Your search keyword '"Barford D"' showing total 15 results

1. The allosteric transition of glycogen phosphorylase

Author

Barford, D. and Johnson, L.N.

Subjects

Phosphorylase -- Research, Allosteric proteins -- Research, Protein binding -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Published

1989

2. Structural basis of human separase regulation by securin and CDK1-cyclin B1.

Author

Yu J, Raia P, Ghent CM, Raisch T, Sadian Y, Cavadini S, Sabale PM, Barford D, Raunser S, Morgan DO, and Boland A

Subjects

Amino Acid Motifs, CDC2 Protein Kinase antagonists & inhibitors, CDC2 Protein Kinase ultrastructure, CDC2-CDC28 Kinases chemistry, CDC2-CDC28 Kinases metabolism, CDC2-CDC28 Kinases ultrastructure, Cell Cycle Proteins metabolism, Chromosome Segregation, Cryoelectron Microscopy, Cyclin B1 ultrastructure, DNA-Binding Proteins metabolism, Humans, Models, Molecular, Phosphoserine metabolism, Protein Binding, Protein Domains, Securin ultrastructure, Separase antagonists & inhibitors, Separase ultrastructure, Substrate Specificity, CDC2 Protein Kinase chemistry, CDC2 Protein Kinase metabolism, Cyclin B1 chemistry, Cyclin B1 metabolism, Securin chemistry, Securin metabolism, Separase chemistry, Separase metabolism

Abstract

In early mitosis, the duplicated chromosomes are held together by the ring-shaped cohesin complex 1 . Separation of chromosomes during anaphase is triggered by separase-a large cysteine endopeptidase that cleaves the cohesin subunit SCC1 (also known as RAD21 2-4 ). Separase is activated by degradation of its inhibitors, securin 5 and cyclin B 6 , but the molecular mechanisms of separase regulation are not clear. Here we used cryogenic electron microscopy to determine the structures of human separase in complex with either securin or CDK1-cyclin B1-CKS1. In both complexes, separase is inhibited by pseudosubstrate motifs that block substrate binding at the catalytic site and at nearby docking sites. As in Caenorhabditis elegans 7 and yeast 8 , human securin contains its own pseudosubstrate motifs. By contrast, CDK1-cyclin B1 inhibits separase by deploying pseudosubstrate motifs from intrinsically disordered loops in separase itself. One autoinhibitory loop is oriented by CDK1-cyclin B1 to block the catalytic sites of both separase and CDK1 9,10 . Another autoinhibitory loop blocks substrate docking in a cleft adjacent to the separase catalytic site. A third separase loop contains a phosphoserine 6 that promotes complex assembly by binding to a conserved phosphate-binding pocket in cyclin B1. Our study reveals the diverse array of mechanisms by which securin and CDK1-cyclin B1 bind and inhibit separase, providing the molecular basis for the robust control of chromosome segregation., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

3. Structure of the inner kinetochore CCAN complex assembled onto a centromeric nucleosome.

Author

Yan K, Yang J, Zhang Z, McLaughlin SH, Chang L, Fasci D, Ehrenhofer-Murray AE, Heck AJR, and Barford D

Subjects

Centromere Protein A chemistry, Centromere Protein A ultrastructure, Cryoelectron Microscopy, DNA chemistry, DNA metabolism, DNA ultrastructure, Kinetochores ultrastructure, Models, Molecular, Multiprotein Complexes ultrastructure, Nucleosomes ultrastructure, Protein Subunits chemistry, Protein Subunits metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae ultrastructure, Centromere Protein A metabolism, Kinetochores chemistry, Kinetochores metabolism, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Nucleosomes chemistry, Nucleosomes metabolism

Abstract

In eukaryotes, accurate chromosome segregation in mitosis and meiosis maintains genome stability and prevents aneuploidy. Kinetochores are large protein complexes that, by assembling onto specialized Cenp-A nucleosomes 1,2 , function to connect centromeric chromatin to microtubules of the mitotic spindle 3,4 . Whereas the centromeres of vertebrate chromosomes comprise millions of DNA base pairs and attach to multiple microtubules, the simple point centromeres of budding yeast are connected to individual microtubules 5,6 . All 16 budding yeast chromosomes assemble complete kinetochores using a single Cenp-A nucleosome (Cenp-A Nuc ), each of which is perfectly centred on its cognate centromere 7-9 . The inner and outer kinetochore modules are responsible for interacting with centromeric chromatin and microtubules, respectively. Here we describe the cryo-electron microscopy structure of the Saccharomyces cerevisiae inner kinetochore module, the constitutive centromere associated network (CCAN) complex, assembled onto a Cenp-A nucleosome (CCAN-Cenp-A Nuc ). The structure explains the interdependency of the constituent subcomplexes of CCAN and shows how the Y-shaped opening of CCAN accommodates Cenp-A Nuc to enable specific CCAN subunits to contact the nucleosomal DNA and histone subunits. Interactions with the unwrapped DNA duplex at the two termini of Cenp-A Nuc are mediated predominantly by a DNA-binding groove in the Cenp-L-Cenp-N subcomplex. Disruption of these interactions impairs assembly of CCAN onto Cenp-A Nuc . Our data indicate a mechanism of Cenp-A nucleosome recognition by CCAN and how CCAN acts as a platform for assembly of the outer kinetochore to link centromeres to the mitotic spindle for chromosome segregation.

Published

2019

4. Mechanism for remodelling of the cell cycle checkpoint protein MAD2 by the ATPase TRIP13.

Author

Alfieri C, Chang L, and Barford D

Subjects

ATPases Associated with Diverse Cellular Activities chemistry, ATPases Associated with Diverse Cellular Activities ultrastructure, Apoproteins chemistry, Apoproteins metabolism, Apoproteins ultrastructure, Binding Sites, Biocatalysis drug effects, Cdc20 Proteins chemistry, Cdc20 Proteins metabolism, Cdc20 Proteins ultrastructure, Cell Cycle Proteins chemistry, Cell Cycle Proteins ultrastructure, Cryoelectron Microscopy, Humans, M Phase Cell Cycle Checkpoints drug effects, Mad2 Proteins ultrastructure, Models, Molecular, Protein Conformation, Spindle Apparatus drug effects, Substrate Specificity, ATPases Associated with Diverse Cellular Activities metabolism, Cell Cycle Proteins metabolism, Mad2 Proteins chemistry, Mad2 Proteins metabolism

Abstract

The maintenance of genome stability during mitosis is coordinated by the spindle assembly checkpoint (SAC) through its effector the mitotic checkpoint complex (MCC), an inhibitor of the anaphase-promoting complex (APC/C, also known as the cyclosome) 1,2 . Unattached kinetochores control MCC assembly by catalysing a change in the topology of the β-sheet of MAD2 (an MCC subunit), thereby generating the active closed MAD2 (C-MAD2) conformer 3-5 . Disassembly of free MCC, which is required for SAC inactivation and chromosome segregation, is an ATP-dependent process driven by the AAA+ ATPase TRIP13. In combination with p31 comet , an SAC antagonist 6 , TRIP13 remodels C-MAD2 into inactive open MAD2 (O-MAD2) 7-10 . Here, we present a mechanism that explains how TRIP13-p31 comet disassembles the MCC. Cryo-electron microscopy structures of the TRIP13-p31 comet -C-MAD2-CDC20 complex reveal that p31 comet recruits C-MAD2 to a defined site on the TRIP13 hexameric ring, positioning the N terminus of C-MAD2 (MAD2 NT ) to insert into the axial pore of TRIP13 and distorting the TRIP13 ring to initiate remodelling. Molecular modelling suggests that by gripping MAD2 NT within its axial pore, TRIP13 couples sequential ATP-driven translocation of its hexameric ring along MAD2 NT to push upwards on, and simultaneously rotate, the globular domains of the p31 comet -C-MAD2 complex. This unwinds a region of the αA helix of C-MAD2 that is required to stabilize the C-MAD2 β-sheet, thus destabilizing C-MAD2 in favour of O-MAD2 and dissociating MAD2 from p31 comet . Our study provides insights into how specific substrates are recruited to AAA+ ATPases through adaptor proteins and suggests a model of how translocation through the axial pore of AAA+ ATPases is coupled to protein remodelling.

Published

2018

5. Molecular basis of APC/C regulation by the spindle assembly checkpoint.

Author

Alfieri C, Chang L, Zhang Z, Yang J, Maslen S, Skehel M, and Barford D

Subjects

Anaphase-Promoting Complex-Cyclosome chemistry, Anaphase-Promoting Complex-Cyclosome metabolism, Biocatalysis, Cdc20 Proteins chemistry, Cdc20 Proteins metabolism, Cdc20 Proteins ultrastructure, Cell Cycle Proteins metabolism, Chromosome Segregation, Humans, Kinetochores metabolism, Models, Molecular, Protein Binding, Protein Conformation, Protein Serine-Threonine Kinases chemistry, Protein Serine-Threonine Kinases metabolism, Protein Serine-Threonine Kinases ultrastructure, Protein Subunits chemistry, Protein Subunits metabolism, Spindle Apparatus chemistry, Structure-Activity Relationship, Ubiquitin-Conjugating Enzymes chemistry, Ubiquitin-Conjugating Enzymes metabolism, Ubiquitin-Conjugating Enzymes ultrastructure, Ubiquitin-Protein Ligases metabolism, Ubiquitination, Anaphase-Promoting Complex-Cyclosome antagonists & inhibitors, Anaphase-Promoting Complex-Cyclosome ultrastructure, Cryoelectron Microscopy, M Phase Cell Cycle Checkpoints physiology, Spindle Apparatus metabolism, Spindle Apparatus ultrastructure

Abstract

In the dividing eukaryotic cell, the spindle assembly checkpoint (SAC) ensures that each daughter cell inherits an identical set of chromosomes. The SAC coordinates the correct attachment of sister chromatid kinetochores to the mitotic spindle with activation of the anaphase-promoting complex (APC/C), the E3 ubiquitin ligase responsible for initiating chromosome separation. In response to unattached kinetochores, the SAC generates the mitotic checkpoint complex (MCC), which inhibits the APC/C and delays chromosome segregation. By cryo-electron microscopy, here we determine the near-atomic resolution structure of a human APC/C–MCC complex (APC/C(MCC)). Degron-like sequences of the MCC subunit BubR1 block degron recognition sites on Cdc20, the APC/C coactivator subunit responsible for substrate interactions. BubR1 also obstructs binding of the initiating E2 enzyme UbcH10 to repress APC/C ubiquitination activity. Conformational variability of the complex enables UbcH10 association, and structural analysis shows how the Cdc20 subunit intrinsic to the MCC (Cdc20(MCC)) is ubiquitinated, a process that results in APC/C reactivation when the SAC is silenced., Competing Interests: The authors declare no competing financial interests.

Published

2016

6. Molecular mechanism of APC/C activation by mitotic phosphorylation.

Author

Zhang S, Chang L, Alfieri C, Zhang Z, Yang J, Maslen S, Skehel M, and Barford D

Subjects

Amino Acid Motifs, Anaphase-Promoting Complex-Cyclosome chemistry, Anaphase-Promoting Complex-Cyclosome ultrastructure, Antigens, CD, Apc1 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc1 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apc3 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apoenzymes metabolism, Binding Sites, Cadherins chemistry, Cadherins metabolism, Cadherins ultrastructure, Cdc20 Proteins antagonists & inhibitors, Cdc20 Proteins chemistry, Cdc20 Proteins metabolism, Cdc20 Proteins ultrastructure, Cryoelectron Microscopy, Cyclin-Dependent Kinases metabolism, Cyclins metabolism, Enzyme Activation, Humans, Models, Molecular, Phosphoproteins chemistry, Phosphoproteins ultrastructure, Phosphorylation, Protein Binding, Protein Conformation, Tosylarginine Methyl Ester pharmacology, Anaphase-Promoting Complex-Cyclosome metabolism, Mitosis, Phosphoproteins metabolism

Abstract

In eukaryotes, the anaphase-promoting complex (APC/C, also known as the cyclosome) regulates the ubiquitin-dependent proteolysis of specific cell-cycle proteins to coordinate chromosome segregation in mitosis and entry into the G1 phase. The catalytic activity of the APC/C and its ability to specify the destruction of particular proteins at different phases of the cell cycle are controlled by its interaction with two structurally related coactivator subunits, Cdc20 and Cdh1. Coactivators recognize substrate degrons, and enhance the affinity of the APC/C for its cognate E2 (refs 4-6). During mitosis, cyclin-dependent kinase (Cdk) and polo-like kinase (Plk) control Cdc20- and Cdh1-mediated activation of the APC/C. Hyperphosphorylation of APC/C subunits, notably Apc1 and Apc3, is required for Cdc20 to activate the APC/C, whereas phosphorylation of Cdh1 prevents its association with the APC/C. Since both coactivators associate with the APC/C through their common C-box and Ile-Arg tail motifs, the mechanism underlying this differential regulation is unclear, as is the role of specific APC/C phosphorylation sites. Here, using cryo-electron microscopy and biochemical analysis, we define the molecular basis of how phosphorylation of human APC/C allows for its control by Cdc20. An auto-inhibitory segment of Apc1 acts as a molecular switch that in apo unphosphorylated APC/C interacts with the C-box binding site and obstructs engagement of Cdc20. Phosphorylation of the auto-inhibitory segment displaces it from the C-box-binding site. Efficient phosphorylation of the auto-inhibitory segment, and thus relief of auto-inhibition, requires the recruitment of Cdk-cyclin in complex with a Cdk regulatory subunit (Cks) to a hyperphosphorylated loop of Apc3. We also find that the small-molecule inhibitor, tosyl-l-arginine methyl ester, preferentially suppresses APC/C(Cdc20) rather than APC/C(Cdh1), and interacts with the binding sites of both the C-box and Ile-Arg tail motifs. Our results reveal the mechanism for the regulation of mitotic APC/C by phosphorylation and provide a rationale for the development of selective inhibitors of this state.

Published

2016

7. Atomic structure of the APC/C and its mechanism of protein ubiquitination.

Author

Chang L, Zhang Z, Yang J, McLaughlin SH, and Barford D

Subjects

Anaphase-Promoting Complex-Cyclosome chemistry, Antigens, CD, Apc1 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc1 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apc1 Subunit, Anaphase-Promoting Complex-Cyclosome ultrastructure, Apc10 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc10 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apc10 Subunit, Anaphase-Promoting Complex-Cyclosome ultrastructure, Apc11 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc11 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apc3 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc3 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apc8 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc8 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Apc8 Subunit, Anaphase-Promoting Complex-Cyclosome ultrastructure, Cadherins chemistry, Cadherins metabolism, Cadherins ultrastructure, Catalytic Domain, Cell Cycle Proteins chemistry, Cell Cycle Proteins metabolism, Cell Cycle Proteins ultrastructure, Cryoelectron Microscopy, Cytoskeletal Proteins chemistry, Cytoskeletal Proteins metabolism, F-Box Proteins chemistry, F-Box Proteins metabolism, F-Box Proteins ultrastructure, Humans, Lysine metabolism, Models, Molecular, Phosphorylation, Protein Binding, Protein Subunits chemistry, Protein Subunits metabolism, Structure-Activity Relationship, Substrate Specificity, Ubiquitin chemistry, Ubiquitin metabolism, Ubiquitin ultrastructure, Ubiquitin-Conjugating Enzymes chemistry, Ubiquitin-Conjugating Enzymes metabolism, Ubiquitin-Conjugating Enzymes ultrastructure, Anaphase-Promoting Complex-Cyclosome metabolism, Anaphase-Promoting Complex-Cyclosome ultrastructure, Ubiquitination

Abstract

The anaphase-promoting complex (APC/C) is a multimeric RING E3 ubiquitin ligase that controls chromosome segregation and mitotic exit. Its regulation by coactivator subunits, phosphorylation, the mitotic checkpoint complex and interphase early mitotic inhibitor 1 (Emi1) ensures the correct order and timing of distinct cell-cycle transitions. Here we use cryo-electron microscopy to determine atomic structures of APC/C-coactivator complexes with either Emi1 or a UbcH10-ubiquitin conjugate. These structures define the architecture of all APC/C subunits, the position of the catalytic module and explain how Emi1 mediates inhibition of the two E2s UbcH10 and Ube2S. Definition of Cdh1 interactions with the APC/C indicates how they are antagonized by Cdh1 phosphorylation. The structure of the APC/C with UbcH10-ubiquitin reveals insights into the initiating ubiquitination reaction. Our results provide a quantitative framework for the design of future experiments to investigate APC/C functions in vivo.

Published

2015

8. Molecular architecture and mechanism of the anaphase-promoting complex.

Author

Chang LF, Zhang Z, Yang J, McLaughlin SH, and Barford D

Subjects

Allosteric Regulation, Anaphase-Promoting Complex-Cyclosome chemistry, Apc10 Subunit, Anaphase-Promoting Complex-Cyclosome chemistry, Apc10 Subunit, Anaphase-Promoting Complex-Cyclosome metabolism, Catalytic Domain, Cdh1 Proteins chemistry, Cdh1 Proteins metabolism, Cdh1 Proteins ultrastructure, Cryoelectron Microscopy, Humans, Models, Molecular, Pliability, Protein Folding, Protein Structure, Secondary, Protein Subunits chemistry, Protein Subunits metabolism, Ubiquitin metabolism, Ubiquitin-Conjugating Enzymes metabolism, Ubiquitination, Anaphase-Promoting Complex-Cyclosome metabolism, Anaphase-Promoting Complex-Cyclosome ultrastructure

Abstract

The ubiquitination of cell cycle regulatory proteins by the anaphase-promoting complex/cyclosome (APC/C) controls sister chromatid segregation, cytokinesis and the establishment of the G1 phase of the cell cycle. The APC/C is an unusually large multimeric cullin-RING ligase. Its activity is strictly dependent on regulatory coactivator subunits that promote APC/C-substrate interactions and stimulate its catalytic reaction. Because the structures of many APC/C subunits and their organization within the assembly are unknown, the molecular basis for these processes is poorly understood. Here, from a cryo-electron microscopy reconstruction of a human APC/C-coactivator-substrate complex at 7.4 Å resolution, we have determined the complete secondary structural architecture of the complex. With this information we identified protein folds for structurally uncharacterized subunits, and the definitive location of all 20 APC/C subunits within the 1.2 MDa assembly. Comparison with apo APC/C shows that the coactivator promotes a profound allosteric transition involving displacement of the cullin-RING catalytic subunits relative to the degron-recognition module of coactivator and APC10. This transition is accompanied by increased flexibility of the cullin-RING subunits and enhanced affinity for UBCH10-ubiquitin, changes which may contribute to coactivator-mediated stimulation of APC/C E3 ligase activity.

Published

2014

9. Mechanism of farnesylated CAAX protein processing by the intramembrane protease Rce1.

Author

Manolaridis I, Kulkarni K, Dodd RB, Ogasawara S, Zhang Z, Bineva G, Reilly NO, Hanrahan SJ, Thompson AJ, Cronin N, Iwata S, and Barford D

Subjects

Amino Acid Motifs, Amino Acid Sequence, Animals, Archaeal Proteins chemistry, Archaeal Proteins metabolism, Conserved Sequence, Crystallography, X-Ray, Cysteine metabolism, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, Endopeptidases chemistry, Endopeptidases metabolism, Endoplasmic Reticulum enzymology, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Glutamic Acid metabolism, Humans, Membrane Proteins metabolism, Metalloendopeptidases chemistry, Metalloendopeptidases metabolism, Mice, Models, Molecular, Molecular Sequence Data, Peptide Hydrolases classification, Protein Structure, Tertiary, Proto-Oncogene Proteins p21(ras) chemistry, Signal Transduction, Substrate Specificity, Biocatalysis, Membrane Proteins chemistry, Methanococcus enzymology, Peptide Hydrolases chemistry, Peptide Hydrolases metabolism, Prenylation, Proto-Oncogene Proteins p21(ras) metabolism

Abstract

CAAX proteins have essential roles in multiple signalling pathways, controlling processes such as proliferation, differentiation and carcinogenesis. The ∼120 mammalian CAAX proteins function at cellular membranes and include the Ras superfamily of small GTPases, nuclear lamins, the γ-subunit of heterotrimeric GTPases, and several protein kinases and phosphatases. The proper localization of CAAX proteins to cell membranes is orchestrated by a series of post-translational modifications of the carboxy-terminal CAAX motifs (where C is cysteine, A is an aliphatic amino acid and X is any amino acid). These reactions involve prenylation of the cysteine residue, cleavage at the AAX tripeptide and methylation of the carboxyl-prenylated cysteine residue. The major CAAX protease activity is mediated by Rce1 (Ras and a-factor converting enzyme 1), an intramembrane protease (IMP) of the endoplasmic reticulum. Information on the architecture and proteolytic mechanism of Rce1 has been lacking. Here we report the crystal structure of a Methanococcus maripaludis homologue of Rce1, whose endopeptidase specificity for farnesylated peptides mimics that of eukaryotic Rce1. Its structure, comprising eight transmembrane α-helices, and catalytic site are distinct from those of other IMPs. The catalytic residues are located ∼10 Å into the membrane and are exposed to the cytoplasm and membrane through a conical cavity that accommodates the prenylated CAAX substrate. We propose that the farnesyl lipid binds to a site at the opening of two transmembrane α-helices, which results in the scissile bond being positioned adjacent to a glutamate-activated nucleophilic water molecule. This study suggests that Rce1 is the founding member of a novel IMP family, the glutamate IMPs.

Published

2013

10. Structure of the mitotic checkpoint complex.

Author

Chao WC, Kulkarni K, Zhang Z, Kong EH, and Barford D

Subjects

Amino Acid Motifs, Anaphase-Promoting Complex-Cyclosome, Cdc20 Proteins, Cdh1 Proteins, Cell Cycle Proteins metabolism, Conserved Sequence, Crystallography, X-Ray, Humans, Mad2 Proteins, Models, Molecular, Multiprotein Complexes metabolism, Nuclear Proteins metabolism, Protein Structure, Quaternary, Protein Structure, Tertiary, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Schizosaccharomyces pombe Proteins metabolism, Spindle Apparatus, Structure-Activity Relationship, Substrate Specificity, Ubiquitin-Protein Ligase Complexes antagonists & inhibitors, Ubiquitin-Protein Ligase Complexes chemistry, Ubiquitin-Protein Ligase Complexes metabolism, Ubiquitin-Protein Ligase Complexes ultrastructure, Cell Cycle Proteins chemistry, M Phase Cell Cycle Checkpoints, Multiprotein Complexes chemistry, Nuclear Proteins chemistry, Schizosaccharomyces chemistry, Schizosaccharomyces pombe Proteins chemistry

Abstract

In mitosis, the spindle assembly checkpoint (SAC) ensures genome stability by delaying chromosome segregation until all sister chromatids have achieved bipolar attachment to the mitotic spindle. The SAC is imposed by the mitotic checkpoint complex (MCC), whose assembly is catalysed by unattached chromosomes and which binds and inhibits the anaphase-promoting complex/cyclosome (APC/C), the E3 ubiquitin ligase that initiates chromosome segregation. Here, using the crystal structure of Schizosaccharomyces pombe MCC (a complex of mitotic spindle assembly checkpoint proteins Mad2, Mad3 and APC/C co-activator protein Cdc20), we reveal the molecular basis of MCC-mediated APC/C inhibition and the regulation of MCC assembly. The MCC inhibits the APC/C by obstructing degron recognition sites on Cdc20 (the substrate recruitment subunit of the APC/C) and displacing Cdc20 to disrupt formation of a bipartite D-box receptor with the APC/C subunit Apc10. Mad2, in the closed conformation (C-Mad2), stabilizes the complex by optimally positioning the Mad3 KEN-box degron to bind Cdc20. Mad3 and p31(comet) (also known as MAD2L1-binding protein) compete for the same C-Mad2 interface, which explains how p31(comet) disrupts MCC assembly to antagonize the SAC. This study shows how APC/C inhibition is coupled to degron recognition by co-activators.

Published

2012

11. A Raf-induced allosteric transition of KSR stimulates phosphorylation of MEK.

Author

Brennan DF, Dar AC, Hertz NT, Chao WC, Burlingame AL, Shokat KM, and Barford D

Subjects

Adenosine Triphosphate metabolism, Allosteric Regulation physiology, Animals, Biocatalysis, Catalytic Domain, Crystallography, X-Ray, Enzyme Activation, Extracellular Signal-Regulated MAP Kinases metabolism, Humans, Models, Molecular, Phosphorylation, Protein Multimerization, Protein Structure, Quaternary, Proto-Oncogene Proteins B-raf chemistry, Proto-Oncogene Proteins B-raf genetics, Rabbits, Signal Transduction, MAP Kinase Kinase 1 chemistry, MAP Kinase Kinase 1 metabolism, Protein Serine-Threonine Kinases chemistry, Protein Serine-Threonine Kinases metabolism, Proto-Oncogene Proteins B-raf metabolism

Abstract

In metazoans, the Ras-Raf-MEK (mitogen-activated protein-kinase kinase)-ERK (extracellular signal-regulated kinase) signalling pathway relays extracellular stimuli to elicit changes in cellular function and gene expression. Aberrant activation of this pathway through oncogenic mutations is responsible for a large proportion of human cancer. Kinase suppressor of Ras (KSR) functions as an essential scaffolding protein to coordinate the assembly of Raf-MEK-ERK complexes. Here we integrate structural and biochemical studies to understand how KSR promotes stimulatory Raf phosphorylation of MEK (refs 6, 7). We show, from the crystal structure of the kinase domain of human KSR2 (KSR2(KD)) in complex with rabbit MEK1, that interactions between KSR2(KD) and MEK1 are mediated by their respective activation segments and C-lobe αG helices. Analogous to BRAF (refs 8, 9), KSR2 self-associates through a side-to-side interface involving Arg 718, a residue identified in a genetic screen as a suppressor of Ras signalling. ATP is bound to the KSR2(KD) catalytic site, and we demonstrate KSR2 kinase activity towards MEK1 by in vitro assays and chemical genetics. In the KSR2(KD)-MEK1 complex, the activation segments of both kinases are mutually constrained, and KSR2 adopts an inactive conformation. BRAF allosterically stimulates the kinase activity of KSR2, which is dependent on formation of a side-to-side KSR2-BRAF heterodimer. Furthermore, KSR2-BRAF heterodimerization results in an increase of BRAF-induced MEK phosphorylation via the KSR2-mediated relay of a signal from BRAF to release the activation segment of MEK for phosphorylation. We propose that KSR interacts with a regulatory Raf molecule in cis to induce a conformational switch of MEK, facilitating MEK's phosphorylation by a separate catalytic Raf molecule in trans.

Published

2011

12. Structures of APC/C(Cdh1) with substrates identify Cdh1 and Apc10 as the D-box co-receptor.

Author

da Fonseca PC, Kong EH, Zhang Z, Schreiber A, Williams MA, Morris EP, and Barford D

Subjects

Amino Acid Motifs, Anaphase-Promoting Complex-Cyclosome, Apc10 Subunit, Anaphase-Promoting Complex-Cyclosome, Apc2 Subunit, Anaphase-Promoting Complex-Cyclosome, Biocatalysis, Cdh1 Proteins, Cell Cycle Proteins chemistry, Cell Cycle Proteins ultrastructure, Cryoelectron Microscopy, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Binding, Protein Conformation, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins ultrastructure, Substrate Specificity, Ubiquitin-Protein Ligase Complexes ultrastructure, Ubiquitination, Cell Cycle Proteins metabolism, Peptides chemistry, Peptides metabolism, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins metabolism, Ubiquitin-Protein Ligase Complexes chemistry, Ubiquitin-Protein Ligase Complexes metabolism

Abstract

The ubiquitylation of cell-cycle regulatory proteins by the large multimeric anaphase-promoting complex (APC/C) controls sister chromatid segregation and the exit from mitosis. Selection of APC/C targets is achieved through recognition of destruction motifs, predominantly the destruction (D)-box and KEN (Lys-Glu-Asn)-box. Although this process is known to involve a co-activator protein (either Cdc20 or Cdh1) together with core APC/C subunits, the structural basis for substrate recognition and ubiquitylation is not understood. Here we investigate budding yeast APC/C using single-particle electron microscopy and determine a cryo-electron microscopy map of APC/C in complex with the Cdh1 co-activator protein (APC/C(Cdh1)) bound to a D-box peptide at ∼10 Å resolution. We find that a combined catalytic and substrate-recognition module is located within the central cavity of the APC/C assembled from Cdh1, Apc10--a core APC/C subunit previously implicated in substrate recognition--and the cullin domain of Apc2. Cdh1 and Apc10, identified from difference maps, create a co-receptor for the D-box following repositioning of Cdh1 towards Apc10. Using NMR spectroscopy we demonstrate specific D-box-Apc10 interactions, consistent with a role for Apc10 in directly contributing towards D-box recognition by the APC/C(Cdh1) complex. Our results rationalize the contribution of both co-activator and core APC/C subunits to D-box recognition and provide a structural framework for understanding mechanisms of substrate recognition and catalysis by the APC/C.

Published

2011

13. Structural basis for the subunit assembly of the anaphase-promoting complex.

Author

Schreiber A, Stengel F, Zhang Z, Enchev RI, Kong EH, Morris EP, Robinson CV, da Fonseca PC, and Barford D

Subjects

Amino Acid Motifs, Anaphase-Promoting Complex-Cyclosome, Animals, Apc2 Subunit, Anaphase-Promoting Complex-Cyclosome, Apc5 Subunit, Anaphase-Promoting Complex-Cyclosome, Apc8 Subunit, Anaphase-Promoting Complex-Cyclosome, Biocatalysis, Cell Line, Holoenzymes chemistry, Holoenzymes metabolism, Holoenzymes ultrastructure, Mass Spectrometry, Microscopy, Electron, Models, Molecular, Molecular Weight, Protein Binding, Protein Conformation, Protein Subunits chemistry, Protein Subunits isolation & purification, Protein Subunits metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Recombinant Proteins ultrastructure, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins isolation & purification, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins ultrastructure, Scattering, Radiation, Schizosaccharomyces chemistry, Structure-Activity Relationship, Substrate Specificity, Ubiquitin-Protein Ligase Complexes ultrastructure, Ubiquitination, Ubiquitin-Protein Ligase Complexes chemistry, Ubiquitin-Protein Ligase Complexes metabolism

Abstract

The anaphase-promoting complex or cyclosome (APC/C) is an unusually large E3 ubiquitin ligase responsible for regulating defined cell cycle transitions. Information on how its 13 constituent proteins are assembled, and how they interact with co-activators, substrates and regulatory proteins is limited. Here, we describe a recombinant expression system that allows the reconstitution of holo APC/C and its sub-complexes that, when combined with electron microscopy, mass spectrometry and docking of crystallographic and homology-derived coordinates, provides a precise definition of the organization and structure of all essential APC/C subunits, resulting in a pseudo-atomic model for 70% of the APC/C. A lattice-like appearance of the APC/C is generated by multiple repeat motifs of most APC/C subunits. Three conserved tetratricopeptide repeat (TPR) subunits (Cdc16, Cdc23 and Cdc27) share related superhelical homo-dimeric architectures that assemble to generate a quasi-symmetrical structure. Our structure explains how this TPR sub-complex, together with additional scaffolding subunits (Apc1, Apc4 and Apc5), coordinate the juxtaposition of the catalytic and substrate recognition module (Apc2, Apc11 and Apc10 (also known as Doc1)), and TPR-phosphorylation sites, relative to co-activator, regulatory proteins and substrates.

Published

2011

14. Structural insights into mRNA recognition from a PIWI domain-siRNA guide complex.

Author

Parker JS, Roe SM, and Barford D

Subjects

Base Sequence, Models, Molecular, Nucleic Acid Conformation, Protein Structure, Tertiary, RNA Interference, RNA, Messenger chemistry, RNA, Messenger genetics, RNA, Small Interfering genetics, Substrate Specificity, RNA, Small Untranslated, Archaeal Proteins chemistry, Archaeal Proteins metabolism, Archaeoglobus fulgidus chemistry, RNA, Messenger metabolism, RNA, Small Interfering chemistry, RNA, Small Interfering metabolism

Abstract

RNA interference and related RNA silencing phenomena use short antisense guide RNA molecules to repress the expression of target genes. Argonaute proteins, containing amino-terminal PAZ (for PIWI/Argonaute/Zwille) domains and carboxy-terminal PIWI domains, are core components of these mechanisms. Here we show the crystal structure of a Piwi protein from Archaeoglobus fulgidus (AfPiwi) in complex with a small interfering RNA (siRNA)-like duplex, which mimics the 5' end of a guide RNA strand bound to an overhanging target messenger RNA. The structure contains a highly conserved metal-binding site that anchors the 5' nucleotide of the guide RNA. The first base pair of the duplex is unwound, separating the 5' nucleotide of the guide from the complementary nucleotide on the target strand, which exits with the 3' overhang through a short channel. The remaining base-paired nucleotides assume an A-form helix, accommodated within a channel in the PIWI domain, which can be extended to place the scissile phosphate of the target strand adjacent to the putative slicer catalytic site. This study provides insights into mechanisms of target mRNA recognition and cleavage by an Argonaute-siRNA guide complex.

Published

2005

15. Redox regulation of protein tyrosine phosphatase 1B involves a sulphenyl-amide intermediate.

Author

Salmeen A, Andersen JN, Myers MP, Meng TC, Hinks JA, Tonks NK, and Barford D

Subjects

Amides chemistry, Amino Acid Substitution, Binding Sites, Cysteine metabolism, Epidermal Growth Factor pharmacology, Insulin pharmacology, Models, Molecular, Oxidation-Reduction drug effects, Phosphorylation, Protein Binding, Protein Conformation, Protein Tyrosine Phosphatase, Non-Receptor Type 1, Protein Tyrosine Phosphatases genetics, Receptor, Insulin chemistry, Receptor, Insulin metabolism, Serine metabolism, Sulfenic Acids chemistry, Amides metabolism, Protein Tyrosine Phosphatases chemistry, Protein Tyrosine Phosphatases metabolism, Sulfenic Acids metabolism

Abstract

The second messenger hydrogen peroxide is required for optimal activation of numerous signal transduction pathways, particularly those mediated by protein tyrosine kinases. One mechanism by which hydrogen peroxide regulates cellular processes is the transient inhibition of protein tyrosine phosphatases through the reversible oxidization of their catalytic cysteine, which suppresses protein dephosphorylation. Here we describe a structural analysis of the redox-dependent regulation of protein tyrosine phosphatase 1B (PTP1B), which is reversibly inhibited by oxidation after cells are stimulated with insulin and epidermal growth factor. The sulphenic acid intermediate produced in response to PTP1B oxidation is rapidly converted into a previously unknown sulphenyl-amide species, in which the sulphur atom of the catalytic cysteine is covalently linked to the main chain nitrogen of an adjacent residue. Oxidation of PTP1B to the sulphenyl-amide form is accompanied by large conformational changes in the catalytic site that inhibit substrate binding. We propose that this unusual protein modification both protects the active-site cysteine residue of PTP1B from irreversible oxidation to sulphonic acid and permits redox regulation of the enzyme by promoting its reversible reduction by thiols.

Published

2003