Species Heterogeneity of Pineal Hydroxyindole-O-Methyltransferase

Abstract: Hydroxyindole- O -methyltransferase was purified from bovine and chicken pineal glands to apparent homogeneity and their properties were compared. The purified enzymes from both pineal glands differed in electrophoretic mobility and isoelectric point. Sodium dodecyl sulfate gel electrophoresis revealed that hydroxyindole- O -methyltransferase of both bovine and chicken pineals was a dimer consisting of a subunit of molecular weight 39,000. The two enzymes also differed in substrate specificity. Bovine hydroxyindole- O -methyltransferase showed a high specificity toward N -acetylserotonin, whereas chicken enzyme methylated N -acetylserotonin and, to some extent, serotonin and bufotenine. The methylation of the three substrates was probably catalyzed by the same enzyme of chicken pineal, because the ratio of substrate availability did not change throughout the purification steps. Using the purified enzymes, we prepared antibody to both bovine and chicken hydroxyindole- O -methyltransferase. The antibody to bovine enzyme cross-reacted with both avian and mammalian enzymes, whereas the antibody to chicken hydroxyindole- O -methyltransferase reacted with avian enzymes, but far less with mammalian enzymes, indicating an immunochemical difference between avian and mammalian hydroxyindole- O -methyltransferase. The results suggest that the properties of hydroxyindole- O -methyltransferase have changed during the evolutionary development of the pineal glands.     

BIOSYNTHESIS OF S-ADENOSYL-L-METHIONINE IN THE RAT PINEAL GLAND

This investigation provides direct evidence that rat pineal gland contains ATP:L-methionine S-adenosyltransferase. The specific activity of the enzyme is about 25 times greater than that of hydroxyindole-O-methyltransferase, the unique marker enzyme in this tissue. The major product of the reaction catalyzed by ATP:L-methionine S-adenosyltransferase has been identified as S-adenosyl-methionine which can function as a methyl group donor for the formation of melatonin. The specific activity of pineal ATP:L-methionine S-adenosyltransferase is at least eight times greater than that of brain, and one-half that of the liver enzyme.     

Rapid and Sensitive Single-Step Radiochemical Assay for Catechol-O-Methyltransferase

Abstract: A simple, rapid and reliable radiometric assay for the determination of catechol- O -methyltransferase activity is described. The method is based on the conversion of catechol to [³H]guaiacol by catechol- O -methyltransferase in the presence of Mg²⁺, adenosine deaminase and S -adenosyl l -[methyl-³H]methionine. Incubation and direct extraction of [³H]guaiacol into organic scintillation fluid, as well as counting, are performed in the same standard scintillation vial. The assay is easy to perform and more sensitive than previous analogous procedures. The method has been applied to the assay of catechol- O -methyltransferase activity in discrete brain areas and also peripheral organs of rat and in human erythrocytes.     

Regional Distribution of Methionine Adenosyltransferase in Rat Brain as Measured by a Rapid Radiochemical Method

Abstract: The distribution of methionine adenosyltransferase (MAT) in the CNS of the rat was studied by use of a rapid, sensitive and specific radiochemical method. The S -adenosyl-[methyl-¹⁴C] l -methionine ([¹⁴C]SAM) generated by adenosyl transfer from ATP to [methyl-¹⁴C] l -methionine is quantitated by use of a SAM-consuming transmethylation reaction. Catechol O -methyltransferase (COMT), prepared from rat liver, transfers the methyl-¹⁴C group of SAM to 3,4-dihydroxybenzoic acid. The ¹⁴C-labelled methylation products, vanillic acid and isovanillic acid, are separated from unreacted methionine by solvent extraction and quantitated by liquid scintillation counting. Compared to other methods of MAT determination, which include separation of generated SAM from methionine by ion-exchange chromatography, the assay described exhibited the same high degree of specificity and sensitivity but proved to be less time consuming. MAT activity was found to be uniformly distributed between various brain regions and the pituitary gland of adult male rats. In the pineal gland the enzyme activity is about tenfold higher.     

Interactions of Methionine and Selenomethionine with Methionine Adenosyltransferase and Ethylene-generating Systems

Since selenomethionine appears to be a better precursor of ethylene in senescing flower tissue of Ipomoea tricolor and in indole acetic acid-treated pea stem sections than is methionine (Konze JR, N Schilling, H Kende 1978 Plant Physiol 62: 397-401), we compared the effectiveness of selenomethionine and methionine to participate in reactions which may be connected to ethylene biosynthesis. Evidence is presented that selenomethionine is also a better substrate of methionine adenosyltransferase (ATP: methionine S-adenosyltransferase, EC 2.5.1.6) from I. tricolor, the V_max for selenomethionine being twice as high as that for methionine. The affinity of the enzyme is higher for methionine than for selenomethionine, however. Methionine added to flower tissue together with selenomethionine inhibits the enhancement of ethylene synthesis by the seleno analog. Likewise, methionine reduces the high, selenomethionine-dependent reaction rates of methionine adenosyltransferase from I. tricolor flower tissue. On the other hand, selenomethionine is less effective as an ethylene precursor than is methionine in model systems involving oxidation by free radicals. It was concluded that activation of methionine by methionine adenosyltransferase and formation of S-adenosylmethionine are more likely to be involved in ethylene biosynthesis than is oxidation of methionine by free radicals.     

A substrate switch: a new mode of regulation in the methionine metabolic pathway

We propose a simple mathematical model of liver S -adenosylmethionine (AdoMet) metabolism. Analysis of the model has shown that AdoMet metabolism can operate under two different modes. The first, with low metabolic rate and low AdoMet concentration, serves predominantly to supply the cell with AdoMet, the substrate for various cellular methylation reactions. The second, with high metabolic rate and high AdoMet concentration, provides an avenue for cleavage of excess methionine and can serve as a source of cysteine when its increased synthesis is necessary. The switch that triggers interconversion between the "low" and "high" modes is methionine concentration. Under a certain set of parameters both modes may coexist. This behavior results from the kinetic properties of (i) the two isoenzymes of AdoMet synthetase, MATI and MATIII, that catalyse AdoMet production; one is inhibited by AdoMet, whereas the other is activated by it, and (ii) glycine- N -methyltransferase that displays highly cooperative kinetics that is different from that of other AdoMet-dependent methyltransferases. Thus, the model provides an explanation for how different cellular needs are met by regulation of this pathway. The model also correctly identifies a critical role for glycine N -methyltransferase in depleting excess methionine in the high mode, thus avoiding the toxicity associated with elevated levels of this essential amino acid.     

Overexpression of a heterologous sam gene encoding S-adenosylmethionine synthetase in flax (Linum usitatissimum) cells: Consequences on methylation of lignin precursors and pectins

The Arabidopsis thaliana sam1 gene encoding S-adenosylmethionine synthetase (EC 2.5.1.6) was transferred to flax ( Linum usitatissimum ) cells via Agrobacterium tumefaciens . This enzyme catalyses the conversion of methionine to S-adenosylmethionine (SAM), the major methyl group donor in living cells. The aim of this work was to study the consequences of an increased SAM-synthetase (SAM-S) activity in transgenic cell lines on both the production of mono- and dimethoxylated lignin monomers and the degree of methylesterification of pectins. Hypocotyls were cocultivated with Agrobacterium tumefaciens strain GV3101 (pGV2260) harbouring the pO35SSAM binary vector carrying the sam1 gene under the control of the 35S promoter and the nptII gene for selection of putative transformed cells. Most of the transgenic cell lines exhibited a significant (up to 3.2-fold) increase in SAM-S activity compared to the controls. The results showed that for the cell lines analysed this transformation had no effect on caffeic acid O -methyltransferase (COMT, EC 2.1.1.68) in vitro activity, degree of methoxylation of lignin precursors or lignin deposition, pectin methyltransferase (PMT, EC 2.1.1) in vitro activity, but led to an increase of pectin methylesterification in friable and fast-growing transgenic cell lines.     

Methionine and Serine Synergistically Suppress Hyperhomocysteinemia Induced by Choline Deficiency,but Not by Guanidinoacetic Acid,in Rats Fed a Low Casein Diet

The effects of dietary supplementation with 0.5% methionine, 2.5% serine, or both on hyperhomocysteinemia induced by deprivation of dietary choline or by dietary addition of 0.5% guanidinoacetic acid (GAA) were investigated in rats fed a 10% casein diet. Hyperhomocysteinemia induced by choline deprivation was not suppressed by methionine alone and was only partially suppressed by serine alone, whereas it was completely suppressed by a combination of methionine and serine, suggesting a synergistic effect of methionine and serine. Fatty liver was also completely prevented by the combination of methionine and serine. Compared with methionine alone, the combination of methionine and serine decreased hepatic S-adenosylhomocysteine and homocysteine concentrations and increased hepatic betaine and serine concentrations and betaine-homocysteine S-methyltransferase activity. GAA-induced hyperhomocysteinemia was partially suppressed by methionine alone, but no interacting effect of methionine and serine was detected. In contrast, GAA-induced fatty liver was completely prevented by the combination of methionine and serine. These results indicate that a combination of methionine and serine is effective in suppressing both hyperhomocysteinemia and fatty liver induced by choline deprivation, and that methionine alone is effective in suppressing GAA-induced hyperhomocysteinemia partially.     

Effects of nitrous oxide-induced inactivation of cobalamin on methionine and S-asenosylmethionine metabilism in the rat

Inhalation of nitrous oxide oxidises cobalamin and, in turn, inactivates methionine synthetase which forms methionine from homocysteine and which requires cob[I]alamin as a co-factor. This study was planned to determine the effect of virtual cessation of methionine synthesis via a cobalamn-dependeent pathway, on tissue levels of methionine, S-adenosylmethionine and on related enzymes. The level of methionine in liver fell initially after exposure to N₂O but was restored to pre-N₂O levels after 6 days despite continuing N₂O exposure. Brain methionine fell within 12 h of N₂O exposure but the fall was not significant. The restoration of methionine levels is accompanied by an increase in activity of betaine homoysteine methyltransferase in liver but this enzyme was not detected in brain. The activity of methionine synthetase remained very low in both liver and brain as long as N₂O inhalation was continued. There was an initial rise in liver S-adenosyl-methionine levels followed by a steady fall to 40% of its initial level after 11 days of N₂O exposure. However, there was no change in the level of S-adenosylmethionine in brain during this period. The data indicate that either brain meets its requirement by increased methionine uptake from plasma or that there are alternate pathways in brain for methionine synthesis other than those requiring a cobalamin coenzyme.     

The cellular origin of glyoxysomal proteins in germinating castor-bean endosperm.

The capacity of castor-bean endosperm tissue to incorporate [35S]methionine into proteins of the total particulate fraction increased during the first 3 days of germination and subsequently declined. At the onset of germination 66% of the incorporated 35S was found in the separated endoplasmic-reticulum fraction, with the remainder in mitochondria, whereas at later developmental stages an increasing proportion of 35S was recovered in glyoxysomes. The kinetics of [35S]methionine incorporation into the major organelle fractions of 3-day-old endosperm tissue showed that the endoplasmic reticulum was immediately labelled, whereas a lag period preceded the labelling of mitochondria and glyoxysomes. When kinetic experiments were interrupted by the addition of an excess of unlabelled methionine, incorporation of [35S]methionine into the endoplasmic reticulum rapidly ceased, but incorporation into mitochondia and glyoxysomes continued for a further 1h. Examination of isolated organelle membranes during this period showed that the addition of unlabelled methionine resulted in a stimulated incorporation of [35S]no methionine into the endoplasmic-reticulum membrane for 30 min, after which time the 35S content of this fraction declined, whereas that of the glyoxysomal membranes continued to increase slowly. The 35S-labelling kinetics of organelles and fractions derived therefrom are discussed in relation to the role of the endoplasmic reticulum in protein synthesis during glyoxysome biogenesis.     

Ozone-Induced Alterations in the Accumulation of Newly Synthesized Proteins in Leaves of Maize

We examined the response of leaves of 3-week-old maize (Zea mays L.) to short-term (5 h) fumigation with O3-enriched air (0, 0.12, 0.24, or 0.36 [mu]L/L). Older leaves and leaf tissue developed more severe visible damage at higher external O3 concentrations. To investigate the immediate effect of O3 exposure on the accumulation of newly synthesized leaf proteins, leaves were labeled with [35S]methionine after 2 h and fumigated for an additional 3 h. O3-induced alterations of leaf proteins were observed in a concentration-dependent manner. There was a significant decrease in [35S]methionine incorporation into protein at the highest O3 concentration. Developmental differences in accumulation of de novo-synthesized leaf proteins were observed when the leaf tip, middle, and basal sections were labeled under 0 [mu]L/L O3, and additional changes were apparent upon exposure to increasing O3 concentrations. Changes in leaf protein synthesis were observed in the absence of visible leaf injury. Subcellular fractionation revealed O3-induced alterations in soluble and membrane-associated proteins. A number of thylakoid membrane-associated proteins showed specific increases in response to O3 fumigation. In contrast, the synthesis of a 32-kD polypeptide associated with thylakoid membranes was reduced in response to O3 fumigation in parallel with reduced incorporation of [35S]methionine into protein. Immunoprecipitation identified this polypeptide as the D1 protein of photosystem II. A reduction in the accumulation of newly synthesized D1 could have consequences for the efficiency of photosynthesis and other cellular processes.     

The pore region of the Kv1.2alpha subunit is an important component of recombinant Kv1.2 channel oxygen sensitivity

Oxygen-sensitive K(+) channels are important elements in the cellular response to hypoxia. Although much progress has been made in identifying their molecular composition, the structural components associated to their O(2)-sensitivity are not yet understood. Recombinant Kv1.2 currents expressed in Xenopus oocytes are inhibited by a decrease in O(2) availability. On the contrary, heterologous Kv2.1 channels are O(2)-insensitive. To elucidate the protein segment responsible for the O(2)-sensitivity of Kv1.2 channels, we analyzed the response to anoxia of Kv1.2/Kv2.1 chimeric channels. Expression of chimeric Kv2.1 channels each containing the S4, the S1-S3 or the S6-COOH segments of Kv1.2 polypeptide resulted in a K(+) current insensitive to anoxia. In contrast, transferring the S5-S6 segment of Kv1.2 into Kv2.1 produced an O(2)-sensitive K(+) current. Finally, mutating a redox-sensitive methionine residue (M380) of Kv1.2 polypeptide did not affect O(2)-sensitivity. Thus, the pore and its surrounding regions of Kv1.2 polypeptide confer its hypoxic inhibition. This response is independent on the redox modulation of methionine residues in this protein segment.     

Novel Biotransformations of 7-Ethoxycoumarin by Streptomyces griseus

Biotransformation of 7-ethoxycoumarin by Streptomyces griseus resulted in the accumulation of two metabolites which were isolated and identified as 7-hydroxycoumarin and 7-hydroxy-6-methoxycoumarin. A novel series of biotransformation reactions is implicated in the conversion of the ethoxycoumarin substrate to these products, including O-deethylation, 6-hydroxylation to form a 6,7-dihydroxycoumarin catechol, and subsequent O-methylation. Either 7-hydroxycoumarin or 6,7-dihydroxycoumarin was biotransformed to 7-hydroxy-6-methoxycoumarin by S. griseus. Trace amounts of the isomeric 6-hydroxy-7-methoxycoumarin were detected when 6,7-dihydroxycoumarin was used as the substrate. Efforts to obtain a cell-free catechol-O-methyltransferase enzyme system from S. griseus were unsuccessful. However, [methyl-¹⁴C]methionine was used with cultures of S. griseus to form 7-hydroxy-6-[¹⁴C]methoxycoumarin.     

Effect of methionine and vitamin B-12 on the activities of methionine biosynthetic enzymes in metJ mutants of Escherichia coli K12

The effects of supplementation of growth medium with high concentrations of methionine (5 mm) and/or vitamin B₁₂ (10 nm) on the activities of five enzymes of the methionine regulon were measured in wild-type Escherichia coli K12, a metJ prototrophic and three metJ methionine auxotrophic derivatives. Growth on vitamin B₁₂ causes lowering of the activities of the non-B₁₂ methyltransferase while growth on methionine causes elevation of its activity in all four metJ mutants. The previous observation that this enzyme is not repressed by vitamin B₁₂ addition in metH mutants together with our observation that vitamin B₁₂ causes repression in mutants (metF) unable to synthesize the donor for homocysteine methylation supports the model of Kung et al. (10) that the holo-B₁₂-methyltransferase functions as a repressor of synthesis of the non-B₁₂-methyltransferase. Growth on methionine causes lowering of cystathionase activity, and growth on vitamin B₁₂ results in elevation of cystathionase activity in a metJ prototroph and one metJ auxotroph. The metJmetA strain (RG326) has a higher than normal level of cystathionase while the metJmetF strain (RG191) has lower than normal cystathionase activity. These results indicate the existence of a metJ independent system that modulates the activity of cystathionase possibly in response to changes in concentration of unidentified metabolite(s).     

Macromolecules released into the culture medium during the vegetative cell cycle of the unicellular green alga Chlamydomonas reinhardii.

The culture medium of growing Chlamydomonas reinhardii cells contains hydroxyproline-rich glycoproteins, which are mainly liberated during release of the zoospores from the mother-cell wall. Pulse-labelling studies with [3H]proline and [35S]methionine have been performed in order to detect the protein components released by synchronously growing cells at different stages of the cell cycle. When either [3H]proline or [35S]methionine were applied during the phase of cell growth, radioactive label appeared in the released macromolecules after a lag period of 40 min, whereas incorporation into the insoluble part of the cell wall was delayed only by 20 min. When applied at the end of the growth phase, e.g. 13 h after beginning of the illumination period, the radioactive amino acids were incorporated into the cell wall, but radioactive labelling of macromolecules released into the culture medium could not be detected before the zoospores were liberated from the mother-cell wall. Maximal incorporation of [3H]proline and [35S]methionine into the insoluble part of the cell wall was observed during cell division, but essentially no radioactively-labelled macromolecules were released into the culture medium during this time period. Analysis of the macromolecules, which were liberated during cell enlargement, by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis revealed distinct radioactive bands, which were differentially labelled with [3H]proline and [35S]methionine. Among the macromolecules released into the culture medium during cell growth, a component of an apparent Mr 35 000 was preferentially labelled with [3H]proline. This component was also detected after labelling with [35S]methionine, but components of an apparently higher Mr were more prominent after labelling with [35S]methionine. Macromolecules released during the cell-enlargement period of synchronously growing cultures in the presence of [3H]proline contained radioactively-labelled hydroxyproline in addition to proline. These results show that, during cell-wall growth, specific protein components are released into the culture medium and that at least one of these components contains large amounts of proline and hydroxyproline. At least some of these macromolecules seem to be constituents of the cell wall, because during pulse-chase experiments radioactively-labelled macromolecules appeared in the culture medium mainly during the time period when the specific radioactivity of the insoluble inner-cell-wall layer decreased.     

Impaired formylation and uptake of tetrahydrofolate by rat small gut following cobalamin inactivation

The effect of inactivation of cobalamin by N2O on the intestinal absorption of folate was studied using rat everted gut sacs. Further, in view of uncertainties about the presence of methionine synthetase in gut [1], this enzyme was measured. Everted gut sacs were incubated with [2-14C]tetrahydrofolate, and the subsequent appearance of labelled formyl- and methyl [14C] tetrahydrofolate in everted segments of small intestine of rats was studied. Considerable methionine synthetase activity was present in washed everted gut sacs but not in gut segments in the absence of such treatment. Methionine synthetase activity declined after exposure to N2O, which oxidizes and inactivates cob(I)alamin. Folate uptake by gut sacs was not affected by 24 h exposure of the animals to N2O but fell significantly after 7 days exposure. There was a significant fall in the amount of formyltetrahydrofolate formed after cobalamin inactivation and this was reversed by supplying either methionine, methylthioadenosine or sodium formate. Serine had no effect. The data support the hypothesis that methionine and methylthioadenosine act by supplying single carbon units at the formate level of oxidation.     

Synthesis of Na+/K+ ATPase by the preimplantation rabbit blastocyst

The rates of incorporation of [35S]methionine into Na+/K+ ATPase, actin (beta- and gamma-isoforms), and total protein of the preimplantation rabbit blastocyst were determined between Days 4 and 7 of development. Blastocyst proteins were metabolically radiolabelled with [35S]methionine and subsequently analysed by co-isolation with purified Na+/K+ ATPase using two-dimensional polyacrylamide gel electrophoresis, immunoprecipitation, immunoblotting, fluorography, and liquid scintillation spectroscopy. The rate of [35S]methionine incorporation into acid-soluble total protein increased 24-fold between Days 4 and 6 post coitum (p.c.), then diminished approximately 79% on Day 7. In-vitro incorporation of [35S]methionine was linear at each stage of blastocyst development. [35S]methionine incorporation rates were unaffected by low free intracellular methionine concentration (less than 0.06 mM) and stage-related differences in blastocoele volume. Analysis of beta- and gamma-actin synthesis revealed patterns of [35S]methionine incorporation rates which were similar to those of total protein. In contrast, synthesis of blastocyst Na+/K+ ATPase was characterized by a 90-fold increase (P less than 0.001) in the rate of [35S]methionine incorporation between Days 4 and 6 p.c. The results demonstrate that Na+/K+ ATPase is actively synthesized at a high and increasing rate during preimplantation development in the rabbit at a period which is characterized by rapid fluid accumulation by the blastocyst.