Methanomassiliicoccus luminyensis was isolated from the human gut, and requires H 2 and methanol or methylamines to produce methane. The organism lacks cytochromes, indicating that it cannot couple membranebound electron transfer reactions with extrusion of H + or Na + ions using known methanogenic pathways. Furthermore, M. luminyensis contains a soluble hydrogenase/heterodisulfide reductase complex (MvhAGD/ HdrABC) as found in obligate hydrogenotrophic methanogens, but the energy-conserving methyltransferase (MtrA-H) is absent. Thus, the question arises as to how this species synthesizes ATP. We present evidence that M. luminyensis uses two types of heterodisulfide reductases (HdrABC and HdrD) in a novel process for energy conservation. Quantitative RT-PCR studies revealed that genes encoding these heterodisulfide reductases showed high expression levels. Other genes with high transcript abundance were fpoA (part of the operon encoding the 'headless' F 420 H 2 dehydrogenase) and atpB (part of the operon encoding the A 1 A o ATP synthase). High activities of the soluble heterodisulfide reductase HdrABC and the hydrogenase MvhADG were found in the cytoplasm of M. luminyensis. Also, heterologously produced HdrD was able to reduce CoM-S-S-CoB using reduced methylviologen as an electron donor. We propose that membrane-bound electron transfer is based on conversion of two molecules of methanol and concurrent formation of two molecules of the heterodisulfide CoM-S-S-CoB. First the HdrABC/MvhADG complex catalyzes the H 2 -dependent reduction of CoM-S-S-CoB and formation of reduced ferredoxin. In a second cycle, reduced ferredoxin is oxidized by the 'headless' F 420 H 2 dehydrogenase, thereby translocating up to 4 H + across the membrane, and electrons are channeled to HdrD for reduction of the second heterodisulfide.
bIn the present study, we compared the proteome response of Allochromatium vinosum when growing photoautotrophically in the presence of sulfide, thiosulfate, and elemental sulfur with the proteome response when the organism was growing photoheterotrophically on malate. Applying tandem mass tag analysis as well as two-dimensional (2D) PAGE, we detected 1,955 of the 3,302 predicted proteins by identification of at least two peptides (59.2%) and quantified 1,848 of the identified proteins. Altered relative protein amounts (>1.5-fold) were observed for 385 proteins, corresponding to 20.8% of the quantified A. vinosum proteome. A significant number of the proteins exhibiting strongly enhanced relative protein levels in the presence of reduced sulfur compounds are well documented essential players during oxidative sulfur metabolism, e.g., the dissimilatory sulfite reductase DsrAB. Changes in protein levels generally matched those observed for the respective relative mRNA levels in a previous study and allowed identification of new genes/proteins participating in oxidative sulfur metabolism. One gene cluster (hyd; Alvin_2036-Alvin_2040) and one hypothetical protein (Alvin_2107) exhibiting strong responses on both the transcriptome and proteome levels were chosen for gene inactivation and phenotypic analyses of the respective mutant strains, which verified the importance of the so-called Isp hydrogenase supercomplex for efficient oxidation of sulfide and a crucial role of Alvin_2107 for the oxidation of sulfur stored in sulfur globules to sulfite. In addition, we analyzed the sulfur globule proteome and identified a new sulfur globule protein (SgpD; Alvin_2515).
DNA sequence analysis of the human gut revealed the presence a seventh order of methanogens referred to as Methanomassiliicoccales. Methanomassiliicoccus luminyensis is the only member of this order that grows in pure culture. Here, we show that the organism has a doubling time of 1.8 d with methanol + H2 and a growth yield of 2.4 g dry weight/mol CH4. M. luminyensis also uses methylamines + H2 (monomethylamine, dimethylamine, and trimethylamine) with doubling times of 2.1–2.3 d. Similar cell yields were obtained with equimolar concentrations of methanol and methylamines with respect to their methyl group contents. The transcript levels of genes encoding proteins involved in substrate utilization indicated increased amounts of mRNA from the mtaBC2 gene cluster in methanol-grown cells. When methylamines were used as substrates, mRNA of the mtb/mtt operon and of the mtmBC1 cluster were found in high abundance. The transcript level of mtaC2 was almost identical in methanol- and methylamine-grown cells, indicating that genes for methanol utilization were constitutively expressed in high amounts. The same observation was made with resting cells where methanol always yielded the highest CH4 production rate independently from the growth substrate. Hence, M. luminyensis is adapted to habitats that provide methanol + H2 as substrates.
Methanomassiliicoccus luminyensis was originally isolated from human feces and belongs to the seventh order of methanogens, the Methanomassiliicoccales, which are only distantly related to other methanogenic archaea. The organism forms methane from the reduction of methylamines or methanol using molecular hydrogen as reductant. The energy‐conserving system in M. luminyensis is unique and the enzymes involved in this process are not found in this combination in members of the other methanogenic orders. In this context our central question was how the organism is able to generate ATP. Energy transduction was dependent on a membrane‐bound ferredoxin: heterodisulfide oxidoreductase composed of reduced ferredoxin as an electron donor, at least one protein in the membrane fraction and the heterodisulfide reductase HdrD, which reduced the electron acceptor CoM‐S‐S‐CoB. Electron transfer of this respiratory chain proceeded with a rate of 145 nmol reduced heterodisulfide min−1·mg−1 membrane protein. Methanomassiliicoccus luminyensis is the first example of a methanogenic archaeon that does not require Na+ ions for energy conservation. Only protons were used as coupling ions for the generation of the electrochemical ion gradient. The membrane‐bound F420H2:phenazine oxidoreductase complex (without the electron input module FpoF) probably catalyzed the oxidation of reduced ferredoxin and potentially acted as primary proton pump in this electron transport system. In summary, the energy‐conserving system of M. luminyensis possesses features found in the pathways of hydrogenotrophic and methylotrophic/aceticlastic methanogenesis. Consequently, the composition of the enzymes involved in ion translocation across the cytoplasmic membrane is different from all other methanogenic archaea.
Aceticlastic methanogens metabolize acetate to methane and carbon dioxide. The central metabolism and the electron transport chains of these organisms have already been investigated. However, no particular attention has been paid to the mechanism by which acetate enters the archaeal cell. In our study we investigated Methanosarcina mazei acetate kinase (Ack) and the acetate uptake reaction. At a concentration of 2 mM acetate, the Ack activity in cell extract of M. mazei was not limiting for the methane formation rate. Instead, the methanogenesis rate was controlled by the substrate concentration and increased 10-fold at 10 mM acetate. Subsequently, we analyzed the involvement of the putative acetate permease MM_0903 using a corresponding deletion mutant. At 2 mM acetate, only 25% of the wild-type methane formation rate was measured in the mutant. This indicated that the supply of acetate to Ack was limiting the rate of methane formation. Moreover, the mutant revealed an increased acetate kinase activity compared with the wild type. These results show for the first time that an acetate transporter is involved in aceticlastic methanogenesis and may be an important factor in the acetate threshold concentration for methanogenesis of Methanosarcina spp.
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