A conserved function of YidC in the biogenesis of respiratory chain complexes.

The Escherichia coli inner membrane protein (IMP) YidC is involved in the membrane integration of IMPs both in concert with and independently from the Sec translocase. YidC seems to be dispensable for the assembly of Sec-dependent IMPs, and so far it has been shown to be essential only for the proper Sec-independent integration of some phage coat proteins. Here, we studied the physiological consequences of YidC depletion in an effort to understand the essential function of YidC. The loss of YidC rapidly and specifically induced the Psp stress response, which is accompanied by a reduction of the proton-motive force. This reduction is due to defects in the functional assembly of cytochrome o oxidase and the F(1)F(o) ATPase complex, which is reminiscent of the effects of mutations in the yidC homologue OXA1 in the yeast mitochondrial inner membrane. The integration of CyoA (subunit II of the cytochrome o oxidase) and F(o)c (membrane subunit of the F(1)F(o) ATPase) appeared exceptionally sensitive to depletion of YidC, suggesting that these IMPs are natural substrates of a membrane integration and assembly pathway in which YidC plays an exclusive or at least a pivotal role.

Evidence for coupling of membrane targeting and function of the signal recognition particle (SRP) receptor FtsY.

Recent studies have indicated that FtsY, the signal recognition particle receptor of Escherichia coli, plays a central role in membrane protein biogenesis. For proper function, FtsY must be targeted to the membrane, but its membrane-targeting pathway is unknown. We investigated the relationship between targeting and function of FtsY in vivo, by separating its catalytic domain (NG) from its putative targeting domain (A) by three means: expression of split ftsY, insertion of various spacers between A and NG, and separation of A and NG by in vivo proteolysis. Proteolytic separation of A and NG does not abolish function, whereas separation by long linkers or expression of split ftsY is detrimental. We propose that proteolytic cleavage of FtsY occurs after completion of co-translational targeting and assembly of NG. In contrast, separation by other means may interrupt proper synchronization of co-translational targeting and membrane assembly of NG. The co-translational interaction of FtsY with the membrane was confirmed by in vitro experiments.

Molecular characterization of Escherichia coli FtsE and FtsX.

The genes ftsE and ftsX are organized in one operon together with ftsY. FtsY codes for the receptor of the signal recognition particle (SRP) that functions in targeting a subset of inner membrane proteins. We have found no indications for a structural relationship between FtsE/X and FtsY. Evidence is presented that FtsE and FtsX form a complex in the inner membrane that bears the characteristics of an ATP-binding cassette (ABC)-type transporter. FtsE is a hydrophilic nucleotide-binding protein that has a tendency to dimerize and associates with the inner membrane through an interaction with the integral membrane protein FtsX. An FtsE null mutant showed filamentous growth and appeared viable on high salt medium only, indicating a role for FtsE in cell division and/or salt transport.

Membrane association of FtsY, the E. coli SRP receptor.

FtsY, the Escherichia coli homologue of the eukaryotic SRP receptor (SR alpha), is located both in the cytoplasm and in the inner membrane of E. coli. Similar to SR alpha, FtsY consists of two major domains: a strongly acidic N-terminal domain (A) and a C-terminal GTP binding domain (NG) of which the crystal structure has recently been determined. The domains were expressed both in vivo and in vitro to examine their subcellular localization. The results suggest that both domains associate with the membrane but that the nature of the association differs.

Nascent membrane and presecretory proteins synthesized in Escherichia coli associate with signal recognition particle and trigger factor.

The Escherichia coli signal recognition particle (SRP) and trigger factor are cytoplasmic factors that interact with short nascent polypeptides of presecretory and membrane proteins produced in a heterologous in vitro translation system. In this study, we use an E. coli in vitro translation system in combination with bifunctional cross-linking reagents to investigate these interactions in more detail in a homologous environment. Using this approach, the direct interaction of SRP with nascent polypeptides that expose particularly hydrophobic targeting signals is demonstrated, suggesting that inner membrane proteins are the primary physiological substrate of the E. coli SRP. Evidence is presented that the overproduction of proteins that expose hydrophobic polypeptide stretches, titrates SRP. In addition, trigger factor is efficiently cross-linked to nascent polypeptides of different length and nature, some as short as 57 amino acid residues, indicating that it is positioned near the nascent chain exit site on the E. coli ribosome.

Optimization of bacteriocin-release-protein-induced protein release by Escherichia coli: extracellular production of the periplasmic molecular chaperone FaeE.

Expression of the pCloDF13-encoded bacteriocin-release protein (BRP) results in the release of periplasmic proteins into the culture medium. The BRP-mediated release of a periplasmic protein was investigated and optimized. As a periplasmic model protein, the 50-kDa dimeric E., coli fimbrial molecular chaperone FaeE was used. Plasmids were constructed for the simultaneous expression of the BRP and FaeE, controlled by independently inducible promoters. The efficiency of FaeE release increased when the BRP was targeted by the unstable murein lipoprotein signal peptide, instead of by its own stable signal, peptide. Furthermore, optimal efficacy of FaeE release was found when cells of E. coli strain C600 were used, which harboured one plasmid encoding both FaeE and BRP instead of two separate plasmids and which were cultured at 37 degrees C in broth supplemented with MgCl2. Maximal production levels of 21 mg FaeE/l culture were obtained.

An alternative protein targeting pathway in Escherichia coli: studies on the role of FtsY.

In Escherichia coli, a signal recognition particle (SRP) has been identified which binds specifically to the signal sequence of presecretory proteins and which appears to be essential for efficient translocation of a subset of proteins. In this study we have investigated the function of E. coli FtsY which shares sequence similarity with the alpha-subunit of the eukaryotic SRP receptor ('docking protein') in the membrane of the endoplasmic reticulum. A strain was constructed which allows the conditional expression of FtsY. Depletion of FtsY is shown to cause the accumulation of the precursor form of beta-lactamase, OmpF and ribose binding protein in vivo, whereas the processing of various other presecretory proteins is unaffected. Furthermore, FtsY-depleted inverted cytoplasmic membrane vesicles are shown to be defective in the translocation of pre-beta-lactamase using an in vitro import assay. Subcellular localization studies revealed that FtsY is located in part at the cytoplasmic membrane with which it seems peripherally associated. These observations suggest that FtsY is the functional E. coli homolog of the mammalian SRP receptor.

Stability and function of the signal peptide of the pCloDF13-derived bacteriocin release protein.

The pCloDF13-derived bacteriocin release protein (BRP) is synthesized as a prelipoprotein with a signal peptide which remains stable after processing. This signal peptide accumulates in the cytoplasmic membrane and is, together with the mature BRP, required for efficient release of cloacin DF13. We investigated the structural requirements for stability of the BRP signal peptide by constructing hybrid signal peptides consisting of parts of the BRP and Lpp signal peptides. Signal peptide stability was investigated by pulse-labelling and pulse-chase experiments. To study the functioning of the BRP signal peptide, the hybrid constructs were tested for their ability to promote BRP-mediated cloacin DF13-release and their ability to affect the viability of the host cells. The results obtained suggest that the N-terminal part of the BRP signal peptide together with the C-terminal alanine residue are important for stability. When expressed as a separate entity, all mutant signal peptides that contain a part of the BRP signal peptide are capable of affecting cell viability. The results indicated a possible correlation between stability of the BRP signal peptide and cloacin DF13-release.

The stable BRP signal peptide causes lethality but is unable to provoke the translocation of cloacin DF13 across the cytoplasmic membrane of Escherichia coli.

The bacteriocin release protein (BRP) mediates the secretion of cloacin DF13. The BRP precursor is slowly processed to yield the mature BRP and its stable signal peptide which is also involved in cloacin DF13 secretion. The function of the stable BRP signal peptide was analysed by constructing two plasmids. First, the stable BRP signal peptide was fused to the murein lipoprotein and, second, a stop codon was introduced after the BRP signal sequence. Exchange of the unstable murein lipoprotein signal peptide for the stable BRP signal peptide resulted in an accumulation of precursors of the hybrid murein lipoprotein. This indicated that the BRP signal peptide, as part of this hybrid precursor, is responsible for the slow processing. The stable BRP signal peptide itself was not able to direct the transfer of cloacin DF13 into the periplasmic space or into the culture medium. Over-expression of the BRP signal peptide was lethal and caused 'lysis'. Subcellular fractionation experiments revealed that the BRP signal peptide is located exclusively in the cytoplasmic membrane whereas the mature BRP, targeted by either the stable BRP signal peptide or the unstable Lpp signal peptide, is located in both the cytoplasmic and outer membrane. These results are in agreement with the hypothesis that the stable signal peptide and the mature BRP together are required for the passage of cloacin DF13 across the cell envelope.