Structure and conformational plasticity of the intact Thermus thermophilus V/A-type ATPase

Science ◽  
2019 ◽  
Vol 365 (6455) ◽  
pp. eaaw9144 ◽  
Author(s):  
Long Zhou ◽  
Leonid A. Sazanov
Keyword(s):  
Atp Hydrolysis ◽  
Thermus Thermophilus ◽  
Proton Translocation ◽  
Adenosine Diphosphate ◽  
Rotational States ◽  
Torque Transmission ◽  
Conformational Plasticity ◽  
Central Shaft ◽  
Rotary Catalysis ◽  
Lipid Nanodiscs

V (vacuolar)/A (archaeal)-type adenosine triphosphatases (ATPases), found in archaea and eubacteria, couple ATP hydrolysis or synthesis to proton translocation across the plasma membrane using the rotary-catalysis mechanism. They belong to the V-type ATPase family, which differs from the mitochondrial/chloroplast F-type ATP synthases in overall architecture. We solved cryo–electron microscopy structures of the intact Thermus thermophilus V/A-ATPase, reconstituted into lipid nanodiscs, in three rotational states and two substates. These structures indicate substantial flexibility between V1 and Vo in a working enzyme, which results from mechanical competition between central shaft rotation and resistance from the peripheral stalks. We also describe details of adenosine diphosphate inhibition release, V1-Vo torque transmission, and proton translocation, which are relevant for the entire V-type ATPase family.

scholarly journals Structure of a bacterial ATP synthase

2018 ◽  
Author(s):  
Hui Guo ◽  
Toshiharu Suzuki ◽  
John L. Rubinstein
Keyword(s):  
Atp Synthase ◽  
Biochemical Analysis ◽  
Atp Hydrolysis ◽  
Genetic Manipulation ◽  
Proton Translocation ◽  
Atp Synthesis ◽  
Mitochondrial Complex ◽  
Rotational States ◽  
Membrane Region ◽  
Atp Synthases

AbstractATP synthases produce ATP from ADP and inorganic phosphate with energy from a transmembrane proton motive force. Bacterial ATP synthases have been studied extensively because they are the simplest form of the enzyme and because of the relative ease of genetic manipulation of these complexes. We expressed theBacillusPS3 ATP synthase inEschericia coli, purified it, and imaged it by cryo-EM, allowing us to build atomic models of the complex in three rotational states. The position of subunitεshows how it is able to inhibit ATP hydrolysis while allowing ATP synthesis. The architecture of the membrane region shows how the simple bacterial ATP synthase is able to perform the same core functions as the equivalent, but more complicated, mitochondrial complex. The structures reveal the path of transmembrane proton translocation and provide a model for understanding decades of biochemical analysis interrogating the roles of specific residues in the enzyme.

scholarly journals Structure of a bacterial ATP synthase

eLife ◽  
2019 ◽  
Vol 8 ◽  
Author(s):  
Hui Guo ◽  
Toshiharu Suzuki ◽  
John L Rubinstein
Keyword(s):  
Atp Synthase ◽  
Biochemical Analysis ◽  
Atp Hydrolysis ◽  
Genetic Manipulation ◽  
Proton Translocation ◽  
Atp Synthesis ◽  
Mitochondrial Complex ◽  
Rotational States ◽  
Membrane Region ◽  
Atp Synthases

ATP synthases produce ATP from ADP and inorganic phosphate with energy from a transmembrane proton motive force. Bacterial ATP synthases have been studied extensively because they are the simplest form of the enzyme and because of the relative ease of genetic manipulation of these complexes. We expressed the Bacillus PS3 ATP synthase in Eschericia coli, purified it, and imaged it by cryo-EM, allowing us to build atomic models of the complex in three rotational states. The position of subunit ε shows how it is able to inhibit ATP hydrolysis while allowing ATP synthesis. The architecture of the membrane region shows how the simple bacterial ATP synthase is able to perform the same core functions as the equivalent, but more complicated, mitochondrial complex. The structures reveal the path of transmembrane proton translocation and provide a model for understanding decades of biochemical analysis interrogating the roles of specific residues in the enzyme.

CRISPR/Cas9-Mediated Gene Editing of Vacuolar ATPase Subunit D Mediates Phytohormone Biosynthesis and Virus Resistance in Rice

2021 ◽  
Author(s):  
Qinghua Lu ◽  
Xiangwen Luo ◽  
Xiao Yang ◽  
Tong Zhou ◽  
Yu Zhang ◽  
...  
Keyword(s):  
Virus Resistance ◽  
Atp Hydrolysis ◽  
Proton Translocation ◽  
Resistance Breeding ◽  
Rice Stripe Virus ◽  
Proton Pumps ◽  
Wild Type ◽  
Knockout Mutant ◽  
Atpase Subunit ◽  
Vacuolar Atpases

Abstract Background: Vacuolar ATPases (v-ATPases) are proton pumps for proton translocation across membranes that utilize energy derived from ATP hydrolysis; Previous research revealed Osv-ATPases mediates phytohormes levels and resistance in rice. Osv-ATPase subunit d (Osv-ATPase d) is part of an integral, membrane-embedded V0 complex of V-ATPases complex, whether Osv-ATPase d involves in phytohormes biosynthesis and resistance in rice remains unknown.Finding: The knockout mutant line (line 5) of Osv-ATPase d was generated using the CRISPR/Cas9 system, mutation of Osv-ATPase d did not show any detrimental effect on plant growth or yield productivity. Transcriptomic results showed Osv-ATPase d probably involved in mediating the biosynthesis of plant hormones and resistance in rice. Mutation of Osv-ATPase d significantly increased JA and ABA biosynthesis than wild type. Compared to wild type, mutation of Osv-ATPase d increased the resistance against Southern rice black-streaked dwarf virus (SRBSDV), however, decreased the resistance against Rice stripe virus (RSV) in rice. Conclusion: Taken together, our data reveal the Osv-ATPase d mediates phytohormone biosynthesis and virus resistance in rice, which can be selected as a potential target for resistance breeding in rice.

scholarly journals Aerobic Growth of Escherichia coli Is Reduced, and ATP Synthesis Is Selectively Inhibited when Five C-terminal Residues Are Deleted from the ϵ Subunit of ATP Synthase

2015 ◽  
Vol 290 (34) ◽  
pp. 21032-21041 ◽  
Author(s):  
Naman B. Shah ◽  
Thomas M. Duncan
Keyword(s):  
Escherichia Coli ◽  
Atp Synthase ◽  
Atp Hydrolysis ◽  
Atp Synthesis ◽  
Intrinsic Rate ◽  
Synthesis Rate ◽  
Final Segment ◽  
Rotary Catalysis

F-type ATP synthases are rotary nanomotor enzymes involved in cellular energy metabolism in eukaryotes and eubacteria. The ATP synthase from Gram-positive and -negative model bacteria can be autoinhibited by the C-terminal domain of its ϵ subunit (ϵCTD), but the importance of ϵ inhibition in vivo is unclear. Functional rotation is thought to be blocked by insertion of the latter half of the ϵCTD into the central cavity of the catalytic complex (F1). In the inhibited state of the Escherichia coli enzyme, the final segment of ϵCTD is deeply buried but has few specific interactions with other subunits. This region of the ϵCTD is variable or absent in other bacteria that exhibit strong ϵ-inhibition in vitro. Here, genetically deleting the last five residues of the ϵCTD (ϵΔ5) caused a greater defect in respiratory growth than did the complete absence of the ϵCTD. Isolated membranes with ϵΔ5 generated proton-motive force by respiration as effectively as with wild-type ϵ but showed a nearly 3-fold decrease in ATP synthesis rate. In contrast, the ϵΔ5 truncation did not change the intrinsic rate of ATP hydrolysis with membranes. Further, the ϵΔ5 subunit retained high affinity for isolated F1 but reduced the maximal inhibition of F1-ATPase by ϵ from >90% to ∼20%. The results suggest that the ϵCTD has distinct regulatory interactions with F1 when rotary catalysis operates in opposite directions for the hydrolysis or synthesis of ATP.

scholarly journals Mutation of a single residue in the ba3 oxidase specifically impairs protonation of the pump site

2015 ◽  
Vol 112 (11) ◽  
pp. 3397-3402 ◽  
Author(s):  
Christoph von Ballmoos ◽  
Nathalie Gonska ◽  
Peter Lachmann ◽  
Robert B. Gennis ◽  
Pia Ädelroth ◽  
...  
Keyword(s):  
Electron Transfer ◽  
Time Constant ◽  
Thermus Thermophilus ◽  
Proton Translocation ◽  
Proton Pumping ◽  
Wild Type ◽  
Structural Variant ◽  
In The Wild ◽  
Membrane Bound ◽  
Proton Uptake

The ba3-type cytochrome c oxidase from Thermus thermophilus is a membrane-bound protein complex that couples electron transfer to O2 to proton translocation across the membrane. To elucidate the mechanism of the redox-driven proton pumping, we investigated the kinetics of electron and proton transfer in a structural variant of the ba3 oxidase where a putative “pump site” was modified by replacement of Asp372 by Ile. In this structural variant, proton pumping was uncoupled from internal electron transfer and O2 reduction. The results from our studies show that proton uptake to the pump site (time constant ∼65 μs in the wild-type cytochrome c oxidase) was impaired in the Asp372Ile variant. Furthermore, a reaction step that in the wild-type cytochrome c oxidase is linked to simultaneous proton uptake and release with a time constant of ∼1.2 ms was slowed to ∼8.4 ms, and in Asp372Ile was only associated with proton uptake to the catalytic site. These data identify reaction steps that are associated with protonation and deprotonation of the pump site, and point to the area around Asp372 as the location of this site in the ba3 cytochrome c oxidase.

scholarly journals Targeting Mycobacterial F-ATP Synthase C-Terminal α Subunit Interaction Motif on Rotary Subunit γ

Antibiotics ◽  
2021 ◽  
Vol 10 (12) ◽  
pp. 1456
Author(s):  
Amaravadhi Harikishore ◽  
Chui-Fann Wong ◽  
Priya Ragunathan ◽  
Dennis Litty ◽  
Volker Müller ◽  
...  
Keyword(s):  
Atp Synthase ◽  
Atp Hydrolysis ◽  
Atp Synthesis ◽  
Membrane Vesicles ◽  
Α Subunit ◽  
Rotational States ◽  
C Terminus ◽  
Inverted Membrane Vesicles ◽  
Hydrolysis Of ◽  
Micromolar Range

Mycobacteria regulate their energy (ATP) levels to sustain their survival even in stringent living conditions. Recent studies have shown that mycobacteria not only slow down their respiratory rate but also block ATP hydrolysis of the F-ATP synthase (α3:β3:γ:δ:ε:a:b:b’:c9) to maintain ATP homeostasis in situations not amenable for growth. The mycobacteria-specific α C-terminus (α533-545) has unraveled to be the major regulative of latent ATP hydrolysis. Its deletion stimulates ATPase activity while reducing ATP synthesis. In one of the six rotational states of F-ATP synthase, α533-545 has been visualized to dock deep into subunit γ, thereby blocking rotation of γ within the engine. The functional role(s) of this C-terminus in the other rotational states are not clarified yet and are being still pursued in structural studies. Based on the interaction pattern of the docked α533-545 region with subunit γ, we attempted to study the druggability of the α533-545 motif. In this direction, our computational work has led to the development of an eight-featured α533-545 peptide pharmacophore, followed by database screening, molecular docking, and pose selection, resulting in eleven hit molecules. ATP synthesis inhibition assays using recombinant ATP synthase as well as mycobacterial inverted membrane vesicles show that one of the hits, AlMF1, inhibited the mycobacterial F-ATP synthase in a micromolar range. The successful targeting of the α533-545-γ interaction motif demonstrates the potential to develop inhibitors targeting the α site to interrupt rotary coupling with ATP synthesis.

scholarly journals Structural basis for DEAH-helicase activation by G-patch proteins

2020 ◽  
Vol 117 (13) ◽  
pp. 7159-7170 ◽  
Author(s):  
Michael K. Studer ◽  
Lazar Ivanović ◽  
Marco E. Weber ◽  
Sabrina Marti ◽  
Stefanie Jonas
Keyword(s):  
Conformational Changes ◽  
Ribosome Biogenesis ◽  
Rna Binding ◽  
Atp Hydrolysis ◽  
Protein Complexes ◽  
Adenosine Diphosphate ◽  
Structural Basis ◽  
Rna Helicases ◽  
Catalytic Core ◽  
Terminal Domains

RNA helicases of the DEAH/RHA family are involved in many essential cellular processes, such as splicing or ribosome biogenesis, where they remodel large RNA–protein complexes to facilitate transitions to the next intermediate. DEAH helicases couple adenosine triphosphate (ATP) hydrolysis to conformational changes of their catalytic core. This movement results in translocation along RNA, which is held in place by auxiliary C-terminal domains. The activity of DEAH proteins is strongly enhanced by the large and diverse class of G-patch activators. Despite their central roles in RNA metabolism, insight into the molecular basis of G-patch–mediated helicase activation is missing. Here, we have solved the structure of human helicase DHX15/Prp43, which has a dual role in splicing and ribosome assembly, in complex with the G-patch motif of the ribosome biogenesis factor NKRF. The G-patch motif binds in an extended conformation across the helicase surface. It tethers the catalytic core to the flexibly attached C-terminal domains, thereby fixing a conformation that is compatible with RNA binding. Structures in the presence or absence of adenosine diphosphate (ADP) suggest that motions of the catalytic core, which are required for ATP binding, are still permitted. Concomitantly, RNA affinity, helicase, and ATPase activity of DHX15 are increased when G-patch is bound. Mutations that detach one end of the tether but maintain overall binding severely impair this enhancement. Collectively, our data suggest that the G-patch motif acts like a flexible brace between dynamic portions of DHX15 that restricts excessive domain motions but maintains sufficient flexibility for catalysis.

scholarly journals Insights into the origin of the high energy-conversion efficiency of F1-ATPase

2019 ◽  
Vol 116 (32) ◽  
pp. 15924-15929 ◽  
Author(s):  
Kwangho Nam ◽  
Martin Karplus
Keyword(s):  
Single Molecule ◽  
Atp Hydrolysis ◽  
Theoretical Models ◽  
Adenosine Diphosphate ◽  
Energy Conversion Efficiency ◽  
High Energy ◽  
Structural Deformation ◽  
Coupling Mechanism ◽  
Surprising Result ◽  
X Ray Crystallography

Our understanding of the rotary-coupling mechanism of F1-ATPase has been greatly enhanced in the last decade by advances in X-ray crystallography, single-molecular imaging, and theoretical models. Recently, Volkán-Kacsó and Marcus [S. Volkán-Kacsó, R. A. Marcus, Proc. Natl. Acad. Sci. U.S.A. 112, 14230 (2015)] presented an insightful thermodynamic model based on the Marcus reaction theory coupled with an elastic structural deformation term to explain the observed γ-rotation angle dependence of the adenosine triphosphate (ATP)/adenosine diphosphate (ADP) exchange rates of F1-ATPase. Although the model is successful in correlating single-molecule data, it is not in agreement with the available theoretical results. We describe a revision of the model, which leads to consistency with the simulation results and other experimental data on the F1-ATPase rotor compliance. Although the free energy liberated on ATP hydrolysis by F1-ATPase is rapidly dissipated as heat and so cannot contribute directly to the rotation, we show how, nevertheless, F1-ATPase functions near the maximum possible efficiency. This surprising result is a consequence of the differential binding of ATP and its hydrolysis products ADP and Pi along a well-defined pathway.

Transhydrogenase and the anaerobic mitochondrial metabolism of adult Hymenolepis diminuta

Parasitology ◽  
2009 ◽  
Vol 137 (3) ◽  
pp. 395-410 ◽  
Author(s):  
C. F. FIORAVANTI ◽  
K. P. VANDOCK
Keyword(s):  
Electron Transport ◽  
Malic Enzyme ◽  
Atp Hydrolysis ◽  
Proton Translocation ◽  
Phosphorylation Site ◽  
Hymenolepis Diminuta ◽  
Intermembrane Space ◽  
Hydride Ion ◽  
Matrix Surface ◽  
Atp Generation

SUMMARYThe adult cestode, Hymenolepis diminuta, is essentially anaerobic energetically. Carbohydrate dissimilation results in acetate, lactate and succinate accumulation with succinate being the major end product. Succinate accumulation results from the anaerobic, mitochondrial, ‘malic’ enzyme-dependent utilization of malate coupled to ATP generation via the electron transport-linked fumarate reductase. A lesser peroxide-forming oxidase is apparent, however, fumarate reduction to succinate predominates even in air. The H. diminuta matrix-localized ‘malic’ enzyme is NADP-specific whereas the inner membrane (IM)-associated electron transport system prefers NADH. This dilemma is circumvented by the mitochondrial, IM-associated NADPH→NAD+ transhydrogenase in catalyzing hydride ion transfer from NADPH to NAD+ on the IM matrix surface. Hydride transfer is reversible and phospholipid-dependent. NADP+ reduction occurs as a non energy-linked and energy-linked reaction with the latter requiring electron transport NADH utilization or ATP hydrolysis. With NAD+ reduction, the cestode transhydrogenase also engages in concomitant proton translocation from the mitochondrial matrix to the intermembrane space and supports net ATP generation. Thus, the cestode NADPH→NAD+ system can serve not only as a metabolic connector, but an additional anaerobic phosphorylation site. Although its function(s) is unknown, a separate IM-associated NADH→ NAD+ transhydrogenation, catalyzed by the lipoamide and NADH dehydrogenases, is noted.

scholarly journals Structures of an intact yeast V-ATPase alone and in complex with bacterial effector VopQ

2020 ◽  
Author(s):  
Wei Peng ◽  
Jessie Fernandez ◽  
Amanda K. Casey ◽  
Lisa N. Kinch ◽  
Diana R. Tomchick ◽  
...  
Keyword(s):  
Atp Hydrolysis ◽  
Proton Translocation ◽  
Regulatory Subunit ◽  
Cellular Membranes ◽  
Catalytic Subunits ◽  
Catalysis Mechanism

AbstractVacuolar-type ATPase (V-ATPase) is a rotary protein pump involved in proton translocation across various cellular membranes using the energy of ATP hydrolysis. Despite previous studies on bacterial and eukaryotic V-ATPases, information on the intact structure of a eukaryotic V-ATPase is missing. Here we report cryo-EM structures of the intact yeast V-ATPase and this complex bound to a bacterial effector. We reveal the interaction of the elusive regulatory subunit H with its neighboring subunits. Insight for the catalysis mechanism is gained by determining conformations of the catalytic subunits either empty or bound with nucleotides.

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