A novel very small subunit of a selenium containing [NiFe] hydrogenease of <i>Methanococcus voltae</i> is postranslationally processed by cleavage at a defined position

Sorgenfrei, Oliver; Linder, Dietmar; Karas, Michael; Klein, Albrecht

doi:10.1111/j.1432-1033.1993.tb17888.x

Cited by 76 publications

(54 citation statements)

References 19 publications

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“…In the purified coenzyme-F420 non-reducing selenium-containing NiFe-hydrogenase from Methanococcus voltae, this conserved motif is located on a third subunit composed of 25 residues. The corresponding vhuU gene encodes a precursor of 44 amino acids whose C-terminal part is removed after the histidyl residue during the processing [12]. The structural data indicate that the two conserved cysteines in the motif DPCxxCxxH in the large subunits of D. gigas provide the ligands required for the binding of nickel [11].…”

Section: Introductionmentioning

confidence: 99%

Requirement for nickel of the transmembrane translocation of NiFe‐hydrogenase 2 in Escherichia coli

Rodrigue¹,

Boxer

Mandrand‐Berthelot³

et al. 1996

FEBS Letters

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The cellular location of membrane-bound NiFehydrogenase 2 (HYD2) from Escherichia coil was studied by immunobiot analysis and by activity staining. Treatment of spheroplasts with trypsin was able to release active HYD2 into the soluble fraction, indicating that HYD2 is attached to the periplasmic side of the cytoplasmic membrane and that HYD2 undergoes a trans-membrane translocation during its biosynthesis. By using a n/k mutant deficient in the high affinity specific nickel transport system, we show that the intracellniar availability of nickel is essential for the processing of the large subunit and for the transmembrane translocation of HYD2. We also demonstrate that the processing of the precursor, which is related with nickel incorporation, can occur in the membrane-depleted soluble fraction and that it is associated with the increase in resistance to proteolysis of the processed form of the large subunit. The mechanism of the transmembrane translocation of HYD2 is discussed.

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Section: Introductionmentioning

confidence: 99%

Requirement for nickel of the transmembrane translocation of NiFe‐hydrogenase 2 in Escherichia coli

Rodrigue¹,

Boxer

Mandrand‐Berthelot³

et al. 1996

FEBS Letters

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“…Near the carboxy terminus, HoxH possesses a strongly conserved motif ending with a histidine. The formation of the mature protein and the incorporation of Ni into it might require the cleavage of a stretch of 26 amino acids behind this His similar as in the proteins from Methanococcus voltae [16], E. eoli (hydrogenase 3) [17], and A. eutrophus [18]. An N-terminal leader sequence is also not observed in HoxH of A. nidulans.…”

Section: (K) (I) (S) Vflddqgnaementioning

confidence: 99%

Cloning, molecular analysis and insertional mutagenesis of the bidirectional hydrogenase genes from the cyanobacterium Anacystis nidulans

et al. 1996

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“…6). In the case of the wild-type enzyme, the 46-kDa VhuA subunit [14] was detected. In the case of the mutant enzyme, the antiserum reacted with a larger polypeptide.…”

Section: Fig 5 Sds/polyacrylamide Gel Analysis Of the Purified Vhu mentioning

confidence: 99%

“…Therefore, this strain does not carry genetic information for the wild-type Vhu-hydrogenase. The purification of the Vhuhydrogenase and the mutant enzyme was performed as described [14] with the following modifications. The active DEAE-Sepharose fraction was adjusted to 0.8 M ammonium sulfate in 50 mM Tris/HCl pH 7.5 (buffer A).…”

Section: Methodsmentioning

confidence: 99%

“…It appears that the gene normally encoding the largest subunit has been split. The homologue of the larger N-terminal part of the subunit carrying the primary reaction center is encoded by the gene vhuA, directly followed by a very small gene vhuU encoding what would be the C-terminal part of a normal large subunit [14,17]. The vhuU gene product is C-terminally processed, probably prior to its incorporation into the enzyme and the formation of the [NiFe] cluster to which it contributes a cysteinyl residue and a selenocysteinyl residue.…”

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

Pfeiffer

Bingemann

Klein

1998

European Journal of Biochemistry

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[NiFe]-hydrogenases generally carry the bimetallic Ni-Fe reaction center on their largest subunit. The [NiFeSe]-hydrogenase Vhu from Methanococcus voltae has an unusual subunit composition. Some of the amino acids participating in the formation of the reaction center are within a separate, very small subunit, called VhuU. It consists of only 25 amino acids and contains the selenocysteinyl residue, a ligand to the Ni atom. We have tested whether the special configuration of the Vhu-hydrogenase is of particular biochemical relevance. We have constructed a fusion subunit derived from the VhuA and VhuU subunits by generating a gene fusion which was inserted into the chromosome of M. voltae by gene replacement. The enzyme was purified and shown to be as active as the wild-type enzyme. M. voltae carries the genetic information for four different [NiFe]-hydrogenases. In addition to the Vhu-hydrogenase, a second selenium-containing enzyme, Fru, has been purified. Two selenium-free enzymes, Vhc and Frc, are homologues of Vhu and Fru, respectively. Their gene groups, vhc and frc are transcribed only upon selenium depletion. The selenium-containing subunit VhuU has been implicated in their negative regulation. However, cells containing the fusion hydrogenase still exhibited normal regulation of the vhc and frc promoter activities as tested in reporter gene constructs. This indicates that the free VhuU polypeptide is not required for the negative regulation of the vhc or frc genes. second subunit. These two subunits form a functional enzyme as tested with artificial electron acceptors.Two [NiFeSe]-hydrogenases have been purified from the archaeon Methanococcus voltae. They have been characterized with respect of the electronic configurations of their primary reaction centers at different redox states [14Ϫ16]. One of these enzymes, termed Fru, reduces the deazaflavine cofactor F 420. It consists of three subunits with the canonical large subunit carrying the [NiFe] cluster. The other, Vhu, whose natural electron acceptor remains unknown, has a special subunit composition. While the subunit containing the Fe-S clusters corresponds to those of other [NiFe]-hydrogenases, the [NiFe] center is formed by two subunits each contributing two ligands [12,13]. It appears that the gene normally encoding the largest subunit has been split. The homologue of the larger N-terminal part of the subunit carrying the primary reaction center is encoded by the gene vhuA, directly followed by a very small gene vhuU encoding what would be the C-terminal part of a normal large subunit [14,17]. The vhuU gene product is C-terminally processed, probably prior to its incorporation into the enzyme and the formation of the [NiFe] cluster to which it contributes a cysteinyl residue and a selenocysteinyl residue. This processing is a general feature and normally occurs at the C-terminus of the large subunit polypetide concomitantly with the incorporation of Ni [18].M. voltae carries genetic information for two further [NiFe]-hydrogenases, Frc and Vhc, wh...

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A novel very small subunit of a selenium containing [NiFe] hydrogenease of Methanococcus voltae is postranslationally processed by cleavage at a defined position

Cited by 76 publications

References 19 publications

Requirement for nickel of the transmembrane translocation of NiFe‐hydrogenase 2 in Escherichia coli

Requirement for nickel of the transmembrane translocation of NiFe‐hydrogenase 2 in Escherichia coli

Cloning, molecular analysis and insertional mutagenesis of the bidirectional hydrogenase genes from the cyanobacterium Anacystis nidulans

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

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