Project description:The connection between bioenergetics and cell fate remains poorly understood. It is wildly accepted that pluripotent stem cells mainly on anaerobic glycolysis for energy production rather than oxidative phosphorylation (OXPHOS) compared with differentiated cells. However, mitochondria in PSCs still possess functional respiratory complexes. Here we generated the transcriptome profiling (RNA-seq) of OXPHOS inhibited ESC, glycolysis inhibited ESC and control ESC, presenting the variation of the global gene expression induced by metabolism inhibition

Project description:Pseudomonas aeruginosa undergoes cell elongation and forms robust biofilms during anaerobic respiratory growth using nitrate (NO3-) as an alternative electron acceptor. Understanding the mechanism of cell shape change induced upon anaerobiosis is crucial to the development of effective treatments against P. aeruginosa biofilm infection. Anaerobic growth of PAO1 reached higher cell density in the presence of vitamin B12, an essential coenzyme of class II ribonucleotide reductase. In addition, cell morphology returned to a normal rod shape. These results suggest that vitamin B12, the production of which was suppressed during anaerobic growth, can restore cellular machineries for DNA replication and therefore facilitate better anaerobic growth of P. aeruginosa with normal cell division. We used microarray to elucidate the global gene expression profiles underlying vitamin B12-induced changes in bacterial cell shape and growth-associated properties.

Project description:Eutopic endometrium (EuE) and endometriotic peritoneal lesions (ectopic endometrium, EcE) are heterogenous tissues according to the recent scRNA studies. We aimed to explore metabolic profile of cell populations in paired samples of EuE and EcE from four women with endometriosis. We found changes in the regulation of progesterone and estradiol signaling pathways in perivascular, stromal and endothelial cells of EcE compared to EuE, which might have a direct effect on cellular metabolism and contribute to cell proliferation and angiogenesis. The metabolic pathways were differentially regulated in perivascular, stromal and endothelial clusters, and metabolic pathway activity change between EcE and EuE was the highest for AMPK, HIF-1, glutathione metabolism, OXPHOS, and glycolysis/ gluconeogenesis. Remarkably, we identified co-activation of glycolysis and OXPHOS in perivascular and stromal cells of EcE compared to EuE. Previous studies reported a Warburg-like effect in endometriosis with a high use of glycolysis pathway over oxidative metabolism. Our observations might suggest the employment of both OXPHOS and glycolysis to meet the energy demands of proliferating cells in endometriotic lesions.

Project description:Pseudomonas aeruginosa undergoes cell elongation and forms robust biofilms during anaerobic respiratory growth using nitrate (NO3-) as an alternative electron acceptor. Understanding the mechanism of cell shape change induced upon anaerobiosis is crucial to the development of effective treatments against P. aeruginosa biofilm infection. Anaerobic growth of PAO1 reached higher cell density in the presence of vitamin B12, an essential coenzyme of class II ribonucleotide reductase. In addition, cell morphology returned to a normal rod shape. These results suggest that vitamin B12, the production of which was suppressed during anaerobic growth, can restore cellular machineries for DNA replication and therefore facilitate better anaerobic growth of P. aeruginosa with normal cell division. We used microarray to elucidate the global gene expression profiles underlying vitamin B12-induced changes in bacterial cell shape and growth-associated properties. Gene expression profiles of PAO1 grown in LBN (LB+NO3-) or LBN supplemented with 1 microM vitamin B12 are compared.

Project description:Cell proliferation is achieved by numerous enzyme reactions. Temperature governs the activity of each enzyme, which overall determines the optimal growth temperature. Synthesizing useful chemicals and fuels utilizes only part of the metabolic pathways, especially the central metabolic pathways such as glycolysis and TCA cycle to metabolize glucose. However, the optimal temperature for the activity of the central metabolic pathways is inconclusive whether it is correlated with the optimal temperature for cell proliferation. Here, we found that Corynebacterium glutamicum wild type increased the metabolic activity to consume glucose under anaerobic (oxygen deprived) conditions at 42.5ºC, in which the cell hardly grows under aerobic conditions. Glucose consumption rate was increased by 24% at 42.5ºC compared to that at the optimal growth temperature of 30.0ºC. Transcriptional analysis showed that gapX gene encoding glycelaldehydre-3-phosphate dehydrogenase, glucokinase gene, and a gene involved in glucose uptake were upregulated at 42.5ºC. Production of fermentative lactate was increased by 69% than that at 30.0ºC, whereas succinate production was decreased by 13%. In addition to several glycolytic enzymes, the activity of pyruvate kinase was increased with increasing the temperature, whereas the activity of phosphoenolpyruvate carboxylase in anapleotic pathway leading to succinate synthesis was decreased. However, a metabolically engineered succinate over-producing strain, in which lactate production was shut off and pyruvate carboxylase encoding gene in another anapleotic pathway was overexpressed, produced 34% higher succinate at 42.5ºC than that at 30.0ºC with increased glucose consumption. This study provides the evidence that the optimal reaction temperature for production of fermentative products can be set beyond upper limit of growth temperature in C. glutamicum, and hence it could be applicable for producing various chemicals and fuels in C. glutamicum under anaerobic conditions and non-growing cell reactions in other microorganisms.

Project description:RNA-sequencing of sublineage 2.2 Salmonella Enterica strain D37712 under in vitro growth conditions (EEP, MEP, LEP, ESP, LSP, 25ºC, NaCl, low Fe2+ shock, low Mg2+ shock, anaerobic shock, anaerobic growth, oxygen shock, NonSPI2, InSPI2, peroxide shock, and nitric oxide shock) and murine RAW265.7 macrophages.

Project description:Group 2 innate lymphoid cells (ILC2) represent innate homologues of Th2 cells that participate in immune defense and tissue homeostasis through production of type 2 cytokines. While T lymphocytes metabolically adapt to microenvironmental changes, knowledge of human ILC2 metabolism is limited and its key regulators are unknown. Here we show that circulating “naïve” ILC2 have an unexpected metabolic profile with a higher level of oxidative phosphorylation (OXPHOS) than NK cells. Accordingly, ILC2 are severely reduced in patients with mitochondrial disease and impaired OXPHOS. Metabolomic and nutrient receptors analysis reveals ILC2 uptake amino acids to sustain OXPHOS at steady-state. Upon activation with interleukin 33 (IL-33), ILC2 become highly proliferative relying on glycolysis and mTOR to produce IL-13, while continuing to fuel OXPHOS with amino acids to maintain cellular fitness and proliferation. Our results suggest that proliferation and function are metabolically uncoupled in human ILC2, offering new strategies to target ILC2 in disease settings.

Project description:Temperature shift under anaerobic conditions

Project description:Investigation of whole genome gene expression level changes in Thermoplasma acidophilum cultured under aerobic and anaerobic conditions. The analysis are further described in Na Sun, Cuiping Pan, Stephan Nickell, Matthias Mann, Wolfgang Baumeister, and István Nagy, Quantitative proteome and transcriptome analysis of the archaeon Thermoplasma acidophilum cultured under aerobic and anaerobic conditions (submitted).

Project description:RNA-sequencing of two Salmonella Enterica strains (4/74, D23580) under in vitro growth conditions (EEP, MEP, LEP, ESP, LSP, 25ºC, NaCl, bile shock, low Fe2+ shock, anaerobic shock, anaerobic growth, oxygen shock, NonSPI2, InSPI2, peroxide shock, and nitric oxide shock) and murine RAW264.7 macrophages.