Molecular Mechanism of ATP Hydrolysis in F<sub>1</sub>-ATPase Revealed by Molecular Simulations and Single-Molecule Observations

Hayashi, Shigehiko; Ueno, Hiroshi; Shaikh, Abdul Rajjak; Umemura, Myco; Kamiya, Motoshi; Ito, Yuko; Ikeguchi, Mitsunori; Komoriya, Yoshihito; Iino, Ryota; Noji, Hiroyuki

doi:10.1021/ja211027m

Cited by 94 publications

(150 citation statements)

References 53 publications

(113 reference statements)

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“…The connection between binding and release events to the rotation of the γ shaft has been investigated by several groups using structural calculations (30)(31)(32)(33)(34)(35). A question arising from our study that simulations could treat is the evolution of the hydrogen-bonding network during structural displacements of a β subunit, and how it is affected by the presence of the binding nucleotide.…”

Section: Discussionmentioning

confidence: 99%

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F ₁ -ATPase

Volkan-Kacso

Marcus

2016

Proc. Natl. Acad. Sci. U.S.A.

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A recently proposed chemomechanical group transfer theory of rotary biomolecular motors is applied to treat single-molecule controlled rotation experiments. In these experiments, singlemolecule fluorescence is used to measure the binding and release rate constants of nucleotides by monitoring the occupancy of binding sites. It is shown how missed events of nucleotide binding and release in these experiments can be corrected using theory, with F 1 -ATP synthase as an example. The missed events are significant when the reverse rate is very fast. Using the theory the actual rate constants in the controlled rotation experiments and the corrections are predicted from independent data, including other single-molecule rotation and ensemble biochemical experiments. The effective torsional elastic constant is found to depend on the binding/releasing nucleotide, and it is smaller for ADP than for ATP. There is a good agreement, with no adjustable parameters, between the theoretical and experimental results of controlled rotation experiments and stalling experiments, for the range of angles where the data overlap. This agreement is perhaps all the more surprising because it occurs even though the binding and release of fluorescent nucleotides is monitored at single-site occupancy concentrations, whereas the stalling and free rotation experiments have multiple-site occupancy. S ingle-molecule manipulation techniques, including stalling and controlled rotation methods or "pulling" force microscopies, have been used to augment imaging experiments in biomolecular motors (1-4). In F 1 -ATPase, for example, beyond observing the kinetics of stepping rotation resolved into ∼80°a nd ∼40°substeps (5-7), the manipulation of the rotor shaft by magnetic tweezers recently opened up the possibility of directly probing the dynamical response of the system to externally constraining the rotor angle θ. In tandem with the experimental tools of X-ray crystallography (8) and ensemble biochemical methods (9), these experiments provide added insight into the processes in chemomechanical energy transduction (7, 10-13). The kinetic pathway along which concerted substeps occur in free rotation has been established (14), whereby binding of solution ATP to an empty subunit is initiated at θ = 0°, and the release of hydrolyzed ADP from the clockwise neighboring subunit occurs simultaneously as the θ completes the ∼80°ro-tation step (Fig. 1). Using the detailed knowledge of individual substeps, stalling (3, 15) and controlled rotation (3) experiments provide an estimate of the rate constants of nucleotide binding and other processes as a function of θ. In particular, binding and release of ATP and analogs can be externally controlled to occur at angles other than 0°.In the controlled rotation experiments (1, 4) we consider here, a slow constant angular velocity rotation of the shaft was produced by magnetic tweezers. A magnetic bead was attached to the rotor shaft protruding from the stator ring with a constant magnetic dipole moment pointing in the pl...

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Section: Discussionmentioning

confidence: 99%

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F ₁ -ATPase

Volkan-Kacso

Marcus

2016

Proc. Natl. Acad. Sci. U.S.A.

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“…As noted earlier, the present formulation of the model is not intended to apply to the ATP hydrolysis step, which is believed to involve two or more substeps, rather than just one (28,30,50). An α of 0.83 for ATP hydrolysis in tyrosyl-tRNA synthase was inferred by use of mutants, and an explanation of this high α for this reaction, where overall ΔG 0 is small, was given by Warshel, who postulated two transition states of about equal energy with a shallow minimum in between (28).…”

Section: Concluding Discussion and Outlookmentioning

confidence: 99%

“…Thereby the first step had a barrier almost equal to the energy to reach the shallow well, and so α was close to unity. Electronic structure calculations in F 1 -ATPase of a more ab initio nature (30,50) indicated at least two TS's, but further studies are needed to explore these TS's, and the valley between them should be treated. Obtaining α via stalling experiments has an advantage over obtaining it via mutations because the latter may also affect λ.…”

Section: Concluding Discussion and Outlookmentioning

confidence: 99%

“…Nevertheless, the general features of the model are intended to apply also to other rotation-coupled steps involving the reversible binding and release of a ligand molecule, such as ADP and P i , and to other ring-shaped NTPases, and can be tested once sufficient kinetic data become available. The model, as presently formulated, does not apply to the ATP hydrolysis (cleavage) step, because it may be a multistep process (28)(29)(30), as discussed in more detail in a later section.…”

Section: Significancementioning

confidence: 99%

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Theory for rates, equilibrium constants, and Brønsted slopes in F ₁ -ATPase single molecule imaging experiments

Volkan-Kacso

Marcus

2015

Proc. Natl. Acad. Sci. U.S.A.

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A theoretical model of elastically coupled reactions is proposed for single molecule imaging and rotor manipulation experiments on F 1 -ATPase. Stalling experiments are considered in which rates of individual ligand binding, ligand release, and chemical reaction steps have an exponential dependence on rotor angle. These data are treated in terms of the effect of thermodynamic driving forces on reaction rates, and lead to equations relating rate constants and free energies to the stalling angle. These relations, in turn, are modeled using a formalism originally developed to treat electron and other transfer reactions. During stalling the free energy profile of the enzymatic steps is altered by a work term due to elastic structural twisting. Using biochemical and single molecule data, the dependence of the rate constant and equilibrium constant on the stall angle, as well as the Børnsted slope are predicted and compared with experiment. Reasonable agreement is found with stalling experiments for ATP and GTP binding. The model can be applied to other torque-generating steps of reversible ligand binding, such as ADP and P i release, when sufficient data become available. S ingle molecule imaging directly demonstrated a stepping rotation in F 1 -ATPase (1) that was resolved into ∼ 40°and ∼ 80°s ubsteps (initially reported as ∼ 30°and ∼ 90°; cf. refs. 2 and 3), and much information has been extracted by elaborate techniques at the single molecule level (3-6). Complementing experimental tools such as X-ray spectroscopy (7) and ensemble biochemical methods (8), single molecule experiments reveal key details of the coupling between enzymatic processes and rotation (9-12). A detailed picture of highly coordinated substeps has emerged in which the binding of solution ATP to an empty subunit and release of hydrolyzed ADP from the clockwise neighbor (viewed from the rotor side) occur in concert during the ∼ 80°rotation step (13). As depicted in Fig. 1 and Table 1, the subsequent ∼ 40°r otation is coordinated with the hydrolysis of ATP in the third subunit and the release of P i from the subunit that just released ADP (13).Recent stalling (6,13,14) and controlled rotation (15) experiments provide additional insight into the dynamics of the coupling between the rotation of the central shaft and the reaction steps in the stator ring subunits. These experiments yielded the rate constants of various steps, binding and release of ligands, and hydrolysis/synthesis reaction, as a function of the stalled rotor angle θ. The rates show an exponential dependence on θ over a wide range, such as a range of 80°for ATP binding and 40°for hydrolysis. Free energy profiles for the initial and final dwell angles at a specific 40°or 80°step are given in Fig. 2. For intermediate stalling angles, the profile is intermediate between these two limits.In stalling experiments (14) the freely rotating shaft of the ATPase is stalled by magnetic tweezers upon reaching a dwell angle. Rotation experiments have resolved two dwells: the binding dwell (before...

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“…The glutamic acid general base has been thought to activate the intervening water molecule to induce nucleophilic attack of the water molecule on the ␥ phosphate. Recent quantum chemical calculation and single-molecule analysis revealed that the role of general base may be not water activation but the enhancement of proton transfer from phosphoester to bulk solution (135). In some ATPases the glutamic acid also plays a role as a sensor for the ATP binding state and changes orientation drastically upon ATP binding (136).…”

Section: Motion Mechanism Energy Conversion: Transition Among Entropymentioning

confidence: 99%

Biological Nanomotors with a Revolution, Linear, or Rotation Motion Mechanism

Guo

Noji

Yengo

et al. 2016

Microbiol Mol Biol Rev

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SUMMARYThe ubiquitous biological nanomotors were classified into two categories in the past: linear and rotation motors. In 2013, a third type of biomotor, revolution without rotation (http://rnanano.osu.edu/movie.html), was discovered and found to be widespread among bacteria, eukaryotic viruses, and double-stranded DNA (dsDNA) bacteriophages. This review focuses on recent findings about various aspects of motors, including chirality, stoichiometry, channel size, entropy, conformational change, and energy usage rate, in a variety of well-studied motors, including FoF1ATPase, helicases, viral dsDNA-packaging motors, bacterial chromosome translocases, myosin, kinesin, and dynein. In particular, dsDNA translocases are used to illustrate how these features relate to the motion mechanism and how nature elegantly evolved a revolution mechanism to avoid coiling and tangling during lengthy dsDNA genome transportation in cell division. Motor chirality and channel size are two factors that distinguish rotation motors from revolution motors. Rotation motors use right-handed channels to drive the right-handed dsDNA, similar to the way a nut drives the bolt with threads in same orientation; revolution motors use left-handed motor channels to revolve the right-handed dsDNA. Rotation motors use small channels (<2 nm in diameter) for the close contact of the channel wall with single-stranded DNA (ssDNA) or the 2-nm dsDNA bolt; revolution motors use larger channels (>3 nm) with room for the bolt to revolve. Binding and hydrolysis of ATP are linked to different conformational entropy changes in the motor that lead to altered affinity for the substrate and allow work to be done, for example, helicase unwinding of DNA or translocase directional movement of DNA.

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Molecular Mechanism of ATP Hydrolysis in F₁-ATPase Revealed by Molecular Simulations and Single-Molecule Observations

Cited by 94 publications

References 53 publications

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F ₁ -ATPase

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F ₁ -ATPase

Theory for rates, equilibrium constants, and Brønsted slopes in F ₁ -ATPase single molecule imaging experiments

Biological Nanomotors with a Revolution, Linear, or Rotation Motion Mechanism

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Molecular Mechanism of ATP Hydrolysis in F1-ATPase Revealed by Molecular Simulations and Single-Molecule Observations

Cited by 94 publications

References 53 publications

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F 1 -ATPase

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F 1 -ATPase

Theory for rates, equilibrium constants, and Brønsted slopes in F 1 -ATPase single molecule imaging experiments

Biological Nanomotors with a Revolution, Linear, or Rotation Motion Mechanism

Contact Info

Product

Resources

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Molecular Mechanism of ATP Hydrolysis in F₁-ATPase Revealed by Molecular Simulations and Single-Molecule Observations

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F ₁ -ATPase

Theory of single-molecule controlled rotation experiments, predictions, tests, and comparison with stalling experiments in F ₁ -ATPase

Theory for rates, equilibrium constants, and Brønsted slopes in F ₁ -ATPase single molecule imaging experiments