general.

Deanol affects choline metabolism in peripheral tissues of mice

Administration of 2-dimethylaminoethanol (deanol) to mice induced an increase in both the concentration and the rate of turnover of free choline in blood. Treatment with deanol also caused an increase in the concentration of choline in kidneys, and markedly inhibited the rates of oxidation and phosphorylation of intravenously administered [3H-methyl]choline. In the liver, deanol inhibited the rate of phosphorylation of [3H-methyl]choline, but did not inhibit its rate of oxidation or cause an increase in the level of free choline. These findings suggest that deanol increases the choline concentration in blood by inhibition of its metabolism in tissues. Deanol may ultimately produce its central cholinergic effects by inhibition of choline metabolism in peripheral tissues, causing free choline choline to accumulate in blood, enter the brain, and stimulate cholinergic receptors.

The release of acetylcholine from post-ganglionic cell bodies in response to depolarization

1. Acetylcholine (Ach) release from parasympathetic ganglia cell somata was investigated in denervated avian ciliary ganglia. Three days after the input to the ganglion (the oculomotor nerve) was sectioned, all presynaptic nerve terminals had degenerated. 2. Denervated ganglia were shown to contain endogenous ACh and to be capable of synthesizing [3H]ACh from [3H]choline added to the incubation medium. 3. In response to depolarization induced by incubation in 50 mM-[K+]o, denervated ganglia released [3H]ACh into bath effluents in amounts approximately 15% of the non-denervated contralateral control. This release was shown to be Ca2+ dependent in both intact and denervated ganglia. 4. Antidromic electrical stimulation of ciliary nerves also elicited [3H]ACh release. Nicotine (1 microgram/microliter.) depolarized denervated ciliary ganglion cells and evoked release of the transmitter and this release was antagonized by curare. 5. It is concluded that the ganglionic cell bodies sysnthesized ACh and released the transmitter in response to K+ depolarization, antidromic stimulation and cholinergic agonists, despite the lack of morphological specializations usually associated with stimulus-induced release of neurotransmitter. The evidence suggests the existence of a mechanism of transmitter release which is Ca2+ dependent, probably from a cytoplasmic pool and therefore distinct from the usual vesicular release at the nerve terminal.

Lipid metabolism in germinating seeds. Purification of ethanolamine kinase from soya bean

Ethanolamine kinase has been purified to homogeneity from germinating soya bean (Glycine max L.) seeds. The purified enzyme had a molecular weight of 17--19 000 as estimated by gel filtration and sodium dodecyl suphate-polyacrylamide gel electrophoresis. It would not phosphorylate choline, had a Km for ethanolamine of 8 microM and utilised Mg-ATP. The kinase could be purified in a 37 000 molecular weight form (dimer) which would easily dissociate on storage. In contrast to ethanolamine kinase whose activity was unaffected by the presence of choline in the assay system, soya bean choline kinase, although not phosphorylating ethanolamine, was competitively inhibited by the latter. The purification of specific choline and ethanolamine kinases from germinating soya bean confirmed in vivo observations which had indicated separate enzymes.

Choline pathways during normal and stimulated renal growth in rats

Cellular membrane synthesis occurs during normal and stimulated renal growth. Choline in the kidney is utilized as a precursor for membrane synthesis via the choline kinase reaction. We investigated choline phosphorylation during normal and stimulated renal growth. Rapidly growing neonatal rat kidneys contained relatively high levels of choline kinase activity (61 pmol phosphorylcholine/min per mg protein). Choline kinase activity and phosphorylcholine production then fell gradually over the 1st mo of life; by 1 mo phosphorylcholine production was 34 pmol phosphorylcholine/min per mg protein. Choline kinase activity increased by 27% (P less than 0.001) in 28-day-old rats when renal growth was stimulated by contralateral nephrectomy; the increase occurred within 2 h after surgery. Thus, changes in the activity of this important enzyme in the initiation of membrane synthesis is associated both with normal renal development and with adaptation to nephron loss. The findings further suggest that the cell membrane may be involved in the initiation of compensatory renal growth.

Phospholipid synthesis in mammary tissue. Choline and ethanolamine kinases: kinetic evidence for two discrete active sites

Choline and ethanolamine kinases are located in the high speed supernatant of lactating bovine mammary gland. Maximum activities of choline and ethanolamine kinases were observed at pH 9.2 and 8.0, respectively, with the rate of ethanolamine phosphorylation being 1/15 that of choline phosphorylation. Activation energies of 29 joules (Q10--1.5) and 31 joules (Q10 = 1.5) were calculated between 3.4 and 31.3 C for choline kinase and ethanolamine kinase, respectively. Above 31.3 C, the Arrhenius plot deviated from linearity for both enzymes, suggesting that denaturation was occurring. An apparent Km of 0.25 mM for choline was obtained for choline kinase activity. The apparent Km of ethanolamine kinase for ethanolamine was unusually high (17 mM), the activity was not linear with increasing protein concentration. Activity was tripled and the Km decreased to 2.5 mM when the enzyme preparation was washed with butanol: benzene mixture, suggesting the presence of an endogenous competitive inhibitor(s), with respect to ethanolamine. Choline kinase was not affected by the solvent wash. Substrate competition studies revealed that choline kinase was slightly inhibited competitively by ethanolamine (apparent Ki = 19-21 mM), whereas choline was a potent competitive inhibitor of ethanolamine kinase (apparent Ki = 0.33-0.50 mM). The results indicated that these two kinase activities were mediated by two distinct active sites, possibly on a single protein. The significance of choline in the regulation of phosphatidylethanolamine synthesis is discussed.