Project description:Industrial bioethanol production may involve a low pH environment,improving the tolerance of S. cerevisiae to a low pH environment caused by inorganic acids may be of industrial importance to control bacterial contamination, increase ethanol yield and reduce production cost. Through analysis the transcriptomic data of Saccharomyces cerevisiae with different ploidy under low pH stress, we hope to find the tolerance mechanism of Saccharomyces cerevisiae to low pH.

Project description:Physiological responses of Saccharomyces cerevisiae to industrially relevant conditions: slow growth, low pH and high CO2 levels

Project description:Saccharomyces cerevisiae has become a popular host for production of non-native compounds. The metabolic pathways involved generally require a net input of energy. To maximize the ATP yield on sugar in S. cerevisiae, industrial cultivation is typically performed in aerobic, sugar-limited fed-batch reactors which, due to constraints in oxygen transfer and cooling capacities, have to be operated at low specific growth rates. Because intracellular levels of key metabolites and cellular energy status are growth-rate dependent, slow growth can significantly affect biomass-specific productivity. Using an engineered Saccharomyces cerevisiae strain expressing a heterologous pathway for resveratrol production as a model energy-requiring product, the impact of specific growth rate on yeast physiology and productivity was investigated in aerobic, glucose-limited chemostat cultures. Stoichiometric analysis revealed that de novo resveratrol production from glucose requires a net input of 2 moles of ATP per mole of produced resveratrol. The biomass-specific production rate of resveratrol showed a strong positive correlation with the specific growth rate. At low growth rates, a substantial fraction of the carbon source was invested in cellular maintenance-energy requirements (e.g., 27% at 0.03 h-1). This distribution of resources was unaffected by resveratrol production. Formation of the by-products coumaric, phloretic and cinnamic acid had no detectable effect on maintenance energy requirement and yeast physiology in the chemostats. Expression of the heterologous pathway led to marked differences in transcript levels in the resveratrol-producing strain, including increased expression levels of genes involved in pathways for precursor supply (e.g., ARO7 and ARO9 involved in phenylalanine biosynthesis). The observed strong differential expression of many glucose-responsive genes in the resveratrol producer as compared to a congenic reference strain could be explained from higher residual glucose concentrations and higher relative growth rates in cultures of the resveratrol producer. De novo resveratrol production by engineered S. cerevisiae is an energy demanding process. Resveratrol production by an engineered strain exhibited a strong correlation with specific growth rate. Since industrial production in fed-batch reactors typically involves low specific growth rates, this study emphasizes the need for uncoupling growth and product formation via energy-requiring pathways. The goal of the present study is to investigate the impact of specific growth rate on biomass-specific productivity, product yield, by-product formation and host strain physiology of an S. cerevisiae strain that was previously engineered for de novo production of resveratrol from glucose. To this end, (by)product formation, physiology and transcriptome were analysed in steady-state, glucose-limited chemostat cultures grown at different dilution rates.

Project description:Saccharomyces cerevisiae is an excellent microorganism for industrial succinic acid production, but high succinic acid concentration will inhibit the growth of Saccharomyces cerevisiae then reduce the production of succinic acid. Through analysis the transcriptomic data of Saccharomyces cerevisiae with different genetic backgrounds under different succinic acid stress, we hope to find the response mechanism of Saccharomyces cerevisiae to succinic acid.

Project description:Second fermentation in a bottle supposes such specific conditions that undergo yeasts to a set of stress situations like high ethanol, low nitrogen, low pH or sub-optimal temperature. Also, yeast have to grow until 1 or 2 generations and ferment all sugar available while they resist increasing CO2 pressure produced along with fermentation. Because of this, yeast for second fermentation must be selected depending on different technological criteria such as resistance to ethanol, pressure, high flocculation capacity, and good autolytic and foaming properties. All of these stress factors appear sequentially or simultaneously, and their superposition could amplify their inhibitory effects over yeast growth. Considering all of the above, it has supposed interesting to characterize the adaptive response of commercial yeast strain EC1118 during second-fermentation experiments under oenological/industrial conditions by transcriptomic profiling. We have pointed ethanol as the most relevant environmental condition in the induction of genes involved in respiratory metabolism, oxidative stress, autophagy, vacuolar and peroxisomal function, after comparison between time-course transcriptomic analysis in alcoholic fermentation and transcriptomic profiling in second fermentation. Other examples of parallelism include overexpression of cellular homeostasis and sugar metabolism genes. Finally, this study brings out the role of low-temperature on yeast physiology during second-fermentation. S. cerevisiae EC1118 pre-adapted to ethanol cells and sucrose (20 g/L) were added to 20 L of base wine (Cavas Freixenet, Sant Sadurní D’Anoia, Spain). Complete volume was bottled with 350 mL each one. All were sealed and incubated in static conditions at 16ºC for approximately 40 days after tirage. Three samples were taken during the process for transcriptional study of the physiological adaptation of yeast cells to industrial second fermentation conditions. A sample corresponding to exponential-growth phase under unstressed conditions (in YPD at 28ºC) was used as an external reference. Three timepoints from second-fermentation were monitored and three biological replicates from each timepoint were analyzed.

Project description:Aim: Analyse inhibitory effects of galacturonic acid, an important constituent of plant biomass hydrolysates, on growing and starving cultures of Saccharomyces cerevisiae CEN.PK113-7D. Method & Results: Biomass yields in aerobic and anaerobic glucose-limited chemostat cultures (pH 3.5) were reduced by 25 and 10%, respectively, upon addition of 10 g∙l-1 galacturonic acid. Genes previously reported to show a transcriptional response to other organic acids were overrepresented in a set of galacturonic-acid responsive genes identified by microarray analysis. These results suggested that galacturonic acid causes weak-acid uncoupling of the yeast plasma membrane pH gradient. Consistent with this hypothesis, galacturonate-accelerated loss of viability in starving cell suspensions was strongly pH dependent. Loss of viability was much slower in a strain in which all HXT (hexose transporter) genes were deleted. Moreover, deletion of HXT genes alleviated growth inhibition on ethanol observed at galacturonic acid concentrations of 10 g∙l-1 and above. Conclusions: At low pH, galacturonic acid negatively affects the physiology of S. cerevisiae. Reduced sensitivity of hexose-transporter mutants indicated that one or more HXT transporters are involved in transport of galacturonic acid. Significance and Impact: This study shows that galacturonic acid toxicity should be taken into account in process development for yeast-based fermentative conversion of pectin-rich feedstocks such as sugar beet pulp and citrus peel. Involvement of hexose transporters in galacturonic acid toxicity provides leads for improving tolerance. To investigate the impact of galacturonic acid on S. cerevisiae, a DNA microarray-based transcriptome analysis was performed on aerobic, glucose-limited chemostat cultures grown in the presence and absence of 10 g∙l-1 galacturonic acid at pH3.5.

Project description:Aim: Analyse inhibitory effects of galacturonic acid, an important constituent of plant biomass hydrolysates, on growing and starving cultures of Saccharomyces cerevisiae CEN.PK113-7D. Method & Results: Biomass yields in aerobic and anaerobic glucose-limited chemostat cultures (pH 3.5) were reduced by 25 and 10%, respectively, upon addition of 10 g∙l-1 galacturonic acid. Genes previously reported to show a transcriptional response to other organic acids were overrepresented in a set of galacturonic-acid responsive genes identified by microarray analysis. These results suggested that galacturonic acid causes weak-acid uncoupling of the yeast plasma membrane pH gradient. Consistent with this hypothesis, galacturonate-accelerated loss of viability in starving cell suspensions was strongly pH dependent. Loss of viability was much slower in a strain in which all HXT (hexose transporter) genes were deleted. Moreover, deletion of HXT genes alleviated growth inhibition on ethanol observed at galacturonic acid concentrations of 10 g∙l-1 and above. Conclusions: At low pH, galacturonic acid negatively affects the physiology of S. cerevisiae. Reduced sensitivity of hexose-transporter mutants indicated that one or more HXT transporters are involved in transport of galacturonic acid. Significance and Impact: This study shows that galacturonic acid toxicity should be taken into account in process development for yeast-based fermentative conversion of pectin-rich feedstocks such as sugar beet pulp and citrus peel. Involvement of hexose transporters in galacturonic acid toxicity provides leads for improving tolerance.

Project description:Our paper presents the results of a study in which we used Illumina RNA-Seq (i.e. transcriptomics) and high-CO2 nutrient limitation experiments to examine transcriptional variation of iron-limited, phosphorus-limited, and iron-phosphorus co-limited cultures following long-term (~7 years) low- (380 µatm CO2) and high-CO2 (750 µatm CO2) selection. Hence, we describe the molecular physiology of the globally-significant, biogeochemically-critical marine cyanobacterium Trichodesmium.

Project description:Saccharomyces cerevisiae has become a popular host for production of non-native compounds. The metabolic pathways involved generally require a net input of energy. To maximize the ATP yield on sugar in S. cerevisiae, industrial cultivation is typically performed in aerobic, sugar-limited fed-batch reactors which, due to constraints in oxygen transfer and cooling capacities, have to be operated at low specific growth rates. Because intracellular levels of key metabolites and cellular energy status are growth-rate dependent, slow growth can significantly affect biomass-specific productivity. Using an engineered Saccharomyces cerevisiae strain expressing a heterologous pathway for resveratrol production as a model energy-requiring product, the impact of specific growth rate on yeast physiology and productivity was investigated in aerobic, glucose-limited chemostat cultures. Stoichiometric analysis revealed that de novo resveratrol production from glucose requires a net input of 2 moles of ATP per mole of produced resveratrol. The biomass-specific production rate of resveratrol showed a strong positive correlation with the specific growth rate. At low growth rates, a substantial fraction of the carbon source was invested in cellular maintenance-energy requirements (e.g., 27% at 0.03 h-1). This distribution of resources was unaffected by resveratrol production. Formation of the by-products coumaric, phloretic and cinnamic acid had no detectable effect on maintenance energy requirement and yeast physiology in the chemostats. Expression of the heterologous pathway led to marked differences in transcript levels in the resveratrol-producing strain, including increased expression levels of genes involved in pathways for precursor supply (e.g., ARO7 and ARO9 involved in phenylalanine biosynthesis). The observed strong differential expression of many glucose-responsive genes in the resveratrol producer as compared to a congenic reference strain could be explained from higher residual glucose concentrations and higher relative growth rates in cultures of the resveratrol producer. De novo resveratrol production by engineered S. cerevisiae is an energy demanding process. Resveratrol production by an engineered strain exhibited a strong correlation with specific growth rate. Since industrial production in fed-batch reactors typically involves low specific growth rates, this study emphasizes the need for uncoupling growth and product formation via energy-requiring pathways.

Project description:Shelled pteropods play key roles in the global carbon cycle and foodwebs of various ecosystems. Their thin external shell is extremely sensitive to changes in pH and shell dissolution has already been observed in areas where aragonite saturation state is ~ 1. A decline in pteropod abundance has the potential to disrupt trophic networks and directly impact commercial fisheries. Therefore it is crucial to understand how pteropods will be affected by global environmental change, particularly ocean acidification. In the present study, physiological and molecular approaches were used to investigate the response of the Mediterranean pteropod, Heliconoides inflatus, to pH values projected for 2100 under a moderate emissions trajectory (RCP6.0). Pteropods were subjected to pHT 7.9 for 3d and gene expression levels, calcification and respiration rates measured relative to pHT 8.1 controls. Gross calcification decreased markedly under low pH conditions, while genes potentially involved in calcification were up-regulated, reflecting the inability of pteropods to maintain calcification rates. Gene expression data imply that under low pH conditions both metabolic processes and protein synthesis may be compromised, while genes involved in acid-base regulation were up-regulated. A large number of genes related to nervous system structure and function were also up-regulated in the low pH treatment, including a GABAA receptor subunit. This is particularly interesting because GABAA receptor disturbances, leading to altered behaviour, have been documented in several other marine animals after exposure to elevated CO2. The up-regulation of many genes involved in nervous system function suggests that, in addition to its impacts on other aspects of biology, exposure to low pH could have major effects on pteropod behavior. This study not only illustrates the utility of combining physiological and molecular approaches, but also highlights the desirability of including behavioural analyses in studies aimed at understanding the impacts of low pH on marine animals.