Project description:Respiratory ATP-synthesis is at present the only known mechanism for ATP synthesis in Mtb. This makes Mtb particularly vulnerable to inhibition of respiratory ATP synthase inhibitors such as TMC207, a novel compound for treatment of tuberculosis. We now provide first evidence that Mtb possesses a pathway that is fermentative in nature that could compensate lack of respiratory ATP synthesis. We identified acetate as a fermentation product in Mtb. Production of acetate was mediated by phosphotransacetylase (Pta) and acetate kinase (AckA). In acetate fermenting Mtb cultures, ATP levels remained stable despite inhibition of respiratory ATP synthase. Deletion of the PtaAckA pathway in Mtb decreased ATP content and impaired survival. This study provides evidence that in Mtb substrate level phosphorylation can compensate lack of oxidative phosphorylation, and thus facilitates survival of Mtb in the absence of respiration. Acetate fermentation contributes to adaptation to respiration-limiting conditions, and plays an important role in the emerging field of fermentative metabolism of Mtb.

Project description:Aerobic Escherichia coli growth at restricted iron concentrations (≤ 1.75 ± 0.04 mM) is characterized by lower biomass yield, higher acetate accumulation, and higher activation of the siderophore iron-acquisition systems. Although iron homeostasis in E. coli has been studied intensively, these studies focused only on understanding the regulation of the iron import systems and the iron-requiring enzymes. In this study, the effect of iron availability on the energy metabolism of E. coli was investigated. It was established that aerobic cultures growing at limiting iron conditions showed lower ATP yield per glucose, lower growth rate, and lower TCA cycle activity and respiration, and at the same time increased glucose consumption, acetate and pyruvate accumulation, practically mimicking microaerobic growth. However, at excess iron, independently of oxygen availability, the cultures showed high cellular energetics (5.8 ATP/mol of glucose) by using pathways requiring iron-rich complex proteins found in the TCA cycle and respiration chain. At conditions of iron excess, some iron requiring terminal reductases of the respiratory chain, that were supposed to be anaerobic, were used by the E. coli, when in aerobic conditions, to keep high respiration activity. This high respiration activity allowed E. coli to produce more biomass and more reactive oxygen species that were controlled by the higher activity of the antioxidant defenses (SOD, peroxidase, and catalase) and the iron-sulfur cluster repair systems.

Project description:Acetate Fermentation facilitates survival of Mtb when respiration is inhibited

Project description:Lactococcus lactis is the main bacterium used for food fermentation and is a candidate for probiotic development. In addition to fermentation growth, supplementation with heme in aerobic conditions activates a cytochrome oxidase, which promotes respiration metabolism. In contrast to fermentation in which cells consume energy to produce mainly lactic acid, respiration metabolism dramatically changes energy metabolism, such that massive amounts of acetic acid and acetoin are produced at the expense of lactic acid. Our goal was to investigate the metabolic changes that correlate with significantly improved growth and survival during respiration growth. Using transcriptional time course analyses, mutational analyses, and promoter reporter fusions, we uncover two main pathways that can explain the robust growth and stability of respiration cultures: The acetate pathway contributes to biomass yield in respiration, without affecting medium pH. The acetoin pathway allows cells to cope with internal acidification, which directly affects cell density and survival in stationary phase. Our results suggest that manipulation of these pathways could lead to fine tuning respiration growth, with improved yield and stability.

Project description:When the yeast Saccharomyces cerevisiae is subjected to increasing glycolytic fluxes under aerobic conditions, there is a threshold value of the glucose uptake rate at which the metabolism shifts from being purely respiratory to mixed respiratory and fermentative. This shift is characterized by ethanol production, a phenomenon known as the Crabtree effect due to its analogy with lactate overflow in cancer cells. It is well known that at high glycolytic fluxes there is glucose repression of respiratory pathways resulting in a decrease in the respiratory capacity. Despite many years of detailed studies on this subject, it is not known whether the onset of the Crabtree effect (or overflow metabolism) is due to a limited respiratory capacity or caused by glucose-mediated repression of respiration. We addressed this issue by increasing respiration in S. cerevisiae by introducing a heterologous alternative oxidase, and observed reduced aerobic ethanol formation. In contrast, increasing non-respiratory NADH oxidation by overexpression of a water-forming NADH oxidase reduced aerobic glycerol formation. The metabolic response to elevated alternative oxidase occurred predominantly in the mitochondria, while NADH oxidase affected genes that catalyze cytosolic reactions. Moreover, NADH oxidase restored the deficiency of cytosolic NADH dehydrogenases in S. cerevisiae. These results indicate that NADH oxidase localizes in the cytosol, while alternative oxidase is directed to the mitochondria. The onset of aerobic ethanol formation is demonstrated to be a consequence of an imbalance in mitochondrial redox balancing. In addition to answering fundamental physiological questions, our findings are relevant for all biomass derived applications of S. cerevisiae. Experiment Overall Design: Heterologous gene expression in chemostats using Affymetrix Yeast Genome 2.0 arrays. Total RNA extraction and sample preparation, hybridization was done according to the manufacturer's protocol.

Project description:Metabolic efficiency profoundly influences organismal fitness. Heterotrophs, from yeast to mammals, derive usable energy primarily through glycolysis and respiration. While respiration is more energy-efficient, some cells favor glycolysis even when oxygen is available (aerobic glycolysis, Warburg effect). A leading explanation is that glycolysis is more efficient in terms of ATP production per unit mass of protein (i.e. faster). Through quantitative flux analysis and proteomics, we find however that mitochondrial respiration is actually more proteome-efficient than aerobic glycolysis. This is shown across yeasts, T cells, cancer cells, and tissues and tumors in vivo. Instead of aerobic glycolysis being valuable for fast ATP production, it correlates with high glycolytic protein expression, which is valuable for hypoxic growth. Aerobic glycolytic yeasts do not excel at aerobic growth, but outgrow respiratory cells in oxygen limitation. Thus, aerobic glycolysis emerges from cells maintaining a proteome conducive to both aerobic and hypoxic growth.

Project description:Metabolic efficiency profoundly influences organismal fitness. Heterotrophs, from yeast to mammals, derive usable energy primarily through glycolysis and respiration. While respiration is more energy-efficient, some cells favor glycolysis even when oxygen is available (aerobic glycolysis, Warburg effect). A leading explanation is that glycolysis is more efficient in terms of ATP production per unit mass of protein (i.e. faster). Through quantitative flux analysis and proteomics, we find however that mitochondrial respiration is actually more proteome-efficient than aerobic glycolysis. This is shown across yeasts, T cells, cancer cells, and tissues and tumors in vivo. Instead of aerobic glycolysis being valuable for fast ATP production, it correlates with high glycolytic protein expression, which is valuable for hypoxic growth. Aerobic glycolytic yeasts do not excel at aerobic growth, but outgrow respiratory cells in oxygen limitation. Thus, aerobic glycolysis emerges from cells maintaining a proteome conducive to both aerobic and hypoxic growth.

Project description:Metabolic efficiency profoundly influences organismal fitness. Heterotrophs, from yeast to mammals, derive usable energy primarily through glycolysis and respiration. While respiration is more energy-efficient, some cells favor glycolysis even when oxygen is available (aerobic glycolysis, Warburg effect). A leading explanation is that glycolysis is more efficient in terms of ATP production per unit mass of protein (i.e. faster). Through quantitative flux analysis and proteomics, we find however that mitochondrial respiration is actually more proteome-efficient than aerobic glycolysis. This is shown across yeasts, T cells, cancer cells, and tissues and tumors in vivo. Instead of aerobic glycolysis being valuable for fast ATP production, it correlates with high glycolytic protein expression, which is valuable for hypoxic growth. Aerobic glycolytic yeasts do not excel at aerobic growth, but outgrow respiratory cells in oxygen limitation. Thus, aerobic glycolysis emerges from cells maintaining a proteome conducive to both aerobic and hypoxic growth.

Project description:When the yeast Saccharomyces cerevisiae is subjected to increasing glycolytic fluxes under aerobic conditions, there is a threshold value of the glucose uptake rate at which the metabolism shifts from being purely respiratory to mixed respiratory and fermentative. This shift is characterized by ethanol production, a phenomenon known as the Crabtree effect due to its analogy with lactate overflow in cancer cells. It is well known that at high glycolytic fluxes there is glucose repression of respiratory pathways resulting in a decrease in the respiratory capacity. Despite many years of detailed studies on this subject, it is not known whether the onset of the Crabtree effect (or overflow metabolism) is due to a limited respiratory capacity or caused by glucose-mediated repression of respiration. We addressed this issue by increasing respiration in S. cerevisiae by introducing a heterologous alternative oxidase, and observed reduced aerobic ethanol formation. In contrast, increasing non-respiratory NADH oxidation by overexpression of a water-forming NADH oxidase reduced aerobic glycerol formation. The metabolic response to elevated alternative oxidase occurred predominantly in the mitochondria, while NADH oxidase affected genes that catalyze cytosolic reactions. Moreover, NADH oxidase restored the deficiency of cytosolic NADH dehydrogenases in S. cerevisiae. These results indicate that NADH oxidase localizes in the cytosol, while alternative oxidase is directed to the mitochondria. The onset of aerobic ethanol formation is demonstrated to be a consequence of an imbalance in mitochondrial redox balancing. In addition to answering fundamental physiological questions, our findings are relevant for all biomass derived applications of S. cerevisiae. Keywords: Genetic Modification

Project description:Pathogens that grow during infections must cope with the reactive oxygen species (ROS) released by host immune cells. Among the different strategies to prevent oxidative damage during infections, pathogenic bacteria have evolved mechanisms to reduce respiration and other cellular processes that are particularly sensitive to free radicals, obtaining energy preferentially by undergoing to fermentative metabolism. As fermentation produces fewer ATP per glucose than respiration, bacteria ensure an appropriate supply of energy by increasing the glycolytic flux. The opportunistic human pathogen Staphylococcus aureus is one such microbe but the underlying mechanism that enables S. aureus to induce fermentation during infections is still unclear. Here we show that the ComK-like regulator of natural competence that is present in many gram-positive bacteria is crucial to redirect S. aureus metabolism to fermentation during infection. ComK is cryptic in laboratory conditions but highly induced during infections or in response to infection-related cues, such as ROS. ComK induces the glycolytic flux and glucose consumption rate, a key step to redirect ATP production to fermentation. This licenses fermenting S. aureus to reduce oxidative damage while increasing DNA uptake by natural transformation. As a consequence, a comK-defective mutant shows an accumulation of ROS as well as DNA mutations that lower bacterial survival. This mutant shows no distinctive phenotype in laboratory conditions but is unable to cause infection in vertebrates or invertebrate infection models. ComK-mediated synchronization of natural transformation to fermentative metabolism may allow S. aureus, and probably other gram-positive bacteria, to use the fermentation acid end products to eliminate bacterial competitors while assimilating their DNA. Assimilated DNA may serve as a source of nucleotides for DNA repair or to promote genetic variability, thereby enabling a successful host colonization of this bacterium.