Effect of ArcA and FNR on the expression of genes related to the oxygen regulation and the glycolysis pathway in Escherichia coli under microaerobic growth conditions

Escherichia coli has several elaborate sensing mechanisms for response to the availability of oxygen and the presence of other electron acceptors. The adaptive responses are coordinated by a group of global regulators, which include the one-component Fnr protein, and the two-component Arc system. To quantitate the contribution of Arc and FNR dependent regulation under microaerobic conditions, the gene expression pattern of the fnr the arcA and arcB regulator genes, and the glycolysis related genes in a wild-type E. coli, an arcA mutant, an fnr mutant, and a double arcA, fnr mutant, in glucose limited cultures and different oxygen concentrations was studied in chemostat cultures at steady state using QRT-PCR. It was found that ArcA has a negative effect on fnr expression under microaerobic conditions. Moreover, the expression levels of the FNR regulated genes, yfiD and frdA, were higher in cultures of the arcA mutant strain compared to the wild-type. These imply that a higher level of the FNR regulator is in the activated form in cultures of the arcA mutant strain compared to the wild-type during the transition from aerobic to microanaerobic growth. The results also show that the highest expression level of aceE, pflB, and adhE were obtained in cultures of the arcA mutant strain under microaerobic growth while higher levels of ldhA expression were obtained in cultures of the arcA mutant strain and the arcA, fnr double mutant strain compared to the wild-type and the fnr mutant strain. While the highest expression of adhE and pflB in cultures of the arcA mutant strain can explain the previous report of high ethanol flux and flux through pyruvate formate lyase (PFL) in cultures of this strain, the higher level of ldhA expression was not sufficient to explain the trend in lactate fluxes. The results indicate that lower conversion of pyruvate to acetyl-CoA is the main reason for high fluxes through lactate dehydrogenase (LDH) in cultures of the arcA, fnr double mutant strain.     

Comprehensive analysis of metabolic sensitivity of 1,4-butanediol producing Escherichia coli toward substrate and oxygen availability

Nowadays, chemical production of 1,4-butanediol is supplemented by biotechnological processes using a genetically modified Escherichia coli strain, which is an industrial showcase of successful application of metabolic engineering. However, large scale bioprocess performance can be affected by presence of physical and chemical gradients in bioreactors which are a consequence of imperfect mixing and limited oxygen transfer. Hence, upscaling comes along with local and time dependent fluctuations of cultivation conditions. This study emphasizes on scale-up related effects of microbial 1,4-butanediol production by comprehensive bioprocess characterization in lab scale. Due to metabolic network constraints 1,4-butanediol formation takes place under oxygen limited microaerobic conditions, which can be hardly realized in large scale bioreactor. The purpose of this study was to assess the extent to which substrate and oxygen availability influence the productivity. It was found, that the substrate specific product yield and the production rate are higher under substrate excess than under substrate limitation. Furthermore, the level of oxygen supply within microaerobic conditions revealed strong effects on product and by-product formation. Under strong oxygen deprivation nearly 30% of the consumed carbon is converted into 1,4-butanediol, whereas an increase in oxygen supply results in 1,4-butanediol reduction of 77%. Strikingly, increasing oxygen availability leads to strong increase of main by-product acetate as well as doubled carbon dioxide formation. The study provides clear evidence that scale-up of microaerobic bioprocesses constitute a substantial challenge. Although oxygen is strictly required for product formation, the data give clear evidence that terms of anaerobic and especially aerobic conditions strongly interfere with 1,4-butanediol production.     

Effect of oxygen, and ArcA and FNR regulators on the expression of genes related to the electron transfer chain and the TCA cycle in Escherichia coli

Microbial cells possess numerous sensing/regulator systems in order to respond rapidly to environmental changes. Escherichia coli has several elaborate sensing mechanisms for response to the availability of oxygen and the presence of other electron acceptors. A group of global regulators, which include the one component Fnr protein and the two-component Arc system, coordinate the adaptive responses. To quantitate the contribution of Arc and FNR-dependent regulation under microaerobic conditions, the gene expression pattern of the electron transfer chain genes and the TCA cycle genes in wild-type E. coli, an arcA mutant, an fnr mutant, and a double arcA, fnr mutant, in glucose limited cultures and different oxygen concentrations was studied in chemostat cultures at steady state using QRT-PCR. It was found that the TCA cycle genes, icd, gltA, sucC, and sdhC are repressed by ArcA while Fnr has a minor or no effect on the expression of these genes under microaerobic conditions. The expression levels of the electron transfer chain genes, nuoA, ndh, and ubiE, were not significantly affected by either ArcA or Fnr regulation proteins, while a lower expression of cydA (up to 9-fold lower) and a higher expression of cyoA (up to 31-fold higher) were observed in cultures of the arcA mutant strain compared to those of the wild type. Since significantly higher NADH/NAD+ ratios were previously observed in cultures of the arcA mutant strain compared to the wild type it seems that the cytochrome o oxidase (the product of cyoABCDE) cannot efficiently support aerobic respiration when the cells are grown under microaerobic conditions.     

Effect of oxygen on the Escherichia coli ArcA and FNR regulation systems and metabolic responses

Escherichia coli has several elaborate sensing mechanisms for response to the availability of oxygen and the presence of other electron acceptors. The adaptive responses are coordinated by a group of global regulators, which include the one-component Fnr protein, and the two-component Arc system. To quantitate the contribution of Arc and Fnr-dependent regulation in catabolism, arcA and fnr mutant strains were constructed using the recently developed lambda derived recombination system. The metabolic activity of wildtype E. coli, an arcA mutant, an fnr mutant, and a double arcA-fnr mutant, via the fermentative pathways in glucose-limited cultures and different oxygen concentrations was studied in chemostat cultures at steady state. It was found that the most significant role of ArcA is under microaerobic conditions, while that of FNR is under more strictly anaerobic conditions. The FNR protein is normally inactive during microaerobic conditions. However, our results indicate that in the arcA mutant strain the cells behave as if a higher level of the FNR regulator is in the activated form compared to the wildtype strain during the transition from aerobic to microanaerobic growth. The results show a significant increase in the flux through pyruvate formate lyase (PFL) in the presence of oxygen. The activity of FNR-regulated pathways in the arcA mutant strain is correlated with the high redox potential obtained under microaerobic growth.     

Escherichia coli arcA mutants: metabolic profile characterization of microaerobic cultures using glycerol as a carbon source

ArcA is a global regulator that switches on the expression of fermentation genes and represses the aerobic pathways when Escherichia coli enters low oxygen growth conditions. The metabolic profile of E. coli CT1062 (DeltaarcA)and CT1061 (arcA2) grown in microaerobiosis with glycerol as carbon source were determined and compared with E. coli K1060, the arcA+ parent strain. Both arcA mutants achieved higher biomass yields than the wild-type strain. The production of acetate, formate, lactate, pyruvate, succinate and ethanol were determined in the supernatants of cultures grown on glycerol under microaerobic conditions for 48 h. The yield of extracellular metabolites on glycerol showed lower acid and higher ethanol values for the mutants. The ethanol/acetate ratio was 0.87 for the parent strain, 2.01 for CT1062, and 12.51 for CT1061. Accordingly, the NADH/NAD+ ratios were 0.18, 0.63, and 0.97, respectively. The extracellular succinate yield followed a different pattern, with yield values of 0.164 for K1060, 0.442 for CT1062 and 0.214 for CT1061. The dissimilarities observed can be attributed to the different effects exerted by the deletion and point mutations in a global regulator.     

Biodegradation of chlorobenzene under hypoxic and mixed hypoxic-denitrifying conditions

Pseudomonas veronii strain UFZ B549, Acidovorax facilis strain UFZ B530, and a community of indigenous groundwater bacteria, adapted to oxygen limitation, were cultivated on chlorobenzene and its metabolites 2-chloro-cis,cis-muconate and acetate/succinate under hypoxic and denitrifying conditions. Highly sensitive approaches were used to maintain defined low oxygen partial pressures in an oxygen-re-supplying headspace. With low amounts of oxygen available all cultures converted chlorobenzene, though the pure strains accumulated 3-chlorocatechol and 2-chloro-cis,cis-muconate as intermediates. Under strictly anoxic conditions no chlorobenzene transformation was observed, while 2-chloro-cis,cis-muconate, the fission product of oxidative ring cleavage, was readily degraded by the investigated chlorobenzene-degrading cultures at the expense of nitrate as terminal electron acceptor. Hence, we conclude that oxygen is an obligatory reactant for initial activation of chlorobenzene and fission of the aromatic ring, but it can be partially replaced by nitrate in respiration. The tendency to denitrify in the presence of oxygen during growth on chlorobenzene appeared to depend on the oxygen availability and the efficiency to metabolize chlorobenzene under oxygen limitation, which is largely regulated by the activity of the intradiol ring fission dioxygenase. Permanent cultivation of a groundwater consortium under reduced oxygen levels resulted in enrichment of a community almost exclusively composed of members of the β-Proteobacteria and Bacteroidetes. Thus, it is deduced that these strains can still maintain high activities of oxygen-requiring enzymes that allow for efficient CB transformation under hypoxic conditions.     

Hydrolysis and acidogenic fermentation of gelatin under anaerobic conditions in a laboratory scale upflow reactor

Summary Gelatin was dissolved in a mineral salts medium for growth under carbon limitation and fed to a mixed population of bacteria in a lab-scale upflow reactor for hydrolysis and acidogenic fermentation under anaerobic conditions, at pH=7 and 30°C.With the shortest applied liquid retention time (30 min), 84% of the protein was hydrolysed. The majority (85%) of the hydrolysed protein was fermented. The ammonia concentration in the reactor was about 1,400 mg N·l^-1.The fermentation products were mainly acetate, propionate, and valerate. Iso-butyrate, butyrate, and iso-valerate were formed to a limited extent. Gas production was very low and consisted of carbon dioxide and methane. The product composition was independent of the retention time applied. The sludge formed was slimy. No granules were formed, however a hold-up factor of 46 could be obtained.     

Arc and Sfr functions of the Escherichia coli K-12 arcA gene product are genetically and physiologically separable.

The Escherichia coli arcA gene product regulates chromosomal gene expression in response to deprivation of oxygen (Arc function; Arc stands for aerobic respiration control) and is required for expression of the F plasmid DNA transfer (tra) genes (Sfr function; Sfr stands for sex factor regulation). Using appropriate lacZ fusions, we have examined the relationship between these two genetic regulatory functions. Arc function in vivo was measured by anaerobic repression of a chromosomal sdh-lacZ operon fusion (sdh stands for succinate dehydrogenase). Sfr function was measured by activation of a plasmid traY-lacZ gene fusion. An eight-codon insertion near the 5' terminus of arcA, designated arcA1, abolished Arc function, as previously reported by S. Iuchi and E.C.C. Lin (Proc. Natl. Acad. Sci. USA 85:1888-1892, 1988), but left Sfr function largely (greater than or equal to 60%) intact. Similarly, the arcB1 mutation, which depressed sdh expression and is thought to act by abolishing the signal input that elicits ArcA function, had little effect (less than or equal to 20%) on the Sfr function of the arcA+ gene product. Conversely, a valine-to-methionine mutation at codon 203 (the sfrA5 allele) essentially abolished Sfr activity without detectably altering Arc activity. These data indicate that Sfr and Arc functions are separately expressed and regulated properties of the same protein.     

The ArcA regulon and oxidative stress resistance in Haemophilus influenzae

Haemophilus influenzae transits between niches within the human host that are predicted to differ in oxygen levels. The ArcAB two-component signal transduction system controls gene expression in response to respiratory conditions of growth and has been implicated in bacterial pathogenesis, yet the mechanism is not understood. We undertook a genome-scale study to identify genes of the H. influenzae ArcA regulon. Deletion of arcA resulted in increased anaerobic expression of genes of the respiratory chain and of H. influenzae's partial tricarboxylic acid cycle, and decreased anaerobic expression levels of genes of polyamine metabolism, and iron sequestration. Deletion of arcA also conferred a susceptibility to transient exposure to hydrogen peroxide that was greater following anaerobic growth than after aerobic growth. Array data revealed that the dps gene, not previously assigned to the ArcA modulon in bacteria, exhibited decreased expression in the arcA mutant. Deletion of dps resulted in hydrogen peroxide sensitivity and complementation restored resistance, providing insight into the previously uncharacterized mechanism of arcA-mediated H(2)O(2) resistance. The results indicate a role for H. influenzae arcA and dps in pre-emptive defence against transitions from growth in low oxygen environments to aerobic exposure to hydrogen peroxide, an antibacterial oxidant produced by phagocytes during infection.     

New insights into the energy metabolism and taxonomy of Deferribacteres revealed by the characterization of a new isolate from a hypersaline microbial mat

Strain L21-Ace-BES^T, isolated from a lithifying cyanobacterial mat, could be assigned to a novel species and genus within the class Deferribacteres. It is an important model organism for the study of anaerobic acetate degradation under hypersaline conditions. The metabolism of strain L21-Ace-BES^T was characterized by biochemical studies, comparative genome analyses, and the evaluation of gene expression patterns. The central metabolic pathway is the citric acid cycle, which is mainly controlled by the enzyme succinyl-CoA:acetate-CoA transferase. The potential use of a reversed oxidative citric acid cycle to fix CO₂ has been revealed through genome analysis. However, no autotrophic growth was detected in this strain, whereas sulfide and H₂ can be used mixotrophically. Preferred electron acceptors for the anaerobic oxidation of acetate are nitrate, fumarate and dimethyl sulfoxide, while oxygen can be utilized only under microoxic conditions. Aerotolerant growth by fermentation was observed at higher oxygen concentrations. The redox cycling of sulfur/sulfide enables the generation of reducing power for the assimilation of acetate during growth and could prevent the over-reduction of cells in stationary phase. Extracellular electron transfer appears to be an essential component of the respiratory metabolism in this clade of Deferribacteres and may be involved in the reduction of nitrite to ammonium.     

Metabolic regulation analysis of wild-type and arcA mutant Escherichia coli under nitrate conditions using different levels of omics data

It is of practical interest to investigate the effect of nitrates on bacterial metabolic regulation of both fermentation and energy generation, as compared to aerobic and anaerobic growth without nitrates. Although gene level regulation has previously been studied for nitrate assimilation, it is important to understand this metabolic regulation in terms of global regulators. In the present study, therefore, we measured gene expression using DNA microarrays, intracellular metabolite concentrations using CE-TOFMS, and metabolic fluxes using the (13)C-labeling technique for wild-type E. coli and the ΔarcA (a global regulatory gene for anoxic response control, ArcA) mutant to compare the metabolic state under nitrate conditions to that under aerobic and anaerobic conditions without nitrates in continuous culture conditions at a dilution rate of 0.2 h(-1). In wild-type, although the measured metabolite concentrations changed very little among the three culture conditions, the TCA cycle and the pentose phosphate pathway fluxes were significantly different under each condition. These results suggested that the ATP production rate was 29% higher under nitrate conditions than that under anaerobic conditions, whereas the ATP production rate was 10% lower than that under aerobic conditions. The flux changes in the TCA cycle were caused by changes in control at the gene expression level. In ΔarcA mutant, the TCA cycle flux was significantly increased (4.4 times higher than that of the wild type) under nitrate conditions. Similarly, the intracellular ATP/ADP ratio increased approximately two-fold compared to that of the wild-type strain.     

The problem of glycollate formation from acetate in green algae

Summary The activity of the NADPH: glyoxylate reductase and the NADH: glyoxylate reductase in cell free preparations of Chlorella pyrenoidosa and Chlamydobotrys stellata grown under autotrophic or photoheterotrophic conditions has been demonstrated as well as the rapid reduction of glyoxylate by intact organisms. The results obtained indicate, that the appearance of glycollate in the course, of acetate assimilation by these organisms can result from the reduction of glyoxylate in a side reaction of the glyoxylate cycle.     

Online monitoring of the respiratory quotient reveals metabolic phases during microaerobic 2,3‐butanediol production with Bacillus licheniformis

Microaerobic cultivation conditions are often beneficial for the biotechnological production of reduced metabolites like 2,3‐butanediol. However, due to oxygen limitation, process monitoring based on oxygen transfer rate, or dissolved oxygen measurement provides only limited information. In this study, online monitoring of the respiratory quotient is used to investigate the metabolic activity of Bacillus licheniformis DSM 8785 during mixed acid‐2,3‐butanediol production under microaerobic conditions. Thereby, the respiratory quotient provides valuable information about different metabolic phases. Based on partial reaction stoichiometries, the metabolic activity in each phase of the cultivation was revealed, explaining the course of the respiratory quotient. This provides profound information on the formation or consumption of glucose, 2,3‐butanediol, ethanol and lactate, both, in shake flasks and stirred tank reactor cultivations. Furthermore, the average respiratory quotient correlates with the oxygen availability during the cultivation. Carbon mass balancing revealed that this reflects the increased formation of reduced metabolites with increasing oxygen limitation. The results clearly demonstrate that the respiratory quotient is a valuable online signal to reveal and understand the metabolic activity during microaerobic cultivations. The approach of combining respiratory quotient monitoring with stoichiometric considerations can be applied to other organisms and processes to define suitable cultivation conditions to produce the desired product spectrum.     

Analyses of the acetate-producing pathways in <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis> under oxygen-deprived conditions

Corynebacterium glutamicum R efficiently produces valuable chemicals from glucose under oxygen-deprived conditions. In an effort to reduce acetate as a byproduct, acetate productivity of several mutant-disrupted genes encoding possible key enzymes for acetate formation was determined. Disruption of the aceE gene that encodes the E1 enzyme of the pyruvate dehydrogenase complex resulted in almost complete elimination of acetate formation under oxygen-deprived conditions, implying that acetate synthesis under these conditions was essentially via acetyl-coenzyme A (CoA). Simultaneous disruption of pta, encoding phosphotransacetylase, and ack, encoding acetate kinase, resulted in no measurable change in acetate productivity. A mutant strain with disruptions in pta, ack and as-yet uncharacterized gene (cgR2472) exhibited 65% reduced acetate productivity compared to the parental strain, although a single disruption of cgR2472 exhibited no effect on acetate productivity. The gene cgR2472 was shown to encode a CoA-transferase (CTF) that catalyzes the formation of acetate from acetyl-CoA. These results indicate that PTA-ACK as well as CTF is involved in acetate production in C. glutamicum. This study provided basic information to reduce acetate production under oxygen-deprived conditions. An erratum to this article can be found at     

Dilution rates influence ammonia-assimilating enzyme activities and cell parameters of Selenomonas ruminantium strain D in continuous (glucose-limited) culture

Aims: The objective of this study was to examine the effect of dilution rates (Ds, varying from 0·05 to 0·42 h^?1) in glucose‐limited continuous culture on cell yield, cell composition, fermentation pattern and ammonia assimilation enzymes of Selenomonas ruminantium strain D. Methods and Results: All glucose‐limited continuous culture experiments were conducted under anaerobic conditions. Except for protein, all cell constituents including carbohydrates, RNA and DNA yielded significant cubic responses to Ds with the highest values at Ds of either 0·10 or 0·20 h^?1. At Ds higher than 0·2 h^?1, fermentation acid pattern shifted primarily from propionate and acetate to lactate production. Succinate also accumulated at the higher Ds (0·30 and 0·42 h^?1). Glucose was most efficiently utilized by S. ruminantium D at 0·20 h^?1 after which decreases in glucose and ATP yields were observed. Under energy limiting conditions, glutamine synthetase (GS) and glutamate dehydrogenase (GDH) appeared to be the major enzymes involved in nitrogen assimilation suggesting that other potential ammonia incorporating enzymes were of little importance in ammonia assimilation in S. ruminantium D. GS exhibited lower activities than GDH at all Ds, which indicates that the bacterial growth rate is not a primary regulator of their activities. Conclusions: Studied dilution rates influenced cell composition, fermentation pattern and nitrogen assimilation of S. ruminantium strain D grown in glucose‐limited continuous culture. Significance and Impact of the Study: Selenomonas ruminantium D is an ecologically and evolutionary important bacterium in ruminants and is present under most rumen dietary conditions. Characterizing the growth physiology and ammonia assimilation enzymes of S. ruminantium D during glucose limitation at Ds, which simulate the liquid turnover rates in rumen, will provide a better understanding of how this micro‐organism responds to differing growth conditions.     

Differentiation of arcA, arcB, and cpxA mutant phenotypes of Escherichia coli by sex pilus formation and enzyme regulation.

In Escherichia coli, mutations in arcA (dye) or arcB anaerobically derepress the synthesis of a multitude of enzymes of aerobic function, and mutations in arcA or cpxA impair F-pilus formation. It is thought that arcA encodes a promoter-recognizing protein, whereas arcB and cpxA encode sensor proteins which interact with the arcA product. In this study we found that anaerobic growth of a wild-type F' strain decreased the synthesis of both the enzymes and the pilus. Although the two arcA mutants examined were both anaerobically derepressed in the enzymes and impaired in aerobic pilus formation as expected, one mutant hyperproduced the pilus anaerobically. The two arcB mutants examined showed normal pilus formation when grown aerobically. When grown anaerobically they developed more pili than the wild-type strain did when grown aerobically. When a cpxA mutant was examined for synthesis of two aerobic enzymes, normal regulation was found. The available data suggest the following. The arcA product anaerobically represses certain genes of aerobic function and activates certain genes related to F function. It appears that the arcB product senses the redox or energy state; absence of the gene function shifts the arcA product to the nonrepressive form for enzyme synthesis for aerobic pathways. The cpxA product, on the other hand, senses the sexual state; absence of the gene function shifts the arcA product to the inactive form for F-pilus synthesis.