Strikingly low ATPase activities in flagellar axonemes of a Chlamydomonas mutant missing outer dynein arms

The ATPase activities in Chlamydomonas axonemes were compared between wild type and a mutant (oda) that lacks entire outer dynein arms, at various ionic strengths and pH values, and in the presence of different concentrations of high-molecular-mass dextran. Over a 0-0.2 M KCl concentration range, the ATPase activity of oda axonemes was found to be 5-12 times lower than that of the wild-type axonemes. The low activity in oda is surprising since outer arm-depleted axonemes of sea urchin sperm have been reported to retain about 50% of the normal activity. In both wild type and oda, the ATPase activity of dynein was higher when contained within the axoneme than when released from it with 0.6 M KCl. The ATPase activation within the wild-type axoneme was inhibited by high ionic strengths or by the presence of dextran. The activation in oda axonemes, on the other hand, was not inhibited by these factors. These significantly different ATPase properties suggest that the inner and outer dynein arms perform somewhat different functions in this organism.     

CYTOPLASMIC DYNEIN OF THE SEA URCHIN EGG I. PARTIAL PURIFICATION AND CHARACTERIZATION*

Cytoplasmic ATPase of sea urchin eggs was partially purified by ammonium sulfate fractionation, DEAE-cellulose chromatography, gel-filtration chromatography and sucrose density gradient centrifugation. The specific activity increased to 0.7 μmole/min/mg protein indicating 100 fold purification. The ATPase had a sedimentation constant of 12S and was highly specific for ATP. The enzyme fraction contained neither (Na, K)-ATPase, Ca-ATPase, oligomycin-sensitive ATPase, phosphatases, nor myosin. This cytoplasmic ATPase was inhibited by a low concentration of vanadate (V). Half-maximal inhibition was observed at a vanadate concentration of 1 μM at low ionic strength. The inhibition was almost totally reversed by addition of norepinephrine. The vanadate-sensitivity of cytoplasmic ATPase decreased with increasing KCl concentration. The activation by Mg²⁺ or Ca²⁺, and dependence of the activity on KCl concentration characteristic of dyneins from sea urchin sperm flagella and the embryonic cilia were observed with cytoplasmic ATPase. These results allowed the cytoplasmic ATPase to be classified as a dynein. In addition, this designation was reinforced by the fact that an oligomeric 23S form of cytoplasmic dynein was identified in the cytoplasm as well as in the isolated mitotic apparatus.     

Steady-state studies of the actin-activated adenosine triphosphatase activity of myosin.

Reconstituted actomyosin (ATP phosphohydrolase, EC 3.6.1.3) (0.400 mg F-actin/mg myosin) in 10.0 muM ATP loses 96% of its specific ATPase activity when its reaction concentration is decreased from 42.0 mug/ml down to 0.700 mug/ml. The loss of specific activity at the very low enzyme concentrations is prevented by the addition of more F-actin to 17.6 mug/ml. It is concluded that at low actomyosin concentrations the complex dissociates into free myosin with a very low specific ATPase activity and free F-actin with no ATPase. The dissociation of the essential low molecular weight subunits of myosin from the heavy chains at very low actomyosin concentrations may be a contributing factor. Actomyosin has its maximum specific activity at pH 7.8-8.2. The Km for ATP is 9.4 muM, which is at least 20-fold greater than myosin's Km for ATP. The actin-activated ATPase of myosin follows hyperbolic kinetics with varying F-actin concentrations. The Km values for F-actin are 0.110 muM (4.95 mug/ml) at pH 7.4 and 0.241 muM (10.8 mug/ml) at pH 7.8. The actin-activated maximum turnover numbers for myosin are 9.3 s-1 at pH 7.4 and 11.6 s-1 at pH 7.8. The actomyosin ATPase is inhibited by KCl. This KCl inhibition is not competitive with respect to F-actin, and it is not a simple form of non-competitive inhibition.     

Kinetic analysis of axoneme and dynein ATPase from sea urchin sperm

The behavior of the ATPase of axoneme (detergent-treated flagellum) and dynein from sea urchin sperm was investigated. The activation of the ATPase by divalent cations was attributed to formation of a complex of ATP and the divalent cation; the metal-ATP complex is an effective substrate. However, free ATP is a modifier of the ATPase. Free ATP markedly changes the affinity of the metal-ATP complex to the enzymes. Calcium-activated ATPase activity of axoneme decreased at high concentration of CaCl₂, but that of dynein did not decrease.     

Inhibition by lead ion of Electrophorus electroplax (Na+ + K+)-adenosine triphosphatase and K+-p-nitrophenylphosphatase.

Inorganic lead ion in micromolar concentrations inhibits Electrophorus electroplax microsomal (Na+ + K+)-adenosine triphosphatase ((Na+ + K+)-ATPase) and K+-p-nitrophenylphosphatase (NPPase). Under the same conditions, the same concentrations of PbCl2 that inhibit ATPase activity also stimulate the phosphorylation of electroplax microsomes in the absence of added Na+. Enzyme activity is protected from inhibition by increasing concentrations of microsomes, ATP, and other metal ion chelators. The kinetics follow the pattern of a reversible noncompetitive inhibitor. No kinetic evidence is elicited for interactions of Pb2+ with Na+, K+, Mg2+, ATP, or p-nitrophenylphosphate. Na+- ATPase, in the absence of K+, and (Na+ + K+)-NPPase activity at low [K+] are also inhibited. ATP inhibition of NPPase is not reversed by Pb2+. The calculated concentrations of free [Pb2+] that produce 50% inhibition are similar for ATPase and NPPase activities. Pb2+ may act at a single independent binding site to produce both stimulation of the kinase and inhibition of the phosphatase activities.     

Structure and function of the two heads of the myosin molecule. I. Binding of adenosine diphosphate to myofibrils during the adenosinetriphosphatase reaction.

1. The myosin content of myofibrils was found to be 51% by SDS-gel electrophoresis. 2. The initial burst of Pi liberation of the ATPase [EC 3.6.1.3] of a solution of myofibrils in 1 M KCl was measured in 0.5 M KCl, and found to be 0.93 mole/mole of myosin. 3. The amount of ADP bound to myofibrils during the ATPase reaction and the ATPase activity were measured by coupling the myofibrillar ATPase reaction with sufficient amounts of pyruvate kinase [EC 2.7.1.40] and PEP to regenerate ATP. The maximum amount of ADP bound to myofibrils in 0.05M KCl and in the relaxed state was about 1.5 mole/mole of myosin. On the other hand, the ATPase activity exhibited substrate inhibition, and the amount of ATP required for a constant level of ATPase activity was smaller than that required for the maximum binding of ADP to myofibrils. 4. The maximum amount of ADP bound to myofibrils in 0.5 M KCl was about 1.9 mole/mole of myosin. When about one mole of ADP was found to 1 mole of myosin in myofibrils, the myofibrillar ATPase activity reached the saturated level, and with further increase in the concentration of ATP one more mole of ADP was found per mole of myosin.     

Characterization of human erythrocyte cytoskeletal ATPase

Human erythrocyte cytoskeletal ATPase was extracted with 0.2 mM ATP (pH 8.0) from Triton X-100 treated ghosts. The ATPase fraction contained mainly spectrin, actin, and band 4.1. When the ATPase fraction was applied to a Sepharose 4B column, 90% of the ATPase activity was recovered in a spectrin, actin, and band 4.1 complex fraction and none was detected in the spectrin fraction. A specific activity of the complex ATPase was 60-120 nmol/(mg protein X h). No ATPase activity was detected in the presence of EDTA. The presence of magnesium in the incubation medium was essential for the ATPase activity. The activity was activated by KCl and was almost completely inhibited by 10(-5) M free calcium in the presence of 0.2 mM MgCl2. The Ki for Ca2+ was 7 X 10(-7) M. Phalloidin and DNase 1, which affect actin, inhibited this K,Mg-ATPase activity by 95%, but cytochalasin B did not inhibit it. N-Ethylmaleimide activated the ATPase 1.6-fold. The order of affinity for nucleotides was ATP greater than ITP greater than CTP, ADP, AMP-PNP, GTP. A specific ATPase activity of purified actin was 50 nmol/(mg X h). These results suggest that the cytoskeletal ATPase is actin ATPase and the actin ATPase is activated by spectrin and band 4.1.     

Plasma membrane adenosine triphosphatase of oat roots: activation and inhibition by mg and ATP

ATPase activity of plasma membrane vesicles isolated from oat (Avena sativa L. cv. Goodfield) roots was examined in the presence of various concentrations of MgCl(2) and ATP. A Mg(2+): ATP ratio of about 1 was required for maximal activity regardless of the concentrations used; the optimum concentration for both Mg(2+) and ATP was 9 mm. Based on the ATPase activity at different concentrations of complexed Mg.ATP and free ATP, it is concluded that Mg.ATP is the true substrate of this enzyme.Under certain experimental conditions, high concentrations of MgCl(2) and ATP inhibited the plasma membrane ATPase. On the basis of the relative amounts of free and complexed ATP and Mg(2+), it was found that the different moieties caused different amounts of inhibition. Free ATP inhibited the ATPase at concentrations in excess of 2 mm. Mg.ATP concentrations above 11 mm inhibited the enzyme. Free Mg(2+) caused only a slight inhibition of the ATPase.The Km for Mg.ATP was found to vary from 0.64 to 1.24 mm depending on the experimental conditions. This variation is thought to be due to variable amounts of Mg.ATP, which serves as an inhibitor as well as the substrate, and free ATP, which also inhibits the enzyme.     

Lanthanum inhibits steady-state turnover of the sarcoplasmic reticulum calcium ATPase by replacing magnesium as the catalytic ion

LaATP is shown to be an effective inhibitor of the calcium ATPase of sarcoplasmic reticulum because the binding of LaATP to cE.Ca2 results in the formation of lanthanum phosphoenzyme, which decays slowly. Steady-state activity of the calcium ATPase in leaky sarcoplasmic reticulum vesicles is inhibited 50% by 0.16 microM LaCl3 (15 nM free La3+, 21 nM LaATP) in the presence of 25 microM Ca2+ and 49 microM MgATP (5 mM MgSO4, 100 mM KCl, 40 mM 4-morpholinepropanesulfonic acid, pH 7.0, 25 degrees C). However, 50% inhibition of the uptake of 45Ca and phosphorylation by [gamma-32P]ATP in a single turnover experiment requires 100 microM LaCl3 (28 microM free La3+) in the presence of 25 microM Ca2+; this inhibition is reversed by calcium but inhibition of steady-state turnover is not. Therefore, binding of La3+ to the cytoplasmic calcium transport site is not responsible for the inhibition of steady-state ATPase activity. The addition of 6.7 microM LaCl3 (1.1 microM free La3+) has no effect on the rate of dephosphorylation of phosphoenzyme formed from MgATP and enzyme in leaky vesicles, while 6.7 mM CaCl2 slows the rate of phosphoenzyme hydrolysis as expected; 6.7 microM LaCl3 and 6.7 mM CaCl2 cause 95 and 98% inhibition of steady-state ATPase activity, respectively. This shows that inhibition of ATPase activity in the steady state is not caused by binding of La3+ to the intravesicular calcium transport site of the phosphoenzyme. Inhibition of ATPase activity by 2 microM LaCl3 (0.16 microM free La3+, 0.31 microM LaATP) requires greater than 5 s, which corresponds to approximately 50 turnovers, to reach a steady-state level of greater than or equal to 80% inhibition. Inhibition by La3+ is fully reversed by the addition of 0.55 mM CaCl2 and 0.50 mM EGTA; this reactivation is slow with t1/2 approximately 9 s. Two forms of phosphoenzyme are present in reactions that are partially inhibited by La3+: phosphoenzyme with Mg2+ at the catalytic site and phosphoenzyme with La3+ at the catalytic site, which undergo hydrolysis with observed rate constants of greater than 4 and 0.05 s-1, respectively. We conclude, therefore, that La3+ inhibits steady-state ATPase activity under these conditions by replacing Mg2+ as the catalytic ion for phosphoryl transfer. The slow development of inhibition corresponds to the accumulation of lanthanum phosphoenzyme. Initially, most of the enzyme catalyzes MgATP hydrolysis, but the fraction of enzyme with La3+ bound to the catalytic site gradually increases because lanthanum phosphoenzyme undergoes hydrolysis much more slowly than does magnesium phosphoenzyme.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reversible inhibition of (Na+, K+) ATPase by Mg2+, adenosine triphosphate, and K+.

Adenosine triphosphate (ATP) hydrolysis catalyzed by the plasma membrane (Na+,K+)ATPase isolated from several sources was inhibited by Mg+, provided that K+ and ATP were also present. Phosphorylation of the adenosine triphosphatase (ATPase) by ATP and by inorganic phosphate was also inhibited, as was p-nitrophenyl phosphatase activity. (Ethylenedinitrilo)tetraacetic acid (EDTA) and catecholamines protected from and reversed the inhibition of ATP hydrolysis by Mg2+, K+ and ATP. EDTA was protected by chelation of Mg2+ but catecholamines acted by some other mechanism. The specificities of various nucleotides as inhibitors (in conjunction with Mg2+ and K+) and as substrates for the (Na+, K+) ATPase were strikingly different. ATP, ADP, beta,gamma-CH2-ATP and alpha,beta-CH2-ADP were active as inhibitors, whereas inosine, cytidine, uridine, and guanosine triphosphates (ITP, CTP, UTP, and GTP) and adenosine monophosphate (AMP) were not. On the other hand, ATP and CTP were substrates and beta,gamma-NH-ATP was a competitive inhibitor of ATP hydrolysis, but not an inhibitor in conjunction with Mg2+ and K+. The Ca2+-ATPase from sarcoplasmic reticulum and F1, the Mg2+-ATPase from the inner mitochondrial membrane, were also inhibited by Mg2+. Catecholamines reversed inhibition of the Ca2+-ATPase, but not that of F1.     

Effect of vanadate on the vacuolar ATPase of Acer pseudoplatanus

The ATPase of vacuoles isolated from Acer pseudoplatanus cells is strongly inhibited by vanadate, a specific inhibitor of plasma membrane ATPase. The degree of inhibition depends upon the ionic composition, ATP and magnesium concentrations of the reaction medium and the inhibition is reversed by EDTA which complexes vanadate. In absence of factor which may interfere with the effectiveness of inhibitor, vanadate inhibits the ATPase non-competitively.     

Inhibition of the sarcoplasmic reticulum Ca2+ transport ATPase by thapsigargin at subnanomolar concentrations.

ATP-dependent calcium uptake by isolated sarcoplasmic reticulum vesicles is inhibited by concentrations of free thapsigargin as low as 10(-10) M. This effect is due to primary inhibition of the Ca(2+)-dependent ATPase which is coupled to active transport. When binding of calcium to the activating sites of the enzyme is measured under equilibrium conditions in the absence of ATP, addition of thapsigargin produces strong inhibition. On the other hand, if [tau-32P]ATP is added to ATPase preincubated with Ca2+ under favorable conditions, significant levels of 32P-phosphorylated intermediate are still formed transiently, even in the presence of thapsigargin. The phosphoenzyme, however, decays rapidly as the calcium-enzyme complex is destabilized as a consequence of ATP utilization, and formation of the thapsigargin-enzyme complex is favored. Formation of the thapsigargin-enzyme complex is also favored by Ca2+ chelation with EGTA, with consequent inhibition of the enzyme reactivity to Pi (i.e. reverse of the ATPase hydrolytic reaction). Neither the Ca(2+)- and ATP-induced Ca2+ release from junctional sarcoplasmic reticulum nor the Ca(2+)- and calmodulin-dependent ATPase of plasma membranes (erythrocyte ghosts) were found to be altered by thapsigargin at such low concentrations.     

Membrane Transport in Isolated Vesicles from Sugarbeet Taproot: III. Effects of Fluoride on ATPase Activity and Transport

The effects of fluoride on the tonoplast type ATPase and transport activities associated with sealed membrane vesicles isolated from sugarbeet (Beta vulgaris L.) storage tissue were examined. This anion had two distinct effects upon the proton-pumping vesicles. When ATP hydrolysis was measured in the presence of gramicidin D, significant inhibition (approximately 50%) only occurred when the fluoride concentration approached 50 millimolar. In contrast, the same degree of inhibition of proton transport occurred when the fluoride concentration was about 24 millimolar. Effects on proton pumping at this concentration of fluoride could be attributed to an inhibition of chloride movement which serves to dissipate the vesicle membrane potential. Valinomycin could partially restore ATPase activity in sealed vesicles which were inhibited by fluoride and this restoration occurred with a reduction in the membrane potential. Fluoride demonstrated a competitive interaction with chloride-stimulation of proton transport and inhibited the uptake of radioactive chloride into sealed vesicles. When the vesicles were allowed to develop a pH gradient in the absence of KCl, and KCl was subsequently added, fluoride reduced enhancement of the existing pH gradient by KCl. The results are consistent with a chloride carrier that is inhibited by fluoride.     

Adenosine triphosphatases associated with bovine brain microtubules. II. Properties of ATPases I and II

The catalytic properties of two ATPases which had been purified from bovine brain microtubules (Tominaga, S. & Kaziro, Y. (1983) J. Biochem. 93, 1085-1092) were studied. ATPase I, which had a molecular weight of 33,000, required the presence of 1.0 microM tubulin, 0.2 mM Mg2+, and 10 mM Ca2+ for maximal activity. The activation of ATPase I by tubulin was specific to the native form of tubulin, which could not be replaced by F-actin or tubulin denatured either by heat or more mildly by dialysis in the absence of glycerol. ATPase I was not specific to ATP, and GTP, and to a lesser extent, UTP and CTP were also hydrolyzed. Km for ATP of ATPase I was about 0.04 mM. ATPase I was inhibited by 5 mM Mg2+, 0.04 M K+, 10(-3) M vanadate, 10 mM N-ethylmaleimide, or 20% (v/v) glycerol. ATPase II, which was associated with membrane vesicles, required the presence of 0.2-2.0 mM Mg2+ and 20 mM KCl for activity. Tubulin stimulated the reaction of ATPase II only partially, and the addition of Ca2+ was rather inhibitory. ATPase II was specific to ATP with a Km value of 0.14 mM. It was inhibited by 1.6 mM N-ethylmaleimide and 20% (v/v) glycerol, but was not very sensitive to vanadate. Instead, ATPase II was inhibited by trifluoperazine, chlorpromazine, and nicardipin at 10(-3) M.     

Activation by lithium ions of the inside sodium sites in (Na+ + K+)-ATPase.

1. Purified pig kidney ATPase was incubated in 30--160 mM Tris-HCl with various monovalent cations. 130 mM LiCl stimulated a ouabain-sensitive ATP hydrolysis (about 5% of the maximal (Na+ + K) activity), whereas 160 mM Tris-HCl did not stimulate hydrolysis. Similar results were obtained with human red blood cell broken membranes. 2. In the absence of Na+ and with 130 mM LiCl, the ATPase activity as a function of KCl concentration showed an initial slight inhibition (50 micrometer KCl) followed by an activation (maximal at 0.2 mM KCl) and a further inhibition, which was total at mM KCl. In the absence of LiCl, the rate of hydrolysis was not affected by any of the KCl concentrations investigated. 3. The lithium-activation curve for ATPase activity in the absence of both Na+ and K+ had sigmoid characteristics. It also showed a marked dependence on the total LiCl + Tris-HCl concentration, being inhibited at high concentrations. This inhibition was more noticeable at low LiCl concentrations. 4. In the absence of Na+, 130 mM Li+ showed promoted phosphorylation of ATPase from 1 to 3 mM ATP in the presence of Mg2+. In enzyme treated with N-ethylmaleimide, the levels of phosphorylation in Li+-containing solutions, amounted to 40% of those in Na+- and up to 7 times of those in K+-containing solutions. 5. The total (Na+ + K+)-ATPase activity was markedly inhibited at high buffer concentrations (Tris-HCl, Imidazole-HCl and tetramethylammonium-HEPES gave similar results) in cases when either the concentration of Na+ or K+ (or both) was below saturation. On the other hand, the maximal (Na+ + K+)-ATPase activity was not affected (or very slightly) by the buffer concentration. 6. Under standard conditions (Tris-HCl + NaCl = 160 mM) the Na+-activation curve of Na+-ATPase had a steep rise between 0 and 2.5 mM, a fall between 2.5 and 20 mM and a further increase between 20 and 130 mM. With 30 mM Tris-HCl, the curve rose more steeply, inhibition was noticeable at 2.5 mM Na+ and was completed at 5 mM Na+. With Tris-HCl + NaCl = 280 mM, the amount of activation decreased and inhibition at intermediate Na+ concentrations was not detected.     

Specific anion effects on ATPase activity, calmodulin sensitivity, and solubilization of dynein ATPases

The basal ATPase activity of 30S dynein, whether obtained by extraction of ciliary axonemes with a high (0.5 M NaCl) or low (1 mM Tris-0.1 mM EDTA) ionic strength buffer is increased by NaCl, NaNO3, and Na acetate, with NaNO3 causing the largest increase. The calmodulin-activated ATPase activity of 30S dynein is also increased by addition of NaCl, NaNO3, or Na acetate, but the effects are less pronounced than on basal activity, so that the calmodulin activation ratio (CAR) decreases to 1.0 as salt concentration increases to 0.2 M. These salts also reduce the CAR of 14S dynein ATPase to 1.0 but by strongly inhibiting the calmodulin-activated ATPase activity and only slightly inhibiting the basal activity. Sodium fluoride differs both quantitatively and qualitatively from the other three salts studied. It inhibits the ATPase activity of both 14S and 30S dyneins at concentrations below 5 mM and, by a stronger inhibition of the calmodulin-activated ATPase activities, reduces the CAR to 1.0. Na acetate does not inhibit axonemal ATPase, nor does it interfere with the drop in turbidity caused by ATP and extracts very little protein from the axonemes. NaCl and, especially, NaNO3, cause a slow decrease in A350 of an axonemal suspension and an inhibition of the turbidity response to ATP. NaF, at concentrations comparable to those that inhibit the ATPase activities of the solubilized dyneins, also inhibits axonemal ATPase activity and the turbidity response. Pretreatment of demembranated axonemes with a buffer containing 0.25 M sodium acetate for 5 min followed by extraction for 5 min with a buffer containing 0.5 M NaCl and resolution of the extracted dynein on a sucrose density gradient generally yields a 30S dynein that is activated by calmodulin in a heterogeneous manner, ie, the "light" 30S dynein ATPase fractions are more activated than the "heavy" 30S dynein fractions. These results demonstrate specific anion effects on the basal and calmodulin-activated dynein ATPase activities, on the extractability of proteins from the axoneme, and on the turbidity response of demembranated axonemes to ATP. They also provide a method that frequently yields 30S dynein fractions with ATPase activities that are activated over twofold by added calmodulin.     

Correlation between the inhibition of the acto-heavy meromyosin ATPase and the binding of tropomyosin to F-actin: effects of Mg2+, KCl, troponin I, and troponin C.

When stoichiometric amounts of tropomyosin (TM) are bound to F-actin in the presence of 2 mM ATP, the MG2+-activated acto-heavy meromyosin (HMM) ATPase is inhibited by about 60% in 5 mM MgCl2-30 mM KCl. If the concentration of MgCl2 is reduced to 1 mM, the inhibition disappears because TM no longer binds to F-actin. Increasing the concentration of KCl to 100 mM restores both the binding and the inhibition. Thus, the binding of TM alone to F-actin causes significant inhibition of the ATPase provided that the HMM is saturated with ATP. (When the HMM is not saturated, TM activates the ATPase). When TM alone can bind stoichiometrically to F-actin, addition of troponin I (TN-I) increases the inhibition from 60% to about 85%, but the TM binding to F-actin is not affected. Under conditions such that TM alone neither inhibits the acto-HMM ATPase nor binds to F-actin, the inhibition caused by TN-I plus TM still approaches 100%. Direct binding studies under these conditions show that TN-I induces binding between TM and F-actin. A dual role for TN-I is proposed: first, TN-I can induce TM to bind to F-actin, causing inhibition of the ATPase; and second, TN-I can itself enhance the inhibition of the ATPase in a cooperative manner. The addition of TN-C in the absence of CA2+ has only a limited effect on the first role, but seems to be able to block completely the cooperative inhibition caused by TN-I such that the residual inhibition is a function only of the TM which remains bound.     

Effects of ATP analogs on the proton pumping by the vacuolar H+-ATPase from maize roots

Understanding the regulatory properties of the activities of the V-type adenosine triphosphatase (ATPase) on tonoplast membranes is important in determining the mechanisms by which this enzyme controls cytoplasmic and vacuolar pH. The possible existence of a regulatory site for adenine nucleotides was examined by comparing the effects of ADP, adenylylimidodiphosphate (AMP-PNP) and 3'- o -(4-benzoyl) benzoyladenine 5'-triphosphate (BzATP) to those of the 2',3'-dialdehyde derivative of AMP (oAMP) and ATP by using highly purified tonoplast vesicles from maize ( Zea mays L. cv. FRB 73) roots. The addition of either AMP-PNP or BzATP reversibly inhibited the initial rate of proton transport catalyzed by the H⁺-ATPase in a concentration-dependent manner. Less than 20 μ M AMP-PNP or 50 μ M BzATP was sufficient to inhibit half the initial rate of proton transport in the presence of 2 m M ATP and an excess of Mg. Both analogs increased the K_m for ATP and reduced the maximum enzyme velocity. The presence of ADP also inhibited proton transport. The characteristics of ADP-induced inhibition were similar to those of BzATP and AMP-PNP. The addition of the periodated derivative of AMP (oAMP) irreversibly inhibited the ATPase in a concentration and time-dependent manner similar to that reported previously (Chow et al. 1992, Plant Physiology 98: 44–52). Irreversible inhibition by oAMP reduced the maximum velocity of the tonoplast ATPase and was prevented by the addition of ATP. The presence of ADP, AMP-PNP or BzATP had no effect on irreversible inhibition by oAMP. The effects of ADP, AMP-PNP and BzATP on the kinetics of ATP utilization and the lack of protection against inhibition by oAMP argue in favor of at least two types of nucleotide binding sites on the V-type ATPase from maize root tonoplast membranes.     

Activation of sea urchin sperm flagellar dynein ATPase activity by salt-extracted axonemes

When 21S dynein ATPase [EC 3.6.1.3] from sea urchin sperm flagellar axonemes was mixed with the salt-extracted axonemes, the ATPase activity was much higher than the sum of ATPase activities in the two fractions, as reported previously (Gibbons, I.R. & Fronk, E. (1979) J. Biol. Chem. 254, 187-196). This high ATPase level was for the first time demonstrated to be due to the activation of the 21S dynein ATPase activity by the axonemes. The mode of the activation was studied to get an insight into the mechanism of dynein-microtubule interaction. The salt-extracted axonemes caused a 7- to 8-fold activation of the 21S dynein ATPase activity at an axoneme : dynein weight ratio of about 14 : 1. The activation was maximal at a low ionic strength (no KCl) at pH 7.9-8.3. Under these conditions, 21S dynein rebound to the salt-extracted axonemes. The maximal binding ratio of 21S dynein to the axonemes was the same as that observed in the maximal activation of 21S dynein ATPase. The sliding between the outer doublet microtubules in the trypsin-treated 21S dynein-rebound axonemes took place upon the addition of 0.05-0.1 mM ATP in the absence of KCl. During the sliding, the rate of ATP hydrolysis was at the same level as that of the 21S dynein activated by the salt-extracted axonemes. However, it decreased to the level of 21S dynein alone after the sliding. These results suggested that an interaction of the axoneme-rebound 21S dynein with B-subfibers of the adjacent outer doublet microtubules in the axoneme causes the activation of the ATPase activity.     

Kinesin's IAK tail domain inhibits initial microtubule-stimulated ADP release

Kinesin undergoes a global folding conformational change from an extended active conformation at high ionic concentrations to a compact inhibited conformation at physiological ionic concentrations. Here we show that much of the observed ATPase activity of folded kinesin is due to contamination with proteolysis fragments that can still fold, but retain an activated ATPase function. In contrast, kinesin that contains an intact IAK-homology region exhibits pronounced inhibition of its ATPase activity (140-fold in 50 mM KCl) and weak net affinity for microtubules in the presence of ATP, resulting from selective inhibition of the release of ADP upon initial interaction with a microtubule. Subsequent processive cycling is only partially inhibited. Fusion proteins containing residues 883-937 of the kinesin alpha-chain bind tightly to microtubules; exposure of this microtubule-binding site in proteolysed species is probably responsible for their activated ATPase activities at low microtubule concentrations.