Evidence for a ferredoxin-dependent choline monooxygenase from spinach chloroplast stroma

Chenopods synthesize betaine in the chloroplast via a two-step oxidation of choline: choline → betaine aldehyde → betaine. Our previous experiments with intact chloroplasts, and in vivo¹⁸O₂ labeling studies, led us to propose that the first step is mediated by a monooxygenase which uses photosynthetically generated reducing power (C Lerma, AD Hanson, D Rhodes [1988] Plant Physiol 88: 695-702). Here, we report the detection of such an activity in vitro. In the presence of O₂ and reduced ferredoxin, the stromal fraction from spinach (Spinacia oleracea) chloroplasts converted choline to betaine aldehyde at rates similar to those in intact chloroplasts (20-50 nanomoles per hour per milligram protein). Incorporation of ¹⁸O from ¹⁸O₂ by the in vitro reaction was demonstrated by fast atom bombardment mass spectrometry. Ferredoxin could be reduced either with thylakoids in the light, or with NADPH plus ferredoxin-NADP reductase in darkness; NADPH alone could not substitute for ferredoxin. No choline-oxidizing activity was detected in the stromal fraction of pea (Pisum sativum L.), a species that does not accumulate betaine. The spinach choline-oxidizing enzyme was stimulated by 10 millimolar Mg²⁺, had a pH optimum close to 8, and was insensitive to carbon monoxide. The specific activity was increased threefold in plants growing in 200 millimolar NaCl. Gel filtration experiments gave a molecular weight of 98 kilodaltons for the choline-oxidizing enzyme, and provided no evidence for other electron carriers which might mediate the reduction of the 98-kilodalton enzyme by ferredoxin.     

Betaine aldehyde oxidation by spinach chloroplasts

Chenopods synthesize betaine by a two-step oxidation of choline: choline → betaine aldehyde → betaine. Both oxidation reactions are carried out by isolated spinach (Spinacia oleracea L.) chloroplasts in darkness and are promoted by light. The mechanism of betaine aldehyde oxidation was investigated with subcellular fractions from spinach leaf protoplasts. The chloroplast stromal fraction contained a specific pyridine nucleotide-dependent betaine aldehyde dehydrogenase (about 150 to 250 nanomoles per milligram chlorophyll per hour) which migrated as one isozyme on native polyacrylamide gels stained for enzyme activity. The cytosol fraction contained a minor isozyme of betaine aldehyde dehydrogenase. Leaves of pea (Pisum sativum L.), a species that lacks betaine, had no betaine aldehyde dehydrogenase isozymes. The specific activity of betaine aldehyde dehydrogenase rose three-fold in spinach plants grown at 300 millimolar NaCl; both isozymes contributed to the increase. Stimulation of betaine aldehyde oxidation in illuminated spinach chloroplasts was due to a thylakoid activity which was sensitive to catalase; this activity occurred in pea as well as spinach, and so appears to be artifactual. We conclude that in vivo, betaine aldehyde is oxidized in both darkness and light by the dehydrogenase isozymes, although some flux via a light-dependent, H₂O₂-mediated reaction cannot be ruled out.     

C Tracer Evidence for Synthesis of Choline and Betaine via Phosphoryl Base Intermediates in Salinized Sugarbeet Leaves

Like other chenopods, sugarbeets (Beta vulgaris L. cv Great Western D-2) accumulate glycine betaine when salinized; this may be an adaptive response to stress. The pathway of betaine synthesis in leaves of salinized (150-200 millimolar NaCl) sugarbeet plants was investigated by supplying [¹⁴C]formate, phosphoryl[¹⁴C]monomethylethanolamine ([¹⁴C][unk] MME) or phosphoryl[¹⁴C]choline ([¹⁴C][unk] choline) to leaf discs and following ¹⁴C incorporation into prospective intermediates. The ¹⁴C kinetic data were used to develop a computer model of the betaine pathway.

When [¹⁴C]formate was fed, [unk] MME, phosphoryldimethylethanolamine ([unk] DME) and [unk] choline were the most prominent methylated products at short labeling times, after which ¹⁴C appeared in free choline and in betaine. Phosphatidylcholine labeled more slowly than [unk] choline, choline, and betaine, and behaved as a minor end product. Very little ¹⁴C entered the free methylethanolamines. When [¹⁴C][unk] MME was supplied, a small amount was hydrolyzed to the free base but the major fate was conversion to [unk] DME, [unk] choline, free choline, and betaine; label also accumulated slowly in phosphatidylcholine. Label from supplied [¹⁴C][unk] choline entered choline and betaine rapidly, while phosphatidylcholine labeled only slowly and to a small extent.

These results are consistent with the pathway [unk] MME →[unk] DME → [unk] choline → choline → → betaine, with a minor side branch leading from [unk] choline into phosphatidylcholine. This contrasts markedly (a) with the pathway of stress-induced choline and betaine synthesis in barley, in which phosphatidylcholine apparently acts as an intermediate (Hitz, Rhodes, Hanson 1981, Plant Physiol 68: 814-822); (b) with choline biogenesis in mammalian liver and microorganisms. Computer modeling of the experimental data pointed strongly to regulation at the [unk] choline → choline step, and also indicated that the rate of [unk] choline synthesis is subject to feedback inhibition by [unk] choline.

     

Heme-Dependent Rubber Oxygenase RoxA of Xanthomonas sp. Cleaves the Carbon Backbone of Poly(cis-1,4-Isoprene) by a Dioxygenase Mechanism

Oxidative cleavage of poly(cis-1,4-isoprene) by rubber oxygenase RoxA purified from Xanthomonas sp. was investigated in the presence of different combinations of ¹⁶O₂, ¹⁸O₂, H₂¹⁶O, and H₂¹⁸O. 12-Oxo-4,8-dimethyl-trideca-4,8-diene-1-al (ODTD; m/z 236) was the main cleavage product in the absence of ¹⁸O-compounds. Incorporation of one ¹⁸O atom in ODTD was found if the cleavage reaction was performed in the presence of ¹⁸O₂ and H₂¹⁶O. Incubation of poly(cis-1,4-isoprene) (with RoxA) or of isolated unlabeled ODTD (without RoxA) with H₂¹⁸O in the presence of ¹⁶O₂ indicated that the carbonyl oxygen atoms of ODTD significantly exchanged with oxygen atoms derived from water. The isotope exchange was avoided by simultaneous enzymatic reduction of both carbonyl functions of ODTD to the corresponding dialcohol (12-hydroxy-4,8-dimethyl-trideca-4,8-diene-1-ol (HDTD; m/z 240) during RoxA-mediated in vitro cleavage of poly(cis-1,4-isoprene). In the presence of ¹⁸O₂, H₂¹⁶O, and alcohol dehydrogenase/NADH, incorporation of two atoms of ¹⁸O into the reduced metabolite HDTD was found (m/z 244), revealing that RoxA cleaves rubber by a dioxygenase mechanism. Based on the labeling results and the presence of two hemes in RoxA, a model of the enzymatic cleavage mechanism of poly(cis-1,4-isoprene) is proposed.     

Role of oxygenases in pisatin biosynthesis and in the fungal degradation of maackiain

Some isolates of the plant pathogen Nectria haematococca detoxify the isoflavonoid phytoalexin (−)maackiain by hydroxylation at carbon 6a. Precursor feeding studies strongly suggest that the penultimate step in (+)pisatin biosynthesis by Pisum sativum is 6a-hydroxylation of (+)maackiain. We have used ¹⁸O labeling to test the involvement of oxygenases in these two reactions. When fungal metabolism of maackiain took place under ¹⁸O₂, the product was labeled with 99% efficiency; no label was incorporated by metabolism in H₂¹⁸O. Pisatin synthesized by pea pods in the presence of ¹⁸O₂ or H₂¹⁸O was a mixture of molecules containing up to three labeled oxygen atoms. Primary mass spectra of such mixtures were complex but were greatly simplified by tandem MS. This analysis indicated that the 6a oxygen of pisatin was derived from H₂O and not from O₂. Labeling patterns for the other five oxygen atoms were consistent with the proposed pathway for biosynthesis of pisatin and related isoflavonoids. We conclude that the fungal hydroxylation of maackiain is catalyzed by an oxygenase, but the biosynthetic route to the 6a hydroxyl of pisatin is unknown.     

Isolation and characterization of a novel peroxisomal choline monooxygenase in barley

Glycine betaine (GB) is a compatible solute accumulated by many plants under various abiotic stresses. GB is synthesized in two steps, choline → betaine aldehyde → GB, where a functional choline-oxidizing enzyme has only been reported in Amaranthaceae (a chloroplastic ferredoxin-dependent choline monooxygenase) thus far. Here, we have cloned a cDNA encoding a choline monooxygenase (CMO) from barley (Hordeum vulgare) plants, HvCMO. In barley plants under non-stress condition, GB had accumulated in all the determined organs (leaves, internodes, awn and floret proper), mostly in the leaves. The expression of HvCMO protein was abundant in the leaves, whereas the expression of betaine aldehyde dehydrogenase (BADH) protein was abundant in the awn, floret proper and the youngest internode than in the leaves. The accumulation of HvCMO mRNA was increased by high osmotic and low-temperature environments. Also, the expression of HvCMO protein was increased by the presence of high NaCl. Immunofluorescent labeling of HvCMO protein and subcellular fractionation analysis showed that HvCMO protein was localized to peroxisomes. [¹⁴C]choline was oxidized to betaine aldehyde and GB in spinach (Spinacia oleracea) chloroplasts but not in barley, which indicates that the subcellular localization of choline-oxidizing enzyme is different between two plant species. We investigated the choline-oxidizing reaction using recombinant HvCMO protein expressed in yeast (Saccharomyces cerevisiae). The crude extract of HvCMO-expressing yeast coupled with recombinant BBD2 protein converted [¹⁴C]choline to GB when NADPH was added as a cofactor. These results suggest that choline oxidation in GB synthesis is mediated by a peroxisomal NADPH-dependent choline monooxygenase in barley plants.     

Photophosphorylation capacity of stable spheroplast preparations of anabaena

Spheroplasts from Anabaena 7119 (formerly designated Nostoc muscorum) were prepared in the presence of serum albumin in 0.5 molar sucrose. Electron transport and photophosphorylation were preserved (> 70% of the maximum rate for 1 week). The pH profile of electron transport and photophosphorylation in the reactions H₂O → NADP, H₂O → methyl viologen, and H₂O → ferricyanide shows that uncoupling by ammonia is small throughout and increases slightly with higher pH. ADP + Pi increased NADP reduction from H₂O by 2.5-fold. The ratios of ATP formed per electron pair transported ranged from 0.9 to 1.5. Effects of catalase and superoxide dismutase on the overall O₂ balance implicate pseudocyclic electron transport and phosphorylation. The quenching of 9-aminoacridine fluorescence indicates the formation of a Δ pH from 2 to 2.6 during illumination. This pH gradient is abolished by uncouplers; however, complete uncoupling is achieved only by 3-chlorocarbonyl cyanide phenylhydrazone or valinomycin + NH₄⁺. In the presence of NH₄⁺ alone, the membrane potential may act as the driving force for photophosphorylation.     

New Type of Oxygenase Involved in the Metabolism of Propane and Isobutane

Nocardia paraffinicum (Rhodococcus rhodochrous), a hydrocarbon-degrading microorganism, was used in a study of propane and isobutane metabolism. The bacterium was able to utilize propane or isobutane as a sole source of carbon, and oxygen was found to be essential for its metabolism. Gas chromatographic analysis showed that n-propanol was the major compound recovered from the metabolism of propane by resting cells, although trace amounts of isopropanol and acetone were detected. When a mixture of propane and isobutane was used, drastic inhibition (72 to 88%) of hydrocarbon utilization by resting cells occurred. The ratio of hydrocarbon to oxygen consumed was found to be approximately 2:1 during the metabolism of propane or isobutane by resting cells when these substrates were provided individually to the organism. Gas chromatographic-mass spectrometric analysis of products formed from ¹⁸O₂ confirmed that the initial oxidative step in the metabolism of these substrates involved molecular oxygen. The proportion of the alcohol containing ¹⁸O was the same as that of ¹⁸O₂ in the gas mixture. Only a negligible amount of ¹⁸O was detected in the alcohol when H₂¹⁸O was incorporated into the system. The observed 2:1 ratio of hydrocarbon to oxygen consumption suggests that the oxygenase in N. paraffinicum, unlike the conventional mono- or dioxygenases, requires two hydrocarbon-binding sites for each of the oxygen-binding sites and is therefore an intermolecular dioxygenase. The newly described oxygenase, which catalyzes the reaction of two molecules of propane with one molecule of oxygen to yield two molecules of a C₃ alcohol, is proposed as the initial oxidation step of the hydrocarbon substrate.     

Betaine Accumulation and [C]Formate Metabolism in Water-stressed Barley Leaves

Barley (Hordeum vulgare L.) plants at the three-leaf stage were water-stressed by flooding the rooting medium with polyethylene glycol 6000 with an osmotic potential of −19 bars, or by withholding water. While leaf water potential fell and leaf kill progressed, the betaine (trimethylglycine) content of the second leaf blade rose from about 0.4 micromole to about 1.5 micromoles in 4 days. The time course of betaine accumulation resembled that of proline accumulation. Choline levels in unstressed second leaf blades were low (<0.1 micromole per blade) and remained low during water stress. Upon relief of stress, betaine-like proline—remained at a high concentration in drought-killed leaf zones, but betaine did not disappear as rapidly as proline from viable leaf tissue during recovery.

When [methyl-¹⁴C]choline was applied to second leaf blades of intact plants in the growth chamber, water-stressed plants metabolized 5 to 10 times more ¹⁴C label to betaine than control plants during 22 hours. When infiltrated with tracer quantities of [¹⁴C]formate and incubated for various times in darkness or light, segments cut from water-stressed leaf blades incorporated about 2- to 10-fold more ¹⁴C into betaine than did segments from unstressed leaves. In segments from stressed leaves incubated with [¹⁴C]formate for about 18 hours in darkness, betaine was always the principal ¹⁴C-labeled soluble metabolite. This ¹⁴C label was located exclusively in the N-methyl groups of betaine, demonstrating that reducing equivalents were available in stressed leaves for the reductive steps of methyl group biosynthesis from formate. Incorporation of ¹⁴C from formate into choline was also increased in stressed leaf tissue, but choline was not a major product formed from [¹⁴C]formate.

These results are consistent with a net de novo synthesis of betaine from 1- and 2-carbon precursors during water stress, and indicate that the betaine so accumulated may be a metabolically inert end product.

     

Purification and Properties of Dimethylglycine Oxidase from Cylindrocarpon didymum M–1

Dimethylglycine oxidase was purified to homogeneity from the cell extract of Cylindrocarpon didymum M–1, aerobically grown in medium containing betaine as the carbon source. The molecular weight of the enzyme was estimated to be 170,000 by the gel filtration method and 180,000 by the sedimentation velocity method. The enzyme exhibited an absorption spectrum characteristic of a flavoprotein with absorption maxima at 277, 345 and 450 nm. The enzyme consisted of two identical subunits with a molecular weight of 82,000, and contained two mol of FAD per mol of enzyme. The flavin was shown to be covalently bound to the protein. The enzyme was inactivated by Ag⁺, Hg²⁺, Zn²⁺ and iodoacetate. The enzyme oxidized dimethylglycine but was inert toward choline, betaine, sarcosine and alkylamines. Km and Vmax values for dimethylglycine were 9.1 mm and 1.22 μmol/min/mg, respectively. The enzyme catalyzed the following reaction: Dimethylglycine+O₂+H₂O → sarcosine+formaldehyde+H₂O₂.     

Influence of buffer system and pH on the amount of oxygen exchanged between solvent H2O and the CO2 produced in the aerobic oxidation of Cypridina luciferin catalyzed by Cypridina luciferase.

Incorporation of ¹⁸O into CO₂ was measured under various buffer conditions when the bioluminescent oxidation of Cypridina luciferin, catalyzed by luciferase, was carried out either in H₂¹⁶O medium with ¹⁸O₂ gas, or in H₂¹⁸O medium with ¹⁶O₂ gas. The results indicate that (1) the exchange of oxygen between CO₂ and solvent H₂O is significantly influenced by the kind of buffer as well as by pH, (2) the exchange of oxygen between solvent H₂O and CO₂ produced from luciferin in a neutral buffer can be reasonably well estimated from the exchange that takes place when the same amount of CO₂ gas is introduced into the same buffer by the presently employed method, and (3) in the Cypridina bioluminescent reaction, one of two oxygens of O₂ is quantitatively incorporated into the product CO₂ prior to the exchange of oxygen between CO₂ and solvent H₂O.     

Choline oxidation by intact spinach chloroplasts

Plants synthesize betaine by a two-step oxidation of choline (choline → betaine aldehyde → betaine). Protoplast-derived chloroplasts of spinach (Spinacia oleracea L.) carry out both reactions, more rapidly in light than in darkness (AD Hanson et al. 1985 Proc Natl Acad Sci USA 82: 3678-3682). We investigated the light-stimulated oxidation of choline, using spinach chloroplasts isolated directly from leaves. The rates of choline oxidation obtained (dark and light rates: 10-50 and 100-300 nanomoles per hour per milligram chlorophyll, respectively) were approximately 20-fold higher than for protoplast-derived chloroplasts. Betaine aldehyde was the main product. Choline oxidation in darkness and light was suppressed by hypoxia. Neither uncouplers nor the Calvin cycle inhibitor glyceraldehyde greatly affected choline oxidation in the light, and maximal choline oxidation was attained far below light saturation of CO₂ fixation. The light stimulation of choline oxidation was abolished by the PSII inhibitors DCMU and dibromothymoquinone, and was partially restored by adding reduced diaminodurene, an electron donor to PSI. Both methyl viologen and phenazine methosulfate prevented choline oxidation. Adding dihydroxyacetone phosphate, which can generate NADPH in organello, doubled the dark rate of choline oxidation. These results indicate that choline oxidation in chloroplasts requires oxygen, and reducing power generated from PSI. Enzymic reactions consistent with these requirements are discussed.     

18O Labeling of Chlorophyll d in Acaryochloris marina Reveals That Chlorophyll a and Molecular Oxygen Are Precursors

The cyanobacterium Acaryochloris marina was cultured in the presence of either H₂¹⁸O or ¹⁸O₂, and the newly synthesized chlorophylls (Chl a and Chl d) were isolated using high performance liquid chromatography and analyzed by mass spectroscopy. In the presence of H₂¹⁸O, newly synthesized Chl a and d, both incorporated up to four isotopic ¹⁸O atoms. Time course H₂¹⁸O labeling experiments showed incorporation of isotopic ¹⁸O atoms originating from H₂¹⁸O into Chl a, with over 90% of Chl a ¹⁸O-labeled at 48 h. The incorporation of isotopic ¹⁸O atoms into Chl d upon incubation in H₂¹⁸O was slower compared with Chl a with ∼50% ¹⁸O-labeled Chl d at 115 h. The rapid turnover of newly synthesized Chl a suggested that Chl a is the direct biosynthetic precursor of Chl d. In the presence of ¹⁸O₂ gas, one isotopic ¹⁸O atom was incorporated into Chl a with approximately the same kinetic incorporation rate observed in the H₂¹⁸O labeling experiment, reaching over 90% labeling intensity at 48 h. The incorporation of two isotopic ¹⁸O atoms derived from molecular oxygen (¹⁸O₂) was observed in the extracted Chl d, and the percentage of double isotopic ¹⁸O-labeled Chl d increased in parallel with the decrease of non-isotopic-labeled Chl d. This clearly indicated that the oxygen atom in the C3¹-formyl group of Chl d is derived from dioxygen via an oxygenase-type reaction mechanism.     

Purification and Properties of Sarcosine Oxidase from Cylindrocarpon didymum M–1

Sarcosine oxidase was purified to homogeneity from the cell extract of Cylindrocarpon didymum M–1, aerobically grown in medium containing choline as the carbon source. The molecular weight of the enzyme was estimated to be 45,000 by gel filtration method and 48,000 by the sodium dodecylsulfate disc gel electrophoresis method. The enzyme exhibited an absorption spectrum with maxima at 277 and 450 run and shoulders at 370 and 470 nm. The anaerobic addition of sarcosine to the enzyme resulted in the disappearance of the peak at 450 nm. The enzyme contained one mol of covalently bound FAD per mol of enzyme. Enzyme activity was inhibited by Ag⁺, Cu²⁺, Hg²⁺, p-chloromercuribenzoate and iodoacetate. The enzyme oxidized sarcosine but was inert toward choline, betaine, dimethylglycine and N-methyl amino acids. Km and V_max values for sarcosine were 1.8 ihm and 26.2 μmol/min/mg, respectively. The enzyme catalyzed the following reaction: Sarcosine+O₂+H₂O→glycine +formaldehyde+H₂O₂.     

High-Affinity Transport of Choline-O-Sulfate and Its Use as a Compatible Solute in Bacillus subtilis

We report here that the naturally occurring choline ester choline-O-sulfate serves as an effective compatible solute for Bacillus subtilis, and we have identified a high-affinity ATP-binding cassette (ABC) transport system responsible for its uptake. The osmoprotective effect of this trimethylammonium compound closely matches that of the potent and widely employed osmoprotectant glycine betaine. Growth experiments with a set of B. subtilis strains carrying defined mutations in the glycine betaine uptake systems OpuA, OpuC, and OpuD and in the high-affinity choline transporter OpuB revealed that choline-O-sulfate was specifically acquired from the environment via OpuC. Competition experiments demonstrated that choline-O-sulfate functioned as an effective competitive inhibitor for OpuC-mediated glycine betaine uptake, with a K_i of approximately 4 μM. Uptake studies with [1,2-dimethyl-¹⁴C]choline-O-sulfate showed that its transport was stimulated by high osmolality, and kinetic analysis revealed that OpuC has high affinity for choline-O-sulfate, with a K_m value of 4 ± 1 μM and a maximum rate of transport (V_max) of 54 ± 3 nmol/min · mg of protein in cells grown in minimal medium with 0.4 M NaCl. Growth studies utilizing a B. subtilis mutant defective in the choline to glycine betaine synthesis pathway and natural abundance ¹³C nuclear magnetic resonance spectroscopy of whole-cell extracts from the wild-type strain demonstrated that choline-O-sulfate was accumulated in the cytoplasm and was not hydrolyzed to choline by B. subtilis. In contrast, the osmoprotective effect of acetylcholine for B. subtilis is dependent on its biotransformation into glycine betaine. Choline-O-sulfate was not used as the sole carbon, nitrogen, or sulfur source, and our findings thus characterize this choline ester as an effective compatible solute and metabolically inert stress compound for B. subtilis. OpuC mediates the efficient transport not only of glycine betaine and choline-O-sulfate but also of carnitine, crotonobetaine, and γ-butyrobetaine (R. Kappes and E. Bremer, Microbiology 144:83–90, 1998). Thus, our data underscore its crucial role in the acquisition of a variety of osmoprotectants from the environment by B. subtilis.     

Comparative Physiological Evidence that beta-Alanine Betaine and Choline-O-Sulfate Act as Compatible Osmolytes in Halophytic Limonium Species

The quaternary ammonium compounds accumulated in saline conditions by five salt-tolerant species of Limonium (Plumbaginaceae) were analyzed by fast atom bombardment mass spectrometry. Three species accumulated β-alanine betaine and choline-O-sulfate; the others accumulated glycine betaine and choline-O-sulfate. Three lines of evidence indicated that β-alanine betaine and choline-O-sulfate replace glycine betaine as osmo-regulatory solutes. First, tests with bacteria showed that β-alanine betaine and choline-O-sulfate have osmoprotective properties comparable to glycine betaine. Second, when β-alanine betaine and glycine betaine accumulators were salinized, the levels of their respective betaines, plus that of choline-O-sulfate, were closely correlated with leaf solute potential. Third, substitution of sulfate for chloride salinity caused an increase in the level of choline-O-sulfate and a matching decrease in glycine betaine level. Experiments with ¹⁴C-labeled precursors established that β-alanine betaine accumulators did not synthesize glycine betaine and vice versa. These experiments also showed that β-alanine betaine synthesis occurs in roots as well as leaves of β-alanine betaine accumulators and that choline-O-sulfate and glycine betaine share choline as a precursor. Unlike glycine betaine, β-alanine betaine synthesis cannot interfere with conjugation of sulfate to choline by competing for choline and does not require oxygen. These features of β-alanine betaine may be advantageous in sulfate-rich salt marsh environments.     

Chemiluminescent determination of acetylcholine,and continuous detection of its release from torpedo electric organ synapses and synaptosomes

A chemiluminescent procedure to determine acetylcholine is described. The enzyme choline oxidase recently purified, oxidises choline to betaine, the H₂O₂ generated is continuously measured with the luminol-peroxidase chemiluminescent reaction for H₂O₂. Other chemi or bioluminescent detectors for H₂O₂ would probably work as well. The chemiluminescent step provides great sensitivity to the method which is slightly less sensitive than the leech bio-assay but much more sensitive than the frog rectus preparation. The specificity of the chemiluminescent method depends on the fact that choline oxidase receives its substrate only when acetylcholine is hydrolysed by acetylcholinesterase. The acetylcholine content of tissue extracts was determined with the chemiluminescent method, and with the frog rectus assay, the values found were very comparable. The chemiluminescent procedure was used to follow the release of acetylcholine from tissues. When a slice of electric organ is incubated with choline oxidase, luminol and peroxidase, KCl depolarization or electrical stimulation in critical experimental conditions triggered an important light emission, which was blocked in high Mg²⁺. The venom of Glycera convoluta, known to induce a substantial transmitter release, was also found to trigger the light emission from tissue slices. Suspensions of synaptosomes release relatively large amounts of acetylcholine following Glycera venom action; this was confirmed with the chemiluminescent reaction. The demonstration that the light emission reflects the release of acetylcholine is supported by several observations. First, when the tissue is omitted no light emission is triggered after KCl or venom addition to the reagents. Second, the time course of the light emission record is very similar to the time course previously found for ACh release with radioactive methods. Third, if choline oxidase is omitted, or if acetylcholinesterase is inhibited by phospholine, the light emission is blocked, showing that the substance released has to be hydrolyzed by acetylcholinesterase and oxidised by choline oxidase to generate chemiluminescence.The procedure described has important potential applications since other transmitters can similarly be measured upon changing the oxidase.     

Betaine or folate can equally furnish remethylation to methionine and increase transmethylation in methionine-restricted neonates

Methionine partitioning between protein turnover and a considerable pool of transmethylation precursors is a critical process in the neonate. Transmethylation yields homocysteine, which is either oxidized to cysteine (i.e., transsulfuration), or is remethylated to methionine by folate- or betaine- (from choline) mediated remethylation pathways. The present investigation quantifies the individual and synergistic importance of folate and betaine for methionine partitioning in neonates. To minimize whole body remethylation, 4–8-d-old piglets were orally fed an otherwise complete diet without remethylation precursors folate, betaine and choline (i.e. methyl-deplete, MD-) (n=18). Dietary methionine was reduced from 0.3 to 0.2 g/(kg∙d) on day-5 to limit methionine availability, and methionine kinetics were assessed during a gastric infusion of [¹³C₁]methionine and [²H₃-methyl]methionine. Methionine kinetics were reevaluated 2 d after pigs were rescued with either dietary folate (38 μg/(kg∙d)) (MD + F) (n=6), betaine (235 mg/(kg∙d)) (MD + B) (n=6) or folate and betaine (MD + FB) (n=6). Plasma choline, betaine, dimethylglycine (DMG), folate and cysteine were all diminished or undetectable after 7 d of methyl restriction (P<.05). Post-rescue, plasma betaine and folate concentrations responded to their provision, and homocysteine and glycine concentrations were lower (P<.05). Post-rescue, remethylation and transmethylation rates were~70–80% higher (P<.05), and protein breakdown was spared by 27% (P<.05). However, rescue did not affect transsulfuration (oxidation), plasma methionine, protein synthesis or protein deposition (P>.05). There were no differences among rescue treatments; thus betaine was as effective as folate at furnishing remethylation. Supplemental betaine or folate can furnish the transmethylation requirement during acute protein restriction in the neonate.     

Source of oxygen in cytochrome P-450 catalyzed carbinolamine formation

N-Methylcarbazole was incubated in H₂O¹⁸ and under an ¹⁸O atmosphere. N-Hydroxymethylcarbazole, 1-OH- and 3-OH-N-methylcarbazole were isolated by HPLC and analyzed for ¹⁸O content In incubations containing ¹⁸O, all three metabolites showed >95% ¹⁸O incorporation. In incubations containing H₂O¹⁸, the N-hydroxymethyl metabolite showed ¹⁶O incorporation equal to control incubations in 100% H₂O. These data demonstrate that the sole source of oxygen in cytochrome P-450 catalyzed, NADPH supported N-hydroxymethylcarbazole formation is atmospheric oxygen.     

H2-CO2-Dependent Anaerobic O-Demethylation Activity in Subsurface Sediments and by an Isolated Bacterium

The ability of microorganisms in sediments from the Atlantic Coastal Plain to biodegrade methoxylated aromatic compounds was examined. O-demethylation activity was detected in deep (121- and 406-m) sediments, as well as in the surface soil. A syringate-demethylating consortium, containing at least three types of bacteria, was enriched from a deep-sediment sample in a medium containing syringate as the sole organic carbon source and with a N₂-CO₂ atmosphere. An isolate which demethylated syringate was obtained from the enrichment on an agar medium incubated under a H₂-CO₂ but not a N₂-CO₂ or N₂ atmosphere. O demethylation of syringate of this isolate was dependent on the presence of both H₂ and CO₂ in the gas phase. The metabolism of syringate occurred in a sequential manner: methylgallate accumulated transiently before it was converted to gallate. Mass balance analysis suggests that the stoichiometry of the reaction in this isolate proceeds in accordance with the following generalized equation: C₇H₃O₃(OCH₃)_n^- + nHCO₃^- + nH₂ → C₇H₃O₃(OH)_n^- + nCH₃COO^- + nH₂O.