Autotrophic synthesis of activated acetic acid from two CO2 inMethanobacterium thermoautotrophicum

An in vitro system of autotropic synthesis of activated acetic acid from¹⁴CO₂ inMethanobacterium thermoautotrophicum was developed.

1. A recognized¹⁴CO₂-fixation product in vitro was activated [¹⁴C] acetic acid. It could be trapped enzymatically into citrate and released again as [¹⁴C] acetate by citrate synthase and citrate lyase, respectively.
2. The synthesis of both activated acetic acid and methane from CO₂ proceeded in parallel under a variety of conditions. Both of these processes were stimulated greatly and to the same extent by the addition of methyl coenzyme M to the assay.
3. Various inhibitors of methanogenesis tested also inhibited acetate synthesis, e.g. CH₂Cl₂, CHCl₃, CCl₄, N₂O, and bromoethane sulfonic acid. Cyanide specifically inhibited the synthesis of activated acetic acid, whereas methane formation was unaffected. Cyanide inhibition was relieved by adding CO, whereas the inhibition by the other compounds was not.

The data suggest: The product studied in vitro was acetyl CoA. Its synthesis involves intermediates of CO₂ reduction to methane. In addition, a cyanide-sensitive reaction is required which does not participate in CO₂ reduction to methane.     

Autotrophic synthesis of activated acetic acid from two CO2 inMethanobacterium thermoautotrophicum

A cell-free preparation of heterocysts from Anabaena variabilis showed high nitrogenase activities with several physiological electron donors, dependent on addition of an ATP-generating system. Light-induced acetylene reduction with the artificial electron donor to photosystem I, diaminodurol, exhibited the same light saturation as with hydrogen as donor. Inhibitors of electron flow through plastoquinone affected light-induced, hydrogen- or NADH-dependent nitrogenase activity in a similar way. Several uncoupling agents were without effect, indicating that energized membranes are not a prerequisite for nitrogen fixation. We conclude that NADH or hydrogen deliver electrons to nitrogenase via photosystem I and ferredoxin, feeding in at the plastoquinone site.In the light, addition of NADP induced a lag in H₂- or NADH-supported acetylene reduction apparently by competing with nitrogenase for electrons at the reducing side of photosystem I. Time reversal of this inibition reflects a regulation of photosystem I-dependent nitrogenase activity by the NADPH/NADP ratio in the cell. This was directly demonstrated by differently adjusted NADPH/NADP ratios.NADPH donates electrons to nitrogenase in the dark and in the light, the light reaction being DBMIB-sensitive. NADPH-supported acetylene reduction was inhibited by NADP. This inhibition was not reversed with time, pointing to an involvement of ferredoxin: NADP oxidoreductase (EC 1.18.1.2) in this pathway. Apparently, in the dark, this enzyme is able to directly reduce ferredoxin, whereas in the light electrons from NADPH first have to pass through photosystem I before reducing ferredoxin, hence nitrogenase.Intermediates of glycolysis, like glucose-6-phosphate, fructose-1,6-bisphosphate, and dihydroxyacetone phosphate supported nitrogenase activity in the dark, each with catalytic amounts of both NAD and NADP as equally effective cofactors.We conclude that in heterocysts electrons for nitrogen fixation are essentially supplied by dark reactions, mainly by glycolysis. NADH (and hydrogen) contribute electrons via photosystem I in the light, whereas the NADPH/NADP ratio regulates linear and cyclic electron flow at the reducing side of photosystem I to provide a ratio of ATP/electrons most effective for nitrogenase.Abbvreviations ATCC American Type Culture Collection - Diaminodurol (DAD) 2,3,5,6-tetramethyl-p-phenylenediamine dihydrochloride - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DNP-INT 2,4-dinitrophenyl ether of 2-iodo-4-nitrothymol - E Einstein (mol photons) - FNR ferredoxin - NADP oxidoreductase (EC 1.18.1.2) - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - Metronidazole 1-(2-hydroxyethyl)-2-methyl-5-nitroimidazole     

Acetate assimilation and the synthesis of alanine,aspartate and glutamate inMethanobacterium thermoautotrophicum

Cultures of the autotrophic bacteriumMethanobacterium thermoautotrophicum were shown to assimilate acetate when grown on CO₂ and H₂ in the presence of acetate. At 1 mM acetate 10% of the cell carbon came from acetate, the rest from CO₂. At higher concentrations the percentage increased to reach a maximum of 65%at acetate concentrations higher than 20 mM. The data suggest that acetate may be an important carbon source under physiological conditions.The incorporation of acetate into alanine, aspartate and glutamate was studied in more detail. The cells were grown on CO₂ and H₂ in the presence of 1 mM U-¹⁴C-acetate. The three amino acids were isolated from the labelled cells by a simplified procedure. Alanine, aspartate and glutamate were found to have the same specific radioactivity. Degradation studies showed that C₁ of alanine C₁ and C₄ of aspartate, and C₁ and C₅ of glutamate were exclusively derived from CO₂, whereas C₂ and C₃ alamine and aspartate, and C₃ and C₄ of glutamate were partially derived from acetate. These findings and the presence of pyruvate synthase, phosphoenolpyruvate carboxylase and -ketoglutarate synthase inM. thermoautotrophicum indicate that CO₂ is assimilated into the three amino acids via acetyl CoA carboxylation to pyruvate, phosphoenolpyruvate carboxylation to oxaloacetate, and succinyl CoA carboxylation to -ketoglutarate.     

Expression from the Escherichia coli dapA promoter is regulated by intracellular levels of diaminopimelic acid

Dihydropicolinate synthase (DHDPS; E.C. 4.2.1.52) catalyses the first committed step of lysine biosynthesis in plants and bacteria. Plant DHDPS enzymes, which are responsible solely for lysine biosynthesis, are strongly inhibited by lysine (I0.5 =10 microM), whereas the bacterial enzymes which are less responsive or insensitive to lysine inhibition have the additional function of meso-diaminopimelate biosynthesis which is required for cell wall formation. Previous studies have suggested that expression of the Escherichia coli dapA gene, encoding DHDPS, is unregulated. We show here that this is not the case and that expression of LacZ from the dapA promoter (PdapA) increases in response to diaminopimelic acid limitation in E. coli K-12.     

Regulatory mutants of Streptomyces clavuligerus affected in free diaminopimelic acid content and antibiotic biosynthesis

The composition of intracellular free amino acid pools was determined in Streptomyces clavuligerus mutants possessing an altered aspartokinase which is insensitive to concerted feedback inhibition by threonine and lysine. These mutants contained total free amino acid pool contents that were considerably higher than those found in the wild-type strain. Diaminopimelic acid accounted for 10 to 20% of the total free amino acid pools, depending on the individual mutant and its culture growth phase, whereas diaminopimelic acid contained in the wild-type strain accounted for only 0.5% of the total free amino acid pool.     

Lysine biosynthesis pathway and biochemical blocks of lysine auxotrophs of Schizosaccharomyces pombe.

The alpha-aminoadipate (AA) pathway for the biosynthesis of lysine was investigated in the wild type and in lysine auxotrophs of the fission yeast Schizosaccharomyces pombe. Of the eight enzyme activities of the AA pathway that have been examined so far, six were present in the extract of wild-type S. pombe cells. Growth response to AA and accumulation studies indicated that three lysine auxotrophs, the lys2-97, lys4-95, and lys8-1 strains, were blocked before the AA step and that four lysine auxotrophs, the lys1-131, lys3-37, lys6-3, and lys7-2 strains, were blocked after the AA step. Among the mutants investigated, the lys2-97 mutant exhibited an enzyme lesion at the cis-homoaconitate hydratase step, the lys1-131 and lys7-2 mutants exhibited lesions at the AA reductase step, and lys3-37 exhibited a lesion at the saccharopine dehydrogenase step. These results demonstrated the basic similarity of the AA pathway in S. pombe and Saccharomyces cerevisiae.     

The shikimic acid pathway and polyketide biosynthesis

The shikimic acid pathway, ubiquitous in microorganisms and plants, provides precursors for the biosynthesis of primary metabolites such as the aromatic amino acids and folic acid. Several branchpoints from the primary metabolic pathway also provide aromatic and, in some unusual cases, nonaromatic precursors for the biosynthesis of secondary metabolites. We report herein recent progress in the analysis of two unusual branches of the shikimic acid pathway in streptomycetes; the formation of the cyclohexanecarboxylic acid (CHC)-derived moiety of the antifungal agent ansatrienin and the dihydroxycyclohexanecarboxylic acid (DHCHC) starter unit for the biosynthesis of the immunosuppressant ascomycin. A gene for 1-cyclohexenylcarbonyl-CoA reductase, chcA, which plays a role in catalyzing three of the reductive steps leading from shikimic acid to CHC has been characterized from Streptomyces collinus. A cluster of six open reading frames (ORFs) has been identified by sequencing in both directions from chcA and the putative role of these in CHC biosynthesis is discussed. The individual steps involved in the biosynthesis of DHCHC from shikimic acid in Streptomyces hygroscopicus var ascomyceticus has been delineated and shown to be stereochemically and enzymatically distinct from the CHC pathway. A dehydroquinate dehydratase gene (dhq) likely involved in providing shikimic acid for both DHCHC biosynthesis and primary metabolism has been cloned, sequenced and characterized. Received 17 February 1998/ Accepted in revised form 26 April 1998     

Lysine biosynthesis in Rhodotorula glutinis: properties of pipecolic acid oxidase.

Pipecolic acid oxidase from Rhodotorula glutinis, which converts pipecolic acid to alpha-aminoadipic-delta-semialdehyde, an intermediate of the biosynthetic pathway of lysine, was purified 290-fold. The enzyme from the crude extract and purified preparation exhibited a molecular weight of approximately 43,000 and was composed of a single subunit. The purified enzyme was heat labile and exhibited a pH optimum of 8.5 and an apparent Km for L-pipecolic acid of 1.67 X 10(-3) M. L-Proline acted as a competitive inhibitor for the enzyme. The enzyme was inhibited by the sulfhydryl agents p-chloromercuribenzoate and mercuric chloride. The in vitro enzyme activity required oxygen and upon oxidation of pipecolic acid, oxygen was reduced to hydrogen peroxide.     

Lysine 199 is the general acid in the NAD-malic enzyme reaction

Site-directed mutagenesis was used to change K199 in the Ascaris suum NAD-malic enzyme to A and R and Y126 to F. The K199A mutant enzyme gives a 10(5)-fold decrease in V and a 10(6)-fold decrease in V/K(malate) compared to the WT enzyme. In addition, the ratio for partitioning of the oxalacetate intermediate toward pyruvate and malate changes from a value of 0.4 for the WT enzyme to 1.6 for K199A, and repeating the experiment with A-side NADD gives isotope effects of 3 and 1 for the WT and K199A mutant enzymes, respectively. The K199R mutant enzyme gives only a factor of 10 decrease in V, and the pK for the general acid in this mutant enzyme has increased from 9 for the WT enzyme to >10 for the K199R mutant enzyme. Tritium exchange from solvent into pyruvate is catalyzed by the WT enzyme, but not by the K199A mutant enzyme. The Y126F mutant enzyme gives a 10(3)-fold decrease in V. The oxalacetate partition ratio and isotope effect on oxalacetate reduction for the Y126F mutant enzyme are identical, within error, to those measured for the WT enzyme. Thus, Y126 is important to the overall reaction, but its role at present is unclear. Data are consistent with K199 functioning as the general acid that protonates C3 of enolpyruvate to generate the pyruvate product in the malic enzyme reaction.     

Lysine biosynthesis in Penicillium chrysogenum is regulated by feedback inhibition of α-aminoadipate reductase

A partially purified preparation of alpha-aminoadipate reductase (EC 1.2.1.31) from Penicillium chrysogenum is competitively inhibited by lysine (Ki of 0.26 mM). Exogenous addition of 10 mM L-lysine to resting mycelia of P. chrysogenum increased the intracellular lysine pool concentration 2-fold, but decreased the incorporation of (6-14C)-alpha-aminoadipate into protein-bound lysine to a fifth. The distribution of radioactivity in the pathway metabolites alpha-aminoadipate, saccharopine and lysine was consistent with the assumption of a lysine sensitive enzyme step in vivo between alpha-aminoadipate and saccharopine. Hence lysine inhibition of alpha-aminoadipate reductase may be of physiologic importance.     

Lysine biosynthesis and the evolution-of pennate marine diatoms

The classification of lysine biosynthetic pathways in various organisms have been used to investigate their descent in evolution. We have attempted these determinations in the diatoms Amphora coffeaeformis var:perpusilla (Grunow Cleve.) and Phaeodactylum tricornutum (Bohlin). Additionally, we have verified earlier results of Vogel in a green alga, Chlorella pyrenoidosa strain Tx 71105 (Texas Culture Collection). Our research indicates that the diaminopimelic acid route is involved in all three organisms. While these studies do not exclude the possible co-existence of the α-aminoadipic acid route, the results imply a closer evolutionary relationship of pennate diatoms to bacteria and “classical” photosynthetic plants rather than to heterotrophic or mixotrophic fungi and atypical algal strains such as the Euglenophyta.     

Genetic defects in the hexosamine and sialic acid biosynthesis pathway

BackgroundCongenital disorders of glycosylation are caused by defects in the glycosylation of proteins and lipids. Classically, gene defects with multisystem disease have been identified in the ubiquitously expressed glycosyltransferases required for protein N-glycosylation. An increasing number of defects are being described in sugar supply pathways for protein glycosylation with tissue-restricted clinical symptoms.Scope of reviewIn this review, we address the hexosamine and sialic acid biosynthesis pathways in sugar metabolism. GFPT1, PGM3 and GNE are essential for synthesis of nucleotide sugars uridine diphosphate N-acetylglucosamine (UDP-GlcNAc) and cytidine-5′-monophospho-N-acetylneuraminic acid (CMP-sialic acid) as precursors for various glycosylation pathways. Defects in these enzymes result in contrasting clinical phenotypes of congenital myasthenia, immunodeficiency or adult-onset myopathy, respectively. We therefore discuss the biochemical mechanisms of known genetic defects in the hexosamine and CMP-sialic acid synthesis pathway in relation to the clinical phenotypes.Major conclusionsBoth UDP-GlcNAc and CMP-sialic acid are important precursors for diverse protein glycosylation reactions and for conversion into other nucleotide-sugars. Defects in the synthesis of these nucleotide sugars might affect a wide range of protein glycosylation reactions. Involvement of multiple glycosylation pathways might contribute to disease phenotype, but the currently available biochemical information on sugar metabolism is insufficient to understand why defects in these pathways present with tissue-specific phenotypes.General significanceFuture research on the interplay between sugar metabolism and different glycosylation pathways in a tissue- and cell-specific manner will contribute to elucidation of disease mechanisms and will create new opportunities for therapeutic intervention. This article is part of a Special Issue entitled "Glycans in personalised medicine" Guest Editor: Professor Gordan Lauc.     

A chromoplast-specific carotenoid biosynthesis pathway is revealed by cloning of the tomato white-flower locus

Carotenoids and their oxygenated derivatives xanthophylls play essential roles in the pigmentation of flowers and fruits. Wild-type tomato (Solanum lycopersicum) flowers are intensely yellow due to accumulation of the xanthophylls neoxanthin and violaxanthin. To study the regulation of xanthophyll biosynthesis, we analyzed the mutant white-flower (wf). It was found that the recessive wf phenotype is caused by mutations in a flower-specific beta-ring carotene hyroxylase gene (CrtR-b2). Two deletions and one exon-skipping mutation in different CrtR-b2 wf alleles abolish carotenoid biosynthesis in flowers but not leaves, where the homologous CrtR-b1 is constitutively expressed. A second beta-carotene hydroxylase enzyme as well as flower- and fruit-specific geranylgeranyl diphosphate synthase, phytoene synthase, and lycopene beta-cyclase together define a carotenoid biosynthesis pathway active in chromoplasts only, underscoring the crucial role of gene duplication in specialized plant metabolic pathways. We hypothesize that this pathway in tomato was initially selected during evolution to enhance flower coloration and only later recruited to enhance fruit pigmentation. The elimination of beta-carotene hydroxylation in wf petals results in an 80% reduction in total carotenoid concentration, possibly caused by the inability of petals to store high concentrations of carotenoids other than xanthophylls and by degradation of beta-carotene, which accumulates as a result of the wf mutation but is not due to altered expression of genes in the biosynthetic pathway.