Evidence for extramitochondrial pyruvate dehydrogenase involved in acetylcholine synthesis in nerve endings

Thiazolium salt mimics the non-coenzyme effects of vitamin B1 in rat synaptosomes

Long-term studies have confirmed a causal relationship between the development of neurodegenerative processes and vitamin B1 (thiamine) deficiency. However, the biochemical mechanisms underlying the high neurotropic activity of thiamine are not fully understood. At the same time, there is increasing evidence that vitamin B1, in addition to its coenzyme functions, may have non-coenzyme activities that are particularly important for neurons. To elucidate which effects of vitamin B1 in neurons are due to its coenzyme function and which are due to its non-coenzyme activity, we conducted a comparative study of the effects of thiamine and its derivative, 3-decyloxycarbonylmethyl-5-(2-hydroxyethyl)-4-methyl-1,3-thiazolium chloride (DMHT), on selected processes in synaptosomes. The ability of DMHT to effectively compete with thiamine for binding to thiamine-binding sites on the plasma membrane of synaptosomes and to participate as a substrate in the thiamine pyrophosphokinase reaction was demonstrated. In experiments with rat brain synaptosomes, unidirectional effects of DMHT and thiamine on the activity of the pyruvate dehydrogenase complex (PDC) and on the incorporation of radiolabeled [2-14C]pyruvate into acetylcholine were demonstrated. The observed effects of thiamine and DMHT on the modulation of acetylcholine synthesis can be explained by suggesting that both compounds, which interact in cells with enzymes of thiamine metabolism, are phosphorylated and exert an inhibitory/activating effect (concentration-dependent) on PDC activity by affecting the regulatory enzymes of the complex. Such effects were not observed in the presence of structural analogues of thiamine and DMHT without a 2-hydroxyethyl substituent at position 5 of the thiazolium cycle. The effect of DMHT on the plasma membrane Ca-ATPase was similar to that of thiamine. At the same time, DMHT showed high cytostatic activity against neuroblastoma cells.

Incorporation of an Anion-Coordinated Triple Helicate into a Thin Film for Choline Recognition in an Aqueous System

Functional thin films, being fabricated by incorporating discrete supramolecular architectures, have potential applications in research areas such as sensing, energy storage, catalysis, and optoelectronics. Here, we have determined that an anion-coordinated triple helicate can be solution-processed into a functional thin film by incorporation into a polymethyl methacrylate (PMMA) matrix. The thin films fabricated by the incorporation of the anion-coordinated triple helicate show multiple optical properties, such as fluorescence, CD, and CPL. In addition, the film has the ability to recognize choline and choline derivatives in a water system. The successful recognition of Ch+ by the film represents the first example of utilizing 'aniono'-supramolecular architectures for biomolecule detection in aqueous solution and opens up a new route for designing biocompatible functional materials.

Metabolic fuel utilization and pyruvate oxidation during the postnatal period

The transplacental supply of nutrients is interrupted at birth, which diverts maternal metabolism to lactation. After birth, energy homeostasis is rapidly regained through milk nutrients which supply the newborn with the fatty acids and ketone bodies required for neonatal development. However, immediately after birth and before the onset of suckling there is a time lapse in which the newborn undergoes a unique kind of starvation. During this period glucose is scarce and ketone bodies are not available owing to the delay in ketogenesis. Under these circumstances, the newborn is supplied with another metabolic fuel, lactate, which is utilized as a source of energy and carbon skeletons. Neonatal rat lung, heart, liver and brain utilize lactate for energy production and lipogenesis. Lactate is also utilized by the brain of human babies with type I glycogenosis. Both rat neurons and astrocytes in primary culture actively use lactate as an oxidizable substrate and as a precursor of phospholipids and sterols. Lactate oxidation is enhanced by dichloroacetate, an inhibitor of the pyruvate dehydrogenase kinase in neurons but not in astrocytes, suggesting that the pyruvate dehydrogenase is regulated differently in each type of cell. Despite the low activity of this enzyme in newborn brain, pyruvate decarboxylation is the main fate of glucose in both neurons and astrocytes. The occurrence of a yeast-like pyruvate decarboxylase activity in neonatal brain may explain these results.

Metabolism of lactate in the rat brain during the early neonatal period

The metabolism of lactate in isolated cells from early neonatal rat brain has been studied. In these circumstances, lactate was mainly oxidized to CO2, although a significant portion was incorporated into lipids (78% sterols, 4% phosphatidylcholine, 2% phosphatidylethanolamine, and 1% phosphatidylserine). The rate of lactate incorporation into CO2 and lipids was higher than those found for glucose and 3-hydroxybutyrate. Lactate strongly inhibited glucose oxidation through the pyruvate dehydrogenase-catalyzed reaction and the tricarboxylic acid cycle while scarcely affecting glucose utilization by the pentose phosphate pathway. Lipogenesis from glucose was strongly inhibited by lactate without relevant changes in the rate of glycerol phosphate synthesis. These results suggest that lactate inhibits glucose utilization at the level of the pyruvate dehydrogenase-catalyzed reaction, which may be a mechanism to spare glucose for glycerol and NADPH synthesis. The effect of 3-hydroxybutyrate inhibiting lactate utilization only at high concentrations of 3-hydroxybutyrate suggests that before ketogenesis becomes active, lactate may be the major fuel for the neonatal brain. (-)-Hydroxycitrate and aminooxyacetate markedly inhibited lipogenesis from lactate, suggesting that the transfer of lactate carbons through the mitochondrial membrane is accomplished by the translocation of both citrate and N-acetylaspartate.

Choline acetyltransferase-like activity bound to neuronal plasma membranes

A form of CAT-like activity was found bound present in rat brain synaptosomal membranes which could be recovered in the Triton X-114 phase. The enzyme activity was slightly activated by NaCl, had a pH maximum around 8 and showed a temperature dependence with a Q10 of 2.28. It was inhibited 100% by 10(-6) M naphthyl vinyl pyridinium but not by 10(-5) M diisopropyl phosphofluoridate. The kinetics of this bound form of CAT were similar to the soluble form of the enzyme. The Km was 405 +/- 58 microM for choline and 62 +/- 8 microM for AcCoA. Five isoelectric forms were found with pH's of 4.55, 6.05, 7.05, 7.36, and 8.00 which is in contrast to the three isoelectric forms found of the soluble enzyme in rat brain. The presence of a CAT-like activity in the plasma membrane was confirmed with experiments performed using intact synaptosomes and intact cells in culture. Acetylcholine, synthesized from radioactive AcCoA by intact rat brain synaptosomes, was recovered in the incubation medium and only in the presence of exogenous choline or when the production of choline was stimulated by oleate via the activation of phospholipase D. This was also seen in experiments with intact pheochromocytoma cell cultures (PC 12) which synthesize acetylcholine that was recovered in the incubation medium. Acetylcholine formation in the presence of choline and AcCoA was stimulated in cells that had been grown in the presence of nerve growth factor (NGF).(ABSTRACT TRUNCATED AT 250 WORDS)

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

The Vmax 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 the Km'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 in Vmax 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.

Amino terminal acetylation and protein synthesis in eukaryotes

The amino terminal residue in many proteins is N-acetylated. Available evidence indicates that acetylation occurs during translation whilst the nascent polypeptide is still attached to the ribosome; with some proteins, like the actins, an additional acetylation step occurs which may be catalysed by cytoplasmic enzymes. Studies of protein synthesis in heterologous cell-free systems show that the enzymes which catalyse amino terminal acetylation are ubiquitous and such studies have provided insights into the effects of limitations in the supply of acetyl CoA in vitro. Evidence that availability of acetyl groups in vivo may in part determine the cellular concentration of N-acetylated proteins is examined in terms of the relative amounts of the aceylated fraction of foetal haemoglobin and carbonic anhydrase I in human erythrocytes. Tissue and developmental differences in the concentration of the muscle isoenzyme, carbonic anhydrase III, are considered in terms of changes in the activity and distribution of mitochondria in muscle. Finally, the possibility is discussed that differential effects of thyroid hormone on protein concentration might be partly due to an effect of the hormone on acetyl CoA availability via its action on mitochondria.

Neurone-specific enolase and creatine phosphokinase are protein components of rat brain synaptic plasma membranes

Neuron-specific enolase and creatine phosphokinase were found, by 2-dimensional gel analysis, in rat brain synaptic plasma membranes (SPM). The identity of these enzymes was confirmed by comigration with purified rat brain NSE and CPK and by peptide analysis. The specific enzymatic activities of enolase and creatine phosphokinase, as well as of pyruvate kinase, also present on the membranes, were comparable to those in the homogenates when these three enzymes were fully activated. In the SPM all three enzymes, particularly enolase, were partially cryptic in that enzymatic activities were very low unless the membranes were treated with Triton X-100. They were resistant to both low-salt and high-salt extraction and to trypsin, except when Triton X-100 was present. These results suggest that the enzymes are tightly bound protein components of the membrane and that they may constitute an assembly capable of generating ATP.

The independency of choline transport and acetylcholine synthesis

The coupling of choline transport to acetylcholine synthesis has been investigated by measurement of the isotopic dilution of a pulse of [3H]choline during its incorporation into the recently synthesised acetylcholine of cerebral cortex synaptosomes. Recently synthesised acetylcholine was identified as that containing 14C-labelled precursors introduced by a preincubation before the pulse. When [14C]glucose was used to label acetyl-CoA coupling ratios (calculated as the inverse of the dilution of extracellular [3H]choline during its incorporation into [3H]acetylcholine) of about 0.05-0.2 were found at a choline concentration of 1 microM, rising to 0.5 at choline concentrations of 10-50 microM. Experiments using [14C]choline as a precursor gave similar results, and it was shown that the isotopic dilution did not occur extrasynaptosomally and was not affected by low glucose concentrations. Coupling ratios were always less than unity and rose as the choline concentration increased. It is concluded that choline transported into the nerve terminal has no privileged access to choline acetyltransferase. The results can be explained by a rate-controlling transport of choline into the terminal followed by its rapid acetylation rather than any linkage or coupling of the two processes.

The effects in vitro of hypoglycaemia and recovery from anoxia on synaptosomal metabolism

Synaptosomes from several regions of the rat brain were found to exhibit half-maximal rates of 14CO2 output and [14C]acetylcholine synthesis from D-[U-14C]glucose at glucose concentrations approx. 50-fold lower than those required by the brain in situ. However, synaptosomal acetylcholine synthesis was found not to be directly proportional to substrate oxidation as measured by 14CO2 output. When synaptosomes had been exposed to anoxia in vitro, their metabolic indices (14CO2 and [14C]acetylcholine synthesis, and adenine nucleotide levels) were found not to be significantly different from control aerobic values, unless they had been subjected to veratridine depolarization. This is in accord with previous findings that neither the absolute metabolic rates nor the vulnerability to hypoxic damage exhibited by brain in situ is reflected by brain slices in vitro, unless these are stimulated by depolarization. The use of synaptosomes as a model for synaptic damage in vivo is discussed.

Studies on the pyruvate dehydrogenase complex in brain with the arylamine acetyltransferase-coupled assay

A spectrophotometric assay for the brain pyruvate dehydrogenase complex (PDHC) with arylamine acetyltransferase (ArAT; EC 2.3.1.5) to follow the production of acetyl-CoA has been standardized. Activity was proportional to time and protein. It depended completely on added pyruvate, CoA, NAD, and MgCl2, and partially on thiamine pyrophosphate. Triton X-100, and a sulfhydryl compound. The activities are the highest in the literature for brain PDHC (50 nmol/min/mg protein) and equal to maximum recorded rates of pyruvate flux for brain in vivo. Activities as low as 0.6 nmol/min could be measured. Use of ArAT at different purities (I--2-fold and II--55-fold) allowed convenient measurement of total PDHC (ArAT-I) and of the active form of PDHC (ArAT-II). The proportion of PDHC in the active form was 50% in mouse brain, 30% in brain, and 10% in mouse liver. Total PDHC activity was unchanged postmortem during storage of mouse brain in situ at +4 degrees C or at -20 degrees C for 3 days or at +20 degrees C for 24 h. The relative specific activity of PDHC in cytoplasmic or synaptoplasmic fractions was less than that of two other mitochondrial enzymes, fumarase (EC 4.2.1.2) and monoamine oxidase (EC 1.4.3.4), which argues strongly against the hypothesis of a cytoplasmic PDHC in cholinergic nerve endings.

Utilization of ketone bodies and glucose by established neural cell lines

The rates of utilization of [3-14C]-acetoacetate, [3-14C]-3-hydroxybutyrate, and [6-14C]-glucose were measured in four established cell lines from neuroblastoma of rat (B103) and mouse (N4TG1) and from rat astrocytoma (RGC6) and mouse oligodendroglia (G2620). The rates of incorporation of acetoacetate into lipid were 3-5 times higher than glucose in all cell lines. The incorporation of 3-hydroxybutyrate was similar to that of glucose. Thin-layer chromatography of the total lipid extracts showed the same relative rates of use of these substrates for synthesis of various phospholipids and neutral lipids. The rates of incorporation into neutral lipids and phosphatidylcholine were essentially linear for 12 hr; however, that into phosphatidylethanolamine was markedly higher in the second 6 hr interval than in the first. In all cases, the greatest percentage of label (35-50%) appeared in the phosphatidylcholine fraction. The distribution of label from each of the three substrates among the various lipids was similar in the glial cells, but there were marked differences in distribution of the two ketone bodies in the neuroblastoma lines. These cells also synthesized lipids that migrated to the same area on the chromatogram as cholesterol esters and free fatty acids. In three of the four cell lines the rates of oxidation were highest for glucose, intermediate for acetoacetate, and lowest for 3-hydroxybutyrate. The ratios of the rate of incorporation to the rate of oxidation were higher for ketone bodies (3.32 for 3-hydroxybutyrate and 5.29 for acetoacetate) than for glucose (0.41). This indicates that in these cells ketone bodies are directed toward lipid synthesis rather than oxidation, and glucose is preferentially used as an energy source.

Acetylcholine synthesis in synaptosomes: mode of transfer of mitochondrial acetyl coenzyme A

Labeled acetylcholine derived from labeled pyruvate in a synaptosomal preparation from rat brain, incubated with nicotinamide adenine dinucleotide as well as coenzyme A, is stimulated by calcium ions in the absence but not in the presence of Triton X-100. Whereas citrate is taken up by cholinergic synaptosomes because it suppresses the formation of acetylcholine from pyruvate, it is not itself converted into acetylcholine. The evidence suggests that there is a calcium-dependent transfer of mitochondrial acetyl coenzyme A into the cholinergic synaptoplasm, which is apparently devoid of the citrate cleavage enzyme, and is there converted into acetylcholine. The permeability of the inner mitochondrial membrane to coenzyme A and acetyl coenzyme A seems to be enhanced by calcium ions, and this effect may be mediated by mitochondrial phospholipase A2.

Evidence that the 40,000 Mr phosphoprotein influenced by high frequency synaptic stimulation is the alpha subunit of pyruvate dehydrogenase

We have previously shown that brief periods of high frequency synaptic stimulation of the rat hippocampus influence the endogenous phosphorylation of a 40,000 Mr brain protein (Browning et al.). The results of the present study demonstrate that this brain phosphoprotein is enriched in a purified mitochondrial fraction and co-migrates with the alpha-subunit of pyruvate dehydrogenase in sodium dodecyl sulfate polyacrylamide gels. Comparisons of total and partial proteolytic fingerprints indicate that the two proteins are essentially identical. In addition, the phosphorylation of the 40,000 Mr brain protein is sensitive to both dichloroacetate and magnesium as has been reported for pyruvate dehydrogenase. Taken together these data provide persuasive evidence that the brain protein is the alpha-subunit of pyruvate dehydrogenase and thereby raise the possibility that even very short periods of synaptic activity influence an enzyme of particular importance to mitochondrial metabolism in brain.

Regional and subcellular distribution of ATP-citrate lyase and other enzymes of acetyl-CoA metabolism in rat brain

The activities of ATP-citrate lyase in frog, guinea pig, mouse, rat, and human brain vary from 18 to 30 mu mol/h/g of tissue, being several times higher than choline acetyltransferase activity. Activities of pyruvate dehydrogenase and acetyl coenzyme A synthetase in rat brain are 206 and 18.4 mu mol/h/g of tissue, respectively. Over 70% of the activities of both choline acetyltransferase and ATP-citrate lyase in secondary fractions are found in synaptosomes. Their preferential localization in synaptosomes and synaptoplasm is supported by RSA values above 2. Acetyl CoA synthetase activity is located mainly in whole brain mitochondria (RSA, 2.33) and its activity in synaptoplasm is low (RSA, 0.25). The activities of pyruvate dehydrogenase, citrate synthase, and carnitine acetyltransferase are present mainly in fractions C and Bp. No pyruvate dehydrogenase activity is found in synaptoplasm. Striatum, cerebral cortex, and cerebellum contain similar activities of pyruvate dehydrogenase, citrate synthase, carnitine acetyltransferase, fatty acid synthetase, and acetyl-CoA hydrolase. Activities of acetyl CoA synthetase, choline acetyltransferase and ATP-citrate lyase in cerebellum are about 10 and 4 times lower, respectively, than in other parts of the brain. These data indicate preferential localization of ATP-citrate lyase in cholinergic nerve endings, and indicate that this enzyme is not a rate limiting step in the synthesis of the acetyl moiety of ACh in brain.

The utilization of choline and acetyl coenzyme A for the synthesis of acetylcholine

Acetylcholine synthesis in rat brain synaptosomes was investigated with regard to the intracellular sources of its two precursors, acetyl coenzyme A and choline. Investigations with alpha-cyano-4-hydroxycinnamate, an inhibitor of mitochondrial pyruvate transport, indicated that pyruvate must be utilized by pyruvate dehydrogenase located in the mitochondria, rather than in the cytoplasm, as recently proposed. Evidence for a small, intracellular pool of choline available for acetylcholine synthesis was obtained under three experimental conditions. (1) Bromopyruvate competitively inhibited high-affinity choline transport, perhaps because of accumulation of intracellular choline which was not acetylated when acetyl coenzyme A production was blocked. (2) Choline that was accumulated under high-affinity transport conditions while acetyl coenzyme A production was impaired was subsequently acetylated when acetyl coenzyme A production was resumed. (3) Newly synthesized acetylcholine had a lower specific activity than that of choline in the medium. These results indicate that the acetyl coenzyme A that is used for the synthesis of acetylcholine is derived from mitochondrial pyruvate dehydrogenase and that there is a small pool of choline within cholinergic nerve endings available for acetylcholine synthesis, supporting the proposal that the high-affinity transport and acetylation of choline are kinetically coupled.

Acetyl-CoA synthesizing enzymes in cholinergic nerve terminals

The activities of five enzymes involved in acetyl-CoA synthesis, pyruvate dehydrogenase complex, ATP citrate lyase, carnitine acetyltransferase, acetyl-CoA synthetase, and citrate synthase, were determined in normal nucleus interpeduncularis and nucleus interpeduncularis in which cholinergic terminals were removed following lesion of the habenulointerpeduncular tract. The activities of aspartate transaminase, fumarase, and GABA transaminase also were determined to compare the effect of lesion on other mitochondrial enzymes which are not linked to the biosynthesis of ACh. In normal nucleus interpeduncularis the activities of carnitine acetyltransferase and pyruvate dehydrogenase complex were higher than the activity of ChAT (choline acetyltransferase), whereas the activities of acetyl-CoA synthetase and citrate synthase were considerably lower than that of ChAT. The effect of the lesion separated the enzymes into two groups: the activities of pyruvate dehydrogenase complex, carnitine acetyltransferase, fumarase and aspartate transaminase decreased by 30--40%, whereas the activities of the other enzymes descreased 5--15%. ChAT activity was in all cases less than 15% of normal. It could be concluded that none of the acetyl-CoA synthesizing enzymes decreased to the degree that ChAT did. Only pyruvate dehydrogenase complex and carnitine acetyltransferase seem to be localized in cholinergic terminals to a significant degree. ATP citrate lyase as well as acetyl-CoA synthetase seem to have less significance in supporting acetyl-CoA formation in cholinergic nerve terminals.

Lipogenesis in the brain of suckling rats. Studies on the mechansim of mitochondrial-cytosolic carbon transfer

1. Studies on the incorporation of [3-(14)C]pyruvate and d-3-hydroxy[3-(14)C]butyrate into the brain lipid fraction by brain homogenates of the suckling (7-day-old) rat have been carried out. 2. Whereas approximately twice as much CO(2) was evolved from pyruvate compared with 3-hydroxybutyrate metabolism, similar amounts of the radioactivity of these two precursors were incorporated into the lipid fraction. Furthermore, in both cases the incorporation into lipid was almost tripled when glucose (10mm) or NADPH (2.5mm) was added to the incubation media. 3. If 5mm-(-)-hydroxycitrate, an ATP-citrate lyase inhibitor, was added to the incubation the incorporation of carbon from pyruvate was inhibited to 39% of the control and from 3-hydroxybutyrate to 73% of the control, whereas CO(2) production from both precursors was not affected. 4. The incorporation from pyruvate or 3-hydroxybutyrate into lipids was not affected by the presence of 10mm-glutamate in the medium (to encourage N-acetylaspartate production). However, incorporation from pyruvate was inhibited by 21% in the presence of 5mm-amino-oxyacetate (a transaminase inhibitor) and by 83% in the presence of both hydroxycitrate (5mm) and amino-oxyacetate. 5. Incorporation from 3-hydroxybutyrate into brain lipids was inhibited by 20% by amino-oxyacetate alone, but by 55% in the presence of both hydroxycitrate and amino-oxyacetate. 6. It is concluded that the mechanism of carbon transfer from pyruvate into lipids across the mitochondrial membrane in the suckling rat brain is mainly via citrate and N-acetylaspartate. 3-Hydroxybutyrate, in addition to using these routes, may also be incorporated via acetoacetate formation and transport to the cytosol.

High affinity choline transport and acetylCoA production in brain and their roles in the regulation of acetylcholine synthesis

This review describes recent advances made in the understanding of the regulation of acetylcholine synthesis in brain with regard to the availability of its two precursors, choline and acetylCoA. Choline availability appears to be regulated by the high affinity choline transport system. Investigations of the localization and inhibition of this system are reviewed. Procedures for measuring high affinity choline transport and their shortcomings are described. The kinetics and effects of previous in vivo and in vitro treatments on high affinity choline transport are reviewed. Kinetic and direct coupling of the transport and acetylation of choline are discussed. Recent investigations of the source of acetylCoA used for the synthesis of acetylcholine are reviewed. Three sources of acetylCoA have recently received support: citrate conversion catalyzed by citrate lyase, direct release of acetylCoA from mitochondria following its synthesis from pyruvate catalyzed by pyruvate dehydrogenase, and production of acetylCoA by cytoplasmic pyruvate dehydrogenase. Investigations indicating that acetylCoA availability may limit acetylcholine synthesis are reviewed. A model for the regulation of acetylcholine synthesis which incorporates most of the reviewed material is presented.