Hydrophobic forces drive spontaneous membrane insertion of the bacteriophage Pf3 coat protein without topological control

Kiefer, Dorothee; Kühn, Andreas

doi:10.1093/emboj/18.22.6299

Cited by 94 publications

(107 citation statements)

References 33 publications

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“…The Proton Motive Force Is Required for Membrane Insertion of FtsQ-The PMF has been shown to play an important role in the insertion of some IMPs (27) and membrane topology control (28,29). The ATP needed for the translation reaction is also used by the F 1 F 0 ATPase to generate a PMF.…”

Section: Co-translational Insertion Of Ftsq Intomentioning

confidence: 99%

SecYEG Proteoliposomes Catalyze the Δϕ-Dependent Membrane Insertion of FtsQ

Laan

Nouwen

Driessen

2004

Journal of Biological Chemistry

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In Escherichia coli, the insertion of most inner membrane proteins is mediated by the Sec translocase. Ribosome-bound nascent chains of Sec-dependent inner membrane proteins are targeted to the SecYEG complex via the signal recognition particle pathway. We now demonstrate that the signal recognition particledependent co-translational membrane targeting and membrane insertion of FtsQ can be reconstituted with proteoliposomes containing purified SecYEG. SecA and a transmembrane electrical potential are essential for the translocation of the large periplasmic domain of FtsQ, whereas co-reconstituted YidC has an inhibitory effect. These data demonstrate that membrane protein insertion can be reconstituted with a minimal set of purified Sec components.

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Section: Co-translational Insertion Of Ftsq Intomentioning

confidence: 99%

SecYEG Proteoliposomes Catalyze the Δϕ-Dependent Membrane Insertion of FtsQ

Laan

Nouwen

Driessen

2004

Journal of Biological Chemistry

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“…Hydrophobicity of the TMD-Because hydrophobic forces have a crucial role in membrane translocation of the E. coli Secindependent pathway (17,18,24,26), we examined the role of hydrophobic forces on the insertion of T7-Su8 across INVs. We constructed the T7-Su8 mutants TM1 and TM2, in which hydrophobic residues in the former (TM1) and the latter (TM2) half of the TMD were replaced by hydrophilic residues (Fig.…”

Section: Insertion Of T7-su8 Across the Membrane Depends On Thementioning

confidence: 99%

“…The M13 procoat protein is synthesized with a cleavable signal peptide and spans the membrane once with the processed N terminus exposed to the periplasm and the C terminus remaining in the cytoplasm (18 -24). The Pf3 coat protein is synthesized without a cleavable signal sequence and inserts into the membrane once, exposing the N-terminal segment to the periplasm and the C-terminal segment to the cytoplasm (25,26). In contrast to the predicted direct insertion mechanism, Samuelson et al (27) demonstrated that insertion of the M13 procoat protein across the membrane depends on a Oxa1p homologue, YidC.…”

mentioning

confidence: 99%

Insertion of Mitochondrial DNA-encoded F1F0-ATPase Subunit 8 across the Mitochondrial Inner Membrane in Vitro

Miki

Mihara

2001

Journal of Biological Chemistry

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Cytochrome oxidase subunits I, II, and III, the mitochondrial DNA-encoded proteins, are inserted across the inner membrane by the Oxa1p-containing translocator in a membrane potential-dependent manner. Oxa1p is also involved in the insertion of the cytoplasmically synthesized precursor of Oxa1p itself into the inner membrane from the matrix via the conservative sorting pathway. The mechanism of insertion of the other mitochondrially synthesized proteins, however, is unexplored. The insertion of the mitochondrial DNA-encoded subunit 8 of F 1 F 0 -ATPase (Su8) across the inner membrane was analyzed in vitro using the inverted inner membrane vesicles and the Escherichia coli lysate-synthesized substrate. This assay revealed that the N-terminal segment of Su8 inserted across the membrane to the intermembrane space and assumed the correct trans-cis topology depending on the mitochondrial matrix fraction. This translocation reaction was similar to those of Sec-independent, direct insertion pathways of E. coli and chloroplast thylakoid membranes. (i) It required neither nucleotide triphosphates nor membrane potential, and hydrophobic forces drove the process. (ii) It did not require protease-sensitive membrane components facing the matrix space. (iii) It could be inserted across liposomes in the correct topology in a matrix fraction-dependent manner. Thus, a novel mechanism conserved in bacteria and chloroplasts also functions in the insertion of Su8 across the mitochondrial inner membrane.

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“…When liposomes containing DAG were used for M13 procoat and Pf3 coat integration, DAG also blocked the spontaneous integration of these proteins completely (7,17). 3L-Pf3 coat is a mutant version of Pf3 coat in which three leucine residues are inserted in the middle of the TM domain (18). Although integration of M13 procoat and Pf3 coat proteins is stimulated by the membrane potential, 3L-Pf3 coat does not require the membrane potential (18).…”

Section: Yidcmentioning

confidence: 99%

“…3L-Pf3 coat is a mutant version of Pf3 coat in which three leucine residues are inserted in the middle of the TM domain (18). Although integration of M13 procoat and Pf3 coat proteins is stimulated by the membrane potential, 3L-Pf3 coat does not require the membrane potential (18). In this sense, insertion of this protein is the most spontaneous.…”

Section: Yidcmentioning

confidence: 99%

Glycolipozyme membrane protein integrase (MPIase): recent data

Nishiyama

Shimamoto

2014

Biomolecular Concepts

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A novel factor for membrane protein integration, from the cytoplasmic membrane of Escherichia coli, named MPIase (membrane protein integrase), has recently been identified and characterized. MPIase was revealed to be essential for the membrane integration of a subset of membrane proteins, despite that such integration reactions have been, thus far, thought to occur spontaneously. The structure determination study revealed that MPIase is a novel glycolipid comprising a glycan chain with three N-acetylated amino sugars connected to diacylglycerol through a pyrophosphate linker. As MPIase catalyzes membrane protein integration, we propose that MPIase is a glycolipozyme on the basis of its enzyme-like function. The glycan chain exhibits a molecular chaperone-like function by directly interacting with substrate membrane proteins. Moreover, MPIase also affects the dimer structure of SecYEG, a translocon, thereby significantly stimulating preprotein translocation. The molecular mechanisms of MPIase functions will be outlined.

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Hydrophobic forces drive spontaneous membrane insertion of the bacteriophage Pf3 coat protein without topological control

Cited by 94 publications

References 33 publications

SecYEG Proteoliposomes Catalyze the Δϕ-Dependent Membrane Insertion of FtsQ

SecYEG Proteoliposomes Catalyze the Δϕ-Dependent Membrane Insertion of FtsQ

Insertion of Mitochondrial DNA-encoded F1F0-ATPase Subunit 8 across the Mitochondrial Inner Membrane in Vitro

Glycolipozyme membrane protein integrase (MPIase): recent data

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