Johannes Bongaerts scite author profile

The electron-transport chains of Escherichia coli are composed of many different dehydrogenases and terminal reductases (or oxidases) which are linked by quinones (ubiquinone, menaquinone and demethylmenaquinone). Quinol:cytochrome c oxido-reductase ('bc1 complex') is not present. For various electron acceptors (O2, nitrate) and donors (formate, H2, NADH, glycerol-3-P) isoenzymes are present. The enzymes show great variability in membrane topology and energy conservation. Energy is conserved by conformational proton pumps, or by arrangement of substrate sites on opposite sides of the membrane resulting in charge separation. Depending on the enzymes and isoenzymes used, the H+/e- ratios are between 0 and 4 H+/e- for the overall chain. The expression of the terminal reductases is regulated by electron acceptors. O2 is the preferred electron acceptor and represses the terminal reductases of anaerobic respiration. In anaerobic respiration, nitrate represses other terminal reductases, such as fumarate or DMSO reductases. Energy conservation is maximal with O2 and lowest with fumarate. By this regulation pathways with high ATP or growth yields are favoured. The expression of the dehydrogenases is regulated by the electron acceptors, too. In aerobic growth, non-coupling dehydrogenases are expressed and used preferentially, whereas in fumarate or DMSO respiration coupling dehydrogenases are essential. Coupling and non-coupling isoenzymes are expressed correspondingly. Thus the rationale for expression of the dehydrogenases is not maximal energy yield, but could be maximal flux or growth rates. Nitrate regulation is effected by two-component signal transfer systems with membraneous nitrate/nitrite sensors (NarX, NarQ) and cytoplasmic response regulators (NarL, NarP) which communicate by protein phosphorylation. O2 regulates by a two-component regulatory system consisting of a membraneous sensor (ArcB) and a response regulator (ArcA). ArcA is the major regulator of aerobic metabolism and represses the genes of aerobic metabolism under anaerobic conditions. FNR is a cytoplasmic O2 responsive regulator with a sensory and a regulatory DNA-binding domain. FNR is the regulator of genes required for anaerobic respiration and related pathways. The binding sites of NarL, NarP, ArcA and FNR are characterized for various promoters. Most of the genes are regulated by more than one of the regulators, which can act in any combination and in a positive or negative mode. By this the hierarchical expression of the genes in response to the electron acceptors is achieved. FNR is located in the cytoplasm and contains a 4Fe4S cluster in the sensory domain. The regulatory concentrations of O2 are 1-5 mbar. Under these conditions O2 diffuses to the cytoplasm and is able to react directly with FNR without involvement of other specific enzymes or protein mediators. By oxidation of the FeS cluster, FNR is converted to the inactive state in a reversible process. Reductive activation could be achieved by cellular reductants in the absence of O2. In ...

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Metabolic Engineering for Microbial Production of Aromatic Amino Acids and Derived Compounds

Bongaerts¹,

Krämer²,

Müller³

et al. 2001

Metabolic Engineering

265

144

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Metabolic engineering for microbial production of shikimic acid

Krämer¹,

Bongaerts²,

Bovenberg³

et al. 2003

Metabolic Engineering

196

136

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Optimization of Protease Secretion in Bacillus subtilis and Bacillus licheniformis by Screening of Homologous and Heterologous Signal Peptides

Degering

Eggert²,

Puls³

et al. 2010

Appl Environ Microbiol

162

117

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Bacillus subtilis and Bacillus licheniformis are widely used for the large-scale industrial production of proteins. These strains can efficiently secrete proteins into the culture medium using the general secretion (Sec) pathway. A characteristic feature of all secreted proteins is their N-terminal signal peptides, which are recognized by the secretion machinery. Here, we have studied the production of an industrially important secreted protease, namely, subtilisin BPN from Bacillus amyloliquefaciens. One hundred seventy-three signal peptides originating from B. subtilis and 220 signal peptides from the B. licheniformis type strain were fused to this secretion target and expressed in B. subtilis, and the resulting library was analyzed by high-throughput screening for extracellular proteolytic activity. We have identified a number of signal peptides originating from both organisms which produced significantly increased yield of the secreted protease. Interestingly, we observed that levels of extracellular protease were improved not only in B. subtilis, which was used as the screening host, but also in two different B. licheniformis strains. To date, it is impossible to predict which signal peptide will result in better secretion and thus an improved yield of a given extracellular target protein. Our data show that screening a library consisting of homologous and heterologous signal peptides fused to a target protein can identify more-effective signal peptides, resulting in improved protein export not only in the original screening host but also in different production strains.Gram-positive bacteria of the genus Bacillus are industrially well-established microorganisms for the production of extracellular proteins. Due to the availability of relatively cheap large-scale production systems combined with the ability of bacteria to secrete up to 20 to 25 g/liter of a target protein into the growth medium, about 60% of commercially available enzymes are presently produced in Bacillus species (14, 28).The closely related species Bacillus subtilis and Bacillus licheniformis are widely used as production hosts on an industrial scale, and, in contrast to the well-known production species Escherichia coli, they are free of endotoxin and have GRAS (generally regarded as safe) status. The complete genome sequences of strains B. subtilis 168 (1, 18) and B. licheniformis DSM13 (isogenic to ATCC 14580) (26, 32) are available, greatly facilitating the construction of improved production strains.The Sec pathway constitutes the main secretion pathway in B. subtilis and B. licheniformis. Proteins secreted via the Sec pathway are initially synthesized with an N-terminal hydrophobic signal peptide (SP) consisting of a positively charged N domain followed by a longer, hydrophobic H domain and a C domain consisting of three amino acids which form the signal peptidase recognition site (35). Targeting of a secreted protein to the membrane, the translocation process itself, and subsequent processing by a signal peptidase represent the majo...

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Requirement for the Proton‐Pumping NADH Dehydrogenase I of Escherichia Coli in Respiration of NADH to Fumarate and Its Bioenergetic Implications

Tran¹,

Bongaerts²,

Vlad³

et al. 1997

European Journal of Biochemistry

123

104

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In Escherichia coli the expression of the nuo genes encoding the proton pumping NADH dehydrogenase I is stimulated by the presence of fumarate during anaerobic respiration. The regulatory sites required for the induction by fumarate, nitrate and 0, are located at positions around -309, -277, and downstream of -231 bp, respectively, relative to the transcriptional-start site. The fumarate regulator has to be different from the 0, and nitrate regulators ArcA and NarL. For growth by fumarate respiration, the presence of NADH dehydrogenase I was essential, in contrast to aerobic or nitrate respiration which used preferentially NADH dehydrogenase 11. The electron transport from NADH to fumarate strongly decreased in a mutant lacking NADH dehydrogenase I. The mutant used acetyl-CoA instead of fumarate to an increased extent as an electron acceptor for NADH, and excreted ethanol. Therefore, NADH dehydrogenase I is essential for NADH + fumarate respiration, and is able to use menaquinone as an electron acceptor. NADH + dimethylsulfoxide respiration is also dependent on NADH dehydrogenase I. The consequences for energy conservation by anaerobic respiration with NADH as a donor are discussed.Keywordx: NADH dehydrogenase I; fumarate respiration ; proton potential ; menaquinone; Escherichia coli.In respiratory metabolism, Escherichia coli can use a large variety of electron donors and acceptors (Gunsalus, 1992;Unden et al., 1994;Gennis and Stewart, 1996). The conditions resulting in the synthesis of the oxidases and terminal reductases and their physiological roles are largely known (Spiro and Guest, 1991;Gunsalus, 1992;Iuchi and Lin, 1993;Unden et al., 1994. The variety of dehydrogenases that deliver electrons to the quinones is even larger, and for substrates such as formate, H,, glycerol 3-phosphate and NADH, more than one dehydrogenase is found in the bacteria. The isoenzymes catalyze the same reaction (donor + quinone + quinol + oxidized donor), but often they are produced under differing conditions, such as changes in 0, or nitrate supply. NADH is the most important electron donor for the respiratory chains of E. coli during growth with many substrates. E. coli contains two NADH:quinone oxidoreductases (Matsushita et al., 1987;. NADH dehydrogenase I1 is encoded by the ndh gene and is synthesized mainly during aerobic growth due to the transcriptional repression by the 0,-responsive regulator FNR under anoxic conditions (Spiro et al., 1989;Green and Guest, 1994). The alternative enzyme, NADH dehydrogenase I is encoded by the nuo operon and consists of 14 subunits (Weidner et al., 1993). The enzyme is thought to translocate 2 H+/e-coupled to the redox reaction (Friedrich et al., 1995). The nu0 operon is preceded by a large intergenic region of 650 bp and is subject to complex transcriptional regulation electron acceptors 0, and nitrate compared with fermentative growth, in agreement with the significance of the enzyme in respiratory metabolism. The 0,-dependent regulation consisted mainly of repression by ArcA under an...

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