A Novel Metabolic Cycle Catalyzes Glucose Oxidation and Anaplerosis in Hungry Escherichia coli

Fischer, Eliane; Sauer, Uwe

doi:10.1074/jbc.m307968200

Cited by 179 publications

(195 citation statements)

References 37 publications

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“…4). Only a relatively small fraction of the consumed glucose was oxidized to CO 2 within the TCA cycle, as was described previously for batch cultures of the same strain using a comprehensive isotopomer model (37). Consistent with the flux ratios (Fig.…”

Section: Physiological and Biochemical Characterization Of Transhydrosupporting

confidence: 70%

“…Moreover, the Pgi mutant was the only strain with an exceptional low fraction of oxaloacetate originating from PEP and a significant fraction of oxaloacetate originating from glyoxylate (Fig. 3), as was described before (37). The resulting absolute flux distribution reveals significant activity of the recently identified PEP-glyoxylate cycle (37), i.e.…”

Section: Fig 3 Origin Of Key Metabolic Intermediates In E Coli Mutmentioning

confidence: 87%

“…Metabolic Flux Ratio Analysis by GC-MS-Direct analytical interpretation of GC-MS-derived 13 C-labeling pattern in proteinogenic amino acids was used to quantify independent flux partitioning ratios (36,37). Biomass pellets harvested from 13 C-labeling experiments were resuspended and hydrolyzed in 1.5 ml of 6 M HCl at 105°C for 24 h in sealed 2.2-ml Eppendorf tubes.…”

Section: Methodsmentioning

confidence: 99%

“…3 and 6; Refs. 26,36,37). The resulting flux rerouting caused a metabolic condition with more than 100% excess NADPH formation (Figs.…”

Section: Fig 3 Origin Of Key Metabolic Intermediates In E Coli Mutmentioning

confidence: 99%

“…By comparing 13 C-labeling pattern in proteinogenic amino acids, this strictly local analysis quantifies ratios of converging fluxes at the junction of two or more pathways or reactions (43,44). Different from global data fitting in the net flux analysis described below, this approach yields ratios of fluxes that are independent of each other (23,27,37,45). In separate batch cultures that were grown either on 100% [1-13 C]glucose or on a mixture of 20% [U- 13 C]glucose and 80% unlabeled glucose, the overall flux profiles were very similar in the UdhA mutant and the wild type (Fig.…”

Section: Physiological and Biochemical Characterization Of Transhydromentioning

confidence: 99%

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The Soluble and Membrane-bound Transhydrogenases UdhA and PntAB Have Divergent Functions in NADPH Metabolism of Escherichia coli

Sauer

Canonaco

Heri

et al. 2004

Journal of Biological Chemistry

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514

526

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Pentose phosphate pathway and isocitrate dehydrogenase are generally considered to be the major sources of the anabolic reductant NADPH. As one of very few microbes, Escherichia coli contains two transhydrogenase isoforms with unknown physiological function that could potentially transfer electrons directly from NADH to NADP ؉ and vice versa. Using defined mutants and metabolic flux analysis, we identified the proton-translocating transhydrogenase PntAB as a major source of NADPH in E. coli. During standard aerobic batch growth on glucose, 35-45% of the NADPH that is required for biosynthesis was produced via PntAB, whereas pentose phosphate pathway and isocitrate dehydrogenase contributed 35-45% and 20 -25%, respectively. The energy-independent transhydrogenase UdhA, in contrast, was essential for growth under metabolic conditions with excess NADPH formation, i.e. growth on acetate or in a phosphoglucose isomerase mutant that catabolized glucose through the pentose phosphate pathway. Thus, both isoforms have divergent physiological functions: energy-dependent reduction of NADP ؉ with NADH by PntAB and reoxidation of NADPH by UdhA. Expression appeared to be modulated by the redox state of cellular metabolism, because genetic and environmental manipulations that increased or decreased NADPH formation down-regulated pntA or udhA transcription, respectively. The two transhydrogenase isoforms provide E. coli primary metabolism with an extraordinary flexibility to cope with varying catabolic and anabolic demands, which raises two general questions: why do only a few bacteria contain both isoforms, and how do other organisms manage NADPH metabolism?About 1,000 anabolic reactions synthesize the macromolecular components that make up functional cells (1, 2), but only 11 intermediates of central carbon metabolism and the cofactors ATP, NADH, and NADPH constitute the core of this intricate biochemical network (3, 4). These intermediates and cofactors must be supplied through the catabolism of different substrates at appropriate rates and stoichiometries for balanced growth; hence, anabolism and catabolism are delicately balanced and regulated to enable growth under fluctuating environmental conditions. Although chemically very similar, the redox cofactors NADH and NADPH serve distinct biochemical functions and participate in more than 100 enzymatic reactions (5). The electrons of the main respiratory cofactor NADH are transferred primarily to oxygen, thereby driving oxidative phosphorylation of ADP to ATP (3,4,6). NADPH, in contrast, exclusively drives anabolic reduction reactions. Despite the important role in linking the fundamental processes of catabolism and anabolism, however, even a qualitative understanding of NADPH metabolism is still missing for most organisms.The primary NADPH-generating reactions are considered to be the oxidative pentose phosphate (PP) 1 pathway and the NADPH-dependent isocitrate dehydrogenase in the TCA cycle (Fig.

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Section: Physiological and Biochemical Characterization Of Transhydrosupporting

confidence: 70%

Section: Fig 3 Origin Of Key Metabolic Intermediates In E Coli Mutmentioning

confidence: 87%

Section: Methodsmentioning

confidence: 99%

“…3 and 6; Refs. 26,36,37). The resulting flux rerouting caused a metabolic condition with more than 100% excess NADPH formation (Figs.…”

Section: Fig 3 Origin Of Key Metabolic Intermediates In E Coli Mutmentioning

confidence: 99%

Section: Physiological and Biochemical Characterization Of Transhydromentioning

confidence: 99%

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The Soluble and Membrane-bound Transhydrogenases UdhA and PntAB Have Divergent Functions in NADPH Metabolism of Escherichia coli

Sauer

Canonaco

Heri

et al. 2004

Journal of Biological Chemistry

Self Cite

514

526

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Acetate overflow metabolism regulates a major metabolic shift after glucose depletion in Escherichia coli

et al. 2021

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Acetate overflow refers to the metabolism by which a large part of carbon incorporated as glucose into Escherichia coli cells is catabolized and excreted as acetate into the medium. We previously found that mutants for the acetate overflow pathway enzymes phosphoacetyltransferase (Pta) and acetate kinase (AckA) showed significant diauxic growth after glucose depletion in E. coli. Here, we analyzed the underlying mechanism in the pta mutant. Proteomic and other analyses revealed an increase in pyruvate dehydrogenase complex subunits and a decrease in glyoxylate shunt enzymes, which resulted from pyruvate accumulation. Since restoration of these enzyme levels by overexpressing PdhR (pyruvate‐sensing transcription factor) or deleting iclR (gene encoding a pyruvate‐ and glyoxylate‐sensing transcription factor) alleviated the growth lag of the pta mutant after glucose depletion, these changes were considered as the reason for the phenotype. Given the evidence for decreased coenzyme A (HS‐CoA) levels in the pta mutant, the growth inhibition after glucose depletion was partly explained by limited availability of HS‐CoA in the cell. The findings provide insights into the role of acetate overflow in metabolic regulation, which may be useful for biotechnological applications.

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Glyoxylate Bypass ofEscherichia Coli, Regulation

LaPorte

2010

Encyclopedia of Industrial Biotechnology

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A Novel Metabolic Cycle Catalyzes Glucose Oxidation and Anaplerosis in Hungry Escherichia coli

Cited by 179 publications

References 37 publications

The Soluble and Membrane-bound Transhydrogenases UdhA and PntAB Have Divergent Functions in NADPH Metabolism of Escherichia coli

The Soluble and Membrane-bound Transhydrogenases UdhA and PntAB Have Divergent Functions in NADPH Metabolism of Escherichia coli

Acetate overflow metabolism regulates a major metabolic shift after glucose depletion in Escherichia coli

Glyoxylate Bypass ofEscherichia Coli, Regulation

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