Anait Vassilian scite author profile

The hyc operon of Escherichia coli encodes the H 2 -evolving hydrogenase 3 (Hyd-3) complex that, in conjunction with formate dehydrogenase H (Fdh-H), constitutes a membrane-associated formate hydrogenlyase (FHL) catalyzing the disproportionation of formate to CO 2 and H 2 during fermentative growth at low pH. Recently, an operon (hyf) encoding a potential second H 2 -evolving hydrogenase (Hyd-4) was identified in E. coli. In this study the roles of the hyc-and hyf-encoded systems in formate-dependent H 2 production and Fdh-H activity have been investigated. In cells grown on glucose under fermentative conditions at slightly acidic pH the production of H

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Multiple and reversible hydrogenases for hydrogen production byEscherichia coli: dependence on fermentation substrate, pH and the F₀F₁-ATPase

Trchounian

Poladyan

Vassilian

et al. 2012

Critical Reviews in Biochemistry and Molecular Biology

102

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Molecular hydrogen (H(2)) can be produced via hydrogenases during mixed-acid fermentation by bacteria. Escherichia coli possesses multiple (four) hydrogenases. Hydrogenase 3 (Hyd-3) and probably 4 (Hyd-4) with formate dehydrogenase H (Fdh-H) form two different H(2)-evolving formate hydrogen lyase (FHL) pathways during glucose fermentation. For both FHL forms, the hycB gene coding small subunit of Hyd-3 is required. Formation and activity of FHL also depends on the external pH ([pH](out)) and the presence of formate. FHL is related with the F(0)F(1)-ATPase by supplying reducing equivalents and depending on proton-motive force. Two other hydrogenases, 1 (Hyd-1) and 2 (Hyd-2), are H(2)-oxidizing enzymes during glucose fermentation at neutral and low [pH](out). They operate in a reverse, H(2)-producing mode during glycerol fermentation at neutral [pH](out). Hyd-1 and Hyd-2 activity depends on F(0)F(1). Moreover, Hyd-3 can also work in a reverse mode. Therefore, the operation direction and activity of all Hyd enzymes might determine H(2) production; some metabolic cross-talk between Hyd enzymes is proposed. Manipulating of different Hyd enzymes activity is an effective way to enhance H(2) production by bacteria in biotechnology. Moreover, a novel approach would be the use of glycerol as feedstock in fermentation processes leading to H(2) production, reduced fuels and other chemicals with higher yields than those obtained by common sugars.

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Oxidative and Reductive Routes of Glycerol and Glucose Fermentation by Escherichia coli Batch Cultures and Their Regulation by Oxidizing and Reducing Reagents at Different pHs

et al. 2012

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Glycerol and glucose fermentation redox routes by Escherichia coli and their regulation by oxidizing and reducing reagents were investigated at different pHs. Cell growth was followed by decrease of pH and redox potential (E ( h )). During glycerol utilization at pH 7.5 ∆pH, the difference between initial and end pH, was lower compared with glucose fermentation. After 8 h growth, during glycerol utilization E ( h ) dropped down to negative values (-150 mV) but during glucose fermentation it was positive (+50 mV). In case of glycerol H(2) was evolved at the middle log phase while during glucose fermentation H(2) was produced during early log phase. Furthermore, upon glycerol utilization, oxidizer potassium ferricyanide (1 mM) inhibited both cell growth and H(2) formation. Reducing reagents DL-dithiothreitol (3 mM) and dithionite (1 mM) inhibited growth but stimulated H(2) production. The findings point out the importance of reductive conditions for glycerol fermentation and H(2) production by E. coli.

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Relationship of the Escherichia coli TrkA System of Potassium Ion Uptake with the F0F1-ATPase Under Growth Conditions Without Anaerobic or Aerobic Respiration

Trchоunian

Ohanjanyan

Bagramyan

et al. 1998

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K+ uptake by the Escherichia coli TrkA system is unusual in that it requires both ATP and deltamuH+; a relation with H+ circulation through the membrane is therefore suggested. The relationship of this system with the F0F1-ATPase was studied in intact cells grown under different conditions. A significant increase of the N,N'-dicyclohexylcarbodiimide(DCCD)-inhibited H+ efflux through the F0F1 by 5 mM K+, but not by Na+ added into the potassium-free medium was revealed only in fermenting wild-type or parent cells, that were grown under anaerobic conditions without anaerobic or aerobic respiration and with the production of H2. Such an increase disappeared in the deltaunc or the trkA mutants that have altered F0F1 or defective TrkA, respectively. This finding indicates a closed relationship between TrkA and F0F1, with these transport systems being associated in a single mechanism that functions as an ATP-driven H(+)-K(+)-exchanging pump. A DCCD-inhibited H(+)-L(+)-exchange through these systems with the fixed stoichiometry of H+ and K+ fluxes (2H+/K+) and a higher K+ gradient between the cytoplasm and the external medium were also found in these bacteria. They were not observed in cells cultured under anaerobic conditions in the presence of nitrate or under aerobic conditions with respiration and without production of H2. The role of anaerobic or aerobic respiration as a determinant of the relationship of the TrkA with the F0F1 is postulated. Moreover, an increase of DCCD-inhibited H+ efflux by added K+, as well as the characteristics of DCCD-sensitive H(+)-K(+)-exchange found in a parent strain, were lost in the arcA mutant with a defective Arc system, suggesting a repression of enzymes in respiratory pathways. In addition, K+ influx in the latest mutant was not markedly changed by valinomycin or with temperature. The arcA gene product or the Arc system is proposed to be implicated in the regulation of the relationship between TrkA and F0F1.

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Relationship between the F0F1-ATPase and the K+-transport system within the membrane of anaerobically grownEscherichia coli. N,N?-dicyclohexylcarbodiimide-sensitive ATPase activity in mutants with defects in K+-transport

Trchоunian

Vassilian

1994

J Bioenerg Biomembr

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A considerable (2-fold) stimulation of the DCCD-sensitive ATPase activity by K+ or Rb+, but not by Na+, over the range of zero to 100 mM was shown in the isolated membranes of E. coli grown anaerobically in the presence of glucose. This effect was observed only in parent and in the trkG, but not in the trkA, trkE, or trkH mutants. The trkG or the trkH mutant with an unc deletion had a residual ATPase activity not sensitive to DCCD. A stimulation of the DCCD-sensitive ATPase activity by K+ was absent in the membranes from bacteria grown anaerobically in the presence of sodium nitrate. Growth of the trkG, but not of other trk mutants, in the medium with moderate K+ activity did not depend on K+ concentration. Under upshock, K+ accumulation was essentially higher in the trkG mutant than in the other trk mutant. The K(+)-stimulated DCCD-sensitive ATPase activity in the membranes isolated from anaerobically grown E. coli has been shown to depend absolutely on both the F0F1 and the Trk system and can be explained by a direct interaction between these transport systems within the membrane of anaerobically grown bacteria with the formation of a single supercomplex functioning as a H(+)-K+ pump. The trkG gene is most probably not functional in anaerobically grown bacteria.

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Anait Vassilian

The roles of hydrogenases 3 and 4, and the F₀F₁‐ATPase, in H₂ production by Escherichia coli at alkaline and acidic pH

Multiple and reversible hydrogenases for hydrogen production byEscherichia coli: dependence on fermentation substrate, pH and the F₀F₁-ATPase

Oxidative and Reductive Routes of Glycerol and Glucose Fermentation by Escherichia coli Batch Cultures and Their Regulation by Oxidizing and Reducing Reagents at Different pHs

Relationship of the Escherichia coli TrkA System of Potassium Ion Uptake with the F0F1-ATPase Under Growth Conditions Without Anaerobic or Aerobic Respiration

Relationship between the F0F1-ATPase and the K+-transport system within the membrane of anaerobically grownEscherichia coli. N,N?-dicyclohexylcarbodiimide-sensitive ATPase activity in mutants with defects in K+-transport

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Anait Vassilian

The roles of hydrogenases 3 and 4, and the F0F1‐ATPase, in H2 production by Escherichia coli at alkaline and acidic pH

Multiple and reversible hydrogenases for hydrogen production byEscherichia coli: dependence on fermentation substrate, pH and the F0F1-ATPase

Oxidative and Reductive Routes of Glycerol and Glucose Fermentation by Escherichia coli Batch Cultures and Their Regulation by Oxidizing and Reducing Reagents at Different pHs

Relationship of the Escherichia coli TrkA System of Potassium Ion Uptake with the F0F1-ATPase Under Growth Conditions Without Anaerobic or Aerobic Respiration

Relationship between the F0F1-ATPase and the K+-transport system within the membrane of anaerobically grownEscherichia coli. N,N?-dicyclohexylcarbodiimide-sensitive ATPase activity in mutants with defects in K+-transport

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The roles of hydrogenases 3 and 4, and the F₀F₁‐ATPase, in H₂ production by Escherichia coli at alkaline and acidic pH

Multiple and reversible hydrogenases for hydrogen production byEscherichia coli: dependence on fermentation substrate, pH and the F₀F₁-ATPase