William John Allen
University of Bristol
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Featured researches published by William John Allen.
Proceedings of the National Academy of Sciences of the United States of America | 2014
Ryan J. Schulze; Joanna Komar; Mathieu Botte; William John Allen; Sarah L. Whitehouse; Vicki A. M. Gold; Jelger A. Lycklama a Nijeholt; Karine Huard; Imre Berger; Christiane Schaffitzel; Ian Collinson
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. The SecY/61 complex forms the protein-channel component of the ubiquitous protein secretion and membrane protein insertion apparatus. The bacterial version SecYEG interacts with the highly conserved YidC and SecDF–YajC subcomplex, which facilitates translocation into and across the membrane. Together, they form the holo-translocon (HTL), which we have successfully overexpressed and purified. In contrast to the homo-dimeric SecYEG, the HTL is a hetero-dimer composed of single copies of SecYEG and SecDF–YajC–YidC. The activities of the HTL differ from the archetypal SecYEG complex. It is more effective in cotranslational insertion of membrane proteins and the posttranslational secretion of a β-barreled outer-membrane protein driven by SecA and ATP becomes much more dependent on the proton-motive force. The activity of the translocating copy of SecYEG may therefore be modulated by association with different accessory subcomplexes: SecYEG (forming SecYEG dimers) or SecDF–YajC–YidC (forming the HTL). This versatility may provide a means to refine the secretion and insertion capabilities according to the substrate. A similar modularity may also be exploited for the translocation or insertion of a wide range of substrates across and into the endoplasmic reticular and mitochondrial membranes of eukaryotes.
Philosophical Transactions of the Royal Society B | 2015
Ian Collinson; Robin Adam Corey; William John Allen
The structure of the first protein-conducting channel was determined more than a decade ago. Today, we are still puzzled by the outstanding problem of protein translocation—the dynamic mechanism underlying the consignment of proteins across and into membranes. This review is an attempt to summarize and understand the energy transducing capabilities of protein-translocating machines, with emphasis on bacterial systems: how polypeptides make headway against the lipid bilayer and how the process is coupled to the free energy associated with ATP hydrolysis and the transmembrane protein motive force. In order to explore how cargo is driven across the membrane, the known structures of the protein-translocation machines are set out against the background of the historic literature, and in the light of experiments conducted in their wake. The paper will focus on the bacterial general secretory (Sec) pathway (SecY-complex), and its eukaryotic counterpart (Sec61-complex), which ferry proteins across the membrane in an unfolded state, as well as the unrelated Tat system that assembles bespoke channels for the export of folded proteins.
Journal of Cell Biology | 2012
Sarah L. Whitehouse; Vicki A. M. Gold; Alice Robson; William John Allen; Richard B. Sessions; Ian Collinson
Polypeptide translocation in bacteria, once underway, requires only one copy each of SecA and SecYEG and does not require the mobility of the SecA 2-helix-finger.
eLife | 2016
William John Allen; Robin Adam Corey; Peter Oatley; Richard B. Sessions; Steve A Baldwin; Sheena E. Radford; Roman Tuma; Ian Collinson
The essential process of protein secretion is achieved by the ubiquitous Sec machinery. In prokaryotes, the drive for translocation comes from ATP hydrolysis by the cytosolic motor-protein SecA, in concert with the proton motive force (PMF). However, the mechanism through which ATP hydrolysis by SecA is coupled to directional movement through SecYEG is unclear. Here, we combine all-atom molecular dynamics (MD) simulations with single molecule FRET and biochemical assays. We show that ATP binding by SecA causes opening of the SecY-channel at long range, while substrates at the SecY-channel entrance feed back to regulate nucleotide exchange by SecA. This two-way communication suggests a new, unifying Brownian ratchet mechanism, whereby ATP binding and hydrolysis bias the direction of polypeptide diffusion. The model represents a solution to the problem of transporting inherently variable substrates such as polypeptides, and may underlie mechanisms of other motors that translocate proteins and nucleic acids. DOI: http://dx.doi.org/10.7554/eLife.15598.001
Structure | 2016
Robin Adam Corey; William John Allen; Joanna Komar; Simonas Masiulis; Sam Menzies; Alice Robson; Ian Collinson
Summary The Sec translocon performs protein secretion and membrane protein insertion at the plasma membrane of bacteria and archaea (SecYEG/β), and the endoplasmic reticular membrane of eukaryotes (Sec61). Despite numerous structures of the complex, the mechanism underlying translocation of pre-proteins, driven by the ATPase SecA in bacteria, remains unresolved. Here we present a series of biochemical and computational analyses exploring the consequences of signal sequence binding to SecYEG. The data demonstrate that a signal sequence-induced movement of transmembrane helix 7 unlocks the translocon and that this conformational change is communicated to the cytoplasmic faces of SecY and SecE, involved in SecA binding. Our findings progress the current understanding of the dynamic action of the translocon during the translocation initiation process. The results suggest that the converging effects of the signal sequence and SecA at the cytoplasmic face of SecYEG are decisive for the intercalation and translocation of pre-protein through the SecY channel.
Biochemical Society Transactions | 2016
Robin Adam Corey; William John Allen; Ian Collinson
We came together in Leeds to commemorate and celebrate the life and achievements of Prof. Stephen Baldwin. For many years we, together with Sheena Radford and Roman Tuma (colleagues also of the University of Leeds), have worked together on the problem of protein translocation through the essential and ubiquitous Sec system. Inspired and helped by Steve we may finally be making progress. My seminar described our latest hypothesis for the molecular mechanism of protein translocation, supported by results collected in Bristol and Leeds on the tractable bacterial secretion process–commonly known as the Sec system; work that will be published elsewhere. Below is a description of the alternative and contested models for protein translocation that we all have been contemplating for many years. This review will consider their pros and cons.
bioRxiv | 2017
Robin Adam Corey; Euan Pyle; William John Allen; Bruno Miroux; Ignacio Arechaga; Argyris Politis; Ian Collinson
The transport of proteins across or into membranes is a vital biological process, achieved in every cell by the conserved Sec machinery. In bacteria, SecYEG associates with the SecA motor protein to carry out secretion of pre-proteins across the plasma membrane, in a process powered by ATP and the trans-membrane proton-motive force. The activities of SecYEG and SecA are modulated by membrane lipids, particularly by the bioenergetically-important phospholipid cardiolipin. Here, we identify two specific cardiolipin binding sites on the Thermotoga maritima SecA-SecYEG complex, through application of coarse grained molecular dynamics simulations. We validate the simulation data and demonstrate the conserved nature of the binding sites using in vitro mutagenesis of Escherichia coli SecYEG, followed by native mass spectroscopy and biochemical analyses. Our data reveal that the two sites account for the preponderance of functional cardiolipin binding to SecYEG, and mediate its roles in the ATPase cycle and protein transport. This study demonstrates the power of coupling coarse grained simulation and experimental analyses towards investigation of both the nature and functional implications of protein-lipid interactions.The transport of proteins across or into membranes is a vital biological process, achieved in every cell by the conserved Sec machinery. In bacteria, SecYEG combines with the SecA motor protein for secretion of pre-proteins across the plasma membrane, powered by ATP hydrolysis and the trans-membrane proton-motive-force (PMF). The activities of SecYEG and SecA are modulated by membrane lipids, particularly by cardiolipin, a specialised phospholipid known to associate with a range of energy-transducing machines. Here, we identify two specific cardiolipin binding sites on the Thermotoga maritima SecA-SecYEG complex, through application of coarse-grained molecular dynamics simulations. We validate the computational data and demonstrate the conserved nature of the binding sites using in vitro mutagenesis, native mass spectrometry and biochemical analysis of Escherichia coli SecYEG. The results show that the two sites account for the preponderance of functional cardiolipin binding to SecYEG, and mediate its roles in ATPase and protein transport activity. In addition, we demonstrate an important role for cardiolipin in the conferral of PMF-stimulation of protein transport. The apparent transient nature of the CL interaction might facilitate proton exchange with the Sec machinery and thereby stimulate protein transport, by an as yet unknown mechanism. This study demonstrates the power of coupling the high predictive ability of coarse-grained simulation with experimental analyses, towards investigation of both the nature and functional implications of protein-lipid interactions.
eLife | 2018
Tomas Fessl; Daniel W. Watkins; Peter Oatley; William John Allen; Robin Adam Corey; Jim Horne; Steve A Baldwin; Sheena E. Radford; Ian Collinson; Roman Tuma
Protein translocation across cell membranes is a ubiquitous process required for protein secretion and membrane protein insertion. In bacteria, this is mostly mediated by the conserved SecYEG complex, driven through rounds of ATP hydrolysis by the cytoplasmic SecA, and the trans-membrane proton motive force. We have used single molecule techniques to explore SecY pore dynamics on multiple timescales in order to dissect the complex reaction pathway. The results show that SecA, both the signal sequence and mature components of the pre-protein, and ATP hydrolysis each have important and specific roles in channel unlocking, opening and priming for transport. After channel opening, translocation proceeds in two phases: a slow phase independent of substrate length, and a length-dependent transport phase with an intrinsic translocation rate of ~40 amino acids per second for the proOmpA substrate. Broad translocation rate distributions reflect the stochastic nature of polypeptide transport.
bioRxiv | 2018
Tomas Fessl; Daniel W. Watkins; Peter Oatley; William John Allen; Robin Adam Corey; Jim Horne; Stephen A. Baldwin; Sheena E. Radford; Ian Collinson; Roman Tuma
Protein translocation across cell membranes is a ubiquitous process required for protein secretion and membrane protein insertion. This is mediated, for the majority of proteins, by the highly conserved Sec machinery. The bacterial translocon – SecYMKEG – resides in the plasma membrane, where translocation is driven through rounds of ATP hydrolysis by the cytoplasmic SecA ATPase, and the proton motive force (PMF). We have used single molecule Förster resonance energy transfer (FRET) alongside a combination of confocal and total internal reflection microscopy to gain access to SecY pore dynamics and translocation kinetics on timescales spanning milliseconds to minutes. This allows us to dissect and characterise the translocation process in unprecedented detail. We show that SecA, signal sequence, pre-protein and ATP hydrolysis each have important and specific roles in unlocking and opening the Sec channel, priming it for transport. After channel opening, translocation proceeds in two phases: an initiation phase independent of substrate length, and a length-dependent transport phase with an intrinsic translocation rate of ~ 40 amino acids per second for the model pre-protein substrate proOmpA. The initiation and translocation phases are both coupled to ATP hydrolysis while termination is ATP-independent. Distributions of translocation rates reflect the stochastic nature of the translocation process and are consistent with the recently proposed Brownian ratchet model [Allen et al. doi: 10.7554/eLife.15598]. The results allow us unparalleled access to the kinetics of the complex reaction and provide a framework for understanding the molecular mechanism of protein secretion.
Proceedings of the National Academy of Sciences of the United States of America | 2018
Robin Adam Corey; Euan Pyle; William John Allen; Daniel W. Watkins; Marina Casiraghi; Bruno Miroux; Ignacio Arechaga; Argyris Politis; Ian Collinson
Significance Many proteins are located in lipid membranes surrounding cells and subcellular organelles. The membrane can impart important structural and functional effects on the protein, making understanding of this interaction critical. Here, we apply computational simulation to the identification of conserved lipid binding sites on an important highly conserved bacterial membrane protein, the Sec translocase (SecA-SecYEG), which uses ATP and the proton-motive force (PMF) to secrete proteins across the bacterial plasma membrane. We experimentally validate these binding sites and use functional analyses to investigate the biological significance of the interactions. We demonstrate that these interactions are specific, transient, and critical for both ATP- and PMF-driven protein secretion. The transport of proteins across or into membranes is a vital biological process, achieved in every cell by the conserved Sec machinery. In bacteria, SecYEG combines with the SecA motor protein for secretion of preproteins across the plasma membrane, powered by ATP hydrolysis and the transmembrane proton-motive force (PMF). The activities of SecYEG and SecA are modulated by membrane lipids, particularly cardiolipin (CL), a specialized phospholipid known to associate with a range of energy-transducing machines. Here, we identify two specific CL binding sites on the Thermotoga maritima SecA–SecYEG complex, through application of coarse-grained molecular dynamics simulations. We validate the computational data and demonstrate the conserved nature of the binding sites using in vitro mutagenesis, native mass spectrometry, biochemical analysis, and fluorescence spectroscopy of Escherichia coli SecYEG. The results show that the two sites account for the preponderance of functional CL binding to SecYEG, and mediate its roles in ATPase and protein transport activity. In addition, we demonstrate an important role for CL in the conferral of PMF stimulation of protein transport. The apparent transient nature of the CL interaction might facilitate proton exchange with the Sec machinery, and thereby stimulate protein transport, by a hitherto unexplored mechanism. This study demonstrates the power of coupling the high predictive ability of coarse-grained simulation with experimental analyses, toward investigation of both the nature and functional implications of protein–lipid interactions.