Vicki A. M. Gold scite author profile

Significance In this paper, we describe the biophysical properties, stoichiometry, and activity of the Escherichia coli SecYEG–SecDF–YajC–YidC holo-translocon. This multiprotein complex consists of seven membrane protein subunits, including those components responsible for both protein secretion (SecYEG) and membrane protein insertion (YidC). We demonstrate the isolation of a stable complex containing YidC together with the core SecY translocon. The availability of this intact assembly allows us to reconstitute posttranslational protein export and cotranslational membrane protein insertion from purified components of known stoichiometry. The experiments demonstrate that protein secretion and insertion occur through a single complex. The reconstitution of membrane protein insertion from defined components is a novel development, breaking ground for the functional analysis of this largely unknown process.

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The action of cardiolipin on the bacterial translocon

Gold

Robson

Bao

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

149

153

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Cardiolipin is an ever-present component of the energy-conserving inner membranes of bacteria and mitochondria. Its modulation of the structure and dynamism of the bilayer impacts on the activity of their resident proteins, as a number of studies have shown. Here we analyze the consequences cardiolipin has on the conformation, activity, and localization of the protein translocation machinery. Cardiolipin tightly associates with the SecYEG protein channel complex, whereupon it stabilizes the dimer, creates a high-affinity binding surface for the SecA ATPase, and stimulates ATP hydrolysis. In addition to the effects on the structure and function, the subcellular distribution of the complex is modified by the cardiolipin content of the membrane. Together, the results provide rare and comprehensive insights into the action of a phospholipid on an essential transport complex, which appears to be relevant to a broad range of energy-dependent reactions occurring at membranes.

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Energy transduction in protein transport and the ATP hydrolytic cycle of SecA

Robson

Gold

Hodson

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

124

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The motor protein SecA drives the transport of polypeptides through the ubiquitous protein channel SecYEG. Changes in protein-nucleotide binding energy during the hydrolytic cycle of SecA must be harnessed to drive large conformational changes resulting in channel opening and vectorial substrate polypeptide transport. Here, we elucidate the ATP hydrolysis cycle of SecA from Escherichia coli by transient and steady-state methods. The basal ATPase activity of SecA is very slow with the release of ADP being some 600-fold slower than hydrolysis. Upon binding to SecYEG the release of ADP is stimulated but remains rate-limiting. ADP release is fastest in the fully coupled system when a substrate protein is being translocated; in this case hydrolysis and ADP release occur at approximately the same rate. The data imply that ADP dissociation from SecA is accompanied by a structural rearrangement that is strongly coupled to the protein interface and protein translocation through SecYEG.ATPase ͉ SecYEG ͉ steady-state kinetics ͉ transient kinetics ͉ translocon A TP-dependent molecular motors couple hydrolytic power to mechanical movement in a controlled and directional fashion. Distortions in the structure of the active site driven by different chemical stages in the ATP hydrolysis cycle can be relayed across large distances, resulting in conformational changes in the ATPase and its interacting partners. Hence, ATP binding, formation of the initial ADP:Pi complex or release of either of the products can be coupled to different motions required to drive the protein machine. The reverse can also be accomplished in the capture of free energy e.g., by the F 1 F 0 -ATP synthase (1, 2).The subject of this study, SecA, is an ATPase and the active component of the bacterial protein translocation machinery that also contains the protein channel SecYEG (3, 4). It peripherally associates with the membrane, receives unfolded secretory proteins and facilitates their passage across the inner membrane (5, 6). The structure of SecA reveals a single nucleotide binding site situated between 2 RecA-like folds, a scaffold, wing and preprotein cross-linking domain (7).Addition to SecA of preprotein and SecYEG reconstituted into an acidic phospholipid membrane promotes protein translocation and an increase in the rate of ATP hydrolysis (4,8). This corresponds to the energy-transducing activity and is a multistep process (9-11). How the structure of SecA or the channel (12, 13) relate to specific stages of the ATP coupled reaction is unclear.Although there is still controversy in the field as to the nature and purpose of homo-oligomerisation in SecA, an increasing body of evidence suggests that SecA is dimeric in free solution, but dissociates into monomers as a consequence of the protein transport reaction (14-21). Additional rearrangements within SecA (14,19,21,22) and SecYEG (21,23,24) have also been reported. These studies have been crowned by an X-ray structure of the complex (one copy of each) that reveals the nature and consequences of the...

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The Oligomeric State and Arrangement of the Active Bacterial Translocon

Deville

Gold

Robson

et al. 2011

Journal of Biological Chemistry

116

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Protein secretion in bacteria is driven through the ubiquitous SecYEG complex by the ATPase SecA. The structure of SecYEG alone or as a complex with SecA in detergent reveal a monomeric heterotrimer enclosing a central protein channel, yet in membranes it is dimeric. We have addressed the functional significance of the oligomeric status of SecYEG in protein translocation using single molecule and ensemble methods. The results show that while monomers are sufficient for the SecA- and ATP-dependent association of SecYEG with pre-protein, active transport requires SecYEG dimers arranged in the back-to-back conformation. Molecular modeling of this dimeric structure, in conjunction with the new functional data, provides a rationale for the presence of both active and passive copies of SecYEG in the functional translocon.

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Visualization of cytosolic ribosomes on the surface of mitochondria by electron cryo‐tomography

et al. 2017

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We employed electron cryo‐tomography to visualize cytosolic ribosomes on the surface of mitochondria. Translation‐arrested ribosomes reveal the clustered organization of the TOM complex, corroborating earlier reports of localized translation. Ribosomes are shown to interact specifically with the TOM complex, and nascent chain binding is crucial for ribosome recruitment and stabilization. Ribosomes are bound to the membrane in discrete clusters, often in the vicinity of the crista junctions. This interaction highlights how protein synthesis may be coupled with transport. Our work provides unique insights into the spatial organization of cytosolic ribosomes on mitochondria.

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Vicki A. M. Gold

Membrane protein insertion and proton-motive-force-dependent secretion through the bacterial holo-translocon SecYEG–SecDF–YajC–YidC

The action of cardiolipin on the bacterial translocon

Energy transduction in protein transport and the ATP hydrolytic cycle of SecA

The Oligomeric State and Arrangement of the Active Bacterial Translocon

Visualization of cytosolic ribosomes on the surface of mitochondria by electron cryo‐tomography

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