Structure of the soluble domain of a membrane-anchored thioredoxin-like protein from Bradyrhizobium japonicum reveals unusual properties.

TlpA is an unusual thioredoxin-like protein present in the nitrogen-fixing soil bacterium Bradyrhizobium japonicum. A hydrophobic N-terminal transmembrane domain anchors it to the cytoplasmic membrane, whereby the hydrophilic thioredoxin domain becomes exposed to the periplasmic space. There, TlpA catalyses an essential reaction, probably a reduction, in the biogenesis of cytochrome aa(3). The soluble thioredoxin domain (TlpA(sol)), devoid of the membrane anchor, was purified and crystallized. Oxidized TlpA(sol) crystallized as a non-covalent dimer in the space group P2(1)2(1)2(1). The X-ray structure analysis was carried out by isomorphous replacement using a xenon derivative. This resulted in a high-resolution (1.6 A) three-dimensional structure that displayed all of the features of a classical thioredoxin fold. A number of peculiar structural details were uncovered: (i) Only one of the two active-site-cysteine sulphurs (Cys72, the one closer to the N terminus) is exposed on the surface, making it the likely nucleophile for the reduction of target proteins. (ii) TlpA(sol) possesses a unique structural disulphide bond, formed between Cys10 and Cys155, which connects an unprecedented N-terminal alpha helix with a beta sheet near the C terminus. (iii) An insertion of about 25 amino acid residues, not found in the thioredoxin prototype of Escherichia coli, contributes only marginally to the thioredoxin fold, but forms an extra, surface-exposed alpha helix. This region plus another surface-exposed stretch (-Ile-Gly-Arg-Ala-), which is absent even in the closest TlpA relatives, might be considered as specificity determinants for the recognition of target proteins in the periplasm. The TlpA(sol) structure paves the way towards unraveling important structure-function relationships by rational mutagenesis.

Replacement of Pro109 by His in TlpA, a thioredoxin-like protein from Bradyrhizobium japonicum, alters its redox properties but not its in vivo functions.

TlpA, the membrane-anchored, thioredoxin-like protein from Bradyrhizobium japonicum, is essential for cytochrome aa3 biogenesis. The periplasmic domain of TlpA was previously shown to have protein thiol:disulfide oxidoreductase activity and reducing properties similar to those of cytoplasmic thioredoxins. Here, we replaced the proline-109 in its active-site sequence C107 V108 P109 C110 by a histidine residue. The resulting active-site motif (CVHC) resembles that of oxidizing thiol:disulfide oxidoreductases such as protein disulfide isomerase (PDI) and DsbA. Indeed, the TlpA variant P109H was by 66 mV more oxidizing than the wild-type protein. Nevertheless, the altered protein was even more efficient in catalyzing the reduction of insulin disulfides by dithiothreitol than the wild-type due to a faster recycling of its catalytically active, reduced form. Cells of B. japonicum expressing only the mutated tlpA gene had the same phenotypes as wild-type cells, suggesting that the change in the redox potential of TlpA was not critical for its in vivo function.

Characterisation of a protease from Escherichia coli involved in hydrogenase maturation.

The large subunits of nickel-containing hydrogenases are synthesised in a precursor form which, after nickel incorporation, is processed by proteolytic cleavage at the C-terminal end. The protease involved in processing of HycE, the large subunit of hydrogenase 3 from Escherichia coli, was purified by three chromatographic steps to apparent homogeneity. Its gene was identified by using a hybridisation probe generated by PCR with oligonucleotide primers the sequence of which was derived from the N-terminal and internal amino acid sequences. Determination of the nucleotide sequence showed that the gene is located distally and as a hitherto uncharacterised gene within the hyc operon, coding for hydrogenase 3 components. It was designated hycI. The HycI protease has a molecular mass of 17 kDa and is a monomer. Its cleavage reaction is not inhibited by conventional inhibitors of serine and metalloproteases, which correlates with the fact that the sequence does not contain signature motifs characteristic of serine-, metallo-, cysteine- or acid proteases. Homologous genes are present in other transcriptional units coding for hydrogenases.

Maturation of the large subunit (HYCE) of Escherichia coli hydrogenase 3 requires nickel incorporation followed by C-terminal processing at Arg537.

Purification of the large subunit, HYCE, of Escherichia coli hydrogenase 3 revealed that it is a nickel-containing polypeptide, which is subject to C-terminal proteolytic processing. This processing reaction could be performed in vitro with partially purified components, yielding a low-molecular mass C-terminal peptide which was resolved in a Tricine/SDS/polyacrylamide gel. N-terminal sequencing of this peptide revealed that proteolytic cleavage occurred at the C-terminal side of the arginine residue at position 537, which corresponds to the histidine residue in the highly conserved motif, DPCXXCXXH, of other (NiFe) hydrogenases thought to be involved in active site nickel coordination. Nickel-containing HYCE precursor for in vitro processing, was partially purified from strain HD708 (delta hycH) in the presence of the reducing agent dithiothreitol. Using 2-mercaptoethanol instead of dithiothreitol provided pure precursor, which was, however, no longer susceptible to in vitro processing; it proved to be devoid of nickel indicating that nickel incorporation into the HYCE precursor is a prerequisite for processing. This conclusion was supported by the finding that HYCE precursor from strain HD708 (delta hycH) chromatographed with radioactivity from 83Ni incorporated in vivo and could be processed in vitro, whereas HYCE precursor from strain BEF314 (delta hypB-E) lacking the nickel insertion system appeared to be devoid of nickel and was not sensitive to in vitro processing.