Membrane-bound NADPH dehydrogenase- and ferredoxin: NADP oxidoreductase activity involved in electron transport during acetate oxidation to CO2 in Desulfobacter postgatei

The alternative oxidases are membrane-bound monotopic terminal electron transport proteins found in all plants and in some agrochemically important fungi and parasites including Trypansoma brucei, which is the causative agent of trypanosomiasis. They are integral membrane proteins and reduce oxygen to water in a four electron process. The recent elucidation of the crystal structure of the trypanosomal alternative oxidase at 2.85 Å (1 Å=0.1 nm) has revealed salient structural features necessary for its function. In the present review we compare the primary and secondary ligation spheres of the alternative oxidases with other di-iron carboxylate proteins and propose a mechanism for the reduction of oxygen to water.

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Interaction of respiratory and photosynthetic electron transport, and evidence for membrane-bound pyridine-nucleotide dehydrogenases in Anabaena variabilis

Physiologia Plantarum ◽

10.1111/j.1399-3054.1984.tb04915.x ◽

1984 ◽

Vol 60 (4) ◽

pp. 479-483 ◽

Cited By ~ 19

Author(s):

Erwin Sturzl ◽

Siegfried Scherer ◽

Peter Boger

Keyword(s):

Electron Transport ◽

Photosynthetic Electron Transport ◽

Pyridine Nucleotide ◽

Anabaena Variabilis ◽

Membrane Bound

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Membrane-bound ATPase and electron transport system of Sulfolobus acidocaldarius

Systematic and Applied Microbiology ◽

10.1016/s0723-2020(86)80030-3 ◽

1986 ◽

Vol 7 (2-3) ◽

pp. 342-345 ◽

Cited By ~ 28

Author(s):

Takayoshi Wakagi ◽

Tairo Oshima

Keyword(s):

Electron Transport ◽

Transport System ◽

Electron Transport System ◽

Sulfolobus Acidocaldarius ◽

Membrane Bound

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Effect of cell water amount on photosynthetic yield in the cyanobacterium Nostoc flagelliforme and involvement of NADPH dehydrogenase-mediated cyclic electron transport

Journal of Applied Phycology ◽

10.1007/s10811-008-9348-y ◽

2008 ◽

Vol 21 (2) ◽

pp. 179-184 ◽

Cited By ~ 2

Author(s):

Lanzhen Wei ◽

Weimin Ma ◽

Quanxi Wang ◽

Hualing Mi

Keyword(s):

Electron Transport ◽

Cyclic Electron Transport ◽

Nostoc Flagelliforme ◽

Cell Water ◽

Photosynthetic Yield ◽

Nadph Dehydrogenase ◽

Water Amount

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Oxidation–reduction titration of cytochrome components in the electron transport chain of Azotobacter vinelandii

Canadian Journal of Biochemistry ◽

10.1139/o81-020 ◽

1981 ◽

Vol 59 (2) ◽

pp. 137-144 ◽

Cited By ~ 13

Author(s):

Tsanyen Yang

Keyword(s):

Electron Transport ◽

Cytochrome B ◽

Absorption Maximum ◽

Azotobacter Vinelandii ◽

Reactive Component ◽

Midpoint Potential ◽

Oxidation Reduction ◽

Membrane Bound ◽

The Individual ◽

Cytochrome D

The multiple cytochrome components in the electron transport particle of Azotobacter vinelandii were resolved and their oxidation–reduction midpoint potentials were determined by a simultaneous potentiometric and absorption measurements under anaerobic condition with or without CO. The midpoints of the individual cytochrome component corresponding to the membrane-bound types were also determined in the solubilized fractions prepared by a differential detergent solubilization of the membrane particles of A. vinelandii. Two cytochromes of b type, one with an absorption maximum measured at 559 nm and another at 561 nm in the membrane particle, were resolved and their Em, 7.4 values determined to be −30 mV and +122 mV, respectively. Cytochrome b559 reacted with CO readily in both membrane-bound and solubilized forms, however, cytochrome b561 was inert to CO treatment. Only one cytochrome of c type (c4) measured at 575–551 nm was resolved, its midpoint potential at pH 7.4 was +322 mV in the membrane-bound form and +278 mV in the solubilized form. This c-type cytochrome had no CO reactivity. Cytochrome d, a CO-reactive component, had a midpoint of +270 mV in the membrane fraction. The midpoint of cytochrome a1 in its membrane-bound form could not be measured accurately because of its low concentration. However, in the solubilized preparations, cytochrome a1 apparently had a red shift with an absorption maximum at 613 nm, with an estimated Em, 7.4 of −45 mV, while cytochrome d was no longer detected, possibly because of denaturation.

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Periplasmic nitrate reduction in Wolinella succinogenes: cytoplasmic NapF facilitates NapA maturation and requires the menaquinol dehydrogenase NapH for membrane attachment

Microbiology ◽

10.1099/mic.0.029983-0 ◽

2009 ◽

Vol 155 (8) ◽

pp. 2784-2794 ◽

Cited By ~ 26

Author(s):

Melanie Kern ◽

Jörg Simon

Keyword(s):

Electron Transport ◽

Nitrate Reductase ◽

Deletion Mutant ◽

Electron Flow ◽

Gene Clusters ◽

Nitrate Respiration ◽

Wolinella Succinogenes ◽

Periplasmic Nitrate Reductase ◽

Iron Sulfur ◽

Membrane Bound

Various nitrate-reducing bacteria produce proteins of the periplasmic nitrate reductase (Nap) system to catalyse electron transport from the membraneous quinol pool to the periplasmic nitrate reductase NapA. The composition of the corresponding nap gene clusters varies but, in addition to napA, genes encoding at least one membrane-bound quinol dehydrogenase module (NapC and/or NapGH) are regularly present. Moreover, some nap loci predict accessory proteins such as the iron–sulfur protein NapF, whose function is poorly understood. Here, the role of NapF in nitrate respiration of the Epsilonproteobacterium Wolinella succinogenes was examined. Immunoblot analysis showed that NapF is located in the membrane fraction in nitrate-grown wild-type cells whereas it was found to be a soluble cytoplasmic protein in a napH deletion mutant. This finding indicates the formation of a membrane-bound NapGHF complex that is likely to catalyse NapH-dependent menaquinol oxidation and electron transport to the iron–sulfur adaptor proteins NapG and NapF, which are located on the periplasmic and cytoplasmic side of the membrane, respectively. The cysteine residues of a CX3CP motif and of the C-terminal tetra-cysteine cluster of NapH were found to be required for interaction with NapF. A napF deletion mutant accumulated the catalytically inactive cytoplasmic NapA precursor, suggesting that electron flow or direct interaction between NapF and NapA facilitated NapA assembly and/or export. On the other hand, NapA maturation and activity was not impaired in the absence of NapH, demonstrating that soluble NapF is functional. Each of the four tetra-cysteine motifs of NapF was modified but only one motif was found to be essential for efficient NapA maturation. It is concluded that the NapGHF complex plays a multifunctional role in menaquinol oxidation, electron transfer to periplasmic NapA and maturation of the cytoplasmic NapA precursor.

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The relation of phospholipid and membrane-bound ATPase in mitochondrial electron transport particles

Journal of Bioenergetics and Biomembranes ◽

10.1007/bf01516907 ◽

1970 ◽

Vol 1 (5) ◽

pp. 457-465 ◽

Cited By ~ 8

Author(s):

Ronald Berezney ◽

Y. C. Awasthi ◽

F. L. Crane

Keyword(s):

Electron Transport ◽

Membrane Bound

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Characterization studies on the membrane-bound adenosine triphosphatase (ATPase) of Azotobacter vinelandii

Canadian Journal of Microbiology ◽

10.1139/m75-263 ◽

1975 ◽

Vol 21 (11) ◽

pp. 1807-1814 ◽

Cited By ~ 2

Author(s):

Peter Jurtshuk ◽

John E. McEntire

Keyword(s):

Electron Transport ◽

Atpase Activity ◽

Azotobacter Vinelandii ◽

Specific Activity ◽

Maximal Activity ◽

Molar Ratio ◽

Supernatant Fraction ◽

Time Interval ◽

Time Intervals ◽

Membrane Bound

The adenosinetriphosphatase (ATPase) (EC 3.6.1.3) activity in Azotobacter vinelandii concentrates in the membranous R3 fraction that is directly associated with Azotobacter electron transport function. Sonically disrupted Azotobacter cells were examined for distribution of ATPase activity and the highest specific activity (and activity units) was consistently found in the particulate R3 membranous fraction which sediments on ultracentrifugation at 144 000 × g for 2 h. When the sonication time interval was increased, the membrane-bound ATPase activity could neither be solubilized nor released into the supernatant fraction. Optimal ATPase activity occurred at pH 8.0; Mg2+ ion when added to the assay was stimulatory. Maximal activity always occurred when the Mg2+:ATP stoichiometry was 1:1 on a molar ratio at the 5 mM concentration level. Sodium and potassium ions had no stimulatory effect. The reaction kinetics were linear for the time intervals studied (0–60 min). The membrane-bound ATPase in the R3 fraction was stimulated 12-fold by treatment with trypsin, and fractionation studies showed that trypsin treatment did not solubilize ATPase activity off the membranous R3 electron transport fraction. The ATPase was not cold labile and the temperature during the preparation of the R3 fraction had no effect on activity; overnight refrigeration at 4 °C, however, resulted in a 25% loss of activity as compared with a 14% loss when the R3 fraction was stored overnight at 25 °C. A marked inactivation (although variable, usually about 60%) did occur by overnight freezing (−20 °C), and subsequent sonication failed to restore ATPase activity. This indicates that membrane reaggregation (by freezing) was not responsible for ATPase inactivation. The addition of azide, ouabain, 2,4-dinitrophenol, or oligomycin to the assay system resulted in neither inhibition nor stimulation of the ATPase activity. The property of trypsin activation and that ATPase activity is highest in the R3 electron transport fraction suggests that its probable functional role is in coupling of electron transport to oxidative phosphorylation.

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