Project description:Scaling up the functioning of synthetic circuits from microplates to bioreactors is far from trivial to achieve. We here test the scalability performance of a previously developed growth switch for increasing product yields in bacteria, based on external control of RNA polymerase expression. We show that, in liter-scale bioreactors operating in fed-batch mode, growth-arrested Escherichia coli cells are able to convert glucose to glycerol at an increased yield. A multi-omics quantification of the physiology of the cells shows that apart from acetate production, few metabolic side-effects occur, while a number of specific responses to growth slow-down and growth arrest are launched on the transcriptional level. These responses include the downregulation of genes involved in growth-associated processes, such as amino acid and nucleotide metabolism and translation, and the upregulation of heat shock genes. Interestingly, these transcriptional responses are buffered on the proteomic level, probably due to the strong decrease of the total mRNA concentration after the diminution of transcriptional activity and the absence of growth dilution of proteins. This transforms the growth-arrested cells in “bags of proteins“ with a functioning metabolism. More generally, the analysis shows that physiological characterization of bacterial cells hosting a synthetic circuit may reveal complex patterns of adaptation on different time-scales, dynamically interacting with the bioreactor environment.

Project description:Efficient microbial conversion of lignocellulosic hydrolysates to biofuels is a key barrier to the economically viable deployment of lignocellulosic biofuels. A chief contributor to this barrier is the impact on microbial processes and energy metabolism of lignocellulose-derived inhibitors, including phenolic carboxylates, phenolic amides (for ammonia-pretreated biomass), phenolic aldehydes, and furfurals. To understand the bacterial pathways induced by inhibitors present in ammonia-pretreated biomass hydrolysates, which are less well studied than acid-pretreated biomass hydrolysates, we developed and exploited synthetic mimics of ammonia-pretreated corn stover hydrolysate (ACSH). To determine regulatory responses to the inhibitors normally present in ACSH, we measured transcript and protein levels in an Escherichia coli ethanologen using RNA-seq and quantitative proteomics during fermentation to ethanol of synthetic hydrolysates containing or lacking the inhibitors. Our study identified four major regulators mediating these responses, the MarA/SoxS/Rob network, AaeR, FrmR, and YqhC. Induction of these regulons was correlated with a reduced rate of ethanol production, buildup of pyruvate, depletion of ATP and NAD(P)H, and an inhibition of xylose conversion. The aromatic aldehyde inhibitor 5M-bM-^@M-^Qhydroxymethylfurfural appeared to be reduced to its alcohol form by the ethanologen during fermentation, whereas phenolic acid and amide inhibitors were not metabolized. Together, our findings establish that the major regulatory responses to lignocellulose-derived inhibitors are mediated by transcriptional rather than translational regulators, suggest that energy consumed for inhibitor efflux and detoxification may limit biofuel production, and identify a network of regulators for future synthetic biology efforts. E.coli ethanologen strain GLBRCE1 was grown in 4 media, AFEX corn stover hydrolysate (ACSH), synthetic hydrolysate (SynH), synthetic hydrolysate with added lignotoxins (SynH_LT), or synthetic hydrolysate containing acid or amide lignotoxins only (SynH_Acids_Amides). Fermentations were carried out in 3 L bioreactors (Applikon Biotechnology) containing 2.45 L of ACSH or SynH media, and cultures were diluted into ACSH or SynH with initial OD at 0.2, grown anaerobically overnight, and then inoculated into bioreactors to a starting OD600 of 0.2. Two biological replicates (independent cultures) were grown in each medium. RNA samples were obtained at 6 time points, corresponding to early exponential (Exp1), Mid-exponential (Exp2), Late-exponential (Exp3), transitional (Trans), stationary (Stat1) and late stationary (Stat2) growth phases.

Project description:Efficient microbial conversion of lignocellulosic hydrolysates to biofuels is a key barrier to the economically viable deployment of lignocellulosic biofuels. A chief contributor to this barrier is the impact on microbial processes and energy metabolism of lignocellulose-derived inhibitors, including phenolic carboxylates, phenolic amides (for ammonia-pretreated biomass), phenolic aldehydes, and furfurals. To understand the bacterial pathways induced by inhibitors present in ammonia-pretreated biomass hydrolysates, which are less well studied than acid-pretreated biomass hydrolysates, we developed and exploited synthetic mimics of ammonia-pretreated corn stover hydrolysate (ACSH). To determine regulatory responses to the inhibitors normally present in ACSH, we measured transcript and protein levels in an Escherichia coli ethanologen using RNA-seq and quantitative proteomics during fermentation to ethanol of synthetic hydrolysates containing or lacking the inhibitors. Our study identified four major regulators mediating these responses, the MarA/SoxS/Rob network, AaeR, FrmR, and YqhC. Induction of these regulons was correlated with a reduced rate of ethanol production, buildup of pyruvate, depletion of ATP and NAD(P)H, and an inhibition of xylose conversion. The aromatic aldehyde inhibitor 5M-bM-^@M-^Qhydroxymethylfurfural appeared to be reduced to its alcohol form by the ethanologen during fermentation, whereas phenolic acid and amide inhibitors were not metabolized. Together, our findings establish that the major regulatory responses to lignocellulose-derived inhibitors are mediated by transcriptional rather than translational regulators, suggest that energy consumed for inhibitor efflux and detoxification may limit biofuel production, and identify a network of regulators for future synthetic biology efforts. E.coli ethanologen strain GLBRCE1 or GLBRCE1 lacking the plasmid-borne PET cassette (GLBRCE1_pBBR) was grown in AFEX corn stover hydrolysate (ACSH) Fermentations were carried out in 3 L bioreactors (Applikon Biotechnology) containing 2.45 L of ACSH, and cultures were diluted into ACSH with initial OD at 0.2, grown anaerobically overnight, and then inoculated into bioreactors to a starting OD600 of 0.2. One biological replicate was grown in each medium. RNA samples were obtained at 3 time points, corresponding to exponential (Exp), transitional (Trans), and stationary (Stat) growth phases.

Project description:Efficient microbial conversion of lignocellulosic hydrolysates to biofuels is a key barrier to the economically viable deployment of lignocellulosic biofuels. A chief contributor to this barrier is the impact on microbial processes and energy metabolism of lignocellulose-derived inhibitors, including phenolic carboxylates, phenolic amides (for ammonia-pretreated biomass), phenolic aldehydes, and furfurals. To understand the bacterial pathways induced by inhibitors present in ammonia-pretreated biomass hydrolysates, which are less well studied than acid-pretreated biomass hydrolysates, we developed and exploited synthetic mimics of ammonia-pretreated corn stover hydrolysate (ACSH). To determine regulatory responses to the inhibitors normally present in ACSH, we measured transcript and protein levels in an Escherichia coli ethanologen using RNA-seq and quantitative proteomics during fermentation to ethanol of synthetic hydrolysates containing or lacking the inhibitors. Our study identified four major regulators mediating these responses, the MarA/SoxS/Rob network, AaeR, FrmR, and YqhC. Induction of these regulons was correlated with a reduced rate of ethanol production, buildup of pyruvate, depletion of ATP and NAD(P)H, and an inhibition of xylose conversion. The aromatic aldehyde inhibitor 5M-bM-^@M-^Qhydroxymethylfurfural appeared to be reduced to its alcohol form by the ethanologen during fermentation, whereas phenolic acid and amide inhibitors were not metabolized. Together, our findings establish that the major regulatory responses to lignocellulose-derived inhibitors are mediated by transcriptional rather than translational regulators, suggest that energy consumed for inhibitor efflux and detoxification may limit biofuel production, and identify a network of regulators for future synthetic biology efforts. Fermentations were carried out in 0.5L bioreactors (Sartorius) containing 0.3L of SynH, SynH lacking osmoprotectants, SynH+LT, or SynH lacking osmoprotectants but containing lignotoxins and cultures were diluted into SynH with initial OD at 0.2, grown anaerobically overnight, and then inoculated into bioreactors to a starting OD600 of 0.2. Two biological replicates (independent cultures) were grown in each medium. RNA samples were obtained at 4 time points, corresponding to exponential (Exp), transitional (Trans), early stationary (Stat1), and late stationary (Stat2) growth phases.

Project description:Efficient microbial conversion of lignocellulosic hydrolysates to biofuels is a key barrier to the economically viable deployment of lignocellulosic biofuels. A chief contributor to this barrier is the impact on microbial processes and energy metabolism of lignocellulose-derived inhibitors, including phenolic carboxylates, phenolic amides (for ammonia-pretreated biomass), phenolic aldehydes, and furfurals. To understand the bacterial pathways induced by inhibitors present in ammonia-pretreated biomass hydrolysates, which are less well studied than acid-pretreated biomass hydrolysates, we developed and exploited synthetic mimics of ammonia-pretreated corn stover hydrolysate (ACSH). To determine regulatory responses to the inhibitors normally present in ACSH, we measured transcript and protein levels in an Escherichia coli ethanologen using RNA-seq and quantitative proteomics during fermentation to ethanol of synthetic hydrolysates containing or lacking the inhibitors. Our study identified four major regulators mediating these responses, the MarA/SoxS/Rob network, AaeR, FrmR, and YqhC. Induction of these regulons was correlated with a reduced rate of ethanol production, buildup of pyruvate, depletion of ATP and NAD(P)H, and an inhibition of xylose conversion. The aromatic aldehyde inhibitor 5M-bM-^@M-^Qhydroxymethylfurfural appeared to be reduced to its alcohol form by the ethanologen during fermentation, whereas phenolic acid and amide inhibitors were not metabolized. Together, our findings establish that the major regulatory responses to lignocellulose-derived inhibitors are mediated by transcriptional rather than translational regulators, suggest that energy consumed for inhibitor efflux and detoxification may limit biofuel production, and identify a network of regulators for future synthetic biology efforts. E.coli ethanologen strain GLBRCE1 was grown in 3 media, AFEX corn stover hydrolysate (ACSH), synthetic hydrolysate (SynH) and syntetic hydrolysate with added lignotoxins (SynH_LT). Fermentations were carried out in 3 L bioreactors (Applikon Biotechnology) containing 2.45 L of ACSH or SynH media, and cultures were diluted into ACSH or SynH with initial OD at 0.2, grown anaerobically overnight, and then inoculated into bioreactors to a starting OD600 of 0.2. 3 biological replicates (independent cultures) were grown in each medium. RNA samples were obtained at 4 time points, corresponding to exponential (Exp), transitional (Trans), stationary (Stat1) and late stationary (Stat2) growth phases.

Project description:Efficient microbial conversion of lignocellulosic hydrolysates to biofuels is a key barrier to the economically viable deployment of lignocellulosic biofuels. A chief contributor to this barrier is the impact on microbial processes and energy metabolism of lignocellulose-derived inhibitors, including phenolic carboxylates, phenolic amides (for ammonia-pretreated biomass), phenolic aldehydes, and furfurals. To understand the bacterial pathways induced by inhibitors present in ammonia-pretreated biomass hydrolysates, which are less well studied than acid-pretreated biomass hydrolysates, we developed and exploited synthetic mimics of ammonia-pretreated corn stover hydrolysate (ACSH). To determine regulatory responses to the inhibitors normally present in ACSH, we measured transcript and protein levels in an Escherichia coli ethanologen using RNA-seq and quantitative proteomics during fermentation to ethanol of synthetic hydrolysates containing or lacking the inhibitors. Our study identified four major regulators mediating these responses, the MarA/SoxS/Rob network, AaeR, FrmR, and YqhC. Induction of these regulons was correlated with a reduced rate of ethanol production, buildup of pyruvate, depletion of ATP and NAD(P)H, and an inhibition of xylose conversion. The aromatic aldehyde inhibitor 5M-bM-^@M-^Qhydroxymethylfurfural appeared to be reduced to its alcohol form by the ethanologen during fermentation, whereas phenolic acid and amide inhibitors were not metabolized. Together, our findings establish that the major regulatory responses to lignocellulose-derived inhibitors are mediated by transcriptional rather than translational regulators, suggest that energy consumed for inhibitor efflux and detoxification may limit biofuel production, and identify a network of regulators for future synthetic biology efforts. E.coli ethanologen strain GLBRCE1 was grown in 3 media, AFEX corn stover hydrolysate (ACSH), synthetic hydrolysate (SynH) and syntetic hydrolysate with added lignotoxins (SynH_LT). Fermentations were carried out in 3 L bioreactors (Applikon Biotechnology) containing 2.45 L of ACSH or SynH media, and cultures were diluted into ACSH or SynH with initial OD at 0.2, grown anaerobically overnight, and then inoculated into bioreactors to a starting OD600 of 0.2. 3 biological replicates (independent cultures) were grown in each medium. RNA samples were obtained at 4 time points, corresponding to exponential (Exp), transitional (Trans), stationary (Stat1) and late stationary (Stat2) growth phases.

Project description:Examining the transcriptome of growth arrested keratinocytes

Project description:We have pioneered human pluripotent stem cell (hPSC) manufacturing in stirred suspension bioreactors. Cell therapies require large numbers of quality-controlled hPSCs yet technologies are limited in their ability to efficiently grow and scale clinically-viable hPSCs. We report here that naive hPSCs exhibit superior growth in suspension bioreactors compared to their primed counterpart. Naive hPSCs exhibited a shorter lag phase, and grew into more uniform, homogenous aggregates. Compared to static culture, gene expression analyses revealed that the bioreactor environment promoted the upregulation of naïve- and downregulation of primed-associated transcripts in both primed and naive hPSCs. Bioreactor-cultured naive hPSCs similarly showed more hypomethylated DNA and less primed hPSC-associated surface protein marker compared to statically-cultured naive hPSCs. Gene expression, epigenetic, and cell surface protein marker analyses all suggest that the bioreactor environment promotes the transition from primed-to-naive pluripotent state. Our research shows that reprogramming conventional hPSCs to the naive pluripotent state enhances hPSC manufacturing.

Project description:Global Gene expression analysis of Saccharomyces cerevisiae grown in micro-scale sirred bioreactors equipped with real-time measurements of growth kinetics and humidity control Keywords: other

Project description:Polyamines are absolutely required for cell growth and proliferation. While polyamine depletion results in reversible cell cycle arrest, the actual mechanism of growth inhibition is still obscure. This experiment aimed at determining the cellular processes elicited by re-addition of polyamines to polyamine-depleted (growth arrested) cells. In order to reveal the general transcriptional responses to polyamine re-addition, NIH3T3 mouse fibroblasts were first treated with 1mM L-Difluoromethylornithine (DFMO) for 96 hours and then growth stimulated by spermidine. Cells were collected at 0, 30, 60, 120, 240, 360, 480 and 600 min upon addition of spermidine to polyamine-depleted (growth arrested) cells. Total RNA was isolated, reverse-transcribed, fragmented, labeled and hybridized to Affymetrix MoGene 1.0 ST DNA array.