Purification and characterization of choline/ethanolamine kinase from rat liver

Choline kinase, the first enzyme in the CDP-choline pathway for phosphatidylcholine biosynthesis, was purified 26,000-fold from rat liver to a specific activity of 143,000 nmol.min-1.mg-1 protein. The subunit molecular mass was 47 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, while the apparent native molecular mass was 160 kDa by size exclusion chromatography, suggesting a tetrameric structure. Two peaks of choline kinase activity were obtained by chromatofocusing. These isoforms eluted at pH 4.7 (CKI) and 4.5 (CKII). CKII appeared to be homogeneous by sodium dodecyl sulfate gel electrophoresis. Peptide mapping of two isoforms indicated a high degree of similarity, although there were peptides not common to both. Ethanolamine kinase activity copurified with both isoforms. The ratio of choline to ethanolamine kinase activity was 3.7 +/- 0.7 throughout the purification procedure. Choline and ethanolamine were mutually competitive inhibitors. The respective Km values, 0.013 and 1.2 mM, were similar to the Ki values of 0.014 and 2.2 mM. An antibody raised against CKII immunoprecipitated both choline and ethanolamine kinase activities from liver cytosol at the same titer. These data suggest that both activities reside on the same protein and occur at the same active site. Similarly, both activities were immunoprecipitated from brain, lung, and kidney cytosols. Western blot analysis showed both purified liver isoforms, as well as brain, lung and kidney enzymes, to have a molecular mass of 47 kDa.     

Evidence for the existence of multiple forms of choline (ethanolamine) kinase in rat tissues

In order to characterize the form of choline kinase in rat tissues, both electrophoretic and gel chromatographic patterns of choline kinase activity were compared in the liver, kidney, lung, whole intestine and carbon tetrachloride-induced liver cytosols. Kinetic parameters of the reaction were also compared for the main forms of choline kinase protein from these tissues. The overall results suggested strongly that choline kinase does not exist in one particular active form but exists in multiple forms in rat tissues. In the study present here, the electrophoretic patterns of both choline kinase and ethanolamine kinase activities were compared in rat liver, kidney, lung and intestinal cytosols. The results strongly supported the view that both kinase activities are represented on the same enzyme protein(s) in each of the rat tissues examined.     

Complete co-purification of choline kinase and ethanolamine kinase from rat kidney and immunological evidence for both kinase activities residing on the same enzyme protein(s) in rat tissues

Choline kinase and ethanolamine kinase were completely co-purified from rat kidney cytosol through acid treatment, ammonium sulfate fractionation, DEAE-cellulose column chromatography, Sephadex G-150 gel filtration followed by choline-Sepharose affinity chromatography. The final preparation appeared to be highly homogeneous with respect to both native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (Ishidate, K., Nakagomi, K. and Nakazawa, Y. (1984) J. Biol. Chem. 259, 14706-14710). Throughout the purification steps, the ratio of ethanolamine kinase activity to choline kinase activity was almost constant in a range of 0.3-0.4, which strongly indicated that, in rat kidney, both activities could reside on a single enzyme protein. The rabbit polyclonal antibody raised against highly purified rat kidney choline (ethanolamine) kinase protein inhibited both choline and ethanolamine kinase activities in a parallel manner in crude enzyme preparations not only from rat kidney, but also from rat liver, lung and intestinal cytosols. The results, together with our previous findings, suggested strongly that, in rat tissues, at least large portions of both kinase activities are present on the same enzyme protein(s). The kinetic properties of both kinase reactions with the highly purified kidney enzyme were compared in some detail and the overall result suggested that choline kinase and ethanolamine kinase activities may not have a common active site on a single enzyme protein.     

Several lines of evidence demonstrating that Plasmodium falciparum, a parasitic organism, has distinct enzymes for the phosphorylation of choline and ethanolamine

In Plasmodium falciparum-infected erythrocyte homogenates, the specific activity of ethanolamine kinase (7.6 +/- 1.4 nmol phosphoethanolamine/10(7) infected cells per h) was higher than choline kinase specific activity (1.9 +/- 0.2 nmol phosphocholine/10(7) infected cells per h). The Km of choline kinase for choline was 79 +/- 20 microM, and ethanolamine was a weak competitive inhibitor of the reaction (Ki = 92 mM). Ethanolamine kinase had a Km for ethanolamine of 188 +/- 19 microM, and choline was a competitive inhibitor of ethanolamine kinase with a very high Ki of 268 mM. Hemicholinium 3 inhibited choline kinase activity, but had no effect on ethanolamine kinase activity. In contrast, D-2-amino-1-butanol selectively inhibited ethanolamine kinase activity. Furthermore, when the two enzymes were subjected to heat inactivation, 85% of the choline kinase activity was destroyed after 5 min at 50 degrees C, whereas ethanolamine kinase activity was not altered. Our results indicate that the phosphorylation of choline and ethanolamine was catalyzed by two distinct enzymes. The presence of a de novo phosphatidylethanolamine Kennedy pathway in P. falciparum contributes to the bewildering variety of phospholipid biosynthetic pathways in this parasitic organism.     

Evidence for the existence of a single enzyme catalyzing the phosphorylation of choline and ethanolamine in primate lung.

Choline kinase (ATP:choline phosphotransferase, EC 2.7.1.32) has been isolated and purified 1000-fold from adult African Green monkey lung with a yield of 10%. The purified enzyme also phosphorylated ethanolamine (ratio of ethanolamine kinase to choline kinase = 0.30). This ratio remained constant throughout the purification procedure. The Km for choline (3.0 - 10(-5) M) was lower than that of ethanolamine (1.2 - 10(-3) M.) Choline was also found to inhibit ethanolamine kinase activity by 50% at a concentration of 0.005 mM, while ethanolamine inhibited choline only at very high concentrations (100--150 mM). When the enzyme was subjected to inactivation by heat, hemicholinium-3, trypsin digestion, and p-hydroxymercuribenzoate, both ethanolamine kinase and choline kinase activities were destroyed at the same rate. Freezing and thawing in the absence of glycerol also destroyed both activities at the same rate. Based on these findings, we conclude that in adult African Green monkey lung tissue, there is only one enzyme for the phosphorylation of ethanolamine and choline, and that choline phosphorylation predominates.     

Phosphorylation of choline and ethanolamine in Ehrlich ascites-carcinoma cells

1. Ehrlich ascites-cell extracts convert choline and ethanolamine approximately equally well into their respective phosphoryl derivatives. 2. Choline is a potent inhibitor of ethanolamine phosphorylation, but ethanolamine has little effect on choline phosphorylation. 3. 2,3-Dimercaptopropanol, cysteine and Ca(2+) inhibit ethanolamine phosphorylation, but have no detectable effect on choline phosphorylation. 4. Choline-phosphorylating activity in Ehrlich ascites-cell extracts is more stable during storage than ethanolamine-phosphorylating activity. 5. Choline phosphorylation is stimulated in the presence of benzoylcholine, succinylcholine, butyrylcholine and propionylcholine, whereas ethanolamine phosphorylation is inhibited. This relationship is reciprocal: the compounds causing the greatest stimulation of choline phosphorylation bring about the greatest inhibition of ethanolamine phosphorylation.     

Biochemical characterization of the initial steps of the Kennedy pathway in Trypanosoma brucei: the ethanolamine and choline kinases

Ethanolamine and choline are major components of the trypanosome membrane phospholipids, in the form of GPEtn (phosphatidylethanolamine) [corrected] and GPCho (phosphatidylcholine) [corrected] . Ethanolamine is also found as an integral component of the GPI (glycosylphosphatidylinositol) anchor that is required for membrane attachment of cell-surface proteins, most notably the variant-surface glycoproteins. The de novo synthesis of GPEtn and GPCho starts with the generation of phosphoethanolamine and phosphocholine by ethanolamine and choline kinases via the Kennedy pathway. Database mining revealed two putative C/EKs (choline/ethanolamine kinases) in the Trypanosoma brucei genome, which were cloned, overexpressed, purified and characterized. TbEK1 (T. brucei ethanolamine kinase 1) was shown to be catalytically active as an ethanolamine-specific kinase, i.e. it had no choline kinase activity. The K(m) values for ethanolamine and ATP were found to be 18.4+/-0.9 and 219+/-29 microM respectively. TbC/EK2 (T. brucei choline/ethanolamine kinase 2), on the other hand, was found to be able to phosphorylate both ethanolamine and choline, even though choline was the preferred substrate, with a K(m) 80 times lower than that of ethanolamine. The K(m) values for choline, ethanolamine and ATP were 31.4+/-2.6 microM, 2.56+/-0.31 mM and 20.6+/-1.96 microM respectively. Further substrate specificity analysis revealed that both TbEK1 and TbC/EK2 were able to tolerate various modifications at the amino group, with the exception of a quaternary amine for TbEK1 (choline) and a primary amine for TbC/EK2 (ethanolamine). Both enzymes recognized analogues with substituents on C-2, but substitutions on C-1 and elongations of the carbon chain were not well tolerated.     

Incorporation of choline and ethanolamine into phospholipids in germinating soya bean.

1. Incorporation of [Me-14C]choline and [2-14C]ethanolamine into lipids was studied in germinating soya bean (Glycine max L.) seeds. The precursors are only incorporated into phosphatidylcholine and into phosphatidylethanolamine respectively. 2. Base-labelling via a phospholipase-D type of reaction was eliminated as a significant factor. 3. Cyclo heximide inhibited labelling of phosphatidylcholine from [Me-14C]choline but did not affect labelling of the aqueous choline pool. It had no effect on [2-14C]ethanolamine uptake or incorporation into phosphatidylethanolamine. 4. Hemicholinium-15 at 10mM concentrations decreased uptake and lipid labelling from the both bases. 5. There was no evidence for base competition. 6. The endogenous pool of choline was much larger than that of ethanolamine, which resulted in higher specific radioactivities for phosphatidyl-ethanolamine than for phosphatidylcholine. 7. The results can be interpreted as indicating that the kinase and phosphoryltransferase enzymes of the CDP-base pathways are separate for each phospholipid.     

Effects of amino acids and ethanolamine on choline uptake and phosphatidylcholine biosynthesis in baby hamster kidney-21 cells.

The effects of amino acids and ethanolamine on choline uptake and phosphatidylcholine biosynthesis in baby hamster kidney (BHK-21) cells were investigated. The cells were incubated with labelled choline in the presence of an amino acid or ethanolamine. The uptake of labelled choline was noncompetitively inhibited by amino acids. Glycine, L-alanine, L-serine, L-leucine, L-aspartate, and L-arginine were effective inhibitors and a maximum of 22% inhibition of choline uptake was obtained with 5 mM glycine. Analyses of the labelings in the choline-containing metabolites revealed that the conversion of choline to CDP-choline and subsequently phosphatidylcholine was not affected by the presence of amino acids. The uptake of choline was also inhibited by ethanolamine in a concentration-dependent manner. Kinetic studies on the uptake of choline indicated that the inhibition by ethanolamine was competitive in nature. Although ethanolamine is a potent inhibitor of choline kinase, analyses of the labelings in the choline-containing metabolites indicated that the conversion of choline to phosphocholine was not affected in the cells incubated with ethanolamine. Ethanolamine did not change the pool sizes of phosphocholine and CDP-choline. Based on the specific radioactivity of CDP-choline and the labeling of phosphatidylcholine, the rates of phosphatidylcholine biosynthesis were not significantly different between the control and the ethanolamine-treated cells. In view of the concentrations of amino acids (millimolar) and ethanolamine (micromolar) in most cell culture media, it appeared that only amino acids were important metabolites for the regulation of choline uptake in BHK-21 cells. We conclude that both amino acids and ethanolamine have no direct effect on the biosynthesis of phosphatidylcholine.     

Choline kinase and ethanolamine kinase are separate, soluble enzymes in rat liver.

Choline kinase and ethanolamine kinase are located in the cytosol from rat liver and have been copurified more than 500-fold by affinity chromatography [P. J. Brophy and D. E. Vance (1976) FEBS Lett. 62, 123-125]. Kinetic properties of the two activities were determined. Choline kinase had a Km for choline of 0.033 mM and ethanolamine was a competitive inhibitor (Ki = 6.2 mM). Ethanolamine kinase had a Km for ethanolamine of 7.7 mM and choline was a 'mixed' type of inhibitor with a Ki of 0.037 mM. Both enzymes activities responded in a similar fashion to the adenylate energy charge. Betaine and choline phosphate partially inhibited both kinases with a 93% inhibition of the ethanolamine kinase by 5 mM choline phosphate. CTP and ethanolaminephosphate partially inhibited the ethanolamine kinase, but not the choline kinase. Other metabolites tested had negliglible effects on both kinases. The affinity-column-purified enzyme was analyzed by disc gel electrophoresis which resolved the two activities. Hence, although many of the properties of the two activities are similar, choline kinase and ethanolamine kinase must be separate enzymes. Analysis of rat liver cytosol by disc gel electrophoresis indicated four isoenzymes for choline kinase and ethanolamine kinase.     

Evidence for the existence of isozymes of choline kinase and their selective induction in 3-methylcholanthrene- or carbon tetrachloride-treated rat liver

New evidence is provided that rat liver choline kinase exists in several distinct forms (choline kinases I, II and III) which differ in isoelectric point, molecular size and antigenicity against anti-rat kidney choline kinase IgG. Remarkable and selective induction of the choline kinase II and choline kinase III forms of choline kinase was caused similarly by the administration of polycyclic aromatic hydrocarbon carcinogen, 3-methylcholanthrene or hepatotoxic carbon tetrachloride (CCl4). The immunochemical approach further indicated that the elevation in the activity of choline kinase in the 3-methylcholanthrene- or CCl4-treated rat liver was not accompanied by a parallel increase in the amount of choline kinase II enzyme protein, compatible with the induction of either a small amount of new enzyme protein(s) with very high specific activity or another enzyme which might catalyze post-translational modification of choline kinase.     

Isolation and characterization of the Saccharomyces cerevisiae EKI1 gene encoding ethanolamine kinase.

Ethanolamine kinase (ATP:ethanolamine O-phosphotransferase, EC 2.7.1. 82) catalyzes the committed step of phosphatidylethanolamine synthesis via the CDP-ethanolamine pathway. The gene encoding ethanolamine kinase (EKI1) was identified from the Saccharomyces Genome Data Base (locus YDR147W) based on its homology to the Saccharomyces cerevisiae CKI1-encoded choline kinase, which also exhibits ethanolamine kinase activity. The EKI1 gene was isolated and used to construct eki1Delta and eki1Delta cki1Delta mutants. A multicopy plasmid containing the EKI1 gene directed the overexpression of ethanolamine kinase activity in wild-type, eki1Delta mutant, cki1Delta mutant, and eki1Delta cki1Delta double mutant cells. The heterologous expression of the S. cerevisiae EKI1 gene in Sf-9 insect cells resulted in a 165,500-fold overexpression of ethanolamine kinase activity relative to control insect cells. The EKI1 gene product also exhibited choline kinase activity. Biochemical analyses of the enzyme expressed in insect cells, in eki1Delta mutants, and in cki1Delta mutants indicated that ethanolamine was the preferred substrate. The eki1Delta mutant did not exhibit a growth phenotype. Biochemical analyses of eki1Delta, cki1Delta, and eki1Delta cki1Delta mutants showed that the EKI1 and CKI1 gene products encoded all of the ethanolamine kinase and choline kinase activities in S. cerevisiae. In vivo labeling experiments showed that the EKI1 and CKI1 gene products had overlapping functions with respect to phospholipid synthesis. Whereas the EKI1 gene product was primarily responsible for phosphatidylethanolamine synthesis via the CDP-ethanolamine pathway, the CKI1 gene product was primarily responsible for phosphatidylcholine synthesis via the CDP-choline pathway. Unlike cki1Delta mutants, eki1Delta mutants did not suppress the essential function of Sec14p.     

Enzymic synthesis of ether types of choline and ethanolamine phosphoglycerides by microsomal fractions from rat brain and liver.

The formation of product by ethanolamine phosphotransferases (EC 2.7.8.1) and cholinephosphotransferases (EC 2.7.8.2) in microsomal fractions from brains and livers of mature rats is increased several fold by 1,2-diacyl-sn-glycerols. With the addition of 1-alkyl-2-acyl-sn-glycerols, we have found an 11-fold increase with brain microsomes and a 20-fold increase with lvier microsomes in the synthesis of choline ether lipids (1-alkyl-2-acyl- and 1-alk-1'-enyl-2-acyl-sn-glycero-3-phosphorylcholines). For the synthesis of ethanolamine ether lipids (1-alkyl-2-acyl and 1-alk-1'-enyl-2-acyl-sn-glycero-3-phosphorylethanolamines), the stimulation of alkylacylglycerols was 7-fold for brain microsomes and 18-fold for liver microsomes. The alkylacyl glycerols (8 mM) also inhibited the synthesis of diacyl phosphoglycerides by 44 to 65%, indicating that the same ethanolaminephosphotransferases and cholinephosphotransferases are utilized for the synthesis of alkylacyl phosphoglycerides and diacyl phosphoglycerides. A desaturation of the alkyl groups may take place in the same reaction mixture. The rate of incorporation of phosphorylcholine into alkenylacyl glycerophosphorylcholines (choline plasmalogens) with alkylacylglycerols, cytidine diphosphate choline, and liver microsomes was 15 nmoles per mg protein per hour. The in vitro synthesis of choline plasmalogens with alkylacylglycerols had not been observed previously. The corresponding rate of incorporation of phosphorylethanolamine into ethanolamine plasmalogens was 10 nmoles per mg protein per hour, a value greater than any of the previously reported values for ethanolamine plasmalogen formation from alkylacyl glycerophosphorylethanolamines.     

Complete purification of choline kinase from rat kidney and preparation of rabbit antibody against rat kidney choline kinase

Choline kinase was purified from rat kidney to apparent homogeneity with respect to both native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme showed a minimum molecular weight of 42,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. On the other hand, the molecular size of 75,000-80,000 was estimated through Sephadex G-150 gel filtration, indicating that the enzyme in rat kidney exists most likely in a dimeric form. Specific antibody was raised in rabbit against the highly purified rat kidney choline kinase protein, then immunochemical cross-reactivity was investigated between rabbit antiserum and choline kinase preparations from various rat tissues. The antiserum inhibited choline kinase activity almost completely in the crude preparation not only from kidney but also from lung, intestine, and normal untreated liver cytosol, but it could inhibit only partially the activity from either 3-methylcholanthrene- or carbon tetrachloride-induced rat liver cytosol. The overall results demonstrated that, although choline kinase protein appears to exist in multiple forms in rat tissues, most of them are immunochemically identical, and that either 3-methylcholanthrene- or carbon tetrachloride-inducible form(s) of choline kinase in rat liver could be quite different from a form or forms existing in normal untreated rat liver cytosol.     

Significance of yeast peroxisomes in the metabolism of choline and ethanolamine

The yeasts Candida utilis and Hansenula polymorpha were able to grow in media containing choline or ethanolamine as the sole nitrogen source. During growth in the presence of these substrates, large peroxisomes developed in the cells, and extracts of choline-grown C. utilis cells contained increased levels of amine oxidase and catalase. Incubation of whole cells with choline in the presence of the amine oxidase inhibitor aminoacetonitrile led to excretion of dimethylamine and methylamine. Cytochemical experiments in which spheroplasts prepared from choline-grown cells were incubated with CeCl₃ and choline, trimethylamine, dimethylamine or methylamine revealed positively stained peroxisomes, whereas in the presence of 1 mM aminoacetonitrile staining was not observed. This indicated that choline was degraded via methylated amines and that peroxisomes played a role in its metabolism. A similar involvement of peroxisomes in choline degradation was observed in H. polymorpha. Cell-free extracts of ethanolamine-grown C. utilis and H. polymorpha also contained increased levels of amine oxidase and catalase. Ethanolamine was oxidized by cell-free extracts of both organisms after growth in the presence of ethanolamine or choline. Incubation of spheroplasts of ethanolamine-or choline-grown C. utilis with CeCl₃ and ethanolamine resulted in positively stained peroxisomes. In this organism peroxisomes were therefore also involved in ethanolamine degradation.K. B. Zwart was supported by the Foundation for Fundamental Biological Research (BION) which is subsidized by the Netherlands Organization for the Advancement of Pure Research (ZWO).     

Cloning and characterization of the yeast CKI gene encoding choline kinase and its expression in Escherichia coli

Using a mutant defective in choline kinase (Hosaka, K., and Yamashita, S. (1980) J. Bacteriol. 143, 176-181; Hosaka, K., and Yamashita, S. (1987) Eur. J. Biochem. 162, 7-13), the structural gene (CKI) for choline kinase of the yeast, Saccharomyces cerevisiae, was isolated by means of genetic complementation. Within its sequence there was an open reading frame capable of encoding 582 amino acids with a calculated molecular weight of 66,316. The primary translation product contained a segment closely related to the phosphotransferase consensus sequence (Brenner, S. (1987) Nature 329, 21). A yeast transformant carrying CKI in multiple copies exhibited very high choline kinase activity as well as ethanolamine kinase activity. In-frame insertion of the CKI coding frame into lacZ' on the pUC19 vector led to efficient expression of choline kinase in Escherichia coli cells in the presence of a lac inducer, isopropylthiogalactoside, proving that CKI is the structural gene for choline kinase. Concomitantly, ethanolamine kinase activity was also expressed. When the CKI locus in the wild-type yeast genome was inactivated by its replacement with the in vitro disrupted cki gene, the yeast cells lost virtually all of the choline kinase activity and most of the ethanolamine kinase activity. Thus, it is concluded that choline kinase is mono-cistronic and that the ethanolamine kinase activity is a second activity of choline kinase in the yeast.     

Effects of deoxycholate and phospholipase A2 on choline and ethanolamine phosphotransferases of chicken brain microsomes.

Ethanolamine phosphotransferase (EC 2.7.8.1) and choline phosphotransferase (EC 2.7.8.2) activities were assayed in fresh microsomes from adult chicken brains with either diacylglycerols or alkylacylglycerols. Pretreatment of microsomes with 1.25 mM sodium deoxycholate, a concentration less than the critical micelle concentration, produced a slight inhibition of choline phosphotransferase activity. A deoxycholate concentration (5.0 mM) greater than the critical micelle concentration (3.0 mM) decreased the choline phosphotransferase activity by more than 70% but had no effect on ethanolamine phosphotransferase activity. Inclusion of 1.25 mM deoxycholate in the assay medium decreased choline phosphotransferase activity 35% but increased ethanolamine phosphotransferase activity 50%. The deoxycholate appeared to inactive the choline phosphotransferase. Phospholipase A2 (Vipera russelli) treatments of microsomes removed phosphoglycerides and decreased both phosphotransferase activities to a similar extent. Decreased activities are probably due to disruption of the membrane structure. Choline and ethanolamine phosphotransferase activities are apparently in different enzymes which lack specificity for the type of diglyceride. Thus, the systematic names should include 1,2-diradyl-sn-glycerol instead of 1,2-diacyl-sn-glycerol.     

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.