Subunit Rotation Research Articles

How subunit rotation controls tRNA dynamics in the ribosome.

In order to translate messenger RNA into proteins, the ribosome must coordinate a wide range of conformational rearrangements. Some steps involve individual molecules, whereas others require synchronization of multiple collective motions. For example, the ribosomal "small" subunit (∼1 MDa) is known to undergo rotational motion (∼ 10 ◦ ) that is correlated with large-scale displacements of tRNA molecules (∼50Å). While decades of biochemical, single-molecule and structural analysis have provided many insights into the timing of these motions, little is known about how these dynamical processes influence each other. To address this, we use molecular simulations to isolate specific interactions that allow tRNA kinetics to be controlled by subunit rotation. Specifically, we applied an all-atom structure-based model to perform molecular simulations of P/E hybrid formation, a process by which the tRNA molecules are displaced between ribosomal binding sites. By varying the extent of subunit rotation in each simulation, these calculations reveal a pronounced non-monotonic dependence of tRNA kinetics on subunit rotation. That is, tRNA kinetics increase and then decrease as the subunit is rotated. We further show that this behavior is due to the steric contributions of a single ribosomal protein. Together, these calculations provide insights into the physicochemical properties of the ribosome, while establishing a strategy for isolating causal relationships in biomolecular assemblies.

The molecular structure of an axle-less F1-ATPase

F1Fo ATP synthase is a molecular rotary motor that can generate ATP using a transmembrane proton motive force. Isolated F1-ATPase catalytic cores can hydrolyse ATP, passing through a series of conformational states involving rotation of the central γ rotor subunit and the opening and closing of the catalytic β subunits. Cooperativity in F1-ATPase has long thought to be conferred through the γ subunit, with three key interaction sites between the γ and β subunits being identified. Single molecule studies have demonstrated that the F1 complexes lacking the γ axle still “rotate” and hydrolyse ATP, but with less efficiency. We solved the cryogenic electron microscopy structure of an axle-less Bacillus sp. PS3 F1-ATPase. The unexpected binding-dwell conformation of the structure in combination with the observed lack of interactions between the axle-less γ and the open β subunit suggests that the complete γ subunit is important for coordinating efficient ATP binding of F1-ATPase.

Direct observation of subunit rotation during DNA strand exchange by serine recombinases

Serine recombinases are proposed to catalyse site-specific recombination by a unique mechanism called subunit rotation. Cutting and rejoining DNA occurs within an intermediate synaptic complex comprising a recombinase tetramer bound to two DNA sites. After double-strand cleavage at both sites, one half of the complex rotates 180° relative to the other, before re-ligation of the DNA ends. We used single-molecule FRET (smFRET) methods to provide compelling direct physical evidence for subunit rotation by recombinases Tn3 resolvase and Sin. Synaptic complexes containing fluorescently labelled DNA show FRET fluctuations consistent with the subunit rotation model. FRET changes were associated with the rotation steps, on a timescale of 0.4–1.1 s−1\\documentclass[12pt]{minimal} \\usepackage{amsmath} \\usepackage{wasysym} \\usepackage{amsfonts} \\usepackage{amssymb} \\usepackage{amsbsy} \\usepackage{mathrsfs} \\usepackage{upgreek} \\setlength{\\oddsidemargin}{-69pt} \\begin{document}$${{\\mbox{s}}}^{-1}$$\\end{document}, as well as opening and closing of the gap between the scissile phosphates during cleavage and ligation. Multiple rounds of recombination were observed within the ~25 s observation period, including frequent consecutive rotation events in the cleaved-DNA state without evidence of intermediate ligation.

Substeps during subunit rotation in single FoF1-ATP synthase trapped in solution

Substeps during subunit rotation in single FoF1-ATP synthase trapped in solution

The molecular structure of an axle-less F1-ATPase.

F1Fo ATP synthase is a molecular rotary motor that can generate ATP using a transmembrane proton motive force. Isolated F1-ATPase catalytic cores can hydrolyse ATP, passing through a series of conformational states involving rotation of the central γ rotor subunit and the opening and closing of the catalytic β subunits. Cooperativity in F1-ATPase has long thought to be conferred through the γ subunit, with three key interaction sites between the γ and β subunits being identified. Single molecule studies have demonstrated that the F1 complexes lacking the γ axle still "rotate" and hydrolyse ATP, but with less efficiency. We solved the cryogenic electron microscopy structure of an axle-less Bacillus sp. PS3 F1-ATPase. The unexpected binding-dwell conformation of the structure in combination with the observed lack of interactions between the axle-less γ and the open β subunit suggests that the complete γ subunit is important for coordinating efficient ATP binding of F1-ATPase.

Structural dynamics of the heme pocket and intersubunit coupling in the dimeric hemoglobin from Scapharca inaequivalvis.

Cooperativity is essential for the proper functioning of numerous proteins by allosteric interactions. Hemoglobin from Scapharca inaequivalvis (HbI) is a homodimeric protein that can serve as a minimal unit for studying cooperativity. We investigated the structural changes in HbI after carbon monoxide dissociation using time-resolved resonance Raman spectroscopy and observed structural rearrangements in the Fe-proximal histidine bond, the position of the heme in the pocket, and the hydrogen bonds between heme and interfacial water upon ligand dissociation. Some of the spectral changes were different from those observed for human adult hemoglobin due to differences in subunit assembly and quaternary changes. The structural rearrangements were similar for the singly and doubly dissociated species but occurred at different rates. The rates of the observed rearrangements indicated that they occurred synchronously with subunit rotation and are influenced by intersubunit coupling, which underlies the positive cooperativity of HbI.

Coupled Rotary Motion in Molecular Motors.

Biological molecular machines play a pivotal role in sustaining life by producing a controlled and directional motion. Artificial molecular machines aim to mimic this motion, to exploit and tune the nanoscale produced motion to power dynamic molecular systems. The precise control, transfer, and amplification of the molecular-level motion is crucial to harness the potential of synthetic molecular motors. It is intriguing to establish how directional motor rotation can be utilized to drive secondary motions in other subunits of a multicomponent molecular machine. The challenge to design sophisticated synthetic machines involving multiple motorized elements presents fascinating opportunities for achieving unprecedented functions, but these remain almost unexplored due to their extremely intricate behavior. Here we show intrinsic coupled rotary motion in light-driven overcrowded-alkene based molecular motors. Thus far, molecular motors with two rotors have been understood to undergo independent rotation of each subunit. The new bridged-isoindigo motor design revealed an additional dimension to the motor's unidirectional operation mechanism where communication between the rotors occurs. An unprecedented double metastable state intermediate bridges the rotation cycles of the two rotor subunits. Our findings demonstrate how neighboring motorized subunits can affect each other and thereby drastically change the motor's functioning. Controlling the embedded entanglement of active intramolecular components sets the stage for more advanced artificial molecular machines.

A novel anti-missing-rib lozenge lattice metamaterial with enhanced mechanical properties

In this work, a novel anti-missing-rib lozenge lattice metamaterial (ALLM) is designed. Besides, its mechanical properties are enhanced by introducing lateral and longitudinal auxiliary ribs. The mechanical properties and elasto-plastic deformation behaviors of the proposed metamaterials are systematically investigated through quasi-static compression experiments and finite element analysis. The results show that the designed ALLM exhibits distinct negative Poisson’s ratio (NPR) characteristics and superior specific energy absorption (SEA) capacity. The novel design concurrently enhances the stiffness while preserving the inherent NPR of ALLM. The effects of missing-rib lozenge subunit rotation angles, auxiliary rib configuration, and ligament width on the deformation patterns, energy absorption, stiffness, and NPR of the resulting metamaterials are investigated by parametric analysis. This study provides a reference for the design of tunable lozenge grid missing-rib lattice metamaterials.

The series of conformational states adopted by rotorless F1-ATPase during its hydrolysis cycle

F1Fo ATP synthase interchanges phosphate transfer energy and proton motive force via a rotary catalytic mechanism and isolated F1-ATPase subcomplexes can also hydrolyze ATP to generate rotation of their central γ rotor subunit. As ATP is hydrolyzed, the F1-ATPase cycles through a series of conformational states that mediates unidirectional rotation of the rotor. However, even in the absence of a rotor, the α and β subunits are still able to pass through a series of conformations, akin to those that generate rotation. Here, we use cryoelectron microscopy to establish the structures of these rotorless states. These structures indicate that cooperativity in this system is likely mediated by contacts between the β subunit lever domains, irrespective of the presence of the γ rotor subunit. These findings provide insight into how long-range information may be transferred in large biological systems.

Mechanism of ADP-Inhibited ATP Hydrolysis in Single Proton-Pumping FoF1-ATP Synthase Trapped in Solution.

FoF1-ATP synthases in mitochondria, in chloroplasts, and in most bacteria are proton-driven membrane enzymes that supply the cells with ATP made from ADP and phosphate. Different control mechanisms exist to monitor and prevent the enzymes' reverse chemical reaction of fast wasteful ATP hydrolysis, including mechanical or redox-based blockade of catalysis and ADP inhibition. In general, product inhibition is expected to slow down the mean catalytic turnover. Biochemical assays are ensemble measurements and cannot discriminate between a mechanism affecting all enzymes equally or individually. For example, all enzymes could work more slowly at a decreasing substrate/product ratio, or an increasing number of individual enzymes could be completely blocked. Here, we examined the effect of increasing amounts of ADP on ATP hydrolysis of single Escherichia coli FoF1-ATP synthases in liposomes. We observed the individual catalytic turnover of the enzymes one after another by monitoring the internal subunit rotation using single-molecule Förster resonance energy transfer (smFRET). Observation times of single FRET-labeled FoF1-ATP synthases in solution were extended up to several seconds using a confocal anti-Brownian electrokinetic trap (ABEL trap). By counting active versus inhibited enzymes, we revealed that ADP inhibition did not decrease the catalytic turnover of all FoF1-ATP synthases equally. Instead, increasing ADP in the ADP/ATP mixture reduced the number of remaining active enzymes that operated at similar catalytic rates for varying substrate/product ratios.

Dependence of P/E tRNA hybrid formation on subunit rotation in the ribosome.

The ribosome, a massive nucleoprotein assembly that executes protein synthesis in all living cells, undergoes several large-scale functional rearrangements during the protein elongation cycle. Here we explore two such rearrangements in the ribosome bound tRNA molecules during the translocation step in bacteria, namely, P/E tRNA hybrid formation and inter-subunit rotation in the ribosome. We utilize multi-basin all-atom structure-based models and Ribosome Angle Decomposition (RAD) method to study the dependence of P/E hybrid formation on rotation of small subunit body with respect to the large subunit. Structure-based models provide simplified energetics with experimental atomic structures defined to be the potential energy minima. We employ these models to simulate spontaneous transition of the P-tRNA from P to E tRNA binding site on the large subunit for different degrees of small subunit body rotation. RAD method provides a complete coordinate system that describes any orientation of the ribosomal small subunit body and head in terms of rotation, tilt, tilt direction and translation. We identify reference E. coli structures at different degrees of body rotation but with minimal body tilt, head rotation and head tilt from the Ribosome Analysis Database based on RAD. Utilizing these methods, we explore the influence of subunit rotation on the free-energy barrier associated with P/E tRNA hybrid formation and obtain the quantitative dependence of P/E hybrid formation on subunit rotation.

Structural basis of V-ATPase VO region assembly by Vma12p, 21p, and 22p

Vacuolar-type adenosine triphosphatases (V-ATPases) are rotary proton pumps that acidify specific intracellular compartments in almost all eukaryotic cells. These multi-subunit enzymes consist of a soluble catalytic V1 region and a membrane-embedded proton-translocating VO region. VO is assembled in the endoplasmic reticulum (ER) membrane, and V1 is assembled in the cytosol. However, V1 binds VO only after VO is transported to the Golgi membrane, thereby preventing acidification of the ER. We isolated VO complexes and subcomplexes from Saccharomyces cerevisiae bound to V-ATPase assembly factors Vma12p, Vma21p, and Vma22p. Electron cryomicroscopy shows how the Vma12-22p complex recruits subunits a, e, and f to the rotor ring of VO while blocking premature binding of V1. Vma21p, which contains an ER-retrieval motif, binds the VO:Vma12-22p complex, "mature" VO, and a complex that appears to contain a ring of loosely packed rotor subunits and the proteins YAR027W and YAR028W. The structures suggest that Vma21p binds assembly intermediates that contain a rotor ring and that activation of proton pumping following assembly of V1 with VO removes Vma21p, allowing V-ATPase to remain in the Golgi. Together, these structures show how Vma12-22p and Vma21p function in V-ATPase assembly and quality control, ensuring the enzyme acidifies only its intended cellular targets.

Conformational dynamics of eukaryotic translation.

The ribosome is a molecular machine that adopts multiple conformations during translation. The body of the small ribosomal subunit rotates relatively to the large ribosomal subunit by about 9 degrees. This movement reconfigures tRNA binding sites, which results in a partial movement of tRNAs on the ribosome. At the beginning of the elongation cycle, the ribosome awaits A-site decoding and occupies the non-rotated conformation. Upon A-site tRNA binding, the ribosome rapidly catalyzes peptidyl transfer. It is followed by counterclockwise rotations of the small ribosomal subunit that puts the ribosome into the rotated state. The resultant pre-translocation complex is dynamic and exchanges between rotated and non-rotated conformations. Eukaryotic elongation factor 2 (eEF2) catalyzes translocation, which moves tRNA-mRNA and resets the ribosome into the non-rotated state. Despite extensive biochemical and structural studies, the underlying mechanism of translation elongation remains elusive. We developed a single-molecule fluorescence resonance energy transfer (smFRET) system that allows the observation of intersubunit conformational change of yeast ribosomes in real-time. We followed the ribosome conformational change in pre- and post-translocation ribosome complexes. To interrogate the mechanism of translocation, we applied antifungal sordarin. Sordarin stabilizes eEF2 on the ribosome after GTP hydrolysis and phosphate release. Our results suggest that in the presence of sordarin, the mid and late stages of translocation are thermally driven.

Understanding the energetics of translation in bacterial and eukaryotic ribosomes.

Protein synthesis by the ribosome involves a wide range of large-scale conformational rearrangements. While structural methods have provided exquisite snapshots of this machine during function, and single-molecule methods have tracked transitions between stable conformations, the kinetics is ultimately controlled by free-energy barriers. To begin to probe these barriers and identify the interactions that are characteristic of the associated transition states, we are developing and applying a range of atomic-resolution models that employ simplified energetic representations (i.e. structure-based SMOG models). While early applications of these models illustrated the relationship between tRNA structure and kinetics, newer variants have allowed for larger-scale motions and ionic effects to be studied. As an example, recent efforts have shown how entropy contributes to the dynamics of subunit rotation in the yeast ribosome, where the “small” (∼1 MDa) subunit undergoes reversible ∼10-degree rotations. Similar strategies have elucidated the influence of key ribosomal proteins during hybrid-state formation in the human mitoribosome. In addition, recently developed explicit-ion models have shown that small changes in ionic concentrations can control rate-limiting free-energy barriers during tRNA rearrangements (e.g. accommodation) on the ribosome. Together, these efforts are uncovering the intricate balance of energetic factors that control translation across the kingdoms of life.

Ratchet, swivel, tilt and roll: a complete description of subunit rotation in the ribosome.

Protein synthesis by the ribosome requires large-scale rearrangements of the 'small' subunit (SSU; ∼1 MDa), including inter- and intra-subunit rotational motions. However, with nearly 2000 structures of ribosomes and ribosomal subunits now publicly available, it is exceedingly difficult to design experiments based on analysis of all known rotation states. To overcome this, we developed an approach where the orientation of each SSU head and body is described in terms of three angular coordinates (rotation, tilt and tilt direction) and a single translation. By considering the entire RCSB PDB database, we describe 1208 fully-assembled ribosome complexes and 334 isolated small subunits, which span >50 species. This reveals aspects of subunit rearrangements that are universal, and others that are organism/domain-specific. For example, we show that tilt-like rearrangements of the SSU body (i.e. 'rolling') are pervasive in both prokaryotic and eukaryotic (cytosolic and mitochondrial) ribosomes. As another example, domain orientations associated with frameshifting in bacteria are similar to those found in eukaryotic ribosomes. Together, this study establishes a common foundation with which structural, simulation, single-molecule and biochemical efforts can more precisely interrogate the dynamics of this prototypical molecular machine.

Proton Pumping ATPases: Rotational Catalysis, Physiological Roles in Oral Pathogenic Bacteria, and Inhibitors.

Proton pumping ATPases, both F-type and V/A-type ATPases, generate ATP using electrochemical energy or pump protons/sodium ions by hydrolyzing ATP. The enzymatic reaction and proton transport are coupled through subunit rotation, and this unique rotational mechanism (rotational catalysis) has been intensively studied. Single-molecule and thermodynamic analyses have revealed the detailed rotational mechanism, including the catalytically inhibited state and the roles of subunit interactions. In mammals, F- and V-ATPases are involved in ATP synthesis and organelle acidification, respectively. Most bacteria, including anaerobes, have F- and/or A-ATPases in the inner membrane. However, these ATPases are not believed to be essential in anaerobic bacteria since anaerobes generate sufficient ATP without oxidative phosphorylation. Recent studies suggest that F- and A-ATPases perform indispensable functions beyond ATP synthesis in oral pathogenic anaerobes; F-ATPase is involved in acid tolerance in Streptococcus mutans, and A-ATPase mediates nutrient import in Porphyromonas gingivalis. Consistently, inhibitors of oral bacterial F- and A-ATPases, such as phytopolyphenols and bedaquiline, strongly diminish growth and survival. Herein, we discuss rotational catalysis of bacterial F- and A-ATPases, and discuss their physiological roles, focusing on oral bacteria. We also review the effects of ATPase inhibitors on the growth and survival of oral pathogenic bacteria. The features of the catalytic mechanism and unique physiological roles in oral bacteria highlight the potential for proton pumping ATPases to serve as targets for oral antimicrobial agents.

Druggable differences: Targeting mechanistic differences between trans-translation and translation for selective antibiotic action.

Bacteria usetrans-translation to rescue stalled ribosomes and target incomplete proteins for proteolysis. Despite similarities between tRNAs and transfer-messenger RNA (tmRNA), the key molecule fortrans-translation, new structural and biochemical data show important differences between translation andtrans-translation at most steps of the pathways. tmRNA and its binding partner, SmpB, bind in the A site of the ribosome but do not trigger the same movements of nucleotides in the rRNA that are required for codon recognition by tRNA. tmRNA-SmpB moves from the A site to the P site of the ribosome without subunit rotation to generate hybrid states, and moves from the P site to a site outside the ribosome instead of to the E site. During catalysis, transpeptidation to tmRNA appears to require the ribosomal protein bL27, which is dispensable for translation, suggesting that this protein may be conserved in bacteria due totrans-translation. These differences provide insights into the fundamental nature oftrans-translation, and provide targets for new antibiotics that may have decrease cross-reactivity with eukaryotic ribosomes.

Computational Design of Inhibitors Targeting the Catalytic β Subunit of Escherichia coli FOF1-ATP Synthase.

With the uncontrolled growth of multidrug-resistant bacteria, there is an urgent need to search for new therapeutic targets, to develop drugs with novel modes of bactericidal action. FoF1-ATP synthase plays a crucial role in bacterial bioenergetic processes, and it has emerged as an attractive antimicrobial target, validated by the pharmaceutical approval of an inhibitor to treat multidrug-resistant tuberculosis. In this work, we aimed to design, through two types of in silico strategies, new allosteric inhibitors of the ATP synthase, by targeting the catalytic β subunit, a centerpiece in communication between rotor subunits and catalytic sites, to drive the rotary mechanism. As a model system, we used the F1 sector of Escherichia coli, a bacterium included in the priority list of multidrug-resistant pathogens. Drug-like molecules and an IF1-derived peptide, designed through molecular dynamics simulations and sequence mining approaches, respectively, exhibited in vitro micromolar inhibitor potency against F1. An analysis of bacterial and Mammalia sequences of the key structural helix-turn-turn motif of the C-terminal domain of the β subunit revealed highly and moderately conserved positions that could be exploited for the development of new species-specific allosteric inhibitors. To our knowledge, these inhibitors are the first binders computationally designed against the catalytic subunit of FOF1-ATP synthase.

Conformational changes and CO2-induced channel gating in connexin26

SummaryConnexins form large-pore channels that function either as dodecameric gap junctions or hexameric hemichannels to allow the regulated movement of small molecules and ions across cell membranes. Opening or closing of the channels is controlled by a variety of stimuli, and dysregulation leads to multiple diseases. An increase in the partial pressure of carbon dioxide (PCO2) has been shown to cause connexin26 (Cx26) gap junctions to close. Here, we use cryoelectron microscopy (cryo-EM) to determine the structure of human Cx26 gap junctions under increasing levels of PCO2. We show a correlation between the level of PCO2 and the size of the aperture of the pore, governed by the N-terminal helices that line the pore. This indicates that CO2 alone is sufficient to cause conformational changes in the protein. Analysis of the conformational states shows that movements at the N terminus are linked to both subunit rotation and flexing of the transmembrane helices.

Dependence of tRNA dynamics on subunit rotation in the ribosome

Large-scale conformational rearrangements in biomolecular assemblies can be crucial to their functional dynamics. We investigate the functional rearrangements in a massive nucleoprotein assembly present in all living cells, the ribosome. It is responsible for protein synthesis, which requires several large-scale structural rearrangements in the ribosome bound tRNA molecules. To probe the energetics of the ribosome, we employ all-atom structure-based models and molecular dynamics simulations. Structure-based models provide simplified energetic descriptions, where experimentally obtained atomic structures are defined to be potential energy minima.