Frank Sargent scite author profile

We describe the identification of two Escherichia coli genes required for the export of cofactor-containing periplasmic proteins, synthesized with signal peptides containing a twin arginine motif. Both gene products are homologous to the maize HCF106 protein required for the translocation of a subset of lumenal proteins across the thylakoid membrane. Disruption of either gene affects the export of a range of such proteins, and a complete block is observed when both genes are inactivated. The Sec protein export pathway was unaffected, indicating the involvement of the gene products in a novel export system. The accumulation of active cofactor-containing proteins in the cytoplasm of the mutant strains suggests a role for the gene products in the translocation of folded proteins. One of the two HCF106 homologues is encoded by the first gene of a four cistron operon, tatABCD, and the second by an unlinked gene, tatE. A mutation previously assigned to the hcf106 homologue encoded at the tatABCD locus, mttA, lies instead in the tatB gene.

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The Tat protein export pathway

Berks

Sargent

Palmer

2000

Molecular Microbiology

545

493

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SummaryThe Tat ( twin-arginine translocation) system is a bacterial protein export pathway with the remarkable ability to transport folded proteins across the cytoplasmic membrane. Preproteins are directed to the Tat pathway by signal peptides that bear a characteristic sequence motif, which includes consecutive arginine residues. Here, we review recent progress on the characterization of the Tat system and critically discuss the structure and operation of this major new bacterial protein export pathway.

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An Essential Component of a Novel Bacterial Protein Export System with Homologues in Plastids and Mitochondria

Bogsch¹,

Sargent²,

Stanley³

et al. 1998

Journal of Biological Chemistry

351

313

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Proteins are transported across the bacterial plasma membrane and the chloroplast thylakoid membrane by means of protein translocases that recognize N-terminal targeting signals in their cognate substrates. Transport of many of these proteins involves the well defined Sec apparatus that operates in both membranes. We describe here the identification of a novel component of a bacterial Sec-independent translocase. The system probably functions in a similar manner to a Sec-independent translocase in the thylakoid membrane, and substrates for both systems bear a characteristic twinarginine motif in the targeting peptide. The translocase component is encoded in Escherichia coli by an unassigned reading frame, yigU, disruption of which blocks the export of at least five twin-Arg-containing precursor proteins that are predicted to bind redox cofactors, and hence fold, prior to translocation. The Sec pathway remains unaffected in the deletion strain. The gene has been designated tatC (for twin-arginine translocation), and we show that homologous genes are present in a range of bacteria, plastids, and mitochondria. These findings suggest a central role for TatC-type proteins in the translocation of tightly folded proteins across a spectrum of biological membranes.

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How Escherichia coli Is Equipped to Oxidize Hydrogen under Different Redox Conditions

Lukey

Parkin

Roessler

et al. 2010

Journal of Biological Chemistry

215

271

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The enterobacterium Escherichia coli synthesizes two H 2 uptake enzymes, Hyd-1 and Hyd-2. We show using precise electrochemical kinetic measurements that the properties of Hyd-1 and Hyd-2 contrast strikingly, and may be individually optimized to function under distinct environmental conditions. Hyd-2 is well suited for fast and efficient catalysis in more reducing environments, to the extent that in vitro it behaves as a bidirectional hydrogenase. In contrast, Hyd-1 is active for H 2 oxidation under more oxidizing conditions and cannot function in reverse. Importantly, Hyd-1 is O 2 tolerant and can oxidize H 2 in the presence of air, whereas Hyd-2 is ineffective for H 2 oxidation under aerobic conditions. The results have direct relevance for physiological roles of Hyd-1 and Hyd-2, which are expressed in different phases of growth. The properties that we report suggest distinct technological applications of these contrasting enzymes.Hydrogenases catalyze the reversible cleavage of H 2 into protons and electrons, and play an important role in the energy metabolism of a broad range of microorganisms (1). Hydrogenases are classified according to their active site metal ion content, and three phylogenetically distinct classes have so far been identified: di-iron [FeFe]-, nickel-iron [NiFe]-, and mono-iron [Fe]-hydrogenases (1). Nickel-iron hydrogenases are the most abundant of the three types (1), and many members of this class are membrane bound, with the membrane-extrinsic domain consisting of a large subunit containing the active site, and a small subunit accommodating one to three electron-transferring iron-sulfur clusters. The active sites of [NiFe]-hydrogenases contain a nickel atom coordinated by four cysteine-S ligands, two of which bridge to an iron atom that is further coordinated by three unusual diatomic ligands, two cyanides and one carbonyl (2).Hydrogenases are inactivated by O 2

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Frank Sargent

Overlapping functions of components of a bacterial Sec-independent protein export pathway

The Tat protein export pathway

An Essential Component of a Novel Bacterial Protein Export System with Homologues in Plastids and Mitochondria

How Escherichia coli Is Equipped to Oxidize Hydrogen under Different Redox Conditions

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