Anaerobic Expression of<i>Escherichia coli</i>Succinate Dehydrogenase: Functional Replacement of Fumarate Reductase in the Respiratory Chain during Anaerobic Growth

Maklashina, Elena; Berthold, Deborah A.; Cecchini, Gary

doi:10.1128/jb.180.22.5989-5996.1998

Cited by 129 publications

(53 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In E. coli, it contains two membrane-bound flavoproteins that catalyze the interconversion of fumarate and succinate, succinate dehydrogenase (SDH), and fumarate reductase (FRD) (Cecchini, Schröder, Gunsalus, & Maklashina, 2002). Previous reports already indicated that the FRD and SDH can be interchanged under optimal conditions (Guest, 1981;Maklashina, Berthold, & Cecchini, 1998).…”

Section: Effect Of Engineering Tca Cycle On Succinate Productionmentioning

confidence: 99%

Central pathway engineering for enhanced succinate biosynthesis from acetate in Escherichia coli

Huang

Yang

Fang

et al. 2018

Biotech & Bioengineering

View full text Add to dashboard Cite

Acetate, a non-food based substrate obtained from multiple biological and chemical ways, is now being paid great attention in bio-manufacturing and have a strong potential to compete with sugar-based carbon source. In this study, acetate can be efficiently converted to succinate by engineered Escherichia coli strains via the combination of several metabolic engineering strategies, including reducing OAA decarboxylation, engineering TCA cycle, enhancement of acetate assimilation pathway and increasing aerobic ATP supply through cofactor engineering. The engineered strain HB03(pTrc99a-gltA, pBAD33-Trc-fdh) accumulated 30.9 mM of succinate in 72 hr and the yield reached the maximum theoretical yield (∼0.50 mol/mol). In the resting-cell experiments, the yield of succinate in HB03(pTrc99a-gltA) and HB03(pTrc99a-gltA, pBAD33-Trc-fdh) dropped dramatically, although the productivity of succinate increased due to the high cell density. Further deletion of icdA, formed HB04(pTrc99a-gltA) and HB04(pTrc99a-gltA, pBAD33-Trc-fdh), increased the yield of succinate in the resting-cell experiments. The highest concentration of succinate achieved 194 mM and the yield reached 0.44 mol/mol in 16 hr by HB04(pTrc99a-gltA, pBAD33-Trc-fdh). The results showed the metabolically engineered E. coli strains have great potential to produce succinate from acetate.

show abstract

Section: Effect Of Engineering Tca Cycle On Succinate Productionmentioning

confidence: 99%

Central pathway engineering for enhanced succinate biosynthesis from acetate in Escherichia coli

Huang

Yang

Fang

et al. 2018

Biotech & Bioengineering

View full text Add to dashboard Cite

show abstract

“…On the other hand, fumarate reduction by SQR shuts down' (70^90%) under conditions of high reducing potential (`tunnel diode e¡ect') [6]. Thus, SQRs appear ill-suited as physiological fumarate reducers, in accord with the observation that E. coli grows much less e¤ciently using SQR instead of QFR for anaerobic growth [7]. QFRs characteristically maintain catalytic e¤ciency under highly reducing conditions [6].…”

Section: Introductionmentioning

confidence: 99%

Progress in understanding structure–function relationships in respiratory chain complex II

Ackrell¹

2000

FEBS Letters

126

View full text Add to dashboard Cite

Complex II (succinate:quinone oxidoreductase) of aerobic respiratory chains oxidizes succinate to fumarate and passes the electrons directly into the quinone pool. It serves as the only direct link between activity in the citric acid cycle and electron transport in the membrane. Finer details of these reactions and interactions are but poorly understood. However, complex II has extremely similar structural and catalytic properties to quinol :fumarate oxidoreductases of anaerobic organisms, for which X-ray structures have recently become available. These offer new insights into structure^function relationships of this class of flavoenzymes, including evidence favoring protein movement during catalysis.z 2000 Federation of European Biochemical Societies.

show abstract

“…The recently elucidated signalling functions 32,33 . Interestingly, succinate accumulation occurs in a number of different organisms, including bacteria such as Escherichia coli 34 , Mycobacterium tuberculosis 35 , as well as several bacterial members of the human gut microbiome [36][37][38][39] and the bovine rumen 40,41 ; fungi such as the yeast Saccharomyces cerevisiae 42 and members of the genus Penicillium 43 ; green algae 44 ; parasitic helminths 45 ; the sleeping sickness-causing parasite Trypanosoma brucei 46 ; marine invertebrates 47 ; and humans [48][49][50][51] . More specifically, our observations are consistent with the behavior of the TCA cycle under anaerobiosis and hypoxia [52][53][54][55] .…”

Section: Discussionmentioning

confidence: 99%

A thermodynamic atlas of carbon redox chemical space

Jinich

Sánchez-Lengeling²,

Ren³

et al. 2018

Preprint

View full text Add to dashboard Cite

Redox biochemistry plays a key role in the transduction of chemical energy in living systems.However, the compounds observed in metabolic redox reactions are a minuscule fraction of chemical space. It is not clear whether compounds that ended up being selected as metabolites display specific properties that distinguish them from non-biological compounds. Here we introduce a systematic approach for comparing the chemical space of all possible redox states of linear-chain carbon molecules to the corresponding metabolites that appear in biology. Using cheminformatics and quantum chemistry, we analyze the physicochemical and thermodynamic properties of the biological and non-biological compounds. We find that, among all compounds, aldose sugars have the highest possible number of redox connections to other molecules.Metabolites are enriched in carboxylic acid functional groups and depleted of carbonyls, and have higher solubility than non-biological compounds. Upon constructing the energy landscape for the full chemical space as a function of pH and electron donor potential, we find that over a large range of conditions metabolites tend to have lower Gibbs energies than non-biological molecules. Finally, we generate Pourbaix phase diagrams that serve as a thermodynamic atlas to indicate which compounds are local and global energy minima in redox chemical space across a set of pH values and electron donor potentials. Our work yields insight into the physicochemical principles governing redox metabolism, and suggests that thermodynamic stability in aqueous environments may have played an important role in early metabolic processes. IntroductionRedox reactions are fundamental to biochemistry. The two main biogeochemical carbon-based transformations -respiration and photosynthesis -are at heart oxidative and reductive processes, and a large fraction of catalogued enzymatic reactions ( ) are oxidoreductive in nature 1,2 . 0% ≈ 4Thermodynamics and other physicochemical properties act as constraints on the evolution of metabolism in general and of redox biochemistry in particular. A classic example is the adaptation and expansion of metabolism in response to Earth's great oxidation event (GOE) 3-6 .The rise in molecular oxygen resulted in a standard redox potential difference of 1.1 eV ≈ available from NAD(P)H oxidation, and led to the emergence of novel biochemical pathways such as the biosynthesis of sterols 7-9 .Recent work has uncovered quantitative thermodynamic principles that influence the evolution of carbon redox biochemistry 10-12 . This line of work has focused on the three main types of redox reactions that change the oxidation level of carbon atoms in molecules: reductions of carboxylic acids (-COO) to carbonyls (-C=O); reductions of carbonyls to alcohols (hydroxycarbons) (C-O), and reductions of alcohols to hydrocarbons (C-C). The "rich-get-richer" principle states that more reduced carbon functional groups have higher standard redox potentials 10-12 . Thus, alcohol reduction to a hydrocarbon is more favorable...

show abstract

Anaerobic Expression ofEscherichia coliSuccinate Dehydrogenase: Functional Replacement of Fumarate Reductase in the Respiratory Chain during Anaerobic Growth

Cited by 129 publications

References 34 publications

Central pathway engineering for enhanced succinate biosynthesis from acetate in Escherichia coli

Central pathway engineering for enhanced succinate biosynthesis from acetate in Escherichia coli

Progress in understanding structure–function relationships in respiratory chain complex II

A thermodynamic atlas of carbon redox chemical space

Contact Info

Product

Resources

About