Demethoxylation of [O14CH3]-labelled lignin model compounds by the brown-rot fungi Gloeophyllum trabeum and Poria (Postia) placenta

Demethoxylation reactions in the cultures of the brown-rot fungi Gloeophyllum trabeum and Poria placenta were studied by determining the evolution of (14)CO(2) from a non-phenolic lignin model, beta-O-4 dimer, [O(14)CH(3)]-labelled at position 4 in the A ring (model I), and from [O(14)CH(3)]-labelled vanillic acid (model II). The fungi were grown under oxygen or air atmosphere on an agar medium with or without spruce sapwood blocks. The dimeric model (I) was impregnated onto agar or wood block in cultures to clarify the possible effect of wood as growth substrate. In the case of vanillic acid (model II), birch wood was used. The effect of supplemented nutrient nitrogen (2 mM N) and glucose (0.1 or 1.0% w/v) on demethoxylation was also studied. G. trabeum enhanced the production of (14)CO(2) from the dimer in the presence of spruce wood blocks. It released (14)CO(2) from the methoxyl groups giving 30-60% of the applied activity in 8 weeks. P. placenta produced almost 30% (14)CO(2 )from vanillic acid (model II) in 9 weeks under oxygen, but from the methoxyl group of the dimer only 3% of (14)CO(2) was evolved in 4 weeks. The biomasses determined as ergosterol assay showed variation from 14 to 226 microg g(-1) dry weight of agar, and 2 to 9 microg g(-1 )of wood, but they did not correlate with the production of (14)CO(2). The results indicate that these brown-rot fungi possess different mechanisms for demethoxylation.     

Degradation of veratric acid and other lignin-related aromatic compounds by the white-rot fungus Pycnoporus cinnabarinus

Metabolism of veratric acid and other aromatic compounds has been studied in two strains of Pycnoporus cinnabarinus. In non-agitated cultures which contained cellulose as an additional carbon source, veratric acid was demeth(ox)ylated to vanillic acid which accumulated in the medium. Under these conditions, ¹⁴CO₂ evolution from [4-O¹⁴CH₃]-veratric acid preceded that from [3-O¹⁴CH₃]-veratric acid in the case of both strains. ¹⁴CO₂ evolution was markedly accelerated and increased when 100% oxygen was employed instead of air. Oxygen had not so strong effect on the decarboxylation of ¹⁴COOH-labelled vanillic and p-hydroxybenzoic acid but it did increase decarboxylation of ¹⁴COOH-labelled veratric acid, indicating the effect of oxygen on the preceding demeth(ox)ylation. There were indications, for example rapid demethylation of veratric acid in early stages of growth when apparent phenol oxidase (laccase) activity was zero, for an existence of a separate demethylase enzyme. However, the participation of phenol oxidases in demeth(ox)ylation cannot be ruled out. Degradation pattern of vanillic acid was basically similar in P. cinnabarinus compared to Sporotrichum pulverulentum (Phanerochaete chrysosporium). Also the effect of carbon source was similar: cellulose as a carbon source enhanced degradation of vanillic acid through methoxyhydroquinone whereas in glucose medium, vanillic acid was reduced to the respective aldehyde and alcohol.Non-standard abbreviations CBQ cellobiose: quinone oxidoreductase - MHQ methoxyhydroquinone     

Oxidation of 2-oxoisocaproate and 2-oxoisovalerate by the perfused rat heart. Interactions with fatty acid oxidation

The interactions between fatty acid oxidation and the oxidation of the 2-oxo acids of the branched chain amino acids were studied in the isolated Langendorff-perfused heart. 2-Oxoisocaproate inhibited the oxidation of oleate, but 2-oxoisovalerate and 2-oxo-3-methylvalerate did not. This difference was not attributable to the magnitude of the flux through the branched chain 2-oxo acid dehydrogenase, which was slightly higher with 2-oxoisovalerate than with 2-oxoisocaproate. Oxidation of 2-oxoisocaproate in the perfused heart was virtually complete, since more than 80% of the isovaleryl-CoA formed from 2-oxo[1-14C]isocaproate was further metabolized to CO2, as determined by comparing 14CO2 production from 2-oxo[14C(U)]isocaproate with that from the 1-14C-labelled compound. Only twice as much 14CO2 was produced from 2-oxo[14C(U)]isovalerate as from the 1-14C-labelled compound, indicating incomplete oxidation. This was confirmed by the accumulation in the perfusion medium of substantial quantities of labelled 3-hydroxyisobutyrate (an intermediate in the pathway of valine catabolism), when hearts were perfused with 2-oxo[14C(U)]isovalerate. The failure of 2-oxoisovalerate to inhibit fatty acid oxidation, then, can be attributed to the fact that its partial metabolism in the heart produces little ATP. We have previously shown that 3-hydroxyisobutyrate is a good gluconeogenic substrate in liver and kidney, and postulate that 3-hydroxyisobutyrate serves as an interorgan metabolite such that valine can serve as a glucogenic amino acid, even when its catabolism proceeds beyond the irreversible 2-oxo acid dehydrogenase in muscle.     

Vanillic acid metabolism by the white-rot fungus Sporotrichum pulverulentum

Vanillic acid metabolism was studied in wild-type Sporotrichum pulverulentum and three different mutants. Vanillic acid was found to be oxidatively decarboxylated to methoxyhydroquinone (MHQ) and simultaneously reduced to vanillin and vanillyl alcohol to different degrees depending upon the cultivation conditions. The reducing pathway cannot be utilized unless the fungus has access to an easily metabolized carbon source such as glucose or cellobiose, while decarboxylation takes place in cultures with only vanillic acid present. Polymerization reactions also occurred in the culture solutions. Some evidence for reoxidation of vanillin and vanillyl alcohol was obtained in vivo, and in vitro experiments using horseradish peroxidase.Using vanillic acids labelled in the carboxyl, methoxyl and the aromatic ring it was shown that decarboxylation occures before ring-cleavage, which in turn takes place earlier than the release of ¹⁴CO₂ from O¹⁴CH₃-vanillate. The ¹⁴CO₂ evolution from the methoxyl group is repressed by 1% cellobiose as compared to 0.25% cellobiose, but is stimulated by 26 mM nitrogen (as asparagine plus NH₄NO₃) compared to 2.6 mM nitrogen. Since S. pulverulentum appears to require three hydroxyl groups attached to the benzene ring before ring-cleavage can occur, preparation for ring-cleavage is apparently achieved by hydroxylation rather than by demethylation.A scheme for metabolism of vanillic acid by S. pulverulentum based upon these results is proposed.Non-Standard Abbreviations WT wild type Sporotrichum pulverulentum - MHQ methoxyhydroquinone - MQ methoxyquinone - NKM Norkrans medium - DMS dimethylsuccinate - DHP dehydropolymer of coniferyl alcohol     

Metabolism of radiolabelled energy-yielding substrates by rat Sertoli cells

The rates of metabolism in vitro of 3H- or 14C-labelled glucose, pyruvate, glutamine and leucine by Sertoli cells from immature rats were estimated. The overall rate of glucose utilization exceeded by far the rates of oxidation of pyruvate (derived from glucose) via the citric acid cycle and glucose metabolism via the oxidative branch of the pentose phosphate pathway. This pattern of glucose metabolism was not markedly altered after stimulation of glucose metabolism by FSH. The rate of oxidation of exogenous pyruvate indicated that the energy yield from glucose metabolism by Sertoli cells could be dependent on the extracellular concentrations of pyruvate and lactate. There is no evidence that a high rate of aerobic glycolysis is of vital importance for Sertoli cells. In medium containing glucose and all amino acids, 14C-labelled glutamine and leucine were converted to 14CO2 at considerable rates. It was calculated that the oxidation of glutamine and leucine in addition to glucose and fatty acids can yield much of the required energy of Sertoli cells.     

The metabolism of amino acids in the bovine lens. Their oxidation as a source of energy

1. The metabolism by the bovine lens of nine (14)C-labelled l-amino acids was studied. These were: alanine, aspartate, glutamate, leucine, lysine, proline, serine, tyrosine and tryptophan. 2. All were taken up by the tissue and incorporated into protein. 3. Aspartate and glutamate, although poorly taken up, were readily metabolized to CO(2). Radioactivity from glutamate was also found in glutathione, glutamine, proline and ophthalmic acid. Aspartate was converted into glutamate, glutathione, proline, alanine and lactate. 4. Alanine was largely converted into lactate, which was released into the medium, but incorporation of radioactivity into CO(2), glutamate, glutathione, aspartate and lipids also occurred. 5. Radioactivity from leucine was detected in CO(2), lipids, glutamate, glutathione, proline and glutamine. 6. Lysine was only slightly broken down by the bovine lens; radioactivity was observed in CO(2), glutamate, glutathione, proline and two unidentified compounds. 7. Proline was metabolized to glutamate from which CO(2), glutathione and glutamine were formed. Hydroxyproline in the capsule collagen was labelled. 8. Radioactivity from serine was found in CO(2), lipids, glutathione, glycine, cystine, ATP, lactate and three unidentified compounds, one of which was probably taurine. 9. Neither tyrosine nor tryptophan were metabolized by the bovine lens. 10. The ability of the lens to metabolize amino acids was also shown by measurement of NH(3) production: more NH(3) was formed when glucose was absent from the incubation medium. 11. These experiments suggest that oxidation of amino acids is a source of energy for the lens.     

Transformation of toluene and benzene by mixed methanogenic cultures

The aromatic hydrocarbons toluene and benzene were anaerobically transformed by mixed methanogenic cultures derived from ferulic acid-degrading sewage sludge enrichments. In most experiments, toluene or benzene was the only semicontinuously supplied carbon and energy source in the defined mineral medium. No exogenous electron acceptors other than CO2 were present. The cultures were fed 1.5 to 30 mM unlabeled or 14C-labeled aromatic substrates (ring-labeled toluene and benzene or methyl-labeled toluene). Gas production from unlabeled substrates and 14C activity distribution in products from the labeled substrates were monitored over a period of 60 days. At least 50% of the substrates were converted to CO2 and methane (greater than 60%). A high percentage of 14CO2 was recovered from the methyl group-labeled toluene, suggesting nearly complete conversion of the methyl group to CO2 and not to methane. However, a low percentage of 14CO2 was produced from ring-labeled toluene or from benzene, indicating incomplete conversion of the ring carbon to CO2. Anaerobic transformation pathways for unlabeled toluene and benzene were studied with the help of gas chromatography-mass spectrometry. The intermediates detected are consistent with both toluene and benzene degradation via initial oxidation by ring hydroxylation or methyl oxidation (toluene), which would result in the production of phenol, cresols, or aromatic alcohol. Additional reactions, such as demethylation and ring reduction, are also possible. Tentative transformation sequences based upon the intermediates detected are discussed.     

Effect of glucose on the utilization of palmitate 1 14C by rat kidney cortex slices.

The authors studied the effect of glucose on the uptake and utilization of palmitate 1 14C by rat kidney cortex slices. They found that its inhibitory effect on free fatty acid (FFA) uptake was caused by inhibition of the incorporation of 1 14C-labelled palmitate into the total lipids and FFA and by reduced oxidation to 14CO2. Glucose has a regulative function in the utilization of FFA by the kidneys.     

Decomposition of 14C-labelled lignin and phenols by a Nocardia sp.

A Gram-positive bacterium which was isolated from a Finnish soil and identified as a Nocardia sp., was able to decompose lignin and to assimilate lignin degradation products as a carbon source. It could release ¹⁴CO₂ from ¹⁴C-labelled methoxyl groups, side chains or ring carbons of coniferyl alcohol dehydropolymers (DHP) and from specifically ¹⁴C-labelled lignin of plant material. Furthermore, it could release ¹⁴CO₂ from phenolcarboxylic and cinnamic acids and alcohols labelled in the OCH₃, COOH groups, side chain or aromatic ring carbons.Non-Common Abbreviations Used DHP dehydropolymers of coniferyl alcohol     

Regulation of hexose phosphate metabolism in Acetobacter xylinum

The metabolism of glucose and fructose was studied in resting succinate-grown cells of Acetobacter xylinum. From fructose only cellulose and CO(2) were formed by the cells, whereas from glucose, gluconate was formed much more rapidly than these two products. The molar ratio of sugar converted into cellulose to sugar converted into CO(2) was significantly greater than unity for both hexoses. The pattern of label retention in the cellulose formed by the cells from specifically (14)C-labelled glucose, fructose or gluconate corresponded to that of hexose phosphate in a pentose cycle. On the other hand, the isotopic configuration of cellulose arising from variously singly (14)C-labelled pyruvate did not agree with the operation of a pentose cycle on gluconeogenic hexose phosphate. Readily oxidizable tricarboxylic acid-cycle intermediates such as acetate, pyruvate or succinate promoted cellulose synthesis from fructose and gluconate although retarding their oxidation to CO(2). The incorporation into cellulose of C-1 of fructose was greatly increased in the presence of these non-sugar substrates, although its oxidation to CO(2) was greatly diminished. It is suggested that the flow of hexose phosphate carbon towards cellulose or through the pentose cycle in A. xylinum is regulated by an energy-linked control mechanism.     

Oxidation of glucose, ribose, alanine, and glutamate by Leishmania braziliensis panamensis

The metabolism of [1-14C]- and [6-14C]glucose, [1-14C]ribose, [1-14C]- and [U-14C]alanine, and [1-14C]- and [5-14C]glutamate by the promastigotes of Leishmania braziliensis panamensis was investigated in cells resuspended in Hanks' balanced salt solution supplemented with ribose, alanine, or glutamate. The ratio of 14CO2 produced from [1-14C]glucose to that from [6-14C]glucose ranged from about two to six, indicating appreciable carbon flow through the pentose phosphate pathway. A functional pentose phosphate pathway was further demonstrated by the production of 14CO2 from [1-14C]ribose although the rate of ribose oxidation was much lower than the rate of glucose oxidation. The rate of 14CO2 production from [1-14C]glucose was almost linear with time of incubation, whereas that of [6-14C]glucose accelerated, consistent with an increasing rate of flux through the Embden-Meyerhof pathway during incubation. Increasing the assay temperature from 26 degrees C to 34 degrees C had no appreciable effect on the rates or time courses of oxidation of either [1-14C]- or [6-14C]glucose or of [1-14C]ribose. Both alanine and glutamate were oxidized by L. b. panamensis, and at rates comparable to or appreciably greater than the rate of oxidation of glucose. The ratios of 14CO2 produced from [1-14C]- to [U-14C]alanine and from [1-14C]- to [5-14C]glutamate indicated that these compounds were metabolized via a functioning tricarboxylic acid cycle and that most of the label that entered the tricarboxylic acid cycle was oxidized to carbon dioxide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on lung tumours. III. Oxidative metabolism of dimethylnitrosamine by rodent and human lung tissue.

The oxidative metabolism of the carcinogen dimethylnitrosamine (DMN) was studied in mouse, rat, hamster and human respiratory tissue. [14C]DMN was purified by Dowex-1-bisulfite column chromatography to remove a contaminant (probably [14C]formaldehyde) interfering with the enzyme assay. Since formaldehyde and methyl carbonium ions - yielding methanol with water - are considered to be the primary products of DMN metabolism, tissue slices were assayed for the production of [14C]CO2 from 14C-labelled methanol, formaldehyde, formate, and DMN. Oxidation of formaldehyde to formate was not, but oxidation of formate to CO2 was very much rate-limiting. This rate-limiting step was circumvented by introducing quantitative chemical oxidation of formate to CO2 by mercury(II)chloride following the enzymic reaction. Since oxidation of methanol to CO2 proved to be insignificant, production of CO2 from DMN by lung tissue enzymes and HgCl2 may serve as a parameter for N-demethylating activity and the production of the suspected carcinogenically active methyl carbonium ions. The DMN-N-demethylating activities of lung tissue slices of two mouse strains with widely different susceptibilities to formation of lung adenomas by DMN differed significantly, but the difference seemed too small to explain the divergence in tumourigenic response. The enzymatic activities decreased in hamster bronchus, hamster trachea, hamster lung, GRS/A mouse lung, C3Hf/A mouse lung, human lung, Sprague-Dawley rat lung, in that order. The reported resistance of the hamster respiratory system to tumour induction by DMN may therefore not be due to poor DMN-N-demethylating capacity.     

Über O-Demethylierung und Decarboxylierung von Benzoesäuren in pflanzlichen Zellsuspensionskulturen

Summary Various benzoic acids ¹⁴C-labelled in para and meta methoxyl groups as well as (O-methyl-¹⁴C) p-methoxy cinnamic acid were tested for O-demethylation in cell suspension cultures of Phaseolus aureus Roxb. and Glycine max Merr. On the basis of ¹⁴CO₂-formation and product analyses the O-demethylation reactions were shown to be specific for para methoxyl groups. A vanillate-O-demethylase known from microbial sources seemed to be absent in the plant cell cultures.In this and in an earlier publication (Berlin et al., 1971) some twenty ¹⁴C-labelled aromatic compounds were tested for catabolic reactions in the cell cultures, and here we report on the product analyses and the general pattern of distribution of radioactivity. Finally, some indications for compartmentalisation in connection with catabolic studies of aromatic compounds in plant cell cultures are discussed.Decarboxylation of substituted benzoic acids in the cell cultures is restricted to aromatic acids possessing a hydroxyl group in the para position. Only trace amounts of labelled CO₂ were released from (carboxyl-¹⁴C)-anisic acid. This acid, however, was nearly quantitatively demethylated to p-hydroxybenzoic acid, which itself was decarboxylated to a considerable extent after being fed to cell suspension cultures. Similar differences in respect to decarboxylation were observed with syringic acid produced by demethylation of trimethoxybenzoic acid and syringic acid applied directly to the cell cultures.     

Nitrate as a preferred electron sink for the acetogen Clostridium thermoaceticum.

Nitrate enhanced the vanillin- and vanillate-dependent growth of Clostridium thermoaceticum. Under nitrate-enriched conditions, these aromatic substrates were subject to O demethylation. However, acetate, the normal product obtained from O demethylation, was not detected. Acetate was also not detected when methanol and CO cultures were supplemented with nitrate; glucose cultures likewise produced approximately one-third less acetate when enriched with nitrate. Reductant derived from the oxidation of these substrates was recovered in nitrite and ammonia. With an ammonia-limited medium employed to evaluate N turnover, the following stoichiometry was observed concomitantly with the consumption of 2.0 mM O-methyl groups (the recovery of nitrate-derived N approximated 89%): 3.9 mM NO3(-)-->2.8 mM NO2- +0.7 mM NH3. The results demonstrated that (i) nitrate was preferentially used as an electron sink under conditions that were otherwise acetogenic, (ii) nitrate dissimilation was energy conserving and growth supportive, and (iii) nitrate-coupled utilization of O-methyl groups conserved more energy than acetogenic O demethylation.     

Radiorespirometry evidence for the discrimination between 13C-enriched glucose and unlabelled glucose molecules by Paracoccus denitrificans

Paracoccus denitrificans was grown on either unlabelled glucose, [1-13C]glucose or [6-13C]glucose as the sole carbon source for growth. The cells were then incubated with a range of 14C-glucose substrates to compare the 14CO2-evolution rates between cells grown on the glucose and the 13C-labelled glucose. Cells grown on 13C-glucose had significantly faster rates of 14CO2-evolution than those grown on unlabelled glucose. The % yields of 14CO2, per [1-14C]-, [6-14C]- and [U-14C]glucose supplied were also substantially greater than those measured for cells grown on unlabelled glucose. The data indicated that growth of Paracoccus on 13C-enriched glucose substrates resulted in cells with notably different 14C-glucose oxidation metabolism compared to that observed in cells grown on unlabelled glucose.     

Studies on the biosynthesis of quinones in fungi. Incorporation of 6-methylsalicylic acid into fumigatin and related compounds in Aspergillus fumigatus I.M.I. 89353

1. Orsellinic acid has been detected as a metabolite of Aspergillus fumigatus. 2. The other principal aromatic components of the medium are fumigatin and the quinol, fumigatol. Fumigatol has been shown to be dihydrofumigatin after oxidation to the quinone followed by acetylation. 3. (14)C-labelled 6-methylsalicylic acid can be hydroxylated in A. fumigatus to form orsellinic acid and decarboxylated to give m-cresol. 4. (14)C-labelled 6-methylsalicylic acid is incorporated into fumigatin and fumigatol (1.0-1.5%), but the conversion does not occur until about 2-3 days after supplementation of the medium. At this stage of growth, the organism has already synthesized approx. 20 times as much fumigatol as fumigatin and this ratio is reflected in the much lower specific activity of the quinol. 5. Supplementation of the medium with either orsellinic acid or orcinol, in addition to (14)C-labelled 6-methylsalicylic acid, greatly decreases the latter's incorporation into fumigatin. At the same time, the cultures containing these substances are stimulated to produce another quinone with relatively high specific activity. 6. 6-Methylsalicylic acid has not been detected in the medium of normal cultures. The results indicate that 6-methylsalicylic acid itself is not a direct precursor of fumigatin and fumigatol but that it is converted into a true intermediate, probably after hydroxylation to orsellinic acid. 7. Supplementation of the medium with 6-methylsalicylic acid (15-25mg./200ml.) greatly affects the metabolism of A. fumigatus. Growth is inhibited and the synthesis of fumigatol is markedly depressed in these cultures. The inhibitory effects may possibly be related in some way to the production of m-cresol.     

Solution (sup13)C Nuclear Magnetic Resonance Spectroscopic Analysis of the Amino Acids of Methanosphaera stadtmanae: Biosynthesis and Origin of One-Carbon Units from Acetate and Carbon Dioxide

We found that general pathways for amino acid synthesis of Methanosphaera stadtmanae, a methanogen that forms CH(inf4) from H(inf2) and methanol, resembled those of methanogens that form CH(inf4) from CO(inf2) or from the methyl group of acetate. We determined the incorporation of (sup14)C-labeled CO(inf2), formate, methanol, methionine, serine, and acetate into cell macromolecules. Labeling of amino acid carbons was determined by solution nuclear magnetic resonance spectroscopy after growth with (sup13)C-labeled acetate, CO(inf2), serine, and methanol. The (alpha) and (beta) carbons of serine and alanine were formed from carboxyl and methyl carbons of acetate, respectively, and the amino acid carboxyl groups were formed from CO(inf2). This indicates that pyruvate was formed by reductive carboxylation of acetate. Labeling of the methyl carbon of methionine indicated that the major route of synthesis was from the hydroxymethyl carbon of serine that arises from the methyl carbon of acetate. Methanol was a minor source of the methyl of methionine. Unambiguous assignment was made of the sources of all carbons of histidine. Labeling of the histidine 7 position ((epsilon) carbon) was consistent with formation from the C-2 of the purine ring of ATP and the origin of the C-2 from a formyl unit derived from the hydroxymethyl carbon of serine.     

Acetyl-CoA pathway of autotrophic growth. Identification of the methyl-binding site of the CO dehydrogenase

CO dehydrogenase, a key enzyme of the acetyl-CoA pathway of autotrophic growth, has been methylated using 14CH3I or 14CH3-corrinoid enzyme plus ferredoxin. Acetyl-CoA was synthesized from the resulting 14CH3-CO dehydrogenase, CO, and CoASH, with about 50% yield of the available 14C and without addition of other enzymes except CO dehydrogenase disulfide reductase. Even the reductase could be replaced by dithioerythritol. Amino acid analysis of the 14CH3-CO dehydrogenase showed two radioactive peaks, one of which migrated as S-methylcysteine but very close to the methyl ester of glutamic acid. By oxidation with H2O2, the radioactive component of this peak was identified as S-methylcysteine sulfone. Amino acid analysis of the 14CH3-CO dehydrogenase after synthesis of acetyl-CoA demonstrated that there was a large decrease in radioactivity of the peak containing the S-methyl-cysteine. The compound present in the second peak has not been identified; there was no decrease in its radioactivity. By nonreducing gel electrophoresis of the 14CH3-CO dehydrogenase, followed by autoradiography, it was shown that the beta subunit is the methyl acceptor. These results demonstrate that a cysteine of the beta subunit is the methyl acceptor and that CO dehydrogenase per se catalyzes the synthesis of acetyl-CoA.     

Incorporation of 5-methylorcylaldehyde and methionine into the acetogenin (polyketide) gliorosein in Gliocladium roseum I.M.I. 93065

1. methyl-(14)C-labelled 1,3-dihydroxy-4,5-dimethylbenzene, 5-methylorcylaldehyde and 5-methylorsellinic acid were synthesized from orcinol and sodium [(14)C]cyanide and tested for activity as precursors of gliorosein. ring-(14)C-labelled orcylaldehyde was also prepared. 5[(14)C]-Methylorcylaldehyde was incorporated into gliorosein (36% conversion); all the radioactivity was located in the C-methyl groups. 5-Methylorsellinic acid was decarboxylated by Gliocladium roseum and the resulting phenol was secreted into the medium. 2. The formation of an enzyme-bound derivative of 5-methylorsellinic acid as the first aromatic compound in the biosynthesis of gliorosein is suggested to explain these results. 3. ring-(14)C-labelled 3,4-dihydroxy-6-methyltoluquinone was also effectively incorporated into gliorosein and related products (20% conversion). 4. Sodium [(14)C]formate and [Me-(14)C]-methionine were incorporated into gliorosein and related products (15.4 and 22.2% conversion respectively). Isolation and estimation of the radioactivity in the O-methyl and C-methyl groups in the (14)C-labelled gliorosein thus formed showed an appreciable difference in the specific activities of the two types of methyl group (14 and 15% respectively). The results in the doubly-labelled methionine experiment indicate that the C-methyl group arises in the same manner as that in ergosterol; one of the original hydrogen atoms of the methyl group is lost. This confirms that C-methylation occurs at an ethylenic group at the aliphatic level. 5. The sequence of reactions at the aromatic level leading to the formation of gliorosein is proposed as 5-methylorsellinyl-enzyme-->3-hydroxy-5-methylorsellinyl-enzyme-->3,4-dihydroxy-6-methyltoluquinol-->3,4-dimethoxy-6-methyltoluquinol-->gliorosein.     

Isolation from a methanogenic ferulate degrading consortium of an anaerobe that converts methoxyl groups of aromatic acids to volatile fatty acids

An anaerobic, non-motile, rod shaped bacterium is described which cleaves the phenylether bonds of methoxylated aromatic substrates to give the corresponding hydroxy aromatic derivatives and mixed volatile fatty acids, chain length, C₁, C₂ and C₄. The bacterium was isolated from an anaerobic digestor fed with contents from a wood fiber to alcohol fermentation plant, using anaerobic rolltube medium with ferulate as the carbon and energy source. Moles fatty acid produced per 100 mole of methoxyl group of aromatic substrate fermented were approximately: acetate, 14; butyrate, 18; and formate, 15. For the fermentation of equimolar amounts of methoxylated aromatic compounds, growth yields were proportional to the number of methoxylated groups per molecule, and the amount of cells per methoxyl group did not alter when phenylacrylate derivatives were used as substrates. The organism was unable to reduce the side-chain double bond of phenylacrylate derivatives. Coculture of the bacterium on ferulate with Methanospirillum hungatei, or Desulfovibrio in the presence of SO ₄ ⁼ resulted in no nett production of formate, and small quantities of methane and sulfide were produced respectively. The isolate utilized glucose, fructose, and lactate, but not methanol or H₂–CO₂ as growth substrates. Lactate, butyrate, acetate, formate and small quantities of H₂ were produced from glucose fermentation. No reduction of SO ₄ ⁼ or NO ₃ ^- occurred during fermentation of glucose or methoxylated aromatics and no growth occurred in the presence of oxygen.