Corinne J. Smith
University of Warwick
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Featured researches published by Corinne J. Smith.
Nature Reviews Molecular Cell Biology | 2006
Melissa A. Edeling; Corinne J. Smith; David J. Owen
Membrane sorting between secretory and endocytic organelles is predominantly controlled by small carrier vesicles or tubules that have specific protein coats on their cytoplasmic surfaces. Clathrin–clathrin-adaptor coats function in many steps of intracellular transport and are the most extensively studied of all transport-vesicle coats. In recent years, the determination of structures of clathrin assemblies by electron microscopy, of domains of clathrin and of its adaptors has improved our understanding of the molecular mechanisms of clathrin-coated-vesicle assembly and disassembly.
Journal of the American Chemical Society | 2009
Timothy J. Knowles; Rachael Finka; Corinne J. Smith; Yu-Pin Lin; Timothy R. Dafforn; Michael Overduin
One-third of eukaryotic proteins are integrated within membranes, as are the targets of 40% of approved drugs. However, the lack of a general means of solubilizing, stabilizing and structurally characterizing active membrane proteins has frustrated efforts to understand their mechanisms and exploit their potential value. Here we report that bilayer disks formed by phospholipids and styrene maleic anhydride copolymer preserve the functional and structural integrity of alpha-helical and beta-barrel transmembrane proteins. They form 11 nm particles that are monodispersed, biocompatible, thermostable, and water-soluble, allowing diverse membrane proteins to be simply and rapidly presented for virtually any in vitro analysis.
Biochemical and Biophysical Research Communications | 1987
Anthony R. Clarke; Corinne J. Smith; Keith W. Hart; Helen M. Wilks; William N. Chia; Thomas V. Lee; Jens J. Birktoft; Leonard J. Banaszak; David A. Barstow; Tony Atkinson; J. John Holbrook
Using site-directed mutagenesis on the lactate dehydrogenase gene from Bacillus stearothermophilus, three amino acid substitutions have been made at sites in the enzyme which we suggest in part determine specificity toward different hydroxyacids (R-CHOH-COOH). To change the preferred substrates from the pyruvate/lactate pair (R = -CH3) to the oxaloacetate/malate pair (R = -CH2-COO-), the volume of the active site was increased (thr 246----gly), an acid was neutralized (asp-197----asn) and a base was introduced (gln-102 - greater than arg). The wild type enzyme has a catalytic specificity for pyruvate over oxaloacetate of 1000 whereas the triple mutant has a specificity for oxaloacetate over pyruvate of 500. Despite the severity and extent of these active site alterations, the malate dehydrogenase so produced retains a reasonably fast catalytic rate constant (20 s-1 for oxaloacetate reduction) and is still allosterically controlled by fructose-1,6-bisphosphate.
EMBO Reports | 2004
Timothy R. Dafforn; Corinne J. Smith
It is commonly assumed that a protein must adopt a tertiary structure to achieve its active native state and that regions of a protein that are devoid of α‐helix or β‐sheet structures are functionally inert. Although extended proline‐rich regions are recognized as presenting binding motifs to, for example, Src homology 2 (SH2) and SH3 domains, the idea persists that natively unfolded regions in functional proteins are simply ‘spacers’ between the folded domains. Such a view has been challenged in recent years and the importance of natively unfolded proteins in biology is now being recognized. In this review, we highlight the role of natively unfolded domains in the field of endocytosis, and show that some important endocytic proteins lack a traditionally folded structure and harbour important binding motifs in their unstructured linker regions.
Proceedings of the National Academy of Sciences of the United States of America | 2011
Alice Rothnie; Anthony R. Clarke; Petr Kuzmic; Angus Cameron; Corinne J. Smith
An essential stage in endocytic coated vesicle recycling is the dissociation of clathrin from the vesicle coat by the molecular chaperone, 70-kDa heat-shock cognate protein (Hsc70), and the J-domain-containing protein, auxilin, in an ATP-dependent process. We present a detailed mechanistic analysis of clathrin disassembly catalyzed by Hsc70 and auxilin, using loss of perpendicular light scattering to monitor the process. We report that a single auxilin per clathrin triskelion is required for maximal rate of disassembly, that ATP is hydrolyzed at the same rate that disassembly occurs, and that three ATP molecules are hydrolyzed per clathrin triskelion released. Stopped-flow measurements revealed a lag phase in which the scattering intensity increased owing to association of Hsc70 with clathrin cages followed by serial rounds of ATP hydrolysis prior to triskelion removal. Global fit of stopped-flow data to several physically plausible mechanisms showed the best fit to a model in which sequential hydrolysis of three separate ATP molecules is required for the eventual release of a triskelion from the clathrin–auxilin cage.
Journal of Biological Chemistry | 2012
Daniel O. Beck; Nishi Vasisht; Corinne J. Smith; Colin Robinson
Background: The Tat system transports folded proteins in bacteria. Results: Unlike TatA, the paralogous TatE is found as small, homogeneous complexes. Conclusion: TatE cannot form a variable translocation channel as suggested for TatA. Significance: This work suggests a new model in which a structurally homogeneous form of translocase uses a flexible channel. The twin-arginine translocation (Tat) system transports folded proteins across bacterial and plant thylakoid membranes. Most current models for the translocation mechanism propose the coalescence of a substrate-binding TatABC complex with a separate TatA complex. In Escherichia coli, TatA complexes are widely believed to form the translocation pore, and the size variation of TatA has been linked to the transport of differently sized substrates. Here, we show that the TatA paralog TatE can substitute for TatA and support translocation of Tat substrates including AmiA, AmiC, and TorA. However, TatE is found as much smaller, discrete complexes. Gel filtration and blue native electrophoresis suggest sizes between ∼50 and 110 kDa, and single-particle processing of electron micrographs gives size estimates of 70–90 kDa. Three-dimensional models of the two principal TatE complexes show estimated diameters of 6–8 nm and potential clefts or channels of up to 2.5 nm diameter. The ability of TatE to support translocation of the 90-kDa TorA protein suggests alternative translocation models in which single TatA/E complexes do not contribute the bulk of the translocation channel. The homogeneity of both the TatABC and the TatE complexes further suggests that a discrete Tat translocase can translocate a variety of substrates, presumably through the use of a flexible channel. The presence and possible significance of double- or triple-ring TatE forms is discussed.
Biochemical Journal | 2013
Raúl Pacheco-Gómez; Xi Cheng; Matthew R. Hicks; Corinne J. Smith; David I. Roper; Stephen Addinall; Alison Rodger; Timothy R. Dafforn
Prokaryotic cell division is a highly orchestrated process requiring the formation of a wide range of biomolecular complexes, perhaps the most important of these involving the prokaryotic tubulin homologue FtsZ, a fibre-forming GTPase. FtsZ assembles into a ring (the Z-ring) on the inner surface of the inner membrane at the site of cell division. The Z-ring then acts as a recruitment site for at least ten other proteins which form the division apparatus. One of these proteins, ZapA, acts to enhance lateral associations between FtsZ fibres to form bundles. Previously we have expressed, purified and crystallized ZapA and demonstrated that it exists as a tetramer. We also showed that ZapA binds to FtsZ polymers, strongly promoting their bundling, while inhibiting FtsZ GTPase activity by inducing conformational changes in the bound nucleotide. In the present study we investigate the importance of the tetramerization of ZapA on its function. We generated a number of mutant forms of ZapA with the aim of disrupting the dimer-dimer interface. We show that one of these mutants, I83E, is fully folded and binds to FtsZ, but is a constitutive dimer. Using this mutant we show that tetramerization is a requirement for both FtsZ bundling and GTPase modulation activities.
FEBS Letters | 1997
Corinne J. Smith; Alex F. Drake; Beaulah Banfield; Graham B. Bloomberg; Mark S. Palmer; Anthony R. Clarke; John Collinge
We have used circular dichroism to study synthetic peptides from two important regions of the prion protein: the N‐terminal octa‐repeat domain and a highly conserved hydrophobic section. Our results show that the octa‐repeat sequence in free solution can adopt a non‐random, extended conformation with properties similar to the poly‐l‐proline type II left‐handed helix. We also show that the conformation can be changed by temperature, organic solvents (e.g. acetonitrile) and on binding to phospholipid vesicles. We compared CD data from two peptides corresponding to the hydrophobic region between residues 106 and 136 which contained either methionine or valine at position 129. This variation represents a common polymorphism in humans which has been shown to influence predisposition towards iatrogenic and sporadic CJD. There was no detectable difference between the CD spectra of these peptides irrespective of the solvent conditions we used.
Biophysical Journal | 2012
Daniel J. Turner; Ian Portman; Timothy R. Dafforn; Alison Rodger; David I. Roper; Corinne J. Smith; Matthew S. Turner
Inhibition of the Fts family of proteins causes the growth of long filamentous cells, indicating that they play some role in cell division. FtsZ polymerizes into protofilaments and assembles into the Z-ring at the future site of the septum of cell division. We analyze the rigidity of GTP-bound FtsZ protofilaments by using cryoelectron microscopy to sample their bending fluctuations. We find that the FtsZ-GTP filament rigidity is κ=4.7±1.0×10(-27) Nm(2), with a corresponding thermal persistence length of l(p)=1.15±0.25μm, much higher than previous estimates. In conjunction with other model studies, our new higher estimate for FtsZ rigidity suggests that contraction of the Z-ring may generate sufficient force to facilitate cell division. The good agreement between the measured mode amplitudes and that predicted by equipartition of energy supports our use of a simple mechanical model for FtsZ fibers. The study also provides evidence that the fibers have no intrinsic global or local curvatures, such as might be caused by partial hydrolysis of the GTP.
eLife | 2016
Christopher J. Millard; Niranjan Varma; Almutasem Saleh; Kyle Morris Morris; Peter J. Watson; Andrew R. Bottrill; Louise Fairall; Corinne J. Smith; John W. R. Schwabe
The NuRD complex is a multi-protein transcriptional corepressor that couples histone deacetylase and ATP-dependent chromatin remodelling activities. The complex regulates the higher-order structure of chromatin, and has important roles in the regulation of gene expression, DNA damage repair and cell differentiation. HDACs 1 and 2 are recruited by the MTA1 corepressor to form the catalytic core of the complex. The histone chaperone protein RBBP4, has previously been shown to bind to the carboxy-terminal tail of MTA1. We show that MTA1 recruits a second copy of RBBP4. The crystal structure reveals an extensive interface between MTA1 and RBBP4. An EM structure, supported by SAXS and crosslinking, reveals the architecture of the dimeric HDAC1:MTA1:RBBP4 assembly which forms the core of the NuRD complex. We find evidence that in this complex RBBP4 mediates interaction with histone H3 tails, but not histone H4, suggesting a mechanism for recruitment of the NuRD complex to chromatin. DOI: http://dx.doi.org/10.7554/eLife.13941.001