•In vivo water accessibility of E. coli YidC was determined using NEM labeling•Accessibility of YidC determined from all-atom MD simulations agrees with NEM results•Compared with crystal structure, YidC structure in POPE:POPG is much more compact•YidC thins the bilayer locally due to interface aromatic residues and salt bridgesThe YidC/Oxa1/Alb3 family of membrane proteins function to insert proteins into membranes in bacteria, mitochondria, and chloroplasts. Recent X-ray structures of YidC from Bacillus halodurans and Escherichia coli revealed a hydrophilic groove that is accessible from the lipid bilayer and the cytoplasm. Here, we explore the water accessibility within the conserved core region of the E. coli YidC using in vivo cysteine alkylation scanning and molecular dynamics (MD) simulations of YidC in POPE/POPG membranes. As expected from the structure, YidC possesses an aqueous membrane cavity localized to the membrane inner leaflet. Both the scanning data and the MD simulations show that the lipid-exposed transmembrane helices 3, 4, and 5 are short, leading to membrane thinning around YidC. Close examination of the MD data reveals previously unrecognized structural features that are likely important for protein stability and function.Download high-res image (267KB)Download full-size image

The YidC family members function to insert proteins into membranes in bacteria, chloroplasts, and mitochondria, and they can also act as a platform to fold and assemble proteins into higher-order complexes. Here, we provide information about the proximity relationships and dynamics of the five conserved C-terminal transmembrane (TM) regions within Escherichia coli YidC. By using a YidC construct with tandem thrombin protease sites introduced into the cytoplasmic loop C1, cross-linking between paired-Cys residues located within TM segments or in the membrane border regions was studied using thio-specific homobifunctional cross-linking agents with different spanner lengths or by iodine-catalyzed disulfide formation. These in vivo cross-linking studies that can detect transient interactions and different conformational states of the protein show that TM3, TM4, TM5, and TM6 each have a face oriented toward TM2 of the in vivo expressed YidC. The studies also reveal that YidC is a dynamic protein, as cross-linking was observed between cytoplasmic Cys residues with a variety of cross-linkers. A large number of conserved proline residues on the cytoplasmic side of the five conserved core TM segments could explain the observed flexibility, and the structural fluctuations of the TM segments could provide an explanation for how YidC is able to recognize a variety of different substrates.

In the three domains of life, the Sec, YidC/Oxa1, and Tat translocases play important roles in protein translocation across membranes and membrane protein insertion. While extensive studies have been performed on the endoplasmic reticular and Escherichia coli systems, far fewer studies have been done on archaea, other Gram-negative bacteria, and Gram-positive bacteria. Interestingly, work carried out to date has shown that there are differences in the protein transport systems in terms of the number of translocase components and, in some cases, the translocation mechanisms and energy sources that drive translocation. In this review, we will describe the different systems employed to translocate and insert proteins across or into the cytoplasmic membrane of archaea and bacteria.

The insertion of proteins into the bacterial cytoplasmic membrane is a complex and dynamic process. Sophisticated translocases are responsible for decoding the topogenic sequences within membrane proteins that direct membrane protein insertion and orientation. Here, Xie and Dalbey highlight what is known about the role of the Sec and YidC translocases in the folding and insertion of bacterial membrane proteins.

Escherichia coli signal peptide peptidase A (SppA) is a serine protease which cleaves signal peptides after they have been proteolytically removed from exported proteins by signal peptidase processing. We present here results of site-directed mutagenesis studies of all the conserved serines of SppA in the carboxyl-terminal domain showing that only Ser 409 is essential for enzymatic activity. Also, we show that the serine hydrolase inhibitor FP-biotin inhibits SppA and modifies the protein but does not label the S409A mutant with an alanine substituted for the essential serine. These results are consistent with Ser 409 being directly involved in the proteolytic mechanism. Remarkably, additional site-directed mutagenesis studies showed that none of the lysines or histidine residues in the carboxyl-terminal protease domain (residues 326−549) is critical for activity, suggesting this domain lacks the general base residue required for proteolysis. In contrast, we found that E. coli SppA has a conserved lysine (K209) in the N-terminal domain (residues 56−316) that is essential for activity and important for activation of S409 for reactivity toward the FP-biotin inhibitor and is conserved in those other bacterial SppA proteins that have an N-terminal domain. We also performed alkaline phosphatase fusion experiments that establish that SppA has only one transmembrane segment (residues 29−45) with the C-terminal domain (residues 46−618) protruding into the periplasmic space. These results support the idea that E. coli SppA is a Ser-Lys dyad protease, with the Lys recruited to the amino-terminal domain that is itself not present in most known SppA sequences.

The basic machinery for the translocation of proteins into or across membranes is remarkably conserved from Escherichia coli to humans. In eukaryotes, proteins are inserted into the endoplasmic reticulum using the signal recognition particle (SRP) and the SRP receptor, as well as the integral membrane Sec61 trimeric complex (composed of alpha, beta and gamma subunits)1. In bacteria, most proteins are inserted by a related pathway that includes the SRP homologue Ffh2, 3, 4, 5, the SRP receptor FtsY6, 7, and the SecYEG trimeric complex8, where Y and E are related to the Sec61 alpha and gamma subunits, respectively. Proteins in bacteria that exhibit no dependence on the Sec translocase were previously thought to insert into the membrane directly without the aid of a protein machinery9, 10. Here we show that membrane insertion of two Sec-independent proteins requires YidC. YidC is essential for E. coli viability and homologues are present in mitochondria and chloroplasts. Depletion of YidC also interferes with insertion of Sec-dependent membrane proteins, but it has only a minor effect on the export of secretory proteins. These results provide evidence for an additional component of the translocation machinery that is specialized for the integration of membrane proteins.

TatC, a subunit of the twin arginine translocase, is a 6-membrane-spanning protein exposing three periplasmic loops. We have used TatC as a model system to examine how multispanning proteins insert into the membrane. To assay translocation of each of the three loops of TatC across the membrane, we used trypsin mapping, proteinase K mapping, and chemical modification methods. Here, we show that the signal recognition particle is required for targeting TatC to the inner membrane of Escherichia coli. While translocation of loops 1 and 2 is strictly dependent on the Sec translocase and the YidC insertase, translocation of loop 3 does not depend on the translocase or insertase. None of the periplasmic loops require SecA or the proton motive force for membrane translocation. This work demonstrates a strategy where all the loops of a multispanning membrane protein can be monitored individually. The membrane translocation mechanism of each periplasmic loop can be complex with different energy and translocase requirements for a multispanning membrane protein.Download high-res image (102KB)Download full-size imageResearch Highlights► Individual loops of the multispanning TatC are translocated by different mechanisms. ► YidC functions to clear the SecYEG channel of inserting membrane proteins. ► Translocation of protein regions of membrane proteins can be monitored by various proteases and alkylating agents.

In this issue of Structure, Borowska et al. (2015) report the crystal structure and provide experimental evidence on an archaeal membrane insertase, the DUF106 protein from Methanocaldococcus jannaschii, demonstrating that YidC/Oxa1/Alb3-like insertases exist in the archaeal plasma membrane.

Subunit II (CyoA) of cytochrome bo3 oxidase, which spans the inner membrane twice in bacteria, has several unusual features in membrane biogenesis. It is synthesized with an amino-terminal cleavable signal peptide. In addition, distinct pathways are used to insert the two ends of the protein. The amino-terminal domain is inserted by the YidC pathway whereas the large carboxyl-terminal domain is translocated by the SecYEG pathway. Insertion of the protein is also proton motive force (pmf)-independent. Here we examined the topogenic sequence requirements and mechanism of insertion of CyoA in bacteria. We find that both the signal peptide and the first membrane-spanning region are required for insertion of the amino-terminal periplasmic loop. The pmf-independence of insertion of the first periplasmic loop is due to the loop's neutral net charge. We observe also that the introduction of negatively charged residues into the periplasmic loop makes insertion pmf dependent, whereas the addition of positively charged residues prevents insertion unless the pmf is abolished. Insertion of the carboxyl-terminal domain in the full-length CyoA occurs by a sequential mechanism even when the CyoA amino and carboxyl-terminal domains are swapped with other domains. However, when a long spacer peptide is added to increase the distance between the amino-terminal and carboxyl-terminal domains, insertion no longer occurs by a sequential mechanism.