GltX from Clostridium saccharobutylicum NCP262: glutamate synthase or oxidoreductase?

H2-dependent formate production by hyperthermophilic Thermococcales: an alternative to sulfur reduction for reducing-equivalents disposal

Removal of reducing equivalents is an essential catabolic process for all microorganisms to maintain their internal redox balance. The electron disposal by chemoorganotrophic Thermococcales generates H₂ by proton reduction or H₂S in presence of S⁰. Although in the absence of S⁰ growth of these (hyper)thermopiles was previously described to be H₂-limited, it remains unclear how Thermococcales could be present in H₂-rich S⁰-depleted habitats. Here, we report that 12 of the 47 strains tested, distributed among all three orders of Thermococcales, could grow without S⁰ at 0.8 mM dissolved H₂ and that tolerance to H₂ was always associated with formate production. Two conserved gene clusters coding for a formate hydrogenlyase (FHL) and a putative formate dehydrogenase-NAD(P)H-oxidoreductase were only present in H₂-dependent formate producers, and were both systematically associated with a formate dehydrogenase and a formate transporter. As the reaction involved in this alternative pathway for disposal of reducing equivalents was close to thermodynamic equilibrium, it was strongly controlled by the substrates-products concentration ratio even in the presence of S⁰. Moreover, experimental data and thermodynamic modelling also demonstrated that H₂-dependent CO₂ reduction to formate could occur within a large temperature range in contrasted hydrothermal systems, suggesting it could also provide an adaptive advantage.

Expression and functional analysis of glutamate synthase small subunit-like proteins from archaeon Pyrococcus horikoshii

Glutamate synthase, glutamine α-ketoglutarate amidotransferase (often abbreviated as GOGAT) is a key enzyme in the early stages of ammonia assimilation in bacteria, algae and plants, catalyzing the reductive transamidation of the amido nitrogen from glutamine to α-ketoglutarate to form two molecules of glutamate. Most bacterial glutamate synthases consist of a large and small subunit. The genomes of three Pyrococcus species harbour several open reading frames which show homology with the small subunit of glutamate synthase. There are no open reading frames which may be coding for a large subunit responsible for the glutamate formation in these pyrococcal genomes. In this work, two open reading frames PH0876 and PH1873 from P. horikoshii were cloned and expressed in Escherichia coli as soluble proteins. Both proteins show NADPH-dependent oxidoreductase activity using artificial electron acceptors iodonitrotetrazolium chloride at thermophilic conditions. It is possible that these open reading frames are the products of gene duplication and that they are the early forms of an electron transfer domain in archaea which may have later contributed to many electron transfer enzymes.

Two atypical L-cysteine-regulated NADPH-dependent oxidoreductases involved in redox maintenance, L-cystine and iron reduction, and metronidazole activation in the enteric protozoan Entamoeba histolytica

We discovered novel catalytic activities of two atypical NADPH-dependent oxidoreductases (EhNO1/2) from the enteric protozoan parasite Entamoeba histolytica. EhNO1/2 were previously annotated as the small subunit of glutamate synthase (glutamine:2-oxoglutarate amidotransferase) based on similarity to authentic bacterial homologs. As E. histolytica lacks the large subunit of glutamate synthase, EhNO1/2 were presumed to play an unknown role other than glutamine/glutamate conversion. Transcriptomic and quantitative reverse PCR analyses revealed that supplementation or deprivation of extracellular L-cysteine caused dramatic up- or down-regulation, respectively, of EhNO2, but not EhNO1 expression. Biochemical analysis showed that these FAD- and 2[4Fe-4S]-containing enzymes do not act as glutamate synthases, a conclusion which was supported by phylogenetic analyses. Rather, they catalyze the NADPH-dependent reduction of oxygen to hydrogen peroxide and L-cystine to L-cysteine and also function as ferric and ferredoxin-NADP(+) reductases. EhNO1/2 showed notable differences in substrate specificity and catalytic efficiency; EhNO1 had lower K(m) and higher k(cat)/K(m) values for ferric ion and ferredoxin than EhNO2, whereas EhNO2 preferred L-cystine as a substrate. In accordance with these properties, only EhNO1 was observed to physically interact with intrinsic ferredoxin. Interestingly, EhNO1/2 also reduced metronidazole, and E. histolytica transformants overexpressing either of these proteins were more sensitive to metronidazole, suggesting that EhNO1/2 are targets of this anti-amebic drug. To date, this is the first report to demonstrate that small subunit-like proteins of glutamate synthase could play an important role in redox maintenance, L-cysteine/L-cystine homeostasis, iron reduction, and the activation of metronidazole.

Co-regulation of the nitrogen-assimilatory gene cluster in Clostridium saccharobutylicum

Nitrogen assimilation is important during solvent production by Clostridium saccharobutylicum NCP262, as acetone and butanol yields are significantly affected by the nitrogen source supplied. Growth of this bacterium was dependent on the concentration of organic nitrogen supplied and the expression of the assimilatory enzymes, glutamine synthetase (GS) and glutamate synthase (GOGAT), was shown to be induced in nitrogen-limiting conditions. The regions flanking the gene encoding GS, glnA, were isolated from C. saccharobutylicum genomic DNA, and DNA sequencing revealed that the structural genes encoding the GS (glnA) and GOGAT (gltA and gltB) enzymes were clustered together with the nitR gene in the order glnA-nitR-gltAB. RNA analysis showed that the glnA-nitR and the gltAB genes were co-transcribed on 2.3 and 6.2 kb RNA transcripts respectively, and that all four genes were induced under the same nitrogen-limiting conditions. Complementation of an Escherichia coli gltD mutant, lacking a GOGAT small subunit, was achieved only when both the C. saccharobutylicum gltA and gltB genes were expressed together under anaerobic conditions. This is believed to be the first functional analysis of a gene cluster encoding the key enzymes of nitrogen assimilation, GS and GOGAT. A similar gene arrangement is seen in Clostridium beijerinckii NCIMB 8052, and based on the common regulatory features of the promoter regions upstream of the glnA operons in both species, we suggest a model for their co-ordinated regulation by an antitermination mechanism as well as antisense RNA.

Structure--function studies on the iron-sulfur flavoenzyme glutamate synthase: an unexpectedly complex self-regulated enzyme

Glutamate synthase (GltS) is, with glutamine synthetase, the key enzyme of ammonia assimilation in bacteria, microorganisms and plants. GltS isoforms result from the assembly and co-evolution of conserved functional domains. They share a common mechanism of reductive glutamine-dependent glutamate synthesis from 2-oxoglutarate, which takes place within the alpha subunit ( approximately 150 kDa) of the NADPH-dependent bacterial enzyme and the corresponding polypeptides of other GltS forms, and involves: (i) an Ntn-type amidotransferase domain and (ii) a flavin mononucleotide-containing (beta/alpha)(8) barrel synthase domain connected by (iii) a approximately 30 A-long intramolecular ammonia tunnel. The synthase domain harbors the [3Fe/4S](0,+1) cluster of the enzyme, which participates in the electron transfer process from the physiological reductant: reduced ferredoxin in the plant-type enzyme or NAD(P)H in the bacterial and the non-photosynthetic eukaryotic form. The NAD(P)H-dependent GltS requires a tightly bound flavin adenine dinucleotide-dependent reductase (beta subunit, approximately 50 kDa), also determining the presence of two low-potential [4Fe-4S](+1,+2) clusters. Structural, functional and computational data available on GltS and related enzymes show how the enzyme may control and coordinate the reactions taking place at the glutaminase and synthase sites by sensing substrate binding and cofactor redox state.

Structure-function studies on the complex iron-sulfur flavoprotein glutamate synthase: the key enzyme of ammonia assimilation

Glutamate synthases are complex iron-sulfur flavoproteins that participate in the essential ammonia assimilation pathway in microorganisms and plants. The recent determination of the 3-dimensional structures of the alpha subunit of the NADPH-dependent glutamate synthase form and of the ferredoxin-dependent enzyme of Synechocystis sp. PCC 6803 provides a framework for the interpretation of the functional properties of these enzymes, and highlights protein segments most likely involved in control and coordination of the partial catalytic activities of glutamate synthases, which take place at sites distant from each other in space. In this review, we focus on the current knowledge on structure-function relationships in glutamate synthases, and we discuss open questions on the mechanisms of control of the enzyme reaction and of electron transfer among the enzyme flavin cofactors and iron-sulfur clusters.