Transport ATPases: Structure,Motors, Mechanism and Medicine: A Brief Overview

Today we know there are four different types of ATPases that operate within biological membranes with the purpose of moving many different types of ions or molecules across these membranes. Some of these ions or molecules are transported into cells, some out of cells, and some in or out of organelles within cells. These ATPases span the biological world from bacteria to eukaryotic cells and have become most simply and commonly known as “transport ATPases.” The price that each cell type pays for transport work is counted in molecules of hydrolyzed ATP, a metabolic currency that is itself regenerated by a transport ATPase working in reverse, i.e., the ATP synthase. Four major classes of transport ATPases, the P, V, F, and ABC types are now known. In addition to being involved in many different types of biological/physiological processes, mutations in these proteins also account for a large number of diseases. The purpose of this introductory article to a mini-review series on transport ATPases is to provide the reader with a very brief and focused look at this important area of research that has an interesting history and bears significance to cell physiology, biochemistry, immunology, nanotechnology, and medicine, including drug discovery. The latter involves potential applications to a whole host of diseases ranging from cancer to those that affect bones (osteoporosis), ears (hearing), eyes (macromolecular degeneration), the heart (hypercholesterolemia/cardiac arrest,), immune system (immune deficiency disease), kidney (nephrotoxicity), lungs (cystic fibrosis), pancreas (diabetes and cystic fibrosis), skin (Darier disease), and stomach (ulcers).     

ATP Synthases With Novel Rotor Subunits: New Insights into Structure,Function and Evolution of ATPases

ATPases with unusual membrane-embedded rotor subunits were found in both F₁F₀ and A₁A₀ ATP synthases. The rotor subunit c of A₁A₀ ATPases is, in most cases, similar to subunit c from F₀. Surprisingly, multiplied c subunits with four, six, or even 26 transmembrane spans have been found in some archaea and these multiplication events were sometimes accompanied by loss of the ion-translocating group. Nevertheless, these enzymes are still active as ATP synthases. A duplicated c subunit with only one ion-translocating group was found along with “normal” F₀ c subunits in the Na⁺ F₁F₀ ATP synthase of the bacterium Acetobacterium woodii. These extraordinary features and exceptional structural and functional variability in the rotor of ATP synthases may have arisen as an adaptation to different cellular needs and the extreme physicochemical conditions in the early history of life.     

ATP-dependent calcium transport in membrane vesicles of the cyanobacterium, Anabaena variabilis

Transport of Ca²⁺ in membrane vesicles of the cyanobacterium Anabaena variabilis has been investigated. The light membranes previously shown to carry a Mg²⁺-dependent, Ca²⁺-stimulated ATPase (Lockau, W. and Pfeffer, S. (1982) Z. Naturforsch. 37C, 658–664) accumulate Ca²⁺ upon addition of ATP, whereas the (heavier) thylakoids do not. A stoichiometry of 0.3 Ca²⁺ taken up per ATP hydrolyzed has been determined from initial rates, which is considered to be an underestimation of the true stoichiometry of the pump. Calcium transport and Ca²⁺-stimulated ATPase activity are both sensitive to Na₃VO₄ (an inhibitor of ATPases forming a phosphorylated intermediate), show the same pH optimum and a comparable dependence on ATP concentration. Calcium transport is also supported by nucleoside triphosphates other than ATP, although at lower rates. Accumulation of calcium is abolished by an ionophore of divalent cations, ionophore A23187, but is resistant to ionophores of monovalent cations and to the inhibitor of F₁-F₀-type ATPases, N,N′-dicyclohexylcarbodiimide. It is concluded that the ATPase is a primary calcium pump.     

Presence of an extramitochondrial anion-stimulated ATPase in the rabbit kidney: Localization along the nephron and effect of corticosteroids

Summary To determine whether kidney membrane fractions contain an extramitochondrial anion-stimulated ATPase, we compared the pharmacological and kinetic properties of HCO₃-ATPase activities in mitochondrial and microsomal fractions prepared from rabbit kidney cortex and outer medulla. The results indicated that this activity differed markedly in each type of fraction. Microsomal HCO₃-ATPase was less sensitive than mitochondrial ATPase to azide, oligomycin, DCCD and thiocyanate, but was more sensitive to filipin and displayed different dependency towards ATP, magnesium and pH. Microsomal ATPase activity was stimulated by sulfite much more strongly than by bicarbonate, whereas mitochondrial activity was stimulated by both these anions to a similar extent. These results demonstrate the presence of an extramitochondrial HCO₃-ATPase in kidney membrane fractions. HCO₃-ATPase was also measured in single microdissected segments of the rabbit nephron using a radiochemical microassay previously developed for tubular Na, K-ATPase activity. An enzyme with the pharmacological and kinetic properties of the microsomal enzyme was detected in both proximal tubule, distal convoluted tubule and collecting duct, but the thick ascending limb was devoid of any detectable activity. Long-term DOCA administration markedly increased HCO₃-ATPase activity in the distal convoluted and collecting tubule. The insensitivity of microsomal HCO₃-ATPase to vanadate indicates that it belongs to the F₀–F₁ class of ATPases, and might therefore be involved in proton transport. This hypothesis is also supported by the localization of tubular HCO₃-ATPase activity at the sites of urinary acidification.     

Inter‐subunit interaction and quaternary rearrangement defined by the central stalk of prokaryotic V1‐ATPase

V‐type ATPases (V‐ATPases) are categorized as rotary ATP synthase/ATPase complexes. The V‐ATPases are distinct from F‐ATPases in terms of their rotation scheme, architecture and subunit composition. However, there is no detailed structural information on V‐ATPases despite the abundant biochemical and biophysical research. Here, we report a crystallographic study of V₁‐ATPase, from Thermus thermophilus, which is a soluble component consisting of A, B, D and F subunits. The structure at 4.5 Å resolution reveals inter‐subunit interactions and nucleotide binding. In particular, the structure of the central stalk composed of D and F subunits was shown to be characteristic of V₁‐ATPases. Small conformational changes of respective subunits and significant rearrangement of the quaternary structure observed in the three AB pairs were related to the interaction with the straight central stalk. The rotation mechanism is discussed based on a structural comparison between V₁‐ATPases and F₁‐ATPases.     

Coupling of proteolysis to ATP hydrolysis uponEscherichia coli lon protease functioning: I. kinetic aspects of ATP hydrolysis

Some aspects of theEscherichia coli Lon protease ATPase function were studied around the optimum pH value. It was revealed that in the absence of the protein substrate the maximum ATPase activity of the enzyme is observed at an equimolar ratio of ATP and Mg²⁺ ions in the area of their millimolar concentrations. Free components of the substrate complex (ATP-Mg)²⁻ inhibit the enzyme ATPase activity. It is hypothesized that the effector activity of free Mg²⁺ ions is caused by the formation of the “ADP-Mg-form” of ATPase centers. It was shown that the activation of ATP hydrolysis in the presence of the protein substrate is accompanied by an increase in the affinity of the (ATP-Mg)²⁻ complex to the enzyme, by an elimination of the inhibiting action of free Mg²⁺ ions without altering the efficiency of catalysis of ATP hydrolysis (based on thek _cat value), and by a change in the type of inhibition of ATP hydrolysis by the (ADP-Mg)⁻ complex (without changing theK _i value). Interaction of the Lon protease protein substrate with the enzyme area located outside the peptide hydrolase center was demonstrated by a direct experiment.     

Crystal structure of A3B3 complex of V‐ATPase from Thermus thermophilus

Vacuolar‐type ATPases (V‐ATPases) exist in various cellular membranes of many organisms to regulate physiological processes by controlling the acidic environment. Here, we have determined the crystal structure of the A₃B₃ subcomplex of V‐ATPase at 2.8 Å resolution. The overall construction of the A₃B₃ subcomplex is significantly different from that of the α₃β₃ sub‐domain in F_oF₁‐ATP synthase, because of the presence of a protruding ‘bulge’ domain feature in the catalytic A subunits. The A₃B₃ subcomplex structure provides the first molecular insight at the catalytic and non‐catalytic interfaces, which was not possible in the structures of the separate subunits alone. Specifically, in the non‐catalytic interface, the B subunit seems to be incapable of binding ATP, which is a marked difference from the situation indicated by the structure of the F_oF₁‐ATP synthase. In the catalytic interface, our mutational analysis, on the basis of the A₃B₃ structure, has highlighted the presence of a cluster composed of key hydrophobic residues, which are essential for ATP hydrolysis by V‐ATPases.     

Visualization of mitochondrial coupling factor F1(ATPase) by freeze-drying

It is known that the negatively stained preparations of inner mitochondrial membrane display characteristic ∼9 nmF ₁ (ATPase) knobs projecting from the matrix surface. Freeze-etch studies have reported the absence of such knobs from the “etched” surface of the inner mitochondrial membranes. We have demonstrated their presence on the surface of SMP (submitochondrial particles) prepared by freeze-drying for transmission electron microscopy. This identification has been substantiated by comparison with the freeze-dried TU particles (trypsin-urea treated SMP) that are devoid ofF ₁ (ATPase). It has been suggested that a layer of water molecules is strongly adsorbed to the surface of SMP and does not sublime during normal freeze-“etching.”     

Introduction: A Close Look at the Vacuolar ATPase

The vacuolar ATPases (V-type ATPases) are a family of ATP-dependent ion pumps and found in two principal locations, in endomembranes and in plasma membranes. This family of ATPases is responsible for acidification of intracellulare compartments and, in certain cases, ion transport across the plasma membrane of eucaryotic cells. V-ATPases are composed of two distinct domains: a catalytic V₁ sector, in which ATP hydrolysis takes place, and the membrane-embedded sector, V₀, which functions in ion conduction. In the past decade impressive progress has been made in elucidating the properties structure, function and moleculare biology. These knowledge sheds light also on the evolution of V-ATPases and their related families of A-(A₁A₀-ATPase) and F-type (F₁F₀-ATPases)ATPases.     

Conformational changes in the Escherichia coli ATP synthase b-dimer upon binding to F1-ATPase

Conformational changes within the subunit b-dimer of the E. coli ATP synthase occur upon binding to the F₁ sector. ESR spectra of spin-labeled b at room temperature indicated a pivotal point in the b-structure at residue 62. Spectra of frozen b ± F₁ and calculated interspin distances suggested that where contact between b ₂ and F₁ occurs (above about residue 80), the structure of the dimer changes minimally. Between b-residues 33 and 64 inter-subunit distances in the F₁-bound b-dimer were found to be too large to accommodate tightly coiled coil packing and therefore suggest a dissociation and disengagement of the dimer upon F₁-binding. Mechanistic implications of this “bubble” formation in the tether domain of ATP synthase b ₂ are discussed. This work was supported by grant from the National Science Foundation (MCB 0415713) to PDV     

Lack of Conventional ATPase Properties in CFTR Chloride Channel Gating

CFTR shares structural homology with the ABC transporter superfamily of proteins which hydrolyze ATP to effect the transport of compounds across cell membranes. Some superfamily members are characterized as P-type ATPases because ATP-dependent transport is sensitive to the presence of vanadate. It has been widely postulated that CFTR hydrolyzes ATP to gate its chloride channel. However, direct evidence of CFTR hydrolytic activity in channel gating is lacking and existing circumstantial evidence is contradictory. Therefore, we evaluated CFTR chloride channel activity under conditions known to inhibit the activity of ATPases; i.e., in the absence of divalent cations and in the presence of a variety of ATPase inhibitors. Removal of the cytosolic cofactor, Mg²⁺, reduced both the opening and closing rates of CFTR suggesting that Mg²⁺ plays a modulatory role in channel gating. However, channels continued to both open and close showing that Mg²⁺ is not an absolute requirement for channel activity. The nonselective P-type ATPase inhibitor, vanadate, did not alter the gating of CFTR when used at concentrations which completely inhibit the activity of other ABC transporters (1 mm). Higher concentrations of vanadate (10 mm) blocked the closing of CFTR, but did not affect the opening of the channel. As expected, more selective P-type (Sch28080, ouabain), V-type (bafilomycin A1, SCN⁻) and F-type (oligomycin) ATPase inhibitors did not affect either the opening or closing of CFTR. Thus, CFTR does not share a pharmacological inhibition profile with other ATPases and channel gating occurs in the apparent absence of hydrolysis, although with altered kinetics. Vanadate inhibition of channel closure might suggest that a hydrolytic step is involved although the requirement for a high concentration raises the possibility of previously uncharacterized effects of this compound. Most conservatively, the requirement for high concentrations of vanadate demonstrates that the binding site for this transition state analogue is considerably different than that of other ABC transporters. Received: 18 September 1995/Revised: 9 January 1996     

Sequential Action of MalE and Maltose Allows Coupling ATP Hydrolysis to Translocation in the MalFGK2 Transporter

ATP-binding cassette (ABC) transporters have evolved an ATP-dependent alternating-access mechanism to transport substrates across membranes. Despite important progress, especially in their structural analysis, it is still unknown how the substrate stimulates ATP hydrolysis, the hallmark of ABC transporters. In this study, we measure the ATP turnover cycle of MalFGK₂ in steady and pre-steady state conditions. We show that (i) the basal ATPase activity of MalFGK₂ is very low because the cleavage of ATP is rate-limiting, (ii) the binding of open-state MalE to the transporter induces ATP cleavage but leaves release of P_i limiting, and (iii) the additional presence of maltose stimulates release of P_i, and therefore increases the overall ATP turnover cycle. We conclude that open-state MalE stabilizes MalFGK₂ in the outward-facing conformation until maltose triggers return to the inward-facing state for substrate and P_i release. This concerted action explains why ATPase activity of MalFGK₂ depends on maltose, and why MalE is essential for transport.     

Orphan enzyme or patriarch of a new tribe: the arsenic resistance ATPase of bacterial plasmids

The plasmid-determined arsenite and antimonite efflux ATPase of bacteria differs from other membrane transport ATPases, which are classified into several families (such as the F₀F₁-type H⁺-translocating ATP synthases, the related vacuolar H⁺-translocating ATPases, the P-type cation-translocating ATPases, and the superfamily which includes the periplasmic binding-protein-dependent systems in Gram-negative bacteria, the human multidrug resistance P-glycoprotein, and the cystic fibrosis transport regulator). The amino acid sequences of the components of the arsenic resistance system are not similar to known ATPase proteins. New findings with the arsenic resistance operons of bacterial plasmids suggest that instead of being an orphan the Ars system will now be the first recognized member of a new class of ATPases. Furthermore, fundamental questions of energy-coupling (ATP-driven or chemiosmotic) have recently been raised and the finding that the arsC gene product is a soluble enzyme that reduces arsenate to arsenite changes the previous picture of the functioning of this widespread bacterial system.     

H-ATPase Activity from Storage Tissue of Beta vulgaris: III. Modulation of ATPase Activity by Reaction Substrates and Products

Two distinct membrane fractions containing H⁺-ATPase activity were prepared from red beet. One fraction contained a H⁺-ATPase activity that was inhibited by NO₃⁻ while the other contained a H⁺-ATPase inhibited by vanadate. We have previously proposed that these H⁺-ATPases are associated with tonoplast (NO₃⁻-sensitive) and plasma membrane (vanadate-sensitive), respectively. Both ATPase were examined to determine to what extent their activity was influenced by variations in the concentration of ATPase substrates and products. The substrate for both ATPase was MgATP²⁻, and Mg²⁺ concentrations in excess of ATP had only a slight inhibitory effect on either ATPase. Both ATPases were inhibited by free ATP (i.e. ATP concentrations in excess of Mg²⁺) and ADP but not by AMP. The plasma membrane ATPase was more sensitive than the tonoplast ATPase to free ATP and the tonoplast ATPase was more sensitive than the plasma membrane ATPase to ADP.

Inhibition of both ATPases by free ATP was complex. Inhibition of the plasma membrane ATPase by ADP was competitive whereas the tonoplast ATPase demonstrated a sigmoidal dependence on MgATP²⁻ in the presence of ADP. Inorganic phosphate moderately inhibited both ATPases in a noncompetitive manner.

Calcium inhibited the plasma membrane but not the tonoplast ATPase, apparently by a direct interaction with the ATPase rather than by disrupting the MgATP²⁻ complex.

The sensitivity of both ATPases to ADP suggests that under conditions of restricted energy supply H⁺-ATPase activity may be reduced by increases in ADP levels rather than by decreases in ATP levels per se. The sensitivity of both ATPases to ADP and free ATP suggests that modulation of cytoplasmic Mg²⁺ could modulate ATPase activity at both the tonoplast and plasma membrane.

     

The vacuolar ATPase ofNeurospora crassa

The filamentous fungusNeurospora crassa has many small vacuoles which, like mammalian lysosomes, contain hydrolytic enzymes. They also store large amounts of phosphate and basic amino acids. To generate an acidic interior and to drive the transport of small molecules, the vacuolar membranes are densely studded with a proton-pumping ATPase. The vacuolar ATPase is a large enzyme, composed of 8–10 subunits. These subunits are arranged into two sectors, a complex of peripheral subunits called V₁ and an integral membrane complex called V₀. Genes encoding three of the subunits have been isolated.vma-1 andvma-2 encode polypeptides homologous to the and subunits of F-type ATPases. These subunits appear to contain the sites of ATP binding and hydrolysis.vma-3 encodes a highly hydrophobic polypeptide homologous to the proteolipid subunit of vacuolar ATPases from other organisms. This subunit may form part of the proton-containing pathway through the membrane. We have examined the structures of the genes and attempted to inactivate them.     

Immunological and reconstitution studies on the adenosine triphosphatase complex from Rhodospirillum rubrum

Studies on restoration of membrane-bound adenosinetriphosphatase (ATP phosphohydrolase, EC 3.6.1.3) from Rhodospirillum rubrum show that the δ-subunit is capable of binding to the F₁ factor or to the F₀ moiety of the F₀-F₁ ATPase complex. This subunit is thus likely involved in linking the F₀ and F₁ factor.During solubilization of the oligomycin-sensitive F₀-F₁ ATPase complex with Triton X-100 the detergent becomes specifically associated with the lipophilic F₀ part of the enzyme complex.Crossed immunoelectrophoresis, agglutination tests, and kinetic studies with anti-F₁ ATPase antibodies reveal a reaction of immunological identity of membrane-bound ATPase, F₀-F₁ ATPase, and F₁ ATPase.     

Specific photolabelling of beef-heart mitochondrial ATPase by 8-azido-ATP

1. 8-Azido-ATP is a suitable photoaffinity label for beef-heart mitochondrial ATPase (F₁).2. 8-Azido-ATP is hydrolysed slowly by F₁ in the dark. Photolysis at 350 nm in the presence of F₁ leads to inhibition of the ATPase activity. The presence of ATP during illumination prevents the inhibition. Illumination of F₁ in the absence of 8-azido-ATP causes no inhibition.3. Added Mg²⁺ is not necessary for the binding of the 8-azido-ATP to F₁.4. 8-Azido-ATP binds specifically to the β subunits of F₁.5. The ATPase activity is completely inhibited when 2 mol of 8-azido-ATP are bound per mol F₁.     

Close-Up and Genomic Views of the Yeast Vacuolar H<Superscript>+</Superscript>-ATPase

The yeast V-ATPase has emerged as an excellent model for other eukaryotic V-ATPases. In this review, recent biochemical and genomic studies of the yeast V-ATPase are described, with a focus on: 1) the role of V₁ subunit H in coupling ATP hydrolysis and proton pumping and 2) identification of the full set of yeast haploid deletion mutants that exhibit the pH and calcium-sensitive growth characteristic of loss of V-ATPase activity. The combination of “close-up” biochemical views of V-ATPase structure and mechanism and “geomic” views of its functional reach promises to provide new insights into the physiological of V-ATPases.     

Modeling of the actomyosin ATPase activity

In the rapid “quench” kientics of myosin, the “initial phosphate burst” is the excess inorganic phosphate that is produced during the early time-course of ATP hydrolysis by myosin subfragment-1 (S-1) or HMM. In general, the existence of a Pi burst implies a rapid (i.e., generally an order of magnitude faster than the steady-state hydrolysis rate) lysis of the phospho-anhydride bond within the ATP molecule, followed by one or more slower steps that are rate limiting for the process. Thus, the presence of a Pi burst can provide an important clue to the mechanism of the reaction. However, in the case of actomyosin, this clue as long been the subject of controversy and misunderstanding. To measure the (initial) Pi burst, myosin S-1 (or HMM) is rapidly mixed with ATP and then the mixture is acid quenched after a specific time period. The medium produced contains free Pi generated from hydrolysis of the ATP. The quantitative measure of the phosphate generated in this way has always been significantly greater than that expected by steady-state “release” of Pi alone, and it is that very difference between this measured Pi after the quench and that amount of Pi expected to be released by steady-state considerations in that same time period that has been referred to as the “initial Pi burst”. Recent investigations of the kinetics of Pi release have used an entirely new method that directly measures the release of Pi from the enzyme-product complex. These studies have made reference to the properties of the “initial Pi burst” in the presence of actin, as well as to a new kinetic entity: the “burst of Pi release”, and have been often vague concerning the true nature of the initial Pi burst, as well as the properties of Pi release as predicted by the current models of the actin activation of the myosin ATPase activity. The purpose of the current article is to correct this oversight, to discuss the “burst” in some detail, and to display the kinetics predicted by the current models for the actin activation of myosin. Furthermore, predictions for the kinetics of the new “burst of Pi release” are discussed in terms of its ability to discriminate between the two current competing models for actin activation of the myosin ATPase activity.