Fusion of two subunits does not impair the function of a [NiFeSe]‐hydrogenase in the archaeon <i>Methanococcus voltae</i>

Pfeiffer, Mat­thias; Bingemann, Ruth; Klein, Albrecht

doi:10.1046/j.1432-1327.1998.2560447.x

Cited by 22 publications

(17 citation statements)

References 35 publications

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“…A reporter gene construct was used to show this effect. M. voltae strain V1 carrying the Escherichia coli ␤-glucuronidase gene uidA under the control of the regulated vhc hydrogenase promoter (20) was grown under selenium limitation and shown to produce ␤-glucuronidase. Upon addition of dimethylselenide, the hydrogenase promoter was shut down, indicating that the internal selenium concentration necessary to affect the repression had been exceeded (Table 3).…”

Section: Resultsmentioning

confidence: 99%

Dimethylselenide Demethylation Is an Adaptive Response to Selenium Deprivation in the Archaeon Methanococcus voltae

Niess

Klein

2004

J Bacteriol

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The archaeon Methanococcus voltae needs selenium for optimal growth. A gene group most likely involved in the demethylation of dimethylselenide was discovered, the expression of which is induced upon selenium deprivation. The operon comprises open reading frames for a corrinoid protein and two putative methyltransferases. It is shown that the addition of dimethylselenide to selenium-depleted growth medium relieves the lack of selenium, as indicated by the repression of a promoter of a transcription unit encoding selenium-free hydrogenases which is normally active only upon selenium deprivation. Knockout mutants of the corrinoid protein or one of the two methyltransferase genes did not show repression of the hydrogenase promoter in the presence of dimethylselenide. The mutation of the other methyltransferase gene had no effect. Growth rates of the two effective mutants were reduced compared to wild-type cells in selenium-limited medium in the presence of dimethylselenide.Selenium is a trace element which is important for many organisms. It is a constituent of proteins, where it is found as selenocysteine or selenomethionine, and of special nucleotides of tRNA bases. High concentrations of selenium are toxic for most organisms. Detoxification can be achieved by volatilization through methylation. Different methylation products have been found. The most abundant one is dimethylselenide, which can probably be generated in different ways from inorganic selenium compounds. Dimethylselenide production is performed by microorganisms and plants and has been monitored in soil and marine environments (9).Although selenium is widely distributed in the environment, it is not always readily available. While inorganic selenium compounds such as selenite and selenate are soluble, selenides can be very insoluble (12) as is elementary selenium, which can be formed from the oxidized species. Selenium can thus become limiting in anoxic environments. Access to selenium is essential for organisms depending on selenium-containing enzymes in their central metabolism. This is the case for at least two known methanogenic archaea, Methanocaldococcus jannaschii and Methanococcus voltae. Both organisms convert hydrogen and carbon dioxide to methane, whereby the cells generate their energy. Two selenium-containing hydrogenases, enzymes needed to oxidize hydrogen for the generation of electrons, are involved in the methanogenic pathway (5,25,26). Limiting selenium in growth medium for M. voltae leads to a reduced growth rate (28), and the knockout of a gene encoding a selenium-containing subunit of a hydrogenase has not been possible (19). While limited growth of M. voltae has been observed under selenium depletion, M. jannaschii cannot grow without selenium (6, 16).It was previously shown that M. voltae carries genes encoding selenium-free isoenzymes of its selenium-containing hydrogenases which are only transcribed upon selenium limitation and most likely supplement the selenium enzymes (3). The cell can thus react to the deprivation of the...

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Section: Resultsmentioning

confidence: 99%

Dimethylselenide Demethylation Is an Adaptive Response to Selenium Deprivation in the Archaeon Methanococcus voltae

Niess

Klein

2004

J Bacteriol

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“…A role in the negative regulation of the frc and vhc transcription in the presence of selenium has been discussed (Sorgenfrei et al 1997). Recently, a mutant of M. voltae that carries a fusion of the vhuA gene and the vhuU gene to form a composite subunit equivalent (VhuF) to the large subunits of the common [NiFe]-hydrogenases of other prokaryotes has been constructed (Pfeiffer et al 1998). This mutant is viable when grown under selenium depletion, although in this mutant the free vhuU gene product is no longer available and still shows the normal transcriptional regulation of the genes encoding the selenium-free [NiFe]-hydrogenases.…”

Section: Discussionmentioning

confidence: 99%

“…8. As controls we included wild-type DNA and DNA from a transformant carrying a fusion of genes vhuA and vhuU, named vhuF, which results in the synthesis of a functional fusion subunit, VhuF (Pfeiffer et al 1998). This transformant had been produced using an identical vector, except that it contained the vhuF gene instead of the vhuA gene followed by the vhuU deletion.…”

Section: Introduction Of a Vhuu Deletion Into The Chromosome Of M Vomentioning

confidence: 99%

“…A Assumed mode of integration into a replication fork and asymmetric recombination, followed by the separation of the daughter chromosomes. The chromosomal configuration of the control carrying the vhuF fusion gene after gene replacement (Pfeiffer et al 1998) is also shown. The shaded symbols show the pac cassette flanked by the Pmcr promoter (triangle) and the Tmcr terminator (diamond).…”

Section: Introduction Of a Vhuu Deletion Into The Chromosome Of M Vomentioning

confidence: 99%

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The vhuU gene encoding a small subunit of a selenium-containing [NiFe]-hydrogenase in Methanococcus voltae appears to be essential for the cell

Pfeiffer

Bestgen²,

Burger³

et al. 1998

Archives of Microbiology

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We developed a general method for the site-specific deletion of gene sequences to obtain new selectable markers in the archaeon Methanococcus voltae. Using a deletion in the hisA gene, a vector was integrated into the chromosome by homologous recombination, thereby reconstituting histidine prototrophy. The vector contained the beta-glucuronidase gene uidA of Escherichia coli as a reporter under the control of an M. voltae promoter that normally drives the expression of a selenium-free [NiFe]-hydrogenase after selenium deprivation. This construct has allowed us to check whether the selenium supply was sufficiently low to induce the transcription of the genes encoding the selenium-free hydrogenases. We tried to introduce a chromosomal deletion of the vhuU gene of the archaeon M. voltae by gene replacement and by keeping the cells under selenium deprivation. The gene vhuU encodes the very small, selenocysteine-containing subunit that is part of the primary reaction center of the Vhu hydrogenase. All transformants bearing the deletion also contained the vhuU wild-type gene. Therefore, the vhuU gene appears to be essential for the cell even under conditions that lead to the induction of the selenium-free homologue Vhc of the Vhu hydrogenase.

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“…These two subunits are encoded by the vhuA and vhuU genes that probably resulted from a gene splitting event. The fusion of the vhuA and vhuU genes has no effect in the activity of the enzyme [30] and the small fragment is believed to be important in the expression regulation of these Hases [28] . VhuG is the small electron transferring subunit, and VhuD mediates the electron transfer between the VhuG and the Hdr [2b, 27] .…”

Section: Distributionmentioning

confidence: 99%

Nickel–Iron–Selenium Hydrogenases – An Overview

et al. 2011

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[NiFeSe] hydrogenases are a sub-group of the large family of [NiFe] hydrogenases in which a selenocysteine ligand is coordinating the Ni at the active site. As observed for other selenoproteins, the [NiFeSe] hydrogenases display much higher catalytic activities than their Cys-containing homologues. Here we review the biochemical, catalytic, spectroscopic and structural properties of known [NiFeSe] hydrogenases, namely from the Hys, Fru and Vhu families. A survey of new [NiFeSe] hydrogenases present in the databases showed that all enzymes belong to either group 1 periplasmic uptake hydrogenases (Hys) or to group 3 cytoplasmic hydrogenases (Fru and Vhu), and are present in either sulfate-reducing or methanogenic microorganisms. In both kinds of organisms the [NiFeSe] hydrogenases are preferred over their Cyscontaining homologues if selenium is available. Since no structural information is available for the Vhu and Fru enzymes, we have modelled the large subunit of these enzymes and analyzed the area surrounding the active site. Three [NiFeSe] hydrogenases of the Hys and Vhu types were identified in which the selenocysteine residue is found in a different location in the sequence, which should result in a surprising coordination to the Ni as a bridging, rather than terminal, ligand. The high activity and fast reactivation, together with a degree of oxygen tolerance for the H 2 -production activity, make the Hys hydrogenases attractive catalysts for technological applications. ____________ [a]Protein Modeling

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Fusion of two subunits does not impair the function of a [NiFeSe]‐hydrogenase in the archaeon Methanococcus voltae

Cited by 22 publications

References 35 publications

Dimethylselenide Demethylation Is an Adaptive Response to Selenium Deprivation in the Archaeon Methanococcus voltae

Dimethylselenide Demethylation Is an Adaptive Response to Selenium Deprivation in the Archaeon Methanococcus voltae

The vhuU gene encoding a small subunit of a selenium-containing [NiFe]-hydrogenase in Methanococcus voltae appears to be essential for the cell

Nickel–Iron–Selenium Hydrogenases – An Overview

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