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1. Eukaryotic yeast V1-ATPase rotary mechanism insights revealed by high-resolution single-molecule studies

   https://doi.org/10.3389/fmolb.2024.1269040  

   Yanagisawa, Seiga; Bukhari, Zain A; Parra, Karlett J; Frasch, Wayne D (March 2024, Frontiers in Molecular Biosciences)

   Vacuolar ATP-dependent proton pumps (V-ATPases) belong to a super-family of rotary ATPases and ATP synthases. The V₁complex consumes ATP to drive rotation of a central rotor that pumps protons across membranes via the V_ocomplex. Eukaryotic V-ATPases are regulated by reversible disassembly of subunit C, V₁without C, and V_O.ATP hydrolysis is thought to generate an unknown rotary state that initiates regulated disassembly. Dissociated V₁is inhibited by subunit H that traps it in a specific rotational position. Here, we report the first single-molecule studies with high resolution of time and rotational position ofSaccharomyces cerevisiaeV₁-ATPase lacking subunits H and C (V₁ΔHC), which resolves previously elusive dwells and angular velocity changes. Rotation occurred in 120° power strokes separated by dwells comparable to catalytic dwells observed in other rotary ATPases. However, unique V₁ΔHC rotational features included: 1) faltering power stroke rotation during the first 60°; 2) a dwell often occurring ∼45° after the catalytic dwell, which did not increase in duration at limiting MgATP; 3) a second dwell, ∼2-fold longer occurring 112° that increased in duration and occurrence at limiting MgATP; 4) limiting MgATP-dependent decreases in power stroke angular velocity where dwells were not observed. The results presented here are consistent with MgATP binding to the empty catalytic site at 112° and MgADP released at ∼45°, and provide important new insight concerning the molecular basis for the differences in rotary positions of substrate binding and product release between V-type and F-type ATPases. 

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2. A nanoscale reciprocating rotary mechanism with coordinated mobility control

   https://doi.org/10.1038/s41467-021-27230-7  

   Bertosin, Eva; Maffeo, Christopher M.; Drexler, Thomas; Honemann, Maximilian N.; Aksimentiev, Aleksei; Dietz, Hendrik (December 2021, Nature Communications)

   Abstract Biological molecular motors transform chemical energy into mechanical work by coupling cyclic catalytic reactions to large-scale structural transitions. Mechanical deformation can be surprisingly efficient in realizing such coupling, as demonstrated by the F 1 F O ATP synthase. Here, we describe a synthetic molecular mechanism that transforms a rotary motion of an asymmetric camshaft into reciprocating large-scale transitions in a surrounding stator orchestrated by mechanical deformation. We design the mechanism using DNA origami, characterize its structure via cryo-electron microscopy, and examine its dynamic behavior using single-particle fluorescence microscopy and molecular dynamics simulations. While the camshaft can rotate inside the stator by diffusion, the stator’s mechanics makes the camshaft pause at preferred orientations. By changing the stator’s mechanical stiffness, we accelerate or suppress the Brownian rotation, demonstrating an allosteric coupling between the camshaft and the stator. Our mechanism provides a framework for manufacturing artificial nanomachines that function because of coordinated movements of their components. 

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3. pH-dependent 11° F1FO ATP synthase sub-steps reveal insight into the FO torque generating mechanism

   https://doi.org/10.7554/eLife.70016  

   Yanagisawa, Seiga; Frasch, Wayne D (December 2021, eLife)

   Most cellular ATP is made by rotary F 1 F O ATP synthases using proton translocation-generated clockwise torque on the F O c-ring rotor, while F 1 -ATP hydrolysis can force counterclockwise rotation and proton pumping. The F O torque-generating mechanism remains elusive even though the F O interface of stator subunit-a, which contains the transmembrane proton half-channels, and the c-ring is known from recent F 1 F O structures. Here, single-molecule F 1 F O rotation studies determined that the pKa values of the half-channels differ, show that mutations of residues in these channels change the pKa values of both half-channels, and reveal the ability of F O to undergo single c-subunit rotational stepping. These experiments provide evidence to support the hypothesis that proton translocation through F O operates via a Grotthuss mechanism involving a column of single water molecules in each half-channel linked by proton translocation-dependent c-ring rotation. We also observed pH-dependent 11° ATP synthase-direction sub-steps of the Escherichia coli c 10 -ring of F 1 F O against the torque of F 1 -ATPase-dependent rotation that result from H + transfer events from F O subunit-a groups with a low pKa to one c-subunit in the c-ring, and from an adjacent c-subunit to stator groups with a high pKa. These results support a mechanism in which alternating proton translocation-dependent 11° and 25° synthase-direction rotational sub-steps of the c 10 -ring occur to sustain F 1 F O ATP synthesis. 

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4. The electronic structure of genome editors from the first principles

   https://doi.org/10.1088/2516-1075/acb410  

   Nierzwicki, Łukasz; Ahsan, Mohd; Palermo, Giulia (February 2023, Electronic Structure)

   Abstract Ab-initio molecular dynamics enables following the dynamics of biological systems from the first principles, describing the electronic structure and offering the opportunity to “watch” the evolution of biochemical processes with unique resolution, beyond the capabilities of state-of-the-art experimental techniques. This article reports the role of first-principles ( ab-initio ) molecular dynamics (MD) in the CRISPR-Cas9 genome editing revolution, achieving a profound understanding of the enzymatic function and offering valuable insights for enzyme engineering. We introduce the methodologies and explain the use of ab-initio MD simulations to establish the two-metal dependent mechanism of DNA cleavage in the RuvC domain of the Cas9 enzyme, and how a second catalytic domain, HNH, cleaves the target DNA with the aid of a single metal ion. A detailed description of how ab-initio MD is combined with free-energy methods—i.e., thermodynamic integration and metadynamics—to break and form chemical bonds is given, explaining the use of these methods to determine the chemical landscape and establish the catalytic mechanism in CRISPR-Cas9. The critical role of classical methods is also discussed, explaining theory and application of constant pH MD simulations, used to accurately predict the catalytic residues’ protonation states. Overall, first-principles methods are shown to unravel the electronic structure and reveal the catalytic mechanism of the Cas9 enzyme, providing valuable insights that can serve for the design of genome editing tools with improved catalytic efficiency or controllable activity. 

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5. F1FO ATP synthase molecular motor mechanisms

   https://doi.org/10.3389/fmicb.2022.965620  

   Frasch, Wayne D.; Bukhari, Zain A.; Yanagisawa, Seiga (August 2022, Frontiers in Microbiology)

   The F-ATP synthase, consisting of F 1 and F O motors connected by a central rotor and the stators, is the enzyme responsible for synthesizing the majority of ATP in all organisms. The F 1 (αβ) 3 ring stator contains three catalytic sites. Single-molecule F 1 rotation studies revealed that ATP hydrolysis at each catalytic site (0°) precedes a power-stroke that rotates subunit-γ 120° with angular velocities that vary with rotational position. Catalytic site conformations vary relative to subunit-γ position (β E , empty; β D , ADP bound; β T , ATP-bound). During a power stroke, β E binds ATP (0°–60°) and β D releases ADP (60°–120°). Årrhenius analysis of the power stroke revealed that elastic energy powers rotation via unwinding the γ-subunit coiled-coil. Energy from ATP binding at 34° closes β E upon subunit-γ to drive rotation to 120° and forcing the subunit-γ to exchange its tether from β E to β D , which changes catalytic site conformations. In F 1 F O , the membrane-bound F O complex contains a ring of c-subunits that is attached to subunit-γ. This c-ring rotates relative to the subunit-a stator in response to transmembrane proton flow driven by a pH gradient, which drives subunit-γ rotation in the opposite direction to force ATP synthesis in F 1 . Single-molecule studies of F 1 F O embedded in lipid bilayer nanodisks showed that the c-ring transiently stopped F 1 -ATPase-driven rotation every 36° (at each c-subunit in the c 10 -ring of E. coli F 1 F O ) and was able to rotate 11° in the direction of ATP synthesis. Protonation and deprotonation of the conserved carboxyl group on each c-subunit is facilitated by separate groups of subunit-a residues, which were determined to have different pKa’s. Mutations of any of any residue from either group changed both pKa values, which changed the occurrence of the 11° rotation proportionately. This supports a Grotthuss mechanism for proton translocation and indicates that proton translocation occurs during the 11° steps. This is consistent with a mechanism in which each 36° of rotation the c-ring during ATP synthesis involves a proton translocation-dependent 11° rotation of the c-ring, followed by a 25° rotation driven by electrostatic interaction of the negatively charged unprotonated carboxyl group to the positively charged essential arginine in subunit-a. 

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