Margarida Santana scite author profile

The increasing sequence information on oxygen reductases of the haem-copper superfamily, together with the available three-dimensional structures, allows a clear identification of their common, functionally important features. Taking into consideration both the overall amino acid sequences of the core subunits and key residues involved in proton transfer, a novel hypothesis for the molecular evolution of these enzymes is proposed. Three main families of oxygen reductases are identified on the basis of common features of the core subunits, constituting three lines of evolution: (i) type A (mitochondrial-like oxidases), (ii) type B (ba3-like oxidases) and (iii) type C (cbb3-type oxidases). The first group can be further divided into two subfamilies, according to the helix VI residues at the hydrophobic end of one of the proton pathways (the so-called D-channel): (i) type A1, comprising the enzymes with a glutamate residue in the motif -XGHPEV-, and (ii) type A2, enzymes having instead a tyrosine and a serine in the alternative motif -YSHPXV-. This second subfamily of oxidases is shown to be ancestor to the one containing the glutamate residue, which in the Bacteria domain is only present in oxidases from Gram-positive or purple bacteria. It is further proposed that the Archaea domain acquired terminal oxidases by gene transfer from the Gram-positive bacteria, implying that these enzymes were not present in the last common ancestor before the divergence between Archaea and Bacteria. In fact, most oxidases from archaea have a higher amino acid sequence identity and similarity with those from bacteria, mainly from the Gram-positive group, than with oxidases from other archaea. Finally, a possible relation between the dihaemic subunit (FixP) of the cbb3 oxidases and subunit II of caa3 oxidases is discussed. As the families of haem-copper oxidases can also be identified by their subunit II, a parallel evolution of subunits I and II is suggested.

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Bacillus subtilis genome project: cloning and sequencing of the 97 kb region from 325° to 333deg;

Glaser

Kunst

Arnaud

et al. 1993

Molecular Microbiology

194

147

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In the framework of the European project aimed at the sequencing of the Bacillus subtilis genome the DNA region located between gerB (314 degrees) and sacXY (333 degrees) was assigned to the Institut Pasteur. In this paper we describe the cloning and sequencing of a segment of 97 kb of contiguous DNA. Ninety-two open reading frames were predicted to encode putative proteins among which only forty-two were found to display significant similarities to known proteins present in databanks, e.g. amino acid permeases, proteins involved in cell wall or antibiotic biosynthesis, various regulatory proteins, proteins of several dehydrogenase families and enzymes II of the phosphotransferase system involved in sugar transport. Additional experiments led to the identification of the products of new B. subtilis genes, e.g. galactokinase and an operon involved in thiamine biosynthesis.

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Bacillus subtilis F0F1 ATPase: DNA sequence of the atp operon and characterization of atp mutants

et al. 1994

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We cloned and sequenced an operon of nine genes coding for the subunits of the Bacillus subtilis FOF, ATP synthase. The arrangement of these genes in the operon is identical to that of the atp operon from Escherichia coli and from three other Bacillus species. The deduced amino acid sequences of the nine subunits are very similar to their counterparts from other organisms. We constructed two B. subtilis strains from which different parts of the atp operon were deleted. These B. subtilis atp mutants were unable to grow with succinate as the sole carbon and energy source. ATP was synthesized in these strains only by substrate-level phosphorylation. The two mutants had a decreased growth yield (43 and 56% of the wild-type level) and a decreased growth rate (61 and 66% of the wild-type level), correlating with a twofold decrease of the intracellular ATP/ADP ratio. In the absence of oxidative phosphorylation, B. subtilis increased ATP synthesis through substrate-level phosphorylation, as shown by the twofold increase of by-product formation (mainly acetate). The increased turnover of glycolysis in the mutant strain presumably led to increased synthesis of NADH, which would account for the observed stimulation of the respiration rate associated with an increase in the expression of genes coding for respiratory enzymes. It therefore appears that B. subtilis and E. coli respond in similar ways to the absence of oxidative phosphorylation.ATP plays a central role in energy transduction in living organisms. Although some ATP is synthesized in aerobiosis by soluble enzyme systems like glycolytic enzymes that perform substrate-level phosphorylation, most is synthesized by membrane-bound enzyme complexes through oxidative phosphorylation. The energy-transducing membranes, where these complexes are found, are the plasma membrane of prokaryotic cells, the inner membrane of mitochondria, and the thylakoid membrane of chloroplasts. ATP synthesis from ADP and Pi is catalyzed by the ATP synthase complex and is driven by the proton gradient. This gradient is generated by respiration in mitochondria and respiring bacteria and by photosynthesis in chloroplasts and photosynthetic bacteria.ATP

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Presence and potential role of thermophilic bacteria in temperate terrestrial environments

Guisado

Santana

Gonzalez

2011

Naturwissenschaften

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Organic sulfur and nitrogen are major reservoirs of these elements in terrestrial systems, although their cycling remains to be fully understood. Both sulfur and nitrogen mineralization are directly related to microbial metabolism. Mesophiles and thermophiles were isolated from temperate environments. Thermophilic isolates were classified within the Firmicutes, belonging to the Geobacillus, Brevibacillus, and Ureibacillus genera, and showed optimum growth temperatures between 50°C and 60°C. Sulfate and ammonium produced were higher during growth of thermophiles both for isolated strains and natural bacterial assemblages. They were positively related to organic nutrient load. Temperature also affected the release of sulfate and ammonium by thermophiles. Quantitative, real-time reverse-transcription polymerase chain reaction on environmental samples indicated that the examined thermophilic Firmicutes represented up to 3.4% of the total bacterial community RNA. Temperature measurements during summer days showed values above 40°C for more than 10 h a day in soils from southern Spain. These results support a potential role of thermophilic bacteria in temperate terrestrial environments by mineralizing organic sulfur and nitrogen ruled by the existence and length of warm periods.

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The ‘strict’ anaerobe Desulfovibrio gigas contains a membrane‐bound oxygen‐reducing respiratory chain

et al. 2001

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Sulfate-reducing bacteria are considered as strict anaerobic microorganisms, in spite of the fact that some strains have been shown to tolerate the transient presence of dioxygen. This report shows that membranes from Desulfovibrio gigas grown in fumarate/sulfate contain a respiratory chain fully competent to reduce dioxygen to water. In particular, a membrane-bound terminal oxygen reductase, of the cytochrome bd family, was isolated, characterized, and shown to completely reduce oxygen to water. This oxidase has two subunits with apparent molecular masses of 40 and 29 kDa. Using NADH or succinate as electron donors, the oxygen respiratory rates of D. gigas membranes are comparable to those of aerobic organisms (3.2 and 29 nmol O 2 min 31 mg protein 31 , respectively). This strict anaerobic' bacterium contains all the necessary enzymatic complexes to live aerobically, showing that the relationships between oxygen and anaerobes are much more complex than originally thought. ß 2001 Published by Elsevier Science B.V. on behalf of the Federation of European Biochemical Societies.

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