Project description:Methanol, being electron-rich and derivable from methane or CO2, is a potentially renewable one-carbon (C1) feedstock for microorganisms. Although the ribulose monophosphate (RuMP) cycle used by methylotrophs to assimilate methanol differs from the typical sugar metabolism by only three enzymes, turning a non-methylotrophic organism to a synthetic methylotroph that grows to a high cell density has been challenging. Here, we reprogrammed E. coli using metabolic robustness criteria followed by laboratory evolution to establish a strain that can utilize methanol as the sole carbon source efficiently. This synthetic methylotroph alleviated a heretofore uncharacterized hurdle, DNA-protein crosslinking (DPC), by insertion sequence (IS) mediated copy number variations (CNV) and balanced the metabolic flux by mutations. Being capable of growing at a rate comparable to natural methylotrophs in a wide-range of methanol concentrations, this synthetic methylotrophic strain illustrates genome editing and evolution for microbial tropism changes, and expands the scope of biological C1 conversion.

Project description:A synthetically methylotrophic Escherichia coli as a chassis for bioproduction from methanol

Project description:Reprogramming a non-methylotrophic industrial host, such as Saccharomyces cerevisiae, to a synthetic methylotroph reprents a huge challenge due to the complex regulation in yeast. Through TMC strategy together with ALE strategy, we completed a strict synthetic methylotrophic yeast that could use methanol as the sole carbon source. However, how cells respond to methanol and remodel cellular metabolic network on methanol were not clear. Therefore, genome-scale transcriptional analysis was performed to unravel the cellular reprograming mechanisms underlying the improved growth phenotype.

Project description:Volatile fatty acids found in effluents of the dark fermentation of biowastes can be used for mixotrophic growth of microalgae, improving productivity and reducing the cost of the feedstock. Microalgae can use the acetate in the effluents very well, but butyrate is poorly assimilated and can inhibit growth above 1 gC.L-1. The non-photosynthetic chlorophyte alga Polytomella sp. SAG 198.80 was found to be able to assimilate butyrate fast. To decipher the metabolic pathways implicated in butyrate assimilation, a large-scale differential proteomics study was developed comparing Polytomella sp. cells grown on acetate and butyrate at 1 gC.L-1.

Project description:A total gene expression approach was applied to study the methylotrophic nature of B. methanolicus by comparing the gene expression in bacteria grown methylotropic compared to non-methylotrophic. Genes of interest with different gene expression were quantified in the same RNA samples by real-time PCR, confirming the results found in the microarray experiment. Genes of special interest that are expressed higher when grown methylotrophic, were the RuMP pathway genes located on the pBM19. Bacillus methanolicus was grown in minimal media with either methanol or mannitol as carbon source. The experiment was preformed in triplicate, with bacterial cultures grown on 3 different days.

Project description:Methanol is considered as an interesting carbon source in biobased microbial production processes. As Corynebacterium glutamicum is an important host in industrial biotechnology, in particular for amino acid production, we performed studies on the response of this organism to methanol. C. glutamicum wild type was able to convert 13C-labeled methanol to 13CO2. Analysis of global gene expression in the presence of methanol revealed several genes of ethanol catabolism to be up-regulated, indicating that some of the corresponding enzymes are involved in methanol oxidation. Indeed, a mutant lacking the alcohol dehydrogenase gene adhA showed a 62% reduced methanol consumption rate, indicating that AdhA is mainly responsible for methanol oxidation to formaldehyde. Further studies revealed that oxidation of formaldehyde to formate is catalyzed predominantly by two enzymes, the acetaldehyde dehydrogenase Ald and the mycothiol-dependent formaldehyde dehydrogenase AdhE. The deletion mutants M-oM-^AM-^DaldM-oM-^AM-^DadhE and M-oM-^AM-^DaldM-oM-^AM-^DmshC were severely impaired in their ability to oxidize formaldehyde, but residual methanol oxidation to CO2 was still possible. The oxidation of formate to CO2 is catalyzed by the formate dehydrogenase FdhF recently identified by us. Similar to ethanol, methanol catabolism is subject to carbon catabolite repression in the presence of glucose and is dependent on the transcriptional regulator RamA, which was previously shown to be essential for expression of adhA and ald. In conclusion, we were able to show that C. glutamicum possesses an endogeneous pathway for methanol oxidation to CO2 and to identify the enzymes and a transcriptional regulator involved in this pathway. Whole-genome DNA microarray analyses were performed to monitor changes in the global gene expression of C. glutamicum wild type in response to the presence of methanol.

Project description:One carbon compounds like formate provide a promising and sustainable feedstock for microbial bioproduction of fuels and chemicals, as an alternative to the petro-chemical production industry. Growth of Escherichia coli on formate was recently achieved by introducing the reductive glycine pathway (rGlyP) into its genome, which is theoretically the most efficient aerobic formate assimilation pathway. While adaptive laboratory evolution was used to enhance the growth rate and biomass yield significantly, still the best performing formatotrophic E. coli strain did not approach the theoretical optimal biomass yield of the rGlyP. In this study, we investigated the metabolism of these previously engineered formatotrophic E. coli strains in order to elucidate why the biomass yield was sub-optimal and how it may be improved. Through a combination of metabolic modelling and proteomic analysis, we identified several potential metabolic bottlenecks and targets for expression tuning. This characterization study provides insights that can inform future rational engineering efforts to improve the growth of E. coli on formate.

Project description:RNA-Seq profiling of Methylomicrobium alcaliphilum strain 20Z grown in batch on methane. The RNA-Seq work is one part of a systems approach to characterizing metabolism of 20Z during growth on methane. We demonstrate that methane assimilation is coupled with a highly efficient pyrophosphate-mediated glycolytic pathway, which under O2 limitation participates in a novel form of fermentation-based methanotrophy. This surprising discovery suggests a novel mode of methane utilization in oxygen-limited environments, and opens new opportunities for a modular approach towards producing a variety of excreted chemical products using methane as a feedstock. Four replicates of batch growth

Project description:Thermophilic, methanol-degrading organism

Project description:Thermophilic, methanol-degrading organism