Chris van der Does

YidC, the Escherichia coli homologue of mitochondrial Oxa1p, is a component of the Sec translocase

In Escherichia coli, both secretory and inner membrane proteins initially are targeted to the core SecYEG inner membrane translocase. Previous work has also identified the peripherally associated SecA protein as well as the SecD, SecF and YajC inner membrane proteins as components of the translocase. Here, we use a cross‐linking approach to show that hydrophilic portions of a co‐translationally targeted inner membrane protein (FtsQ) are close to SecA and SecY, suggesting that insertion takes place at the SecA/Y interface. The hydrophobic FtsQ signal anchor sequence contacts both lipids and a novel 60 kDa translocase‐associated component that we identify as YidC. YidC is homologous to Saccharomyces cerevisiae Oxa1p, which has been shown to function in a novel export pathway at the mitochondrial inner membrane. We propose that YidC is involved in the insertion of hydrophobic sequences into the lipid bilayer after initial recognition by the SecAYEG translocase.

SecYEG assembles into a tetramer to form the active protein translocation channel

Translocase mediates preprotein translocation across the Escherichia coli inner membrane. It consists of the SecYEG integral membrane protein complex and the peripheral ATPase SecA. Here we show by functional assays, negative‐stain electron microscopy and mass measurements with the scanning transmission microscope that SecA recruits SecYEG complexes to form the active translocation channel. The active assembly of SecYEG has a side length of 10.5 nm and exhibits an ∼5 nm central cavity. The mass and structure of this SecYEG as well as the subunit stoichiometry of SecA and SecY in a soluble translocase–precursor complex reveal that translocase consists of the SecA homodimer and four SecYEG complexes.

The structural basis of protein targeting and translocation in bacteria

In Gram-negative bacteria, two distinct targeting routes assist in the proper localization of secreted and membrane proteins. Signal recognition particle (SRP) mainly targets ribosome-bound nascent membrane proteins, whereas SecB facilitates the targeting of periplasmic and outer membrane proteins. These routes converge at the translocase, a protein-conducting pore in the membrane that consists of the SecYEG complex associated with the peripheral ATPase, SecA. Recent structural studies of the targeting and the translocating components provide insights into how substrates are recognized and suggest a mechanism by which proteins are transported through an aqueous pore in the cytoplasmic membrane.

The molecular chaperone SecB is released from the carboxy-terminus of SecA during initiation of precursor protein translocation.

The chaperone SecB keeps precursor proteins in a translocation‐competent state and targets them to SecA at the translocation sites in the cytoplasmic membrane of Escherichia coli. SecA is thought to recognize SecB via its carboxy‐terminus. To determine the minimal requirement for a SecB‐binding site, fusion proteins were created between glutathione‐S‐transferase and different parts of the carboxy‐terminus of SecA and analysed for SecB binding. A strikingly short amino acid sequence corresponding to only the most distal 22 aminoacyl residues of SecA suffices for the authentic binding of SecB or the SecB–precursor protein complex. SecAN880, a deletion mutant that lacks this highly conserved domain, still supports precursor protein translocation but is unable to bind SecB. Heterodimers of wild‐type SecA and SecAN880 are defective in SecB binding, demonstrating that both carboxy‐termini of the SecA dimer are needed to form a genuine SecB‐binding site. SecB is released from the translocase at a very early stage in protein translocation when the membrane‐bound SecA binds ATP to initiate translocation. It is concluded that the SecB‐binding site on SecA is confined to the extreme carboxy‐terminus of the SecA dimer, and that SecB is released from this site at the onset of translocation.

How do ABC transporters drive transport

Abstract Members of the ATP-binding cassette (ABC) superfamily are integral membrane proteins that hydrolyze ATP to drive transport. In the last two decades these proteins have been extensively characterized on a genetic and biochemical level, and in recent years high-resolution crystal structures of several nucleotide-binding domains and full-length transporters have extended our knowledge. Here we discuss the possible mechanisms of transport that have been derived from these crystal structures and the extensive available biochemical data.

PomZ, a ParA-like protein, regulates Z-ring formation and cell division in Myxococcus xanthus.

Accurate positioning of the division site is essential to generate appropriately sized daughter cells with the correct chromosome number. In bacteria, division generally depends on assembly of the tubulin homologue FtsZ into the Z‐ring at the division site. Here, we show that lack of the ParA‐like protein PomZ in Myxococcus xanthus resulted in division defects with the formation of chromosome‐free minicells and filamentous cells. Lack of PomZ also caused reduced formation of Z‐rings and incorrect positioning of the few Z‐rings formed. PomZ localization is cell cycle regulated, and PomZ accumulates at the division site at midcell after chromosome segregation but prior to FtsZ as well as in the absence of FtsZ. FtsZ displayed cooperative GTP hydrolysis in vitro but did not form detectable filaments in vitro. PomZ interacted with FtsZ in M. xanthus cell extracts. These data show that PomZ is important for Z‐ring formation and is a spatial regulator of Z‐ring formation and cell division. The cell cycle‐dependent localization of PomZ at midcell provides a mechanism for coupling cell cycle progression and Z‐ring formation. Moreover, the data suggest that PomZ is part of a system that recruits FtsZ to midcell, thereby, restricting Z‐ring formation to this position.

Reconstitution of Purified Bacterial Preprotein Translocase in Liposomes

Publisher Summary Protein translocation is one of the examples of a complex membrane-bound biological process that has been functionally reconstituted into proteoliposomes. This process relies on several membrane proteins that need to be coreconstituted to yield a functional system. This chapter describes methods to express, detergent solubilize, purify, and functionally reconstitute preprotein translocation in proteoliposomes using Escherichia coli translocase components. A coreconstitution protocol and a fluorescence assay to monitor preprotein translocation in vitro are described. The proteins can be solubilized from the membrane and purified to homogeneity (>95%) by anion exchange and nickel-nitrilotriacetic acid (Ni-NTA) affinity chromatography. A multitude of methods are described for the reconstitution of membrane proteins into proteoliposomes. The methods of hydrophobic absorption or rapid dilution for detergent removal are the most significant methods for the functional reconstitution. The functional-membrane integration of newly synthesized inner membrane proteins, using the purified translocase and associated components, remains a challenge for future research. Other challenges lie in the reconstitution of the complete assembly of multisubunit membrane proteins.

Conjugative Plasmids of Neisseria gonorrhoeae

Many clinical isolates of the human pathogen Neisseria gonorrhoeae contain conjugative plasmids. The host range of these plasmids is limited to Neisseria species, but presence of a tetracycline (tetM) determinant inserted in several of these plasmids is an important cause of the rapid spread of tetracycline resistance. Previously plasmids with different backbones (Dutch and American type backbones) and with and without different tetM determinants (Dutch and American type tetM determinants) have been identified. Within the isolates tested, all plasmids with American or Dutch type tetM determinants contained a Dutch type plasmid backbone. This demonstrated that tetM determinants should not be used to differentiate between conjugal plasmid backbones. The nucleotide sequences of conjugative plasmids with Dutch type plasmid backbones either not containing the tetM determinant (pEP5233) or containing Dutch (pEP5289) or American (pEP5050) type tetM determinants were determined. Analysis of the backbone sequences showed that they belong to a novel IncP1 subfamily divergent from the IncP1α, β, γ, δ and ε subfamilies. The tetM determinants were inserted in a genetic load region found in all these plasmids. Insertion was accompanied by the insertion of a gene with an unknown function, and rearrangement of a toxin/antitoxin gene cluster. The genetic load region contains two toxin/antitoxins of the Zeta/Epsilon toxin/antitoxin family previously only found in Gram positive organisms and the virulence associated protein D of the VapD/VapX toxin/antitoxin family. Remarkably, presence of VapX of pJD1, a small cryptic neisserial plasmid, in the acceptor strain strongly increased the conjugation efficiency, suggesting that it functions as an antitoxin for the conjugative plasmid. The presence of the toxin and antitoxin on different plasmids might explain why the host range of this IncP1 plasmid is limited to Neisseria species. The isolated plasmids conjugated efficiently between N. gonorrhoeae strains, but did not enhance transfer of a genetic marker.

Two Small GTPases Act in Concert with the Bactofilin Cytoskeleton to Regulate Dynamic Bacterial Cell Polarity

Cell polarity is essential for many bacterial activities, but the mechanisms responsible for its establishment are poorly understood. In Myxococcus xanthus, the type IV pili (T4P) motor ATPases PilB and PilT localize to opposite cell poles and switch poles during cellular reversals. We demonstrate that polar localization of PilB and PilT depends on the small GTPase SofG and BacP, a bactofilin cytoskeletal protein. Polymeric BacP localizes in both subpolar regions. SofG interacts directly with polymeric BacP and associates with one of these patches, forming a cluster that shuttles to the pole to establish localization of PilB and PilT at the same pole. Next, the small GTPase MglA sorts PilB and PilT to opposite poles to establish their correct polarity. During reversals, the Frz chemosensory system induces the inversion of PilB and PilT polarity. Thus, three hierarchically organized systems function in a cascade to regulate dynamic bacterial cell polarity.

A novel relaxase homologue is involved in chromosomal DNA processing for type IV secretion in Neisseria gonorrhoeae

The Neisseria gonorrhoeae type IV secretion system secretes chromosomal DNA that acts in natural transformation. To examine the mechanism of DNA processing for secretion, we made mutations in the putative relaxase gene traI and used nucleases to characterize the secreted DNA. The nuclease experiments demonstrated that the secreted DNA is single‐stranded and blocked at the 5′ end. Mutation of traI identified Tyr93 as required for DNA secretion, while substitution of Tyr201 resulted in intermediate levels of DNA secretion. TraI exhibits features of relaxases, but also has features that are absent in previously characterized relaxases, including an HD phosphohydrolase domain and an N‐terminal hydrophobic region. The HD domain residue Asp120 was required for wild‐type levels of DNA secretion. Subcellular localization studies demonstrated that the TraI N‐terminal region promotes membrane interaction. We propose that Tyr93 initiates DNA processing and Tyr201 is required for termination or acts in DNA binding. Disruption of an inverted‐repeat sequence eliminated DNA secretion, suggesting that this sequence may serve as the origin of transfer for chromosomal DNA secretion. The TraI domain architecture, although not previously described, is present in 53 uncharacterized proteins, suggesting that the mechanism of TraI function is a widespread process for DNA donation.