Masamitsu Futai

The V-type H+-ATPase in vesicular trafficking: targeting, regulation and function.

n n Vacuolar-type H+-ATPase (V-ATPase)-driven proton pumping and organellar acidification is essential for vesicular trafficking along both the exocytotic and endocytotic pathways of eukaryotic cells. Deficient function of V-ATPase and defects of vesicular acidification have been recently recognized as important mechanisms in a variety of human diseases and are emerging as potential therapeutic targets. In the past few years, significant progress has been made in our understanding of function, regulation, and the cell biological role of V-ATPase. Here, we will review these studies with emphasis on novel direct roles of V-ATPase in the regulation of vesicular trafficking events.n n

The mechanism of rotating proton pumping ATPases.

Two proton pumps, the F-ATPase (ATP synthase, FoF1) and the V-ATPase (endomembrane proton pump), have different physiological functions, but are similar in subunit structure and mechanism. They are composed of a membrane extrinsic (F1 or V1) and a membrane intrinsic (Fo or Vo) sector, and couple catalysis of ATP synthesis or hydrolysis to proton transport by a rotational mechanism. The mechanism of rotation has been extensively studied by kinetic, thermodynamic and physiological approaches. Techniques for observing subunit rotation have been developed. Observations of micron-length actin filaments, or polystyrene or gold beads attached to rotor subunits have been highly informative of the rotational behavior of ATP hydrolysis-driven rotation. Single molecule FRET experiments between fluorescent probes attached to rotor and stator subunits have been used effectively in monitoring proton motive force-driven rotation in the ATP synthesis reaction. By using small gold beads with diameters of 40-60 nm, the E. coli F1 sector was found to rotate at surprisingly high speeds (>400 rps). This experimental system was used to assess the kinetics and thermodynamics of mutant enzymes. The results revealed that the enzymatic reaction steps and the timing of the domain interactions among the beta subunits, or between the beta and gamma subunits, are coordinated in a manner that lowers the activation energy for all steps and avoids deep energy wells through the rotationally-coupled steady-state reaction. In this review, we focus on the mechanism of steady-state F1-ATPase rotation, which maximizes the coupling efficiency between catalysis and rotation.

High-resolution single-molecule characterization of the enzymatic states in Escherichia coli F1-ATPase

The rotary motor F1-ATPase from the thermophilic Bacillus PS3 (TF1) is one of the best-studied of all molecular machines. F1-ATPase is the part of the enzyme F1FO-ATP synthase that is responsible for generating most of the ATP in living cells. Single-molecule experiments have provided a detailed understanding of how ATP hydrolysis and synthesis are coupled to internal rotation within the motor. In this work, we present evidence that mesophilic F1-ATPase from Escherichia coli (EF1) is governed by the same mechanism as TF1 under laboratory conditions. Using optical microscopy to measure rotation of a variety of marker particles attached to the γ-subunit of single surface-bound EF1 molecules, we characterized the ATP-binding, catalytic and inhibited states of EF1. We also show that the ATP-binding and catalytic states are separated by 35±3°. At room temperature, chemical processes occur faster in EF1 than in TF1, and we present a methodology to compensate for artefacts that occur when the enzymatic rates are comparable to the experimental temporal resolution. Furthermore, we show that the molecule-to-molecule variation observed at high ATP concentration in our single-molecule assays can be accounted for by variation in the orientation of the rotating markers.

Rotational catalysis in proton pumping ATPases: From E. coli F-ATPase to mammalian V-ATPase

We focus on the rotational catalysis of Escherichia coli F-ATPase (ATP synthase, F(O)F(1)). Using a probe with low viscous drag, we found stochastic fluctuation of the rotation rates, a flat energy pathway, and contribution of an inhibited state to the overall behavior of the enzyme. Mutational analyses revealed the importance of the interactions among β and γ subunits and the β subunit catalytic domain. We also discuss the V-ATPase, which has different physiological roles from the F-ATPase, but is structurally and mechanistically similar. We review the rotation, diversity of subunits, and the regulatory mechanism of reversible subunit dissociation/assembly of Saccharomyces cerevisiae and mammalian complexes. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).

Stochastic rotational catalysis of proton pumping F-ATPase

F-ATPases synthesize ATP from ADP and phosphate coupled with an electrochemical proton gradient in bacterial or mitochondrial membranes and can hydrolyse ATP to form the gradient. F-ATPases consist of a catalytic F1 and proton channel F0 formed from the α3β3γδε and ab2c10 subunit complexes, respectively. The rotation of γεc10 couples catalyses and proton transport. Consistent with the threefold symmetry of the α3β3 catalytic hexamer, 120° stepped revolution has been observed, each step being divided into two substeps. The ATP-dependent revolution exhibited stochastic fluctuation and was driven by conformation transmission of the β subunit (phosphate-binding P-loop/α-helix B/loop/β-sheet4). Recent results regarding mechanically driven ATP synthesis finally proved the role of rotation in energy coupling.

ATP synthase from Escherichia coli: Mechanism of rotational catalysis, and inhibition with the ε subunit and phytopolyphenols

ATP synthases (FoF1) are found ubiquitously in energy-transducing membranes of bacteria, mitochondria, and chloroplasts. These enzymes couple proton transport and ATP synthesis or hydrolysis through subunit rotation, which has been studied mainly by observing single molecules. In this review, we discuss the mechanism of rotational catalysis of ATP synthases, mainly that from Escherichia coli, emphasizing the high-speed and stochastic rotation including variable rates and an inhibited state. Single molecule studies combined with structural information of the bovine mitochondrial enzyme and mutational analysis have been informative as to an understanding of the catalytic site and the interaction between rotor and stator subunits. We discuss the similarity and difference in structure and inhibitory regulation of F1 from bovine and E. coli. Unlike the crystal structure of bovine F1 (α3β3γ), that of E. coli contains a ε subunit, which is a known inhibitor of bacterial and chloroplast F1 ATPases. The carboxyl terminal domain of E. coli ε (εCTD) interacts with the catalytic and rotor subunits (β and γ, respectively), and then inhibits rotation. The effects of phytopolyphenols on F1-ATPase are also discussed: one of them, piceatannol, lowered the rotational speed by affecting rotor/stator interactions.

Defective assembly of a hybrid vacuolar H(+)-ATPase containing the mouse testis-specific E1 isoform and yeast subunits.

Mammalian vacuolar-type proton pumping ATPases (V-ATPases) are diverse multi-subunit proton pumps. They are formed from membrane V(o) and catalytic V(1) sectors, whose subunits have cell-specific or ubiquitous isoforms. Biochemical study of a unique V-ATPase is difficult because ones with different isoforms are present in the same cell. However, the properties of mouse isoforms can be studied using hybrid V-ATPases formed from the isoforms and other yeast subunits. As shown previously, mouse subunit E isoform E1 (testis-specific) or E2 (ubiquitous) can form active V-ATPases with other subunits of yeast, but E1/yeast hybrid V-ATPase is defective in proton transport at 37 degrees C (Sun-Wada, G.-H., Imai-Senga, Y., Yamamoto, A., Murata, Y., Hirata, T., Wada, Y., and Futai, M., 2002, J. Biol. Chem. 277, 18098-18105). In this study, we have analyzed the properties of E1/yeast hybrid V-ATPase to understand the role of the E subunit. The proton transport by the defective hybrid ATPase was reversibly recovered when incubation temperature of vacuoles or cells was shifted to 30 degrees C. Corresponding to the reversible defect of the hybrid V-ATPase, the V(o) subunit a epitope was exposed to the corresponding antibody at 37 degrees C, but became inaccessible at 30 degrees C. However, the V(1) sector was still associated with V(o) at 37 degrees C, as shown immunochemically. The control yeast V-ATPase was active at 37 degrees C, and its epitope was not accessible to the antibody. Glucose depletion, known to dissociate V(1) from V(o) in yeast, had only a slight effect on the hybrid at acidic pH. The domain between Lys26 and Val83 of E1, which contains eight residues not conserved between E1 and E2, was responsible for the unique properties of the hybrid. These results suggest that subunit E, especially its amino-terminal domain, plays a pertinent role in the assembly of V-ATPase subunits in vacuolar membranes.

Lipopolysaccharide induces multinuclear cell from RAW264.7 line with increased phagocytosis activity

Lipopolysaccharide (LPS), an outer membrane component of Gram-negative bacteria, induces strong proinflammatory responses, including the release of cytokines and nitric oxide from macrophage. In this study, we found that a murine macrophage-derived line, RAW264.7, became multinuclear through cell-cell fusion after incubation with highly purified LPS or synthetic lipid A in the presence of Ca(2+). The same cell line is known to differentiate into multinuclear osteoclast, which expresses a specific proton pumping ATPase together with osteoclast markers on stimulation by the extracellular domain of receptor activator of nuclear factor κB ligand (Toyomura, T., Murata, Y., Yamamoto, A., Oka, T., Sun-Wada, G.-H., Wada, Y. and Futai, M., 2003). The LPS-induced multinuclear cells did not express osteoclast-specific enzymes including tartrate-resistant acid phosphatase and cathepsin K. During multinuclear cell formation, the cells internalized more and larger polystyrene beads (diameter 6-15 μm) than mononuclear cells and osteoclasts. The internalized beads were located in lysosome-marker positive organelles, which were probably phagolysosomes. The LPS-induced multinuclear cell could be a good model system to study phagocytosis of large foreign bodies.

Strong inhibitory effects of curcumin and its demethoxy analog on Escherichia coli ATP synthase F1 sector

Curcumin, a dietary phytopolyphenol isolated from a perennial herb (Curcuma longa), is a well-known compound effective for bacterial infections and tumors, and also as an antioxidant. In this study, we report the inhibitory effects of curcumin and its analogs on the Escherichia coli ATP synthase F1 sector. A structure-activity relationship study indicated the importance of 4-hydroxy groups and a β-diketone moiety for the inhibition. The 3-demethoxy analog (DMC) inhibited F1 more strongly than curcumin did. Furthermore, these compounds inhibited E. coli growth through oxidative phosphorylation, consistent with their effects on ATPase activity. These results suggest that the two compounds affected bacterial growth through inhibition of ATP synthase. Derivatives including bis(arylmethylidene)acetones (C5 curcuminoids) exhibited only weak activity toward ATPase and bacterial growth.

Rotating proton pumping ATPases: subunit/subunit interactions and thermodynamics.

In this article, we discuss single molecule observation of rotational catalysis by E. coli ATP synthase (F‐ATPase) using small gold beads. Studies involving a low viscous drag probe showed the stochastic properties of the enzyme in alternating catalytically active and inhibited states. The importance of subunit interaction between the rotor and the stator, and thermodynamics of the catalysis are also discussed. “Single Molecule Enzymology” is a new trend for understanding enzyme mechanisms in biochemistry and physiology.