A Microscopic Capacitor Model of Voltage Coupling in Membrane Proteins: Gating Charge Fluctuations in Ci-VSD

Kim, Ilsoo; Warshel, Arieh

doi:10.1021/acs.jpcb.5b10956

Cited by 6 publications

(21 citation statements)

References 92 publications

(403 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Each system was then fed into a next step to determine the electrolyte charge distributions and the electrode potentials under an external voltage of 0.1 V. The changes in electrode potentials after the ETs/PTs were used to estimate the voltage generation (the difference in electrode potentials before and after the charge separation). The validity of our approach has been established recently in systematic works (34,37,38).…”

Section: Methodsmentioning

confidence: 77%

“…The resulting quantity is called here "fractional voltage," which is related to the so-called "dielectric distance" (ref. 38 and references therein). We note, however, that in reporting the normalized calculated (fractional) values, we used an observed value of 2.48 mV (25, 33) (in comparison with a calculated value of 2.56 mV) for transferring a proton from the N to the P side of the membrane.…”

Section: Resultsmentioning

confidence: 99%

“…Our method is based on using the CG treatment, which is described in detail elsewhere (34)(35)(36)(37)(38), where we model the protein/membrane system (39) and its interaction with the external potential (Fig. 2).…”

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Analyzing the electrogenicity of cytochrome c oxidase

Kim

Warshel

2016

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

Self Cite

View full text Add to dashboard Cite

Measurements of voltage changes in response to charge separation within membrane proteins can offer fundamental information on spectroscopically "invisible" steps. For example, results from studies of voltage changes associated with electron and proton transfer in cytochrome c oxidase could, in principle, be used to discriminate between different theoretical models describing the molecular mechanism of proton pumping. Earlier analyses of data from these measurements have been based on macroscopic considerations that may not allow for exploring the actual molecular mechanisms. Here, we have used a coarse-grained model describing the relation between observed voltage changes and specific charge-transfer reactions, which includes an explicit description of the membrane, the electrolytes, and the electrodes. The results from these calculations offer mechanistic insights at the molecular level. Our main conclusion is that previously assumed mechanistic evidence that was based on electrogenic measurements is not unique. However, the ability of our calculations to obtain reliable voltage changes means that we have a tool that can be used to describe a wide range of electrogenic charge transfers in channels and transporters, by combining voltage measurements with other experiments and simulations to analyze new mechanistic proposals.electrogenicity | membrane potential | proton transfer | electron transfer C ytochrome c oxidase (CcO) couples the four-electron reduction of O 2 to water, where the released free energy is used to pump protons from the negative (N) to the positive (P) side of the membrane (1-5), leading to an electrochemical proton gradient that drives, for example, ATP synthesis. The elucidation of the structure of CcO (6-12), combined with experimental and theoretical studies (e.g., refs. 3, 13-15), has advanced the understanding of this intriguing system. Progress has been made in defining the conditions that would allow CcO to pump protons against a pH gradient (4, 16), in estimating the electrostatic energy of possible intermediates (17-21), in evaluating the energetics of the key water chains (22,23), and of a number of specific proton-transfer (PT) reactions (16). Furthermore, examination of the energetics of the overall pumping process has been performed by using a semimacroscopic model (16).However, the relationship between protein structure, the PT energetics, and detailed PT trajectories has not been established. Furthermore, to our knowledge, a consistent protonpumping mechanism purely based on structural information and thermodynamic considerations has not been presented. For example, we still cannot identity the primary acceptor for pumped protons, although the D propionate of heme a 3 (Prda3 in Fig. 1) is one of the most likely candidates for being at least a "transient" acceptor. Apparently, there has been some progress in using structures in functional analyses (e.g., refs. 16, 24-26). However, we still do not have a consistent model that correctly reproduces the pumping events, while prev...

show abstract

Section: Methodsmentioning

confidence: 77%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Analyzing the electrogenicity of cytochrome c oxidase

Kim

Warshel

2016

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

Self Cite

View full text Add to dashboard Cite

show abstract

“…The hydrogen-bond "order" can serve as a collective reaction coordinate (16,18) for the binding transition of the nucleotide. The Brønsted slope identifies the nature of the transition state (16,18) and it was recently applied to treat the gating charge fluctuations in membrane proteins as a quantity related to charge transport (36). In that study the gating voltage is a control parameter analogous to the θ of the F 1 -ATPase in our treatment.…”

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.

View full text Add to dashboard Cite

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...

show abstract

“…Here, we show that

is not capricious and that the observations can be explained within a theoretical framework ( Kim and Warshel, 2015 , 2016 ) that derives expressions from a Hamiltonian, which considers three components participating during a voltage clamp experiment: (1) the voltage-sensing protein; (2) the membrane; and (3) the surrounding electrolyte. This model determines the displacement charge by calculating the externally flowing charges in the surrounding electrolyte that arise from the charge movement occurring between two states of a voltage sensor in the membrane.…”

Section: Introductionmentioning

confidence: 93%

A novel theoretical framework reveals more than one voltage-sensing pathway in the lateral membrane of outer hair cells

Farrell

Skidmore

Rajasekharan

et al. 2020

Journal of General Physiology

View full text Add to dashboard Cite

Outer hair cell (OHC) electromotility amplifies acoustic vibrations throughout the frequency range of hearing. Electromotility requires that the lateral membrane protein prestin undergo a conformational change upon changes in the membrane potential to produce an associated displacement charge. The magnitude of the charge displaced and the mid-reaction potential (when one half of the charge is displaced) reflects whether the cells will produce sufficient gain at the resting membrane potential to boost sound in vivo. Voltage clamp measurements performed under near-identical conditions ex vivo show the charge density and mid-reaction potential are not always the same, confounding interpretation of the results. We compare the displacement charge measurements in OHCs from rodents with a theory shown to exhibit good agreement with in silico simulations of voltage-sensing reactions in membranes. This model equates the charge density to the potential difference between two pseudo-equilibrium states of the sensors when they are in a stable conformation and not contributing to the displacement current. The model predicts this potential difference to be one half of its value midway into the reaction, when one equilibrium conformation transforms to the other pseudo-state. In agreement with the model, we find the measured mid-reaction potential to increase as the charge density decreases to exhibit a negative slope of ∼1/2. This relationship suggests that the prestin sensors exhibit more than one stable hyperpolarized state and that voltage sensing occurs by more than one pathway. We determine the electric parameters for prestin sensors and use the analytical expressions of the theory to estimate the energy barriers for the two voltage-dependent pathways. This analysis explains the experimental results, supports the theoretical approach, and suggests that voltage sensing occurs by more than one pathway to enable amplification throughout the frequency range of hearing.

show abstract

A Microscopic Capacitor Model of Voltage Coupling in Membrane Proteins: Gating Charge Fluctuations in Ci-VSD

Cited by 6 publications

References 92 publications

Analyzing the electrogenicity of cytochrome c oxidase

Analyzing the electrogenicity of cytochrome c oxidase

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

A novel theoretical framework reveals more than one voltage-sensing pathway in the lateral membrane of outer hair cells

Contact Info

Product

Resources

About

A Microscopic Capacitor Model of Voltage Coupling in Membrane Proteins: Gating Charge Fluctuations in Ci-VSD

Cited by 6 publications

References 92 publications

Analyzing the electrogenicity of cytochrome c oxidase

Analyzing the electrogenicity of cytochrome c oxidase

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

A novel theoretical framework reveals more than one voltage-sensing pathway in the lateral membrane of outer hair cells

Contact Info

Product

Resources

About

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