Project description:Clostridium ljungdahlii not only utilizes CO, but also H2 as energy source during autotrophic growth. And C. ljungdahlii also grows in fructose fermentation. In theory, fructose is a more energetically favourable energy source than syngas in the fermentation of C. ljungdahlii. However, C. ljungdahlii grows insufficiently in fructose and produces less acetate and ethanol, compared to syngas fermentation. In this study, C. ljungdahlii wild type and mutants were fermented on fructose. C. ljungdahlii produced less ethanol than the ΔadhE1 mutant and consumed less fructose. The ΔadhE1+2 mutant cannot grow in the syngas fermentation and produced less ethanol among the three strains. The results showed that aldehyde dehydrogenase inactivation led to efficient metabolism in C. ljungdahlii and the bifunctional aldehyde/alcohol dehydrogenases inactivation led to decrease metabolism. Thus, comparative transcriptomes among cells grown on fructose of three strains were performed to investigate gene expression profiles based on three biological replicates.

Project description:Gas fermentation is emerging as an economically attractive option for the sustainable production of fuels and chemicals from gaseous waste feedstocks. Clostridium autoethanogenum can use CO and/or CO2 + H2 as its sole carbon and energy sources. Fermentation of C. autoethanogenum is currently being deployed on a commercial scale for ethanol production. Expanding the product spectrum of acetogens will enhance the economics of gas fermentation. To achieve efficient heterologous product synthesis, limitations in redox and energy metabolism must be overcome. Here, we engineered and characterised at a systems-level, a recombinant poly-3-hydroxybutyrate (PHB)-producing strain of C. autoethanogenum. Cells were grown in CO-limited steady-state chemostats on two gas mixtures, one resembling syngas (20% H2) and the other steel mill off-gas (2% H2). Results were characterised using metabolomics and transcriptomics, and then integrated using a genome-scale metabolic model reconstruction. PHB-producing cells had an increased expression of the Rnf complex, suggesting energy limitations for heterologous production. Subsequent optimisation of the bioprocess led to a 12-fold increase in the cellular PHB content. The data suggest that the cellular redox state, rather than the acetyl-CoA pool, was limiting PHB production. Integration of the data into the genome-scale metabolic model showed that ATP availability limits PHB production. Altogether, the data presented here advances the fundamental understanding of heterologous product synthesis in gas-fermenting acetogens.

Project description:Genomes of Clostridium strains

Project description:To identify the mechanism of Microbial Influenced Corrosion (MIC) and the bacterial response toward corrosion, we conducted whole genome microarray expression profile. At log phase, the cell of Clostridium carboxidivorans using iron granule as an electron donor (corroding iron) was collected as a sample, and that of using syngas as an electron donor was collected as a control.

Project description:Background: The global demand for affordable carbon has never been stronger, and there is an imperative in many industrial processes to use waste streams to make products. Gas-fermenting acetogens offer a potential solution and several commercial gas fermentation plants are currently under construction. As energy limits acetogen metabolism, supply of H2 should diminish substrate loss to CO2 and facilitate production of reduced and energy-intensive products. However, the effects of H2 supply on CO-grown acetogens have yet to be experimentally quantified under controlled growth conditions. Results: Here, we quantify the effects of H2 supplementation by comparing growth on CO, syngas, and a high-H2 CO gas mix using chemostat cultures of Clostridium autoethanogenum. Cultures were characterised at the molecular level using metabolomics, proteomics, gas analysis, and a genome-scale metabolic model (GEM). CO-limited chemostats operated at two steady-state biomass concentrations facilitated co-utilisation of CO and H2. We show that H2 supply strongly impacts carbon distribution with a four-fold reduction in substrate loss as CO2 (61% vs. 17%) and a proportional increase of flux to ethanol (15% vs. 61%). Notably, H2 supplementation lowers the molar acetate/ethanol ratio by five-fold. At the molecular level, quantitative proteome analysis showed no obvious changes leading to these metabolic rearrangements suggesting the involvement of post-translational regulation. Metabolic modelling showed that H2 availability provided reducing power via H2 oxidation and saved redox as cells reduced all the CO2 to formate directly using H2 in the Wood-Ljungdahl pathway. Modelling further indicated that the methylene-THF reductase reaction was ferredoxin-reducing under all conditions. In combination with proteomics, modelling also showed that ethanol was synthesised through the acetaldehyde:ferredoxin oxidoreductase (AOR) activity. Conclusions: Our quantitative molecular analysis revealed that H2 drives rearrangements at several layers of metabolism and provides novel links between carbon, energy, and redox metabolism advancing our understanding of energy conservation in acetogens. We conclude that H2 supply can substantially increase the efficiency of gas fermentation and thus the feed gas composition can be considered an important factor in developing gas fermentation-based bioprocesses.

Project description:Genomic DNA of 61 strains of proteolytic Clostridium botulinum or Clostridium sporogenes was subjected to analysis by DNA microarray.

Project description:The purpose of this study was to determine the level of genomic content similarity among selected strains of Clostridium botuinum type F strains.

Project description:Clostridium ljungdahlii derives energy by acetogenesis as a lithotrophic pathway and as part of various organotrophic pathways. Its recently sequenced genome has made it possible to discover changes in gene expression that occur in different growth modes, from which strategies for biofuel production may be developed. C. ljungdahlii was grown with fructose as an organoheterotrophic substrate and also lithoautotrophically, either on syngas or with H2 as the electron donor and CO2 as the electron acceptor. RNA extracted from all three conditions was analyzed by hybridization to a microarray, and gene expression was compared quantitatively by RNA-Seq of C. ljungdahlii grown with fructose and with H2 and CO2. Results. Strongly upregulated (> 10-fold, p < 0.05) genes with both syngas and H2/CO2 encode enzymes that degrade aspartate and arginine through the urea cycle to control the release of ammonia from amino acids. Numerous genes for uptake and degradation of peptides and amino acids, response to sulfur starvation, and molybdopterin-dependent pathways were also significantly (> 2-fold, p < 0.05) upregulated, along with three potentially NADPH-producing pathways for which the key metabolites are (S)-malate, ornithine and 6-phospho-D-gluconate. Upregulation of genes implicated in quorum sensing, sporulation and cell wall remodeling suggests a global and multicellular response to lithoautotrophic conditions. With syngas, (R)-lactate dehydrogenase and associated electron transfer flavoproteins were upregulated, representing a route of electron transfer from ferredoxin to NAD that is independent of the proton-translocating Rnf complex. With H2/CO2, a flavodoxin and histidine biosynthesis enzymes were upregulated. Genes for degradation of purine bases entering the cell by facilitated diffusion were upregulated in lithotrophic cells, whereas genes for degradation of adenine or adenosine derivatives entering by active transport were significantly (2-fold, p < 0.05) downregulated. The most downregulated genes, after those specific to fructose metabolism, encode enzymes of pyrimidine and purine biosynthesis, arginine fermentation to ornithine, threonine biosynthesis and phosphate uptake. Genes for biogenesis of an intracytoplasmic microcompartment were downregulated, within which (S)-1,2-propanediol dehydratase and other enzymes may dispose of methylglyoxal, a toxic byproduct of glycolysis, as 1-propanol. Several redox-active proteins, both cytoplasmic and membrane-associated, and predicted cell surface proteins were identified as differentially regulated. Conclusion. The transcriptomic profiles of C. ljungdahlii in lithoautotrophic and organoheterotrophic growth modes indicate large-scale physiological and metabolic differences, observations that may guide the production of biofuels and commodity chemicals with this species.

Project description:This SuperSeries is composed of the following subset Series: GSE12358: Clostridium beijerinckii NCIMB 8052 wild-type fermentation time course GSE12359: Clostridium beijerinckii BA101 mutant fermentation time course Refer to individual Series

Project description:Modeling guided pathway engineering for isopropanol production in Clostridium sp.