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Browsing by Subject "M13 procoat"

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    Membraninsertion des Phagenproteins M13 procoat in Lipidvesikel mit rekonstituiertem Escherichia coli YidC
    (2011) Stiegler, Natalie; Kuhn, Andreas
    Translocation of proteins across or into the cytoplasmic membrane of Escherichia coli is accomplished by several mechanisms. The cellular secretion machinery, the translocase SecYEG, mediates the transport of unfolded proteins into the periplasm with the help of the ATPase SecA or passes the membrane proteins for bilayer integration to the insertase YidC. Membrane insertion is catalysed by YidC, whereby the native conformation of the proteins in the lipid bilayer is achieved. The translocation of a few membrane proteins occurs Sec-independently solely with the help of the insertase YidC. One of these Sec-independent proteins is the major capsid protein of the bacteriophage M13. This protein is inserted as preprotein, termed M13 procoat, with the orientation Nin-Cin into the inner membrane and a central loop domain located in the periplasm. This process is catalysed by the electrochemical membrane potential and YidC. M13 procoat is then processed by the leader peptidase to its mature form, M13 coat (orientation Nout-Cin). In the present thesis an analysis of the different transport systems of the inner membrane is performed using the example of the M13 procoat protein and its mutants. One mutant is the procoat H5EE which has 2 additional acidic residues introduced between residues +2 and +3. The insertion of this mutant requires the Sec translocase and strictly depends on the electrochemical potential. Membrane insertion of M13 procoat and derived proteins into the cytoplasmic membrane was followed in an in vitro reconstitution and translocation system. Therefore, all components of the Sec translocase (SecYEG and SecA), the insertase YidC and the different procoat proteins were purified and tested with the in vitro translocation system. Reconstitution of YidC into phospholipid vesicles depended on the lipid composition for its orientation. The cytoplasmic-out orientation corresponds to the active topology in E. coli where both termini are located in the cytoplasm. Certain lipid compositions caused the inversed orientation, which affected the catalytic activity of the reconstituted insertase. The procoat mutants H5 und H5EE were membrane inserted only in the presence of reconstituted YidC. Both proteins inserted efficiently into the vesicles with the periplasmic loop in the interior of the vesicles like the mutant PClep of procoat H5 with the C-terminal extension of the leader peptidase. Spontaneous insertion of H5 und H5EE into liposomes occurred only into leaky vesicles of the E. coli lipids. The membrane integrity was improved by the addition of an adequate amount of diacylglycerol (DAG) to the phospholipids. The leaky phospholipids were sealed by the addition of 3-4% DAG. The proteins H5 und H5EE showed a dependency of the membrane potential. Insertion occured more efficiently into YidC proteoliposomes when a stable membrane potential was generated. Proteoliposomes with reconstituted SecYEG translocase were also tested for protein insertion. Remarkedly, the protein M13 procoat H5EE efficiently inserted into SecYEG proteoliposomes, where the wildtype-like protein H5 did not.
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    Publication
    The function of E. coli YidC for the membrane insertion of the M13 procoat protein
    (2018) Spann, Dirk; Kuhn, Andreas
    The YidC/Oxa1/Alb3 family consists of insertase homologues that facilitate the insertion and folding of membrane proteins. YidC is located in the inner membrane of bacterial cells. Oxa1 is found in the inner membrane of mitochondria and Alb3 facilitates the insertion of membrane proteins in the thylakoid membranes of chloroplasts (Wang and Dalbey 2011, Hennon et al. 2015). An archaeal homologue was found in M. jannaschii showing that this insertase family is present in all domains of life (Dalbey and Kuhn 2015). The insertase family shares a structural feature that is conserved among all discovered members. This is a hydrophilic groove that is open towards the cytoplasm and the membrane core with a hydrophobic slide formed by transmembrane domain (TM) 3 and TM5. YidC functions on its own but also cooperates with the Sec translocon to facilitate the insertion of large membrane proteins. One protein that is membrane-inserted by YidC but is Sec-independent is the major coat protein of the M13 bacteriophage. The main objectives of this work are the analysis of the insertion mechanism of M13 procoat, the major capsid protein of the M13 bacteriophage, via the YidC-only pathway and the oligomeric state of the active YidC. The analysis of interactions between YidC and M13 procoat was performed via radioactive disulfide crosslinking mainly using copper phenanthroline as oxidizing agent. M13 procoat contacts YidC extensively in TM3 and TM5. The observed contacts suggest that the M13 procoat substrate “slides” along TM3 and TM5 of the insertase. Additional crosslinking experiments with the hydrophilic groove and the C1 loop of YidC were also performed to test their importance during the insertion process. A contact was found in the C1 loop that indicates a role in the insertion process, which is consistent with the proposed insertion model from Kumazaki et al. (2014a). Parallel to the radioactive disulfide crosslinking, a protocol using DTNB (Bis(3-carboxy-4-nitrophenyl) disulfide, Ellman’s reagent) as the oxidizing reagent and Western blot for detection was established. This method reliably promoted the formation of crosslinking products in vivo between YidC and M13 procoat over several hours and many, but not all, mapped at the same sites as in the radioactive approach. In addition, this protocol was used to purify small amounts of a YidC-substrate complex for biochemical analysis, which could also be applied to other substrates in the future. The oligomeric state of YidC was investigated by an artificial dimer of the insertase (dYidC) that was constructed by connecting two monomers together with a short linker. This dimer can complement YidC-depleted E. coli MK6S cells and facilitates the insertion of M13 procoat in vivo. For further analysis of the dYidC three functionally defective YidC mutants, T362A (Wickles et al. 2014), delta-C1 (Chen et al. 2014) and the 5S YidC mutant, were tested for their complementation and insertion capability. All three mutants were not able to complement under YidC depletion conditions. These mutants were then cloned in either one or both protomers of the dYidC. Complementation and insertion assays with these dYidC constructs show that in general one active protomer suffices to uphold cell viability and to facilitate the insertion of M13 procoat. Binding studies using cysteine mutants of the dYidC and M13 procoat for disulfide crosslinking with DTNB demonstrated that each protomer individually binds one substrate molecule. In summary, these experiments strongly support a monomer as the active state of the insertase for YidC-only substrates. Taken together, this study contributes to the understanding of the insertion of proteins into the inner bacterial cell membrane.