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1. Zinc-binding to the cytoplasmic PAS domain regulates the essential WalK histidine kinase of Staphylococcus aureus

Author

Ian R. Monk, Nausad Shaikh, Stephanie L. Begg, Mike Gajdiss, Liam K. R. Sharkey, Jean Y. H. Lee, Sacha J. Pidot, Torsten Seemann, Michael Kuiper, Brit Winnen, Rikki Hvorup, Brett M. Collins, Gabriele Bierbaum, Saumya R. Udagedara, Jacqueline R. Morey, Neha Pulyani, Benjamin P. Howden, Megan J. Maher, Christopher A. McDevitt, Glenn F. King, and Timothy P. Stinear

Subjects
Science
Abstract

WalKR is an essential two-component regulator that controls peptidoglycan synthesis in the human pathogen Staphylococcus aureus. Here, the authors provide biochemical, structural, and functional evidence supporting that the binding of a zinc ion inhibits autophosphorylation and thus alters WalKR regulatory activity.

Published
2019
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2. The structure of the complex between the arsenite oxidase from Pseudorhizobium banfieldiae sp. strain NT-26 and its native electron acceptor cytochrome c 552

Author

Nilakhi Poddar, Joanne M. Santini, and Megan J. Maher

Subjects
Structural Biology
Abstract

The arsenite oxidase (AioAB) from Pseudorhizobium banfieldiae sp. strain NT-26 catalyzes the oxidation of arsenite to arsenate and transfers electrons to its cognate electron acceptor cytochrome c 552 (cytc 552). This activity underpins the ability of this organism to respire using arsenite present in contaminated environments. The crystal structure of the AioAB/cytc 552 electron transfer complex reveals two A2B2/(cytc 552)2 assemblies per asymmetric unit. Three of the four cytc 552 molecules in the asymmetric unit dock to AioAB in a cleft at the interface between the AioA and AioB subunits, with an edge-to-edge distance of 7.5 Å between the heme of cytc 552 and the [2Fe–2S] Rieske cluster in the AioB subunit. The interface between the AioAB and cytc 552 proteins features electrostatic and nonpolar interactions and is stabilized by two salt bridges. A modest number of hydrogen bonds, salt bridges and relatively small, buried surface areas between protein partners are typical features of transient electron transfer complexes. Interestingly, the fourth cytc 552 molecule is positioned differently between two AioAB heterodimers, with distances between its heme and the AioAB redox active cofactors that are outside the acceptable range for fast electron transfer. This unique cytc 552 molecule appears to be positioned to facilitate crystal packing rather than reflecting a functional complex.

Published
2023
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3. Structural and Functional Investigation of the Periplasmic Arsenate-Binding Protein ArrX from Chrysiogenes arsenatis

Author

Nilakhi Poddar, Shadi Maghool, Consuelo Badilla, Megan J. Maher, Thomas H. Osborne, and Joanne M. Santini

Subjects
0303 health sciences, biology, Stereochemistry, 030302 biochemistry & molecular biology, Chrysiogenes arsenatis, Arsenate, Periplasmic space, biology.organism_classification, Ligand (biochemistry), Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Arsenate reductase, chemistry, Periplasmic Binding Proteins, Binding site, Arsenite
Abstract

The anaerobic bacterium Chrysiogenes arsenatis respires using the oxyanion arsenate (AsO43-) as the terminal electron acceptor, where it is reduced to arsenite (AsO33-) while concomitantly oxidizing various organic (e.g., acetate) electron donors. This respiratory activity is catalyzed in the periplasm of the bacterium by the enzyme arsenate reductase (Arr), with expression of the enzyme controlled by a sensor histidine kinase (ArrS) and a periplasmic-binding protein (PBP), ArrX. Here, we report for the first time, the molecular structure of ArrX in the absence and presence of bound ligand arsenate. Comparison of the ligand-bound structure of ArrX with other PBPs shows a high level of conservation of critical residues for ligand binding by these proteins; however, this suite of PBPs shows different structural alterations upon ligand binding. For ArrX and its homologue AioX (from Rhizobium sp. str. NT-26), which specifically binds arsenite, the structures of the substrate-binding sites in the vicinity of a conserved and critical cysteine residue contribute to the discrimination of binding for these chemically similar ligands.

Published
2021
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4. Human glutaredoxin-1 can transfer copper to isolated metal binding domains of the P1B-type ATPase, ATP7B

Author

Ann H. Kwan, Megan J. Maher, Sharon La Fontaine, Shadi Maghool, and Blaine R. Roberts

Subjects
0301 basic medicine, Multidisciplinary, 030102 biochemistry & molecular biology, biology, Chemistry, ATPase, lcsh:R, lcsh:Medicine, Plasma protein binding, Metallochaperones, ATOX1, 03 medical and health sciences, 030104 developmental biology, Protein structure, Glutaredoxin, biology.protein, Biophysics, lcsh:Q, Metallochaperone activity, lcsh:Science, Intracellular
Abstract

Intracellular copper (Cu) in eukaryotic organisms is regulated by homeostatic systems, which rely on the activities of soluble metallochaperones that participate in Cu exchange through highly tuned protein-protein interactions. Recently, the human enzyme glutaredoxin-1 (hGrx1) has been shown to possess Cu metallochaperone activity. The aim of this study was to ascertain whether hGrx1 can act in Cu delivery to the metal binding domains (MBDs) of the P1B-type ATPase ATP7B and to determine the thermodynamic factors that underpin this activity. hGrx1 can transfer Cu to the metallochaperone Atox1 and to the MBDs 5-6 of ATP7B (WLN5-6). This exchange is irreversible. In a mixture of the three proteins, Cu is delivered to the WLN5-6 preferentially, despite the presence of Atox1. This preferential Cu exchange appears to be driven by both the thermodynamics of the interactions between the proteins pairs and of the proteins with Cu(I). Crucially, protein-protein interactions between hGrx1, Atox1 and WLN5-6 were detected by NMR spectroscopy both in the presence and absence of Cu at a common interface. This study augments the possible activities of hGrx1 in intracellular Cu homeostasis and suggests a potential redundancy in this system, where hGrx1 has the potential to act under cellular conditions where the activity of Atox1 in Cu regulation is attenuated.

Published
2020
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5. Dysregulation of Streptococcus pneumoniae zinc homeostasis breaks ampicillin resistance in a pneumonia infection model

Author

Erin B. Brazel, Aimee Tan, Stephanie L. Neville, Amy R. Iverson, Saumya R. Udagedara, Bliss A. Cunningham, Mwilye Sikanyika, David M.P. De Oliveira, Bernhard Keller, Lisa Bohlmann, Ibrahim M. El-Deeb, Katherine Ganio, Bart A. Eijkelkamp, Alastair G. McEwan, Mark von Itzstein, Megan J. Maher, Mark J. Walker, Jason W. Rosch, and Christopher A. McDevitt

Subjects
Mice, Inbred BALB C, Clioquinol, Microbial Sensitivity Tests, Pneumonia, General Biochemistry, Genetics and Molecular Biology, Anti-Bacterial Agents, Disease Models, Animal, Mice, Zinc, Streptococcus pneumoniae, Animals, Homeostasis, Ampicillin, Female, Ampicillin Resistance, Uncategorized
Abstract

Streptococcus pneumoniae is the primary cause of community-acquired bacterial pneumonia with rates of penicillin and multidrug-resistance exceeding 80% and 40%, respectively. The innate immune response generates a variety of antimicrobial agents to control infection, including zinc stress. Here, we characterize the impact of zinc intoxication on S. pneumoniae, observing disruptions in central carbon metabolism, lipid biogenesis, and peptidoglycan biosynthesis. Characterization of the pivotal peptidoglycan biosynthetic enzyme GlmU indicates a sensitivity to zinc inhibition. Disruption of the sole zinc efflux pathway, czcD, renders S. pneumoniae highly susceptible to β-lactam antibiotics. To dysregulate zinc homeostasis in the wild-type strain, we investigated the safe-for-human-use ionophore 5,7-dichloro-2-[(dimethylamino)methyl]quinolin-8-ol (PBT2). PBT2 rendered wild-type S. pneumoniae strains sensitive to a range of antibiotics. Using an invasive ampicillin-resistant strain, we demonstrate in a murine pneumonia infection model the efficacy of PBT2 + ampicillin treatment. These findings present a therapeutic modality to break antibiotic resistance in multidrug-resistant S. pneumoniae.

Published
2022
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6. Structural basis of interprotein electron transfer in bacterial sulfite oxidation

Author

Aaron P McGrath, Elise L Laming, G Patricia Casas Garcia, Marc Kvansakul, J Mitchell Guss, Jill Trewhella, Benoit Calmes, Paul V Bernhardt, Graeme R Hanson, Ulrike Kappler, and Megan J Maher

Subjects
sinorhizobium meliloti, electron transfer, structural biology, molybdenum, sulfite oxidase, Medicine, Science, Biology (General), QH301-705.5
Abstract

Interprotein electron transfer underpins the essential processes of life and relies on the formation of specific, yet transient protein-protein interactions. In biological systems, the detoxification of sulfite is catalyzed by the sulfite-oxidizing enzymes (SOEs), which interact with an electron acceptor for catalytic turnover. Here, we report the structural and functional analyses of the SOE SorT from Sinorhizobium meliloti and its cognate electron acceptor SorU. Kinetic and thermodynamic analyses of the SorT/SorU interaction show the complex is dynamic in solution, and that the proteins interact with Kd = 13.5 ± 0.8 μM. The crystal structures of the oxidized SorT and SorU, both in isolation and in complex, reveal the interface to be remarkably electrostatic, with an unusually large number of direct hydrogen bonding interactions. The assembly of the complex is accompanied by an adjustment in the structure of SorU, and conformational sampling provides a mechanism for dissociation of the SorT/SorU assembly.

Published
2015
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7. The structural basis of bacterial manganese import

Author

Katherine Ganio, Andrew J. Hayes, Norimichi Nomura, Christopher A. McDevitt, Alex Carey Hulyer, Stephen J. Fairweather, Megan J. Maher, Tess R. Malcolm, Jacinta A. Watts, Aaron P. McGrath, Megan L. O'Mara, So Iwata, Jennie Sjöhamn, Stephanie L. Neville, Mark R. Davies, and Hugo MacDermott-Opeskin

Subjects
chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, 010304 chemical physics, Permease, Mutagenesis, Biophysics, chemistry.chemical_element, SciAdv r-articles, Transporter, ATP-binding cassette transporter, Manganese, 01 natural sciences, Transmembrane protein, Divalent, 03 medical and health sciences, chemistry, Structural Biology, 0103 physical sciences, Extracellular, Research Articles, 030304 developmental biology, Research Article
Abstract

Bacterial manganese import is achieved by unique architectural features that are conserved across the kingdoms of life., Metal ions are essential for all forms of life. In prokaryotes, ATP-binding cassette (ABC) permeases serve as the primary import pathway for many micronutrients including the first-row transition metal manganese. However, the structural features of ionic metal transporting ABC permeases have remained undefined. Here, we present the crystal structure of the manganese transporter PsaBC from Streptococcus pneumoniae in an open-inward conformation. The type II transporter has a tightly closed transmembrane channel due to “extracellular gating” residues that prevent water permeation or ion reflux. Below these residues, the channel contains a hitherto unreported metal coordination site, which is essential for manganese translocation. Mutagenesis of the extracellular gate perturbs manganese uptake, while coordination site mutagenesis abolishes import. These structural features are highly conserved in metal-specific ABC transporters and are represented throughout the kingdoms of life. Collectively, our results define the structure of PsaBC and reveal the features required for divalent cation transport.

Published
2021

8. Mitochondrial COA7 is a heme-binding protein involved in the early stages of complex IV assembly

Author

Luke E. Formosa, Boris Reljic, Alice J. Sharpe, Megan J. Maher, Linden Muellner-Wong, David A. Stroud, Shadi Maghool, and Michael T. Ryan

Subjects
chemistry.chemical_compound, Protein structure, Biochemistry, biology, chemistry, Heme binding, Mitochondrial intermembrane space, biology.protein, Cytochrome c oxidase, Heme, Histidine, Cofactor, Biogenesis
Abstract

Cytochrome c oxidase assembly factor 7 (COA7) is a metazoan-specific assembly factor, critical for the biogenesis of mitochondrial complex IV (cytochrome c oxidase). Although mutations in COA7 have been linked in patients to complex IV assembly defects and neurological conditions such as peripheral neuropathy, ataxia and leukoencephalopathy, the precise role COA7 plays in the biogenesis of complex IV is not known. Here we show that the absence of COA7 leads to arrest of the complex IV assembly pathway at the initial step where the COX1 module is built, which requires incorporation of copper and heme cofactors. In solution, purified COA7 binds heme with micromolar affinity, through axial ligation to the central iron atom by histidine and methionine residues. Surprisingly, the crystal structure of COA7, determined to 2.4 Å resolution, reveals a ‘banana-shaped’ molecule composed of five helix-turn-helix (α/α) repeats, tethered by disulfide bonds, with a structure entirely distinct from proteins with characterized heme binding activities. We therefore propose a role for COA7 in heme binding/chaperoning in the mitochondrial intermembrane space, this activity being crucial for and providing a missing link in complex IV biogenesis.Significance StatementAssembly factors play key roles in the biogenesis of many mitochondrial protein complexes regulating their stability, activity and incorporation of essential cofactors. COA7 is a metazoan-specific assembly factor, the absence or mutation of which in humans accompanies complex IV assembly defects and neurological conditions. Here we report the crystal structure of COA7 to 2.4 Å resolution, revealing a ‘banana-shaped’ molecule composed of five helix-turn-helix (α/α) repeats, tethered by disulfide bonds. Characterization of pathogenic variants reveals significantly lower stabilities, correlating with the associated disease outcomes. Fascinatingly, COA7 binds heme with micromolar affinity, despite the fact that the protein structure does not resemble previously characterized heme-binding proteins. This provides a possible missing link for heme handling in the mitochondrial intermembrane space.

Published
2021
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9. What Role Does COA6 Play in Cytochrome C Oxidase Biogenesis: A Metallochaperone or Thiol Oxidoreductase, or Both?

Author

Megan J. Maher, Michael T. Ryan, and Shadi Maghool

Subjects
0301 basic medicine, Amino Acid Motifs, Review, Mitochondrion, Catalysis, cytochrome c oxidase, Inorganic Chemistry, Electron Transport Complex IV, Mitochondrial Proteins, lcsh:Chemistry, 03 medical and health sciences, Copper binding, Oxidoreductase, Metalloproteins, Cytochrome c oxidase, Animals, Humans, structure, Physical and Theoretical Chemistry, Molecular Biology, lcsh:QH301-705.5, Spectroscopy, chemistry.chemical_classification, Cytochrome c oxidase biogenesis, 030102 biochemistry & molecular biology, biology, Organic Chemistry, General Medicine, Electron transport chain, assembly factor, Computer Science Applications, Cell biology, mitochondria, 030104 developmental biology, chemistry, lcsh:Biology (General), lcsh:QD1-999, copper, Thiol, biology.protein, COA6, Carrier Proteins, Biogenesis, Molecular Chaperones
Abstract

Complex IV (cytochrome c oxidase; COX) is the terminal complex of the mitochondrial electron transport chain. Copper is essential for COX assembly, activity, and stability, and is incorporated into the dinuclear CuA and mononuclear CuB sites. Multiple assembly factors play roles in the biogenesis of these sites within COX and the failure of this intricate process, such as through mutations to these factors, disrupts COX assembly and activity. Various studies over the last ten years have revealed that the assembly factor COA6, a small intermembrane space-located protein with a twin CX9C motif, plays a role in the biogenesis of the CuA site. However, how COA6 and its copper binding properties contribute to the assembly of this site has been a controversial area of research. In this review, we summarize our current understanding of the molecular mechanisms by which COA6 participates in COX biogenesis.

Published
2020

10. Crystal structure of bacterial succinate:quinone oxidoreductase flavoprotein SdhA in complex with its assembly factor SdhE

Author

Megan J. Maher, David A. Dougan, Anuradha S. Herath, Kaye N. Truscott, and Saumya R. Udagedara

Subjects
Models, Molecular, 0301 basic medicine, Protein Conformation, Respiratory chain, SDHA, Flavoprotein, Dehydrogenase, Crystallography, X-Ray, Quinone oxidoreductase, 03 medical and health sciences, Bacterial Proteins, Protein Domains, Escherichia coli, Multidisciplinary, Flavoproteins, biology, Chemistry, Electron Transport Complex II, Escherichia coli Proteins, Succinate dehydrogenase, Biological Sciences, Fumarate reductase, Strobilurins, 030104 developmental biology, Biochemistry, biology.protein, Crystallization, Protein Binding
Abstract

Succinate:quinone oxidoreductase (SQR) functions in energy metabolism, coupling the tricarboxylic acid cycle and electron transport chain in bacteria and mitochondria. The biogenesis of flavinylated SdhA, the catalytic subunit of SQR, is assisted by a highly conserved assembly factor termed SdhE in bacteria via an unknown mechanism. By using X-ray crystallography, we have solved the structure of Escherichia coli SdhE in complex with SdhA to 2.15-A resolution. Our structure shows that SdhE makes a direct interaction with the flavin adenine dinucleotide-linked residue His45 in SdhA and maintains the capping domain of SdhA in an “open” conformation. This displaces the catalytic residues of the succinate dehydrogenase active site by as much as 9.0 A compared with SdhA in the assembled SQR complex. These data suggest that bacterial SdhE proteins, and their mitochondrial homologs, are assembly chaperones that constrain the conformation of SdhA to facilitate efficient flavinylation while regulating succinate dehydrogenase activity for productive biogenesis of SQR.

Published
2018
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11. The initiation of GTP hydrolysis by the G-domain of FeoB: insights from a transition-state complex structure.

Author

Miriam-Rose Ash, Megan J Maher, J Mitchell Guss, and Mika Jormakka

Subjects
Medicine, Science
Abstract

The polytopic membrane protein FeoB is a ferrous iron transporter in prokaryotes. The protein contains a potassium-activated GTPase domain that is essential in regulating the import of iron and conferring virulence to many disease-causing bacteria. However, the mechanism by which the G-domain of FeoB hydrolyzes GTP is not well understood. In particular, it is not yet known how the pivotal step in GTP hydrolysis is achieved: alignment of a catalytic water molecule. In the current study, the crystal structure of the soluble domains from Streptococcus thermophilus FeoB (NFeoB(St)) in complex with the activating potassium ion and a transition-state analogue, GDP⋅AlF(4) (-), reveals a novel mode of water alignment involving contacts with the protein backbone only. In parallel to the structural studies, a series of seven mutant proteins were constructed that targeted conserved residues at the active site of NFeoB(St), and the nucleotide binding and hydrolysis properties of these were measured and compared to the wild-type protein. The results show that mutations in Thr35 abolish GTPase activity of the protein, while other conserved residues (Tyr58, Ser64, Glu66 and Glu67) are not required for water alignment by NFeoB(St). Together with the crystal structure, the findings suggest a new mechanism for hydrolysis initiation in small G-proteins, in which the attacking water molecule is aligned by contacts with the protein backbone only.

Published
2011
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12. The central active site arginine in sulfite oxidizing enzymes alters kinetic properties by controlling electron transfer and redox interactions

Author

Mihwa Lee, Farzana Darain, Ulrike Kappler, Megan J. Maher, Jeffrey Harmer, Paul V. Bernhardt, Aaron P. McGrath, Palraj Kalimuthu, Linda Kielmann, Ju-Chun Hsiao, and Kimberley Meyers

Subjects
0301 basic medicine, Half-reaction, Arginine, Cytochrome, Stereochemistry, Sulfite Dehydrogenase, Mutation, Missense, Biophysics, 010402 general chemistry, 01 natural sciences, Biochemistry, Electron Transport, 03 medical and health sciences, Bacterial Proteins, Oxidoreductase, Catalytic Domain, Sulfite dehydrogenase, Sulfite oxidase deficiency, Molybdenum, chemistry.chemical_classification, biology, Chemistry, Active site, Cell Biology, 0104 chemical sciences, Kinetics, 030104 developmental biology, Amino Acid Substitution, Catalytic cycle, biology.protein, Oxidation-Reduction, Sinorhizobium meliloti
Abstract

A central conserved arginine, first identified as a clinical mutation leading to sulfite oxidase deficiency, is essential for catalytic competency of sulfite oxidizing molybdoenzymes, but the molecular basis for its effects on turnover and substrate affinity have not been fully elucidated. We have used a bacterial sulfite dehydrogenase, SorT, which lacks an internal heme group, but transfers electrons to an external, electron accepting cytochrome, SorU, to investigate the molecular functions of this arginine residue (Arg78). Assay of the SorT Mo centre catalytic competency in the absence of SorU showed that substitutions in the central arginine (R78Q, R78K and R78M mutations) only moderately altered SorT catalytic properties, except for R78M which caused significant reduction in SorT activity. The substitutions also altered the Mo-centre redox potentials (MoVI/V potential lowered by ca. 60-80mV). However, all Arg78 mutations significantly impaired the ability of SorT to transfer electrons to SorU, where activities were reduced 17 to 46-fold compared to SorTWT, precluding determination of kinetic parameters. This was accompanied by the observation of conformational changes in both the introduced Gln and Lys residues in the crystal structure of the enzymes. Taking into account data collected by others on related SOE mutations we propose that the formation and maintenance of an electron transfer complex between the Mo centre and electron accepting heme groups is the main function of the central arginine, and that the reduced turnover and increases in KMsulfite are caused by the inefficient operation of the oxidative half reaction of the catalytic cycle in enzymes carrying these mutations.

Published
2018
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14. Integrated activities of two alternative sigma factors coordinate iron acquisition and uptake byPseudomonas aeruginosa

Author

Megan J. Maher, Iain L. Lamont, Matthew A. Perugini, G Patricia Casas Garcia, Georgina E Hampton, Rebecca J. Edgar, and David F. Ackerley

Subjects
0301 basic medicine, Regulation of gene expression, Siderophore, Pyoverdine, Repressor, Plasma protein binding, Biology, Microbiology, Hedgehog signaling pathway, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Sigma factor, Molecular Biology, Gene
Abstract

Alternative sigma (σ) factors govern expression of bacterial genes in response to diverse environmental signals. In Pseudomonas aeruginosa σPvdS directs expression of genes for production of a siderophore, pyoverdine, as well as a toxin and a protease. σFpvI directs expression of a receptor for ferripyoverdine import. Expression of the genes encoding σPvdS and σFpvI is iron-regulated and an antisigma protein, FpvR20 , post-translationally controls the activities of the sigma factors in response to the amount of ferripyoverdine present. Here we show that iron represses synthesis of σPvdS to a far greater extent than σFpvI . In contrast ferripyoverdine exerts similar effects on the activities of both sigma factors. Using a combination of in vivo and in vitro assays we show that σFpvI and σPvdS have comparable affinities for, and are equally inhibited by, FpvR20 . Importantly, in the absence of ferripyoverdine the amount of FpvR20 per cell is lower than the amount of σFpvI and σPvdS , allowing basal expression of target genes that is required to activate the signalling pathway when ferripyoverdine is present. This complex interplay of transcriptional and post-translational regulation enables a co-ordinated response to ferripyoverdine but distinct responses to iron.

Published
2017
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15. Human glutaredoxin-1 can transfer copper to isolated metal binding domains of the P

Author

Shadi, Maghool, Sharon La, Fontaine, Blaine R, Roberts, Ann H, Kwan, and Megan J, Maher

Subjects
Magnetic Resonance Spectroscopy, Copper Transport Proteins, Biophysical chemistry, Humans, Protein Structure, Quaternary, Copper, Glutaredoxins, Article, Molecular Chaperones, Protein Binding, Ion transport
Abstract

Intracellular copper (Cu) in eukaryotic organisms is regulated by homeostatic systems, which rely on the activities of soluble metallochaperones that participate in Cu exchange through highly tuned protein-protein interactions. Recently, the human enzyme glutaredoxin-1 (hGrx1) has been shown to possess Cu metallochaperone activity. The aim of this study was to ascertain whether hGrx1 can act in Cu delivery to the metal binding domains (MBDs) of the P1B-type ATPase ATP7B and to determine the thermodynamic factors that underpin this activity. hGrx1 can transfer Cu to the metallochaperone Atox1 and to the MBDs 5-6 of ATP7B (WLN5-6). This exchange is irreversible. In a mixture of the three proteins, Cu is delivered to the WLN5-6 preferentially, despite the presence of Atox1. This preferential Cu exchange appears to be driven by both the thermodynamics of the interactions between the proteins pairs and of the proteins with Cu(I). Crucially, protein-protein interactions between hGrx1, Atox1 and WLN5-6 were detected by NMR spectroscopy both in the presence and absence of Cu at a common interface. This study augments the possible activities of hGrx1 in intracellular Cu homeostasis and suggests a potential redundancy in this system, where hGrx1 has the potential to act under cellular conditions where the activity of Atox1 in Cu regulation is attenuated.

Published
2019

16. Integrated activities of two alternative sigma factors coordinate iron acquisition and uptake by Pseudomonas aeruginosa

Author

Rebecca J, Edgar, Georgina E, Hampton, G Patricia Casas, Garcia, Megan J, Maher, Matthew A, Perugini, David F, Ackerley, and Iain L, Lamont

Subjects
Repressor Proteins, Bacterial Proteins, Iron, Pseudomonas aeruginosa, Siderophores, Sigma Factor, Gene Expression Regulation, Bacterial, Regulatory Elements, Transcriptional, Iron Chelating Agents, Oligopeptides, Bacterial Outer Membrane Proteins, Protein Binding
Abstract

Alternative sigma (σ) factors govern expression of bacterial genes in response to diverse environmental signals. In Pseudomonas aeruginosa σ

Published
2017

17. Structural and functional characterization of the mitochondrial complex IV assembly factor Coa6

Author

David A. Stroud, N Dinesha G Cooray, Megan J. Maher, Michael T. Ryan, David Aragão, and Shadi Maghool

Subjects
Models, Molecular, Health, Toxicology and Mutagenesis, Plant Science, Plasma protein binding, Crystallography, X-Ray, Biochemistry, Genetics and Molecular Biology (miscellaneous), Protein Structure, Secondary, Mitochondrial Proteins, 03 medical and health sciences, Protein structure, COX17, Loss of Function Mutation, Oxidoreductase, Humans, Cytochrome c oxidase, Binding site, Protein secondary structure, Research Articles, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Binding Sites, Ecology, biology, 030305 genetics & heredity, Cell biology, HEK293 Cells, chemistry, biology.protein, Carrier Proteins, Copper, Biogenesis, Research Article, Protein Binding
Abstract

The structures of the mitochondrial complex IV assembly factor Coa6 and a pathogenic mutant variant (W59CCoa6) are reported, providing molecular mechanisms for its mode of action and the loss-of-function mutation., Assembly factors play key roles in the biogenesis of many multi-subunit protein complexes regulating their stability, activity, and the incorporation of essential cofactors. The human assembly factor Coa6 participates in the biogenesis of the CuA site in complex IV (cytochrome c oxidase, COX). Patients with mutations in Coa6 suffer from mitochondrial disease due to complex IV deficiency. Here, we present the crystal structures of human Coa6 and the pathogenic W59CCoa6-mutant protein. These structures show that Coa6 has a 3-helical bundle structure, with the first 2 helices tethered by disulfide bonds, one of which likely provides the copper-binding site. Disulfide-mediated oligomerization of the W59CCoa6 protein provides a structural explanation for the loss-of-function mutation.

Published
2019
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18. Structure of an atypical FeoB G-domain reveals a putative domain-swapped dimer

Author

Megan J. Maher, Amy P. Guilfoyle, Josep Font, Mika Jormakka, Aaron P. McGrath, and Chandrika N. Deshpande

Subjects
Models, Molecular, Molecular Sequence Data, Biophysics, GTPase, Biology, Crystallography, X-Ray, 060112 - Structural Biology (incl. Macromolecular Modelling) [FoR], Biochemistry, GTP Phosphohydrolases, Domain (software engineering), Protein structure, Structural Biology, Genetics, Structural Communications, Amino Acid Sequence, Protein Structure, Quaternary, Peptide sequence, Gallionellaceae, Membrane Proteins, Condensed Matter Physics, Transmembrane protein, Protein Structure, Tertiary, Transmembrane domain, Crystallography, Structural Homology, Protein, Cyclic nucleotide-binding domain, G-domain, Protein Multimerization, Sequence Alignment
Abstract

FeoB is a transmembrane protein involved in ferrous iron uptake in prokaryotic organisms. FeoB comprises a cytoplasmic soluble domain termed NFeoB and a C-terminal polytopic transmembrane domain. Recent structures of NFeoB have revealed two structural subdomains: a canonical GTPase domain and a five-helix helical domain. The GTPase domain hydrolyses GTP to GDP through a well characterized mechanism, a process which is required for Fe2+transport. In contrast, the precise role of the helical domain has not yet been fully determined. Here, the structure of the cytoplasmic domain of FeoB fromGallionella capsiferriformansis reported. Unlike recent structures of NFeoB, theG. capsiferriformansNFeoB structure is highly unusual in that it does not contain a helical domain. The crystal structures of both apo and GDP-bound protein forms a domain-swapped dimer.

Published
2013
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19. The cation-dependent G-proteins: In a class of their own

Author

Miriam-Rose Ash, Megan J. Maher, Mika Jormakka, and J. Mitchell Guss

Subjects
Dynamins, Protein Conformation, G protein, Molecular Sequence Data, Molecular Conformation, Biophysics, GTPase, GTPase activation, Biology, Models, Biological, Biochemistry, Ribosome, GTP Phosphohydrolases, Ribosome assembly, 03 medical and health sciences, GTP-binding protein regulators, Protein structure, GTP-Binding Proteins, Structural Biology, Cations, Genetics, Humans, Amino Acid Sequence, Molecular Biology, Peptide sequence, 030304 developmental biology, Dynamin, 0303 health sciences, Binding Sites, Sequence Homology, Amino Acid, Hydrolysis, 030302 biochemistry & molecular biology, Potassium stimulation, Cell Biology, Dynamin-like GTPase, 3. Good health, Cell biology, Ribosome-assembly GTPase, Cation-dependent GTPase, Potassium, G-protein classification, Ribosomes
Abstract

G-proteins are some of the most important and abundant enzymes, yet their intrinsic nucleotide hydrolysis reaction is notoriously slow and must be accelerated in vivo. Recent experiments on dynamin and GTPases involved in ribosome assembly have demonstrated that their hydrolysis activities are stimulated by potassium ions. This article presents the hypothesis that cation-mediated activation of G-proteins is more common than currently realised, and that such GTPases represent a structurally and functionally unique class of G-proteins. Based on sequence analysis we provide a list of predicted cation-dependent GTPases, which encompasses almost all members of the TEES, Obg-HflX, YqeH-like and dynamin superfamilies. The results from this analysis effectively re-define the conditions under which many of these G-proteins should be studied in vitro.

Published
2012
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20. The structure of an N11A mutant of the G-protein domain of FeoB

Author

Megan J. Maher, Mika Jormakka, Miriam-Rose Ash, and J. Mitchell Guss

Subjects
Models, Molecular, Streptococcus thermophilus, Binding Sites, biology, Protein domain, Biophysics, GTPase, Crystallography, X-Ray, Condensed Matter Physics, biology.organism_classification, Biochemistry, Protein Structure, Tertiary, Transport protein, A-site, Protein structure, Bacterial Proteins, Structural Biology, Mutation, Genetics, Structural Communications, Asparagine, Binding site, Cation Transport Proteins
Abstract

The uptake of ferrous iron in prokaryotes is mediated by the G-protein-coupled membrane protein FeoB. The protein contains two N-terminal soluble domains that are together called `NFeoB'. One of these is a G-protein domain, and GTP hydrolysis by this domain is essential for iron transport. The GTPase activity of NFeoB is accelerated in the presence of potassium ions, which bind at a site adjacent to the nucleotide. One of the ligands at the potassium-binding site is a conserved asparagine residue, which corresponds to Asn11 in Streptococcus thermophilus NFeoB. The structure of an N11A S. thermophilus NFeoB mutant has been determined and refined to a resolution of 1.85 Å; the crystals contained a mixture of mant-GDP-bound and mant-GMP-bound protein. The structure demonstrates how the use of a derivatized nucleotide in cocrystallization experiments can facilitate the growth of diffraction-quality crystals.

Published
2011
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21. The structural biology of mitochondrial respiratory complex assembly

Author

David A. Dougan, Shadi Maghool, Michael T. Ryan, Megan J. Maher, Kaye N. Truscott, Saumya R. Udagedara, David A. Stroud, and A. Herath

Subjects
Inorganic Chemistry, Structural biology, Structural Biology, General Materials Science, Computational biology, Physical and Theoretical Chemistry, Respiratory system, Biology, Condensed Matter Physics, Biochemistry
Published
2018
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22. Structural basis of interprotein electron transfer in bacterial sulfite oxidation

Author

Elise L Laming, G Patricia Casas Garcia, Aaron P. McGrath, Marc Kvansakul, Megan J. Maher, Benoit Calmes, Ulrike Kappler, Jill Trewhella, Graeme R. Hanson, J. Mitchell Guss, and Paul V. Bernhardt

Subjects
Models, Molecular, Protein Conformation, QH301-705.5, Science, Crystallography, X-Ray, General Biochemistry, Genetics and Molecular Biology, Electron Transport, chemistry.chemical_compound, Electron transfer, Protein structure, molybdenum, sulfite oxidase, Sulfite, Bacterial Proteins, Oxidoreductase, Sulfite oxidase, sinorhizobium meliloti, Sulfites, structural biology, Biology (General), chemistry.chemical_classification, General Immunology and Microbiology, Hydrogen bond, General Neuroscience, General Medicine, Electron acceptor, Biophysics and Structural Biology, electron transfer, Electron transport chain, Crystallography, Kinetics, chemistry, Biochemistry, Thermodynamics, Medicine, Other, Oxidoreductases, Oxidation-Reduction, Protein Binding, Research Article
Abstract

Interprotein electron transfer underpins the essential processes of life and relies on the formation of specific, yet transient protein-protein interactions. In biological systems, the detoxification of sulfite is catalyzed by the sulfite-oxidizing enzymes (SOEs), which interact with an electron acceptor for catalytic turnover. Here, we report the structural and functional analyses of the SOE SorT from Sinorhizobium meliloti and its cognate electron acceptor SorU. Kinetic and thermodynamic analyses of the SorT/SorU interaction show the complex is dynamic in solution, and that the proteins interact with Kd = 13.5 ± 0.8 μM. The crystal structures of the oxidized SorT and SorU, both in isolation and in complex, reveal the interface to be remarkably electrostatic, with an unusually large number of direct hydrogen bonding interactions. The assembly of the complex is accompanied by an adjustment in the structure of SorU, and conformational sampling provides a mechanism for dissociation of the SorT/SorU assembly. DOI: http://dx.doi.org/10.7554/eLife.09066.001, eLife digest A key feature of many important chemical reactions in cells is the transfer of particles called electrons from one molecule to another. The sulfite oxidizing enzymes (or SOEs) are a group of enzymes that are found in many organisms. These enzymes convert sulfite, which is a very reactive compound that can damage cells, into another compound called sulfate. As part of this process the SOE transfers electrons from sulfite to other molecules, such as oxygen or a protein called cytochrome c. In the past, researchers have described the three-dimensional structure of three SOEs using a technique called X-ray crystallography. However, it has been difficult to study how SOEs pass electrons to other molecules because of the temporary nature of the interactions. McGrath et al. studied an SOE called SorT, which is found in bacteria. The SorT enzyme passes electrons from sulfite to another protein called SorU. McGrath used X-ray crystallography to determine the three-dimensional structures of versions of these proteins from a bacterium called Sinorhizobium meliloti. This included structures of the proteins on their own, and when they were bound to each other. These structures revealed that a subtle change in the shape of SorU occurs when the proteins interact, which enables an electron to be quickly transferred. McGrath et al. also found that the interface between the two proteins showed an unexpectedly high number of contact sites. These strengthen the interaction between the two proteins, which helps to make electron transfer more efficient. However, these contact sites do not prevent the two proteins from quickly moving apart after the electrons have been transferred. The next challenge is to find out whether these observations are common to SOEs from other forms of life. DOI: http://dx.doi.org/10.7554/eLife.09066.002

Published
2015

24. COA6 is a mitochondrial complex IV assembly factor critical for biogenesis of mtDNA-encoded COX2

Author

Elliot Surgenor, David A. Stroud, Caroline Lindau, F-Nora Vögtle, Silke Oeljeklaus, Matteo Bonas, Ann E. Frazier, Megan J. Maher, Bettina Warscheid, Hayley S. Mountford, David R. Thorburn, Abeer P. Singh, Chris Meisinger, and Michael T. Ryan

Subjects
Male, Protein subunit, Mitochondrion, Electron Transport Complex IV, Mitochondrial Proteins, 03 medical and health sciences, 0302 clinical medicine, Genetics, Cytochrome c oxidase, Humans, Molecular Biology, Genetics (clinical), 030304 developmental biology, 0303 health sciences, biology, Infant, Membrane Proteins, General Medicine, Fibroblasts, Cell biology, Mitochondrial respiratory chain, HEK293 Cells, Chaperone (protein), biology.protein, Intermembrane space, Cardiomyopathies, Carrier Proteins, 030217 neurology & neurosurgery, Biogenesis, Copper, Molecular Chaperones
Abstract

Biogenesis of complex IV of the mitochondrial respiratory chain requires assembly factors for subunit maturation, co-factor attachment and stabilization of intermediate assemblies. A pathogenic mutation in COA6, leading to substitution of a conserved tryptophan for a cysteine residue, results in a loss of complex IV activity and cardiomyopathy. Here, we demonstrate that the complex IV defect correlates with a severe loss in complex IV assembly in patient heart but not fibroblasts. Complete loss of COA6 activity using gene editing in HEK293T cells resulted in a profound growth defect due to complex IV deficiency, caused by impaired biogenesis of the copper-bound mitochondrial DNA-encoded subunit COX2 and subsequent accumulation of complex IV assembly intermediates. We show that the pathogenic mutation in COA6 does not affect its import into mitochondria but impairs its maturation and stability. Furthermore, we show that COA6 has the capacity to bind copper and can associate with newly translated COX2 and the mitochondrial copper chaperone SCO1. Our data reveal that COA6 is intricately involved in the copper-dependent biogenesis of COX2.

Published
2015

25. Dysregulation of transition metal ion homeostasis is the molecular basis for cadmium toxicity in Streptococcus pneumoniae

Author

Jacqueline R. Morey, Christopher A. McDevitt, Bart A. Eijkelkamp, Megan J. Maher, Megan L. O'Mara, Cheryl-lynn Y. Ong, Stephanie L. Begg, Alastair G. McEwan, Zhenyao Luo, Rafael M. Couñago, Bostjan Kobe, James C. Paton, Begg, Stephanie L, Eijkelkamp, Bart A, Luo, Zhenyao, Counago, Rafael M, Morey, Jacqueline R, Maher, Megan J, Ong, Cheryl-lynn Y, McEwan, Alastair G, Kobe, Bostjan, O'Mara, Megan L, Paton, James C, and McDevitt, Christopher A

Subjects
Models, Molecular, inorganic chemicals, Protein Conformation, Lipoproteins, Immunoblotting, Microbial metabolism, General Physics and Astronomy, chemistry.chemical_element, Manganese, Zinc, medicine.disease_cause, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, medicine, Homeostasis, Magnesium, cadmium toxicity, Adhesins, Bacterial, 030304 developmental biology, Transition metal ion homeostasis, 0303 health sciences, Cadmium, Multidisciplinary, Reverse Transcriptase Polymerase Chain Reaction, 030306 microbiology, cadmium accumulation, General Chemistry, Glutathione, Multidisciplinary Sciences, Oxidative Stress, Streptococcus pneumoniae, chemistry, Biochemistry, 13. Climate action, Toxicity, Crystallization, Oxidative stress
Abstract

Cadmium is a transition metal ion that is highly toxic in biological systems. Although relatively rare in the Earth’s crust, anthropogenic release of cadmium since industrialization has increased biogeochemical cycling and the abundance of the ion in the biosphere. Despite this, the molecular basis of its toxicity remains unclear. Here we combine metal-accumulation assays, high-resolution structural data and biochemical analyses to show that cadmium toxicity, in Streptococcus pneumoniae, occurs via perturbation of first row transition metal ion homeostasis. We show that cadmium uptake reduces the millimolar cellular accumulation of manganese and zinc, and thereby increases sensitivity to oxidative stress. Despite this, high cellular concentrations of cadmium (~17 mM) are tolerated, with negligible impact on growth or sensitivity to oxidative stress, when manganese and glutathione are abundant. Collectively, this work provides insight into the molecular basis of cadmium toxicity in prokaryotes, and the connection between cadmium accumulation and oxidative stress., The molecular basis for the high toxicity of cadmium is unclear. Here, Begg et al. use the bacterium Streptococcus pneumoniae as a model system, and show that cadmium uptake increases sensitivity to oxidative stress by reducing intracellular concentrations of manganese and zinc through different mechanisms.

Published
2015
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26. Tandem LIM domains provide synergistic binding in the LMO4:Ldb1 complex

Author

Jane E. Visvader, Jacqueline M. Matthews, Megan J. Maher, Daniel P. Ryan, Janet E. Deane, Margaret Sunde, and J. Mitchell Guss

Subjects
Magnetic Resonance Spectroscopy, animal structures, Protein Conformation, Recombinant Fusion Proteins, Molecular Sequence Data, Saccharomyces cerevisiae, Plasma protein binding, Biology, Crystallography, X-Ray, DNA-binding protein, Article, General Biochemistry, Genetics and Molecular Biology, Protein–protein interaction, Mice, Protein structure, Two-Hybrid System Techniques, Animals, Amino Acid Sequence, Binding site, Molecular Biology, Transcription factor, Adaptor Proteins, Signal Transducing, LIM domain, Homeodomain Proteins, Genetics, Binding Sites, Sequence Homology, Amino Acid, General Immunology and Microbiology, General Neuroscience, Signal transducing adaptor protein, Drug Synergism, LIM Domain Proteins, Protein Structure, Tertiary, Cell biology, DNA-Binding Proteins, body regions, Tandem Repeat Sequences, Factor Xa, Mutation, embryonic structures, Protein Binding, Transcription Factors
Abstract

Nuclear LIM-only (LMO) and LIM-homeodomain (LIM-HD) proteins have important roles in cell fate determination, organ development and oncogenesis. These proteins contain tandemly arrayed LIM domains that bind the LIM interaction domain (LID) of the nuclear adaptor protein LIM domain-binding protein-1 (Ldb1). We have determined a high-resolution X-ray crystal structure of LMO4, a putative breast oncoprotein, in complex with Ldb1-LID, providing the first example of a tandem LIM:Ldb1-LID complex and the first structure of a type-B LIM domain. The complex possesses a highly modular structure with Ldb1-LID binding in an extended manner across both LIM domains of LMO4. The interface contains extensive hydrophobic and electrostatic interactions and multiple backbone–backbone hydrogen bonds. A mutagenic screen of Ldb1-LID, assessed by yeast two-hybrid and competition ELISA analysis, identified key features at the interface and revealed that the interaction is tolerant to mutation. These combined properties provide a mechanism for the binding of Ldb1 to numerous LMO and LIM-HD proteins. Furthermore, the modular extended interface may form a general mode of binding to tandem LIM domains.

Published
2004
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28. Functional analysis of the zinc efflux protein CzcD

Author

Megan J. Maher, Christopher A. McDevitt, and Daniel M. La Porta

Subjects
Functional analysis, Stereochemistry, chemistry.chemical_element, Zinc, Condensed Matter Physics, Biochemistry, Inorganic Chemistry, chemistry, Membrane protein, Structural Biology, X-ray crystallography, General Materials Science, Efflux, Physical and Theoretical Chemistry
Published
2017
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29. Sigma anti-sigma factors involved in iron homeostasis in Pseudomonas aeruginosa

Author

G. Patricia Casas, Matthew A. Perugini, Ian Lamont, and Megan J. Maher

Subjects
Pseudomonas aeruginosa, Chemistry, Anti-sigma factors, Sigma, Condensed Matter Physics, medicine.disease_cause, Biochemistry, Microbiology, Inorganic Chemistry, Iron homeostasis, Structural Biology, medicine, General Materials Science, Physical and Theoretical Chemistry
Published
2017
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30. Exploring the correlation between the sequence composition of the nucleotide binding G5 loop of the FeoB GTPase domain (NFeoB) and intrinsic rate of GDP release

Author

Megan J. Maher, Amy P. Guilfoyle, Mika Jormakka, Chandrika N. Deshpande, and Gerhard Schenk

Subjects
Models, Molecular, lcsh:Life, lcsh:QR1-502, EcNFeoB, Escherichia coli FeoB, GTPase, Crystallography, X-Ray, Biochemistry, lcsh:Microbiology, GTP Phosphohydrolases, stopped flow, chemistry.chemical_compound, Protein structure, Peptide sequence, Cation Transport Proteins, G alpha subunit, 0303 health sciences, Nucleotides, Escherichia coli Proteins, 030302 biochemistry & molecular biology, Thermodynamics, Sequence motif, GDP release, Protein Binding, crystal structure, Molecular Sequence Data, Biophysics, Biology, Calorimetry, Guanosine Diphosphate, S2, StNFeoB, Streptococcus thermophiles FeoB, TEV, tobacco etch virus, 03 medical and health sciences, Escherichia coli, Amino Acid Sequence, Binding site, Molecular Biology, GPCR, G protein-coupled receptor, 030304 developmental biology, G protein-coupled receptor, Original Paper, Binding Sites, Sequence Homology, Amino Acid, Cell Biology, Protein Structure, Tertiary, Crystallography, lcsh:QH501-531, Kinetics, chemistry, Guanosine diphosphate, Mutation, sequence motif, Nucleic Acid Conformation
Abstract

GDP release from GTPases is usually extremely slow and is in general assisted by external factors, such as association with guanine exchange factors or membrane-embedded GPCRs (G protein-coupled receptors), which accelerate the release of GDP by several orders of magnitude. Intrinsic factors can also play a significant role; a single amino acid substitution in one of the guanine nucleotide recognition motifs, G5, results in a drastically altered GDP release rate, indicating that the sequence composition of this motif plays an important role in spontaneous GDP release. In the present study, we used the GTPase domain from EcNFeoB (Escherichia coli FeoB) as a model and applied biochemical and structural approaches to evaluate the role of all the individual residues in the G5 loop. Our study confirms that several of the residues in the G5 motif have an important role in the intrinsic affinity and release of GDP. In particular, a T151A mutant (third residue of the G5 loop) leads to a reduced nucleotide affinity and provokes a drastically accelerated dissociation of GDP.

Published
2014

31. Structural and functional analysis of a FeoB A143S G5 loop mutant explains the accelerated GDP release rate

Author

Megan J. Maher, Amy P. Guilfoyle, Chandrika N. Deshpande, Kimberley Vincent, Marcelo Monteiro Pedroso, Mika Jormakka, and Gerhard Schenk

Subjects
G protein, Molecular Sequence Data, GTPase, Biology, Biochemistry, Guanosine Diphosphate, Catalysis, Fluorescence, chemistry.chemical_compound, GTP-binding protein regulators, Bacterial Proteins, GTP-Binding Proteins, Heterotrimeric G protein, Serine, Animals, Humans, Streptococcus thermophilus, Amino Acid Sequence, Structural motif, Molecular Biology, Alanine, Sequence Homology, Amino Acid, Hydrolysis, Cell Biology, Membrane protein, chemistry, Guanosine diphosphate, Sequence motif
Abstract

GTPases (G proteins) hydrolyze the conversion of GTP to GDP and free phosphate, comprising an integral part of prokaryotic and eukaryotic signaling, protein biosynthesis and cell division, as well as membrane transport processes. The G protein cycle is brought to a halt after GTP hydrolysis, and requires the release of GDP before a new cycle can be initiated. For eukaryotic heterotrimeric Gαβγ proteins, the interaction with a membrane-bound G protein-coupled receptor catalyzes the release of GDP from the Gα subunit. Structural and functional studies have implicated one of the nucleotide binding sequence motifs, the G5 motif, as playing an integral part in this release mechanism. Indeed, a Gαs G5 mutant (A366S) was shown to have an accelerated GDP release rate, mimicking a G protein-coupled receptor catalyzed release state. In the present study, we investigate the role of the equivalent residue in the G5 motif (residue A143) in the prokaryotic membrane protein FeoB from Streptococcus thermophilus, which includes an N-terminal soluble G protein domain. The structure of this domain has previously been determined in the apo and GDP-bound states and in the presence of a transition state analogue, revealing conformational changes in the G5 motif. The A143 residue was mutated to a serine and analyzed with respect to changes in GTPase activity, nucleotide release rate, GDP affinity and structural alterations. We conclude that the identity of the residue at this position in the G5 loop plays a key role in the nucleotide release rate by allowing the correct positioning and hydrogen bonding of the nucleotide base.

Published
2014

32. The structure of the yeast NADH dehydrogenase (Ndi1) reveals overlapping binding sites for water- and lipid-soluble substrates

Author

Yang Lee, Megan J. Maher, Takao Yagi, So Iwata, Tetsuo Yamashita, Alexander D. Cameron, and Momi Iwata

Subjects
Cytoplasm, Saccharomyces cerevisiae Proteins, Stereochemistry, Static Electricity, Respiratory chain, Molecular Conformation, Electrons, Saccharomyces cerevisiae, Crystallography, X-Ray, Protein structure, Oxidoreductase, Catalytic Domain, Escherichia coli, chemistry.chemical_classification, Multidisciplinary, Binding Sites, Electron Transport Complex I, biology, Peripheral membrane protein, NADH dehydrogenase, Quinones, Water, Biological Sciences, Lipids, Protein Structure, Tertiary, Glycerol-3-phosphate dehydrogenase, chemistry, Biochemistry, Mutation, biology.protein, NAD+ kinase, Protons, Dimerization
Abstract

Bioenergy is efficiently produced in the mitochondria by the respiratory system consisting of complexes I–V. In various organisms, complex I can be replaced by the alternative NADH-quinone oxidoreductase (NDH-2), which catalyzes the transfer of an electron from NADH via FAD to quinone, without proton pumping. The Ndi1 protein from Saccharomyces cerevisiae is a monotopic membrane protein, directed to the matrix. A number of studies have investigated the potential use of Ndi1 as a therapeutic agent against complex I disorders, and the NDH-2 enzymes have emerged as potential therapeutic targets for treatments against the causative agents of malaria and tuberculosis. Here we present the crystal structures of Ndi1 in its substrate-free, NAD + - and ubiquinone- (UQ2) complexed states. The structures reveal that Ndi1 is a peripheral membrane protein forming an intimate dimer, in which packing of the monomeric units within the dimer creates an amphiphilic membrane-anchor domain structure. Crucially, the structures of the Ndi1–NAD + and Ndi1–UQ2 complexes show overlapping binding sites for the NAD + and quinone substrates.

Published
2012

33. The bacterial SoxAX cytochromes

Author

Megan J. Maher and Ulrike Kappler

Subjects
Models, Molecular, Stereochemistry, Protein Conformation, Protein subunit, Molecular Sequence Data, Thiosulfates, Heme, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Protein structure, Bacterial Proteins, Catalytic Domain, Cluster Analysis, Amino Acid Sequence, Molecular Biology, Peptide sequence, Phylogeny, Pharmacology, biology, Bacteria, Chemistry, Binding protein, Electron Spin Resonance Spectroscopy, Active site, Cell Biology, Ligand (biochemistry), Biochemistry, biology.protein, Molecular Medicine, Cytochromes, Dimerization, Oxidation-Reduction, Cysteine, Signal Transduction
Abstract

SoxAX cytochromes are heme-thiolate proteins that play a key role in bacterial thiosulfate oxidation, where they initiate the reaction cycle of a multi-enzyme complex by catalyzing the attachment of sulfur substrates such as thiosulfate to a conserved cysteine present in a carrier protein. SoxAX proteins have a wide phylogenetic distribution and form a family with at least three distinct types of SoxAX protein. The types of SoxAX cytochromes differ in terms of the number of heme groups present in the proteins (there are diheme and triheme versions) as well as in their subunit structure. While two of the SoxAX protein types are heterodimers, the third group contains an additional subunit, SoxK, that stabilizes the complex of the SoxA and SoxX proteins. Crystal structures are available for representatives of the two heterodimeric SoxAX protein types and both of these have shown that the cysteine ligand to the SoxA active site heme carries a modification to a cysteine persulfide that implicates this ligand in catalysis. EPR studies of SoxAX proteins have also revealed a high complexity of heme dependent signals associated with this active site heme; however, the exact mechanism of catalysis is still unclear at present, as is the exact number and types of redox centres involved in the reaction.

Published
2012

34. Insights into structure and function of the active site of SoxAX cytochromes

Author

Megan J. Maher, Christopher J. Noble, Ulrike Kappler, James R. Kilmartin, Kuakarun Krusong, Mark J. Riley, Graeme R. Hanson, and Paul V. Bernhardt

Subjects
Hemeprotein, Stereochemistry, Dimer, Mutation, Missense, Cytochrome c Group, Heme, Crystallography, X-Ray, Biochemistry, Catalysis, Rhodobacter capsulatus, chemistry.chemical_compound, Structure-Activity Relationship, Protein structure, Bacterial Proteins, Catalytic Domain, Escherichia coli, Structure–activity relationship, Protein Structure, Quaternary, Molecular Biology, biology, Chemistry, Cytochrome c, Active site, Cell Biology, Amino Acid Substitution, Gram-Negative Aerobic Rods and Cocci, biology.protein, Enzymology, Protein Multimerization, Oxidoreductases, Cysteine
Abstract

SoxAX cytochromes catalyze the formation of heterodisulfide bonds between inorganic sulfur compounds and a carrier protein, SoxYZ. They contain unusual His/Cys-ligated heme groups with complex spectroscopic signatures. The heme-ligating cysteine has been implicated in SoxAX catalysis, but neither the SoxAX spectroscopic properties nor its catalysis are fully understood at present. We have solved the first crystal structure for a group 2 SoxAX protein (SnSoxAX), where an N-terminal extension of SoxX forms a novel structure that supports dimer formation. Crystal structures of SoxAX with a heme ligand substitution (C236M) uncovered an inherent flexibility of this SoxA heme site, with both bonding distances and relative ligand orientation differing between asymmetric units and the new residue, Met(236), representing an unusual rotamer of methionine. The flexibility of the SnSoxAX(C236M) SoxA heme environment is probably the cause of the four distinct, new EPR signals, including a high spin ferric heme form, that were observed for the enzyme. Despite the removal of the catalytically active cysteine heme ligand and drastic changes in the redox potential of the SoxA heme (WT, -479 mV; C236M, +85 mV), the substituted enzyme was catalytically active in glutathione-based assays although with reduced turnover numbers (WT, 3.7 s(-1); C236M, 2.0 s(-1)). SnSoxAX(C236M) was also active in assays using SoxYZ and thiosulfate as the sulfur substrate, suggesting that Cys(236) aids catalysis but is not crucial for it. The SoxYZ-based SoxAX assay is the first assay for an isolated component of the Sox multienzyme system.

Published
2011

35. Potassium-activated GTPase Reaction in the G Protein-coupled Ferrous Iron Transporter B*

Author

Amy P. Guilfoyle, J. Mitchell Guss, Ronald J. Clarke, Miriam-Rose Ash, Mika Jormakka, and Megan J. Maher

Subjects
Models, Molecular, GTP', G protein, Stereochemistry, Protein Conformation, Iron, GTPase, Crystallography, X-Ray, Biochemistry, Guanosine Diphosphate, GTP Phosphohydrolases, GTP-binding protein regulators, Protein structure, GTP-Binding Proteins, Streptococcus thermophilus, Molecular Biology, Cation Transport Proteins, Chemistry, Cell Biology, Membrane transport, Transport protein, Protein Structure, Tertiary, Protein Structure and Folding, Potassium, Guanosine Triphosphate, Ferrous iron transport
Abstract

FeoB is a prokaryotic membrane protein responsible for the import of ferrous iron (Fe(2+)). A defining feature of FeoB is that it includes an N-terminal 30-kDa soluble domain with GTPase activity, which is required for iron transport. However, the low intrinsic GTP hydrolysis rate of this domain appears to be too slow for FeoB either to function as a channel or to possess an active Fe(2+) membrane transport mechanism. Here, we present crystal structures of the soluble domain of FeoB from Streptococcus thermophilus in complex with GDP and with the GTP analogue derivative 2'-(or -3')-O-(N-methylanthraniloyl)-beta,gamma-imidoguanosine 5'-triphosphate (mant-GMPPNP). Unlike recent structures of the G protein domain, the mant-GMPPNP-bound structure shows clearly resolved, active conformations of the critical Switch motifs. Importantly, biochemical analyses demonstrate that the GTPase activity of FeoB is activated by K(+), which leads to a 20-fold acceleration in its hydrolysis rate. Analysis of the structure identified a conserved asparagine residue likely to be involved in K(+) coordination, and mutation of this residue abolished K(+)-dependent activation. We suggest that this, together with a second asparagine residue that we show is critical for the structure of the Switch I loop, allows the prediction of K(+)-dependent activation in G proteins. In addition, the accelerated hydrolysis rate opens up the possibility that FeoB might indeed function as an active transporter.

Published
2010

36. Crystal structure of A3B3 complex of V-ATPase from Thermus thermophilus

Author

Momi Iwata, Shigeyuki Yokoyama, Yoshiko Hori, Ken Yokoyama, Megan J. Maher, Koji Nagata, Masasuke Yoshida, Satoru Akimoto, and So Iwata

Subjects
Vacuolar Proton-Translocating ATPases, crystal structure, Protein subunit, ATPase, Bacillus, V-ATPase, Crystallography, X-Ray, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Protein structure, Adenosine Triphosphate, Bacterial Proteins, ATP hydrolysis, Catalytic Domain, Hydrolase, Molecular Biology, 030304 developmental biology, 0303 health sciences, General Immunology and Microbiology, biology, ATP synthase, General Neuroscience, Hydrolysis, Thermus thermophilus, 030302 biochemistry & molecular biology, biology.organism_classification, FoF1, Protein Structure, Tertiary, Protein Subunits, Biochemistry, proton pump, biology.protein, Biophysics, Mutagenesis, Site-Directed, rotary motor, Crystallization, Hydrophobic and Hydrophilic Interactions
Abstract

Vacuolar-type ATPases (V-ATPases) exist in various cellular membranes of many organisms to regulate physiological processes by controlling the acidic environment. Here, we have determined the crystal structure of the A(3)B(3) subcomplex of V-ATPase at 2.8 A resolution. The overall construction of the A(3)B(3) subcomplex is significantly different from that of the alpha(3)beta(3) sub-domain in F(o)F(1)-ATP synthase, because of the presence of a protruding 'bulge' domain feature in the catalytic A subunits. The A(3)B(3) subcomplex structure provides the first molecular insight at the catalytic and non-catalytic interfaces, which was not possible in the structures of the separate subunits alone. Specifically, in the non-catalytic interface, the B subunit seems to be incapable of binding ATP, which is a marked difference from the situation indicated by the structure of the F(o)F(1)-ATP synthase. In the catalytic interface, our mutational analysis, on the basis of the A(3)B(3) structure, has highlighted the presence of a cluster composed of key hydrophobic residues, which are essential for ATP hydrolysis by V-ATPases.

Published
2009

37. Structural basis of GDP release and gating in G protein coupled Fe2+ transport

Author

Mikaela Rapp, Ronald J. Clarke, Amy P. Guilfoyle, Mika Jormakka, Megan J. Maher, and Stephen J. Harrop

Subjects
Models, Molecular, Cytoplasm, G protein, Protein Conformation, Protein subunit, Iron, Biology, Guanosine Diphosphate, General Biochemistry, Genetics and Molecular Biology, Article, Protein structure, GTP-binding protein regulators, GTP-Binding Proteins, Molecular Biology, Integral membrane protein, Cation Transport Proteins, Binding Sites, General Immunology and Microbiology, General Neuroscience, Escherichia coli Proteins, Biological Transport, Transport protein, Cell biology, Membrane protein, Ferrous iron transport, Signal Transduction
Abstract

G proteins are key molecular switches in the regulation of membrane protein function and signal transduction. The prokaryotic membrane protein FeoB is involved in G protein coupled Fe(2+) transport, and is unique in that the G protein is directly tethered to the membrane domain. Here, we report the structure of the soluble domain of FeoB, including the G protein domain, and its assembly into an unexpected trimer. Comparisons between nucleotide free and liganded structures reveal the closed and open state of a central cytoplasmic pore, respectively. In addition, these data provide the first observation of a conformational switch in the nucleotide-binding G5 motif, defining the structural basis for GDP release. From these results, structural parallels are drawn to eukaryotic G protein coupled membrane processes.

Published
2009

38. Crystal structure of the acid-induced arginine decarboxylase from Escherichia coli: reversible decamer assembly controls enzyme activity

Author

Tracy Palmer, So Iwata, Juni Andréll, Megan J. Maher, Matthew G. Hicks, and Elisabeth P. Carpenter

Subjects
Models, Molecular, Aromatic L-amino acid decarboxylase, Carboxy-lyases, Arginine, Pentamer, Stereochemistry, Carboxy-Lyases, Protein Conformation, Biology, Hydrogen-Ion Concentration, Lyase, Crystallography, X-Ray, Biochemistry, Ornithine decarboxylase, chemistry.chemical_compound, Biopolymers, chemistry, Enzyme Induction, Escherichia coli, Agmatine, Arginine decarboxylase, Acids
Abstract

The acid-induced arginine decarboxylase is part of an enzymatic system in Escherichia coli that contributes to making this organism acid resistant. The arginine decarboxylase is a vitamin B(6)-dependent enzyme that is active at acidic pH. It consumes a proton in the decarboxylation of arginine to agmatine, and by working in tandem with an arginine-agmatine antiporter, this enzymatic cycle protects the organism by preventing the accumulation of protons inside the cell. We have determined the structure of the acid-induced arginine decarboxylase by X-ray crystallography to 2.4 A resolution. The arginine decarboxylase structure revealed a ca. 800 kDa decamer composed as a pentamer of five homodimers. Each homodimer has an abundance of acidic surface residues, which at neutral pH prevents inactive homodimers from associating into active decamers. Conversely, acidic conditions favor the assembly of active decamers. Therefore, the structure of arginine decarboxylase presents a mechanism by which its activity is modulated by external pH.

Published
2009

39. Thioredoxin A active-site mutants form mixed disulfide dimers that resemble enzyme-substrate reaction intermediates

Author

So Iwata, Thijs R. H. M. Kouwen, Jan Maarten van Dijl, Elisabeth P. Carpenter, Megan J. Maher, Rianne Schrijver, Jean-Yves F. Dubois, Juni Andréll, and Translational Immunology Groningen (TRIGR)

Subjects
Models, Molecular, ESCHERICHIA-COLI THIOREDOXIN, CONFORMATIONAL-CHANGES, Dimer, ArsC, arsenate reductase, PROTEIN, Bacillus, ESRF, European Synchrotron Radiation Facility, Crystallography, X-Ray, Thioredoxin fold, REDUCTASE, chemistry.chemical_compound, Thioredoxins, BsTrxA, Bacillus subtilis TrxA, Protein structure, AMS, 4-acetamido-4′-maleimidyl-stilbene-2,2′-disulfonate, Structural Biology, CRYSTAL-STRUCTURE, Disulfides, Protein disulfide-isomerase, 0303 health sciences, biology, 030302 biochemistry & molecular biology, Ferredoxin-thioredoxin reductase, TARGET, Biochemistry, NF-κB, nuclear factor κB, Thioredoxin, Dimerization, Oxidation-Reduction, TrxA, thioredoxin A, Bacillus subtilis, Molecular Sequence Data, REDUCED FORM, Article, BACILLUS-SUBTILIS, 03 medical and health sciences, Bacterial Proteins, PDB, Protein Data Bank, Humans, Cysteine, BASI, barley α-amylase/subtilisin inhibitor, structure, Protein Structure, Quaternary, Molecular Biology, 030304 developmental biology, Binding Sites, DNA-REPLICATION, Active site, Hydrogen Bonding, thioredoxin, dimer, chemistry, RESOLUTION, Mutation, biology.protein, disulfide
Abstract

Thioredoxin functions in nearly all organisms as the major thiol-disulfide oxidoreductase within the cytosol. Its prime purpose is to maintain cysteine-containing proteins in the reduced state by converting intramolecular disulfide bonds into dithiols in a disulfide exchange reaction. Thioredoxin has been reported to contribute to a wide variety of physiological functions by interacting with specific sets of substrates in different cell types. To investigate the function of the essential thioredoxin A (TrxA) in the low-GC Gram-positive bacterium Bacillus subtilis, we purified wild-type TrxA and three mutant TrxA proteins that lack either one or both of the two cysteine residues in the CxxC active site. The pure proteins were used for substrate-binding studies known as "mixed disulfide fishing" in which covalent disulfide-bonded reaction intermediates can be visualized. An unprecedented finding is that both active-site cysteine residues can form mixed disulfides with substrate proteins when the other active-site cysteine is absent, but only the N-terminal active-site cysteine forms stable interactions. A second novelty is that both single-cysteine mutant TrxA proteins form stable homodimers due to thiol oxidation of the remaining active-site cysteine residue. To investigate whether these dimers resemble mixed enzyme-substrate disulfides, the structure of the most abundant dimer, C32S, was characterized by X-ray crystallography. This yielded a high-resolution (1.5 angstrom) X-ray crystallographic structure of a thioredoxin homodimer from a low-GC Gram-positive bacterium. The C32S TrxA dimer can be regarded as a mixed disulfide reaction intermediate of thioredoxin, which reveals the diversity of thioredoxin/substrate-binding modes. (c) 2008 Elsevier Ltd. All rights reserved.

Published
2008

41. E. colidihydroorotase: loop movement and cooperativity

Author

J.M. Guss, Camilla Chan, Mihwa Lee, Megan J. Maher, and Richard I. Christopherson

Subjects
chemistry.chemical_classification, biology, Stereochemistry, Protein subunit, Mutagenesis, Active site, Cooperative binding, Cooperativity, Enzyme, Dihydroorotase, chemistry, Structural Biology, Pyrimidine metabolism, biology.protein
Abstract

Dihydroorotase (DHOase) is a zinc metalloenzyme that catalyses the reversible cyclization of N-carbamyl-L-aspartate (CA-asp) to dihydroorotate (DHO) in the de novo pyrimidine biosynthesis. The first structure of a DHOase (from E. coli) has been reported to a resolution of 1.7 A with one homodimer per asymmetric unit [1]. We have collected data from crystals of E. coli DHOase grown in the presence of product, DHO and refined the structure to 1.9 A resolution [2]. As in the original report [1], we find the product DHO bound in the active site of one subunit and CA-asp in the active site of the other. Importantly, we have resolved the conformations of residues B109-112, which were disordered in the reported structure. These residues comprise a loop which takes on different orientations in the two subunits, depending on whether DHO or CA-asp is present in the active site. This is accompanied by movements of residues A/B256258 which seem to 'communicate' between subunits the respective contents of the active sites. Subsequent kinetic analysis at low DHO concentrations shows positive cooperativity [2]. Aspects of this structure of DHOase will be discussed. In addition, the structures of inhibitor complexes and site-directed mutagenesis that allow us to understand more about this loop movement will be described in relation to the enzyme mechanism.

Published
2005
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42. Metal-substituted derivatives of the rubredoxin fromClostridium pasteurianum. Addendum

Author

Matthew C.J. Wilce, A.G. Wedd, Maddalena Cross, J.M. Guss, and Megan J. Maher

Subjects
Metal, Biochemistry, Structural Biology, Stereochemistry, Chemistry, Rubredoxin, visual_art, visual_art.visual_art_medium, medicine, Addendum, General Medicine, Clostridium pasteurianum, medicine.disease_cause
Abstract

In our recent article Maher et al. (2004) we omitted to cite the work of Meyer et al. (1997) who were the first to construct an Fe2S2 centre in rubredoxin. This work was later extended in Cross et al. (2002), with the construction of other altered metal sites.

Published
2004
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44. A GTPase Chimera Illustrates an Uncoupled Nucleotide Affinity and Release Rate, Providing Insight into the Activation Mechanism

Author

Miriam-Rose Ash, Megan J. Maher, Amy P. Guilfoyle, Mika Jormakka, Samuel Tourle, Chandrika N. Deshpande, Gerhard Schenk, and Josep Font Sadurni

Subjects
Conformational change, Biophysical Letter, Escherichia coli Proteins, Molecular Sequence Data, Biophysics, GTPase, GTP-Binding Protein alpha Subunits, Gi-Go, Biology, Guanosine Diphosphate, Fusion protein, Recombinant Proteins, Protein Structure, Tertiary, Transport protein, chemistry.chemical_compound, GTP-binding protein regulators, Protein structure, chemistry, Biochemistry, Guanosine diphosphate, Humans, Amino Acid Sequence, Cation Transport Proteins, Protein Binding, G alpha subunit
Abstract

The release of GDP from GTPases signals the initiation of a GTPase cycle, where the association of GTP triggers conformational changes promoting binding of downstream effector molecules. Studies have implicated the nucleotide-binding G5 loop to be involved in the GDP release mechanism. For example, biophysical studies on both the eukaryotic Gα proteins and the GTPase domain (NFeoB) of prokaryotic FeoB proteins have revealed conformational changes in the G5 loop that accompany nucleotide binding and release. However, it is unclear whether this conformational change in the G5 loop is a prerequisite for GDP release, or, alternatively, the movement is a consequence of release. To gain additional insight into the sequence of events leading to GDP release, we have created a chimeric protein comprised of Escherichia coli NFeoB and the G5 loop from the human Giα1 protein. The protein chimera retains GTPase activity at a similar level to wild-type NFeoB, and structural analyses of the nucleotide-free and GDP-bound proteins show that the G5 loop adopts conformations analogous to that of the human nucleotide-bound Giα1 protein in both states. Interestingly, isothermal titration calorimetry and stopped-flow kinetic analyses reveal uncoupled nucleotide affinity and release rates, supporting a model where G5 loop movement promotes nucleotide release.

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