ORCID Profile
0000-0001-9685-4067
Current Organisation
University of Oxford
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Publisher: eLife Sciences Publications, Ltd
Date: 03-12-2016
DOI: 10.7554/ELIFE.20718
Abstract: The twin-arginine protein translocation system (Tat) transports folded proteins across the bacterial cytoplasmic membrane and the thylakoid membranes of plant chloroplasts. The Tat transporter is assembled from multiple copies of the membrane proteins TatA, TatB, and TatC. We combine sequence co-evolution analysis, molecular simulations, and experimentation to define the interactions between the Tat proteins of Escherichia coli at molecular-level resolution. In the TatBC receptor complex the transmembrane helix of each TatB molecule is sandwiched between two TatC molecules, with one of the inter-subunit interfaces incorporating a functionally important cluster of interacting polar residues. Unexpectedly, we find that TatA also associates with TatC at the polar cluster site. Our data provide a structural model for assembly of the active Tat translocase in which substrate binding triggers replacement of TatB by TatA at the polar cluster site. Our work demonstrates the power of co-evolution analysis to predict protein interfaces in multi-subunit complexes.
Publisher: Proceedings of the National Academy of Sciences
Date: 03-09-2013
Abstract: The twin-arginine translocation (Tat) pathway transports folded proteins across a membrane without significant ion leakage. The mechanism by which Tat is able to carry out this challenging feat is unclear. We used direct imaging of fluorescent protein-tagged Tat components in bacterial cells to show that the TatA element of the Tat system undergoes substrate- and proton motive force-dependent oligomerization. Thus the Tat transporter element is assembled on demand, avoiding the need to seal the transporter between translocation events.
Publisher: Elsevier BV
Date: 04-2005
DOI: 10.1016/J.BBRC.2005.02.038
Abstract: The Tat system functions to transport folded proteins across the bacterial cytoplasmic membrane and the thylakoid membrane of plant chloroplasts. Tat transport involves a high molecular weight TatBC-containing complex that transiently associates with TatA during protein translocation. Sedimentation equilibrium experiments were used to determine a protein-only molecular mass for the TatBC complex of 630+/-30kDa, suggesting that it contains approximately 13 copies of the TatB and TatC protomers. Point mutations that inactivate Tat transport have previously been identified in each of TatA, TatB, and TatC. Analysis of the TatBC complexes formed by these inactive variants demonstrates that the amino acid substitutions neither affect the composition of the TatBC complex nor cause accumulation of the assembled TatABC translocation site. In addition, the TatA protein is shown not to be required for the assembly or stability of the TatBC complex.
Publisher: Proceedings of the National Academy of Sciences
Date: 18-07-2005
Abstract: The Tat system mediates Sec-independent transport of folded precursor proteins across the bacterial plasma membrane or the chloroplast thylakoid membrane. Tat transport involves distinct high-molecular-weight TatA and TatBC complexes. Here we report the 3D architecture of the TatA complex from Escherichia coli obtained by single-particle electron microscopy and random conical tilt reconstruction. TatA forms ring-shaped structures of variable diameter in which the internal channels are large enough to accommodate known Tat substrate proteins. This morphology strongly supports the proposal that TatA forms the protein-conducting channel of the Tat system. One end of the channel is closed by a lid that might gate access to the channel. On the basis of previous protease accessibility measurements, the lid is likely to be located at the cytoplasmic side of the membrane. The observed variation in TatA diameter suggests a model for Tat transport in which the number of TatA protomers changes to match the size of the channel to the size of the substrate being transported. Such dynamic close packing would provide a mechanism to maintain the membrane permeability barrier during transport.
Publisher: Wiley
Date: 15-11-2006
DOI: 10.1111/J.1742-4658.2006.05554.X
Abstract: The Tat system transports folded proteins across the bacterial cytoplasmic membrane and the thylakoid membrane of plant chloroplasts. Substrates are targeted to the Tat pathway by signal peptides containing a pair of consecutive arginine residues. The membrane proteins TatA, TatB and TatC are the essential components of this pathway in Escherichia coli. The complexes that these proteins form at native levels of expression have been investigated by the use of affinity tag-coding sequences fused to chromosomal tat genes. Distinct TatA and TatBC complexes were identified using size-exclusion chromatography and shown to have apparent molecular masses of approximately 700 and 500 kDa, respectively. Following in vivo expression, the Tat substrate protein SufI was found to copurify with the TatBC, but not the TatA, complex. This binding required the SufI signal peptide. Substitution of the twin-arginine residues in the SufI signal peptide by either twin lysine or twin alanine residues abolished export. However, both variant SufI proteins still copurified with the TatBC complex. These data show that the twin-arginine residues of the Tat consensus motif are not essential for binding of precursor to the TatBC complex but are required for the successful entry of the precursor into the transport cycle. The effect on substrate binding of single amino acid substitutions in TatC that affect Tat transport were studied using TatC variants Phe94Ala, Glu103Ala, Glu103Arg and Asp211Ala. Only variant Glu103Arg showed reduced copurification of SufI with TatBC. The transport defects associated with the other TatC variants do not, therefore, arise from an inability to bind substrate proteins.
Publisher: Proceedings of the National Academy of Sciences
Date: 07-03-2013
Abstract: The twin-arginine transport system (Tat) has the remarkable ability of transporting folded proteins across membranes while avoiding uncontrolled ion leakage. Tat is essential for plant photosynthesis and is required for bacterial pathogenesis. The mechanism by which folded proteins are translocated is poorly understood. We have determined the structure of the TatA oligomer, which is responsible for the translocation step, and evaluated its impact on lipid bilayers. The results suggest a mechanism of protein translocation involving thinning and perturbing the membrane bilayer. The approach used here will be useful for structural analysis of other oligomeric proteins that weakly assemble in the membrane.
Location: United Kingdom of Great Britain and Northern Ireland
No related grants have been discovered for Ben Berks.