Elucidation of the stator organization in the V-ATPase of Neurospora crassa

V-ATPases are membrane protein complexes that pump protons in the lumen of various subcellular compartments at the expense of ATP. Proton pumping is done by a rotary mechanism that requires a static connection between the membrane pumping domain (V(0)) and the extrinsic catalytic head (V(1)). This static connection is composed of several known subunits of the V-ATPase, but their location and topological relationships are still a matter of controversy. Here, we propose a model for the V-ATPase of Neurospora crassa on the basis of single-particle analysis by electron microscopy. Comparison of the resulting map to that of the A-ATPase from Thermus thermophilus allows the positioning of two subunits in the static connecting region that are unique to eukaryotic V-ATPases (C and H). These two subunits seem to be located on opposite sides of a semicircular arrangement of the peripheral connecting elements, suggesting a role in stabilizing the stator in V-ATPases.     

The Helix Rearrangement in the Periplasmic Domain of the Flagellar Stator B Subunit Activates Peptidoglycan Binding and Ion Influx

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The b Subunit of Escherichia coli ATP Synthase

The b subunit of ATP synthase is a major component of the second stalk connecting the F₁and F₀ sectors of the enzyme and is essential for normal assembly and function. The156-residue b subunit of the Escherichia coli ATP synthase has been investigated extensivelythrough mutagenesis, deletion analysis, and biophysical characterization. The two copies ofb exist as a highly extended, helical dimer extending from the membrane to near the top ofF₁, where they interact with the subunit. The sequence has been divided into four domains:the N-terminal membrane-spanning domain, the tether domain, the dimerization domain, andthe C-terminal -binding domain. The dimerization domain, contained within residues 60–122,has many properties of a coiled-coil, while the -binding domain is more globular. Sites ofcrosslinking between b and the a, , , and subunits of ATP synthase have been identified,and the functional significance of these interactions is under investigation. The b dimer mayserve as an elastic element during rotational catalysis in the enzyme, but also directly influencesthe catalytic sites, suggesting a more active role in coupling.     

Direct observation of speed fluctuations of flagellar motor rotation at extremely low load close to zero

The bacterial flagellar motor accommodates ten stator units around the rotor to produce large torque at high load. But when external load is low, some previous studies showed that a single stator unit can spin the rotor at the maximum speed, suggesting that the maximum speed does not depend on the number of active stator units, whereas others reported that the speed is also dependent on the stator number. To clarify these two controversial observations, much more precise measurements of motor rotation would be required at external load as close to zero as possible. Here, we constructed a Salmonella filament-less mutant that produces a rigid, straight, twice longer hook to efficiently label a 60 nm gold particle and analyzed flagellar motor dynamics at low load close to zero. The maximum motor speed was about 400 Hz. Large speed fluctuations and long pausing events were frequently observed, and they were suppressed by either over-expression of the MotAB stator complex or increase in the external load, suggesting that the number of active stator units in the motor largely fluctuates near zero load. We conclude that the lifetime of the active stator unit becomes much shorter when the motor operates near zero load.     

Cross-linking of the endogenous inhibitor protein (IF1) with rotor (gamma,epsilon) and stator (alpha) subunits of the mitochondrial ATP synthase

The location of the endogenous inhibitor protein ( IF₁) in the rotor/stator architecture of the bovine mitochondrial ATP synthase was studied by reversible cross-linking with dithiobis(succinimidylpropionate) in soluble F₁I and intact F₁F₀I complexes of submitochondrial particles. Reducing two-dimensional electrophoresis, Western blotting, and fluorescent cysteine labeling showed formation of –IF₁, IF₁–IF₁, –IF₁, and –IF₁ cross-linkages in soluble F₁I and in native F₁F₀I complexes. Cross-linking blocked the release of IF₁ from its inhibitory site and therefore the activation of F₁I and F₁F₀I complexes in a dithiothreitol-sensitive process. These results show that the endogenous IF₁ is at a distance 12 Å,to and subunits of the central rotor of the native mitochondrial ATP synthase. This finding strongly suggests that, without excluding the classical assumption that IF₁ inhibits conformational changes of the catalytic subunits, the inhibitory mechanism of IF₁ may involve the interference with rotation of the central stalk.     

Subunit Composition, Structure, and Distribution of Bacterial V-Type ATPases

The overall structure of V-ATPase complexes resembles that of F-type ATPases, but the stalk region is different and more complex. Database searches followed by sequence analysis of the five water-soluble stalk region subunits C–G revealed that (i) to date V-ATPases are found in 16 bacterial species, (ii) bacterial V-ATPases are closer to archaeal A-ATPases than to eukaryotic V-ATPases, and (iii) different groups of bacterial V-ATPases exist. Inconsistencies in the nomenclature of types and subunits are addressed. Attempts to assign subunit positions in V-ATPases based on biochemical experiments, chemical cross-linking, and electron microscopy are discussed. A structural model for prokaryotic and eukaryotic V-ATPases is proposed. The prokaryotic V-ATPase is considered to have a central stalk between headpiece and membrane flanked by two peripheral stalks. The eukaryotic V-ATPases have one additional peripheral stalk.     

Mutagenic Analysis of the F 0 Stator Subunits

The a and b subunits constitute the stator elements in the F₀ sector of F₁F₀-ATP synthase.Both subunits have been difficult to study by physical means, so most of the information onstructure and function relationships in the a and b subunits has been obtained using mutagenesisin combination with biochemical methods. These approaches were used to demonstrate thatthe a subunit in association with the ring of c subunits houses the proton channel throughF₁F₀-ATP synthase. The map of the amino acids contributing to the proton channel is probablycomplete. The two b subunits dimerize, forming an extended flexible unit in the peripheralstalk linking the F₁ and F₀ sectors. The unique characteristics of specific amino acid substitutionsaffecting the a and b subunits suggested differential effects on rotation during F₁F₀-ATPaseactivity.     

Electron cryomicroscopic visualization of PomA/B stator units of the sodium-driven flagellar motor in liposomes

A motor protein complex of the bacterial flagellum, PomA/B from Vibrio alginolyticus, was reconstituted into liposomes and visualized by electron cryomicroscopy. PomA/B is a sodium channel, composed of two membrane proteins, PomA and PomB, and converts ion flux to the rotation of the flagellar motor. Escherichia coli and Salmonella have a homolog called MotA/B, which utilizes proton instead of sodium ion. PomB and MotB have a peptidoglycan-binding motif in their C-terminal region, and therefore PomA/B and MotA/B are regarded as the stator. Energy filtering electron cryomicroscopy enhanced the image contrast of the proteins reconstituted into liposomes and showed that two extramembrane domains with clearly different sizes stick out of the lipid bilayers on opposite sides. Image analysis combined with gold labeling and deletion of the peptidoglycan-binding motif revealed that the longer one, approximately 70 A long, is likely to correspond to the periplasmic domain, and the other, about half size, to the cytoplasmic domain.     

Subunit Exchange in Protein Complexes

Over the past 50?years, protein complexes have been studied with techniques such as X-ray crystallography and electron microscopy, generating images which although detailed are static and homogeneous. More recently, limited application of in vivo fluorescence and other techniques has revealed that many complexes previously thought stable and compositionally uniform are dynamically variable, continually exchanging components with a freely circulating pool of “spares.” Here, we consider the purpose and prevalence of protein exchange, first reviewing the ongoing story of exchange in the bacterial flagella motor, before surveying reports of exchange in complexes across all domains of life, together highlighting great diversity in timescales and functions. Finally, we put this in the context of high-throughput proteomic studies which hint that exchange might be the norm, rather than an exception.