Properties of an antiserum against native dynein 1 from sea urchin sperm flagella

Effects of an antiserum against native dynein 1 from sperm flagella of the sea urchin Strongylocentrotus purpuratus were compared with effects of an antiserum previously obtained against an ATPase-active tryptic fragment (fragment 1A) of dynein 1 from sperm flagella of the sea urchin, Anthocidaris crassispina. Both antisera precipitate dynein 1 and do not precipitate dynein 2. Only the fragment 1A antiserum precipitates fragment 1A and produces a measurable inhibition of dynein 1 ATPase activity. Both antisera inhibit the movement and the movement-coupled ATP dephosphorylation of reactivated spermatozoa. The inhibition of movement by the antiserum against dynein 1 is much less than by the antiserum against fragment 1A, suggesting that a specific interference with the active ATPase site may be required for effective inhibition of movement. Both antisera reduce the bend angle as well as the beat frequency of reactivated S. purpuratus spermatozoa, suggesting that the bend angle may depend on the activity of the dynein arms which generate active sliding.     

Orientation of membrane vesicles fromEscherichia coli prepared by different procedures

Summary The orientation of membrane vesicles prepared fromEscherichia coli by either French press, sonication or ethylenediamine tetraacetate (EDTA)-lysozyme was examined. The following procedures were used to determine orientation: (1) accessibility of the impermeable ferricyanide ion to the respiratory chain; (2) inhibition of membranal ATPase by specific antiserum; (3) binding of ATPase to the membrane. Data with spheroplasts indicated that ATPase, ATPase binding sites and ferricyanide reductase activities were localized on the inner part of the cytoplasmic membrane. Thus, there was no demonstrable NADH-ferricyanide reductase activity, low ATPase activity, no inhibition of ATPase by antiserum and no binding of purified ATPase by spheroplasts. In the case of membrane vesicles prepared by French press or sonication, the ATPase activity, the ATPase binding site and the site where ferricyanide takes electrons from the respiratory chain all appeared to be on the outside of the vesicles, suggesting that they are inverted. In the case of EDTA-lysozyme vesicles, which are widely used for transport studies, about half of the ATPase binding sites and ferricyanide reactive sites were exposed to the outside. Sixty percent of the ATPase activity was sensitive to antiserum. The two most probable explanations for these data are: (1) partial inversion of EDTA-lysozyme vesicles in the course of preparation; (2) movement of marker enzymes within the membrane vesicles during their isolation.     

The effect of antidynein 1 serum on the movement of reactivated sea urchin sperm

Rabbit antiserum prepared against an ATPase-containing tryptic fragment of dynein by Ogawa and Mohri (J. Biol. Chem. 250: 6476-6483) specifically inhibited the ATPase activity of dynein 1 and not that of dynein 2. Varying amounts of this antidynein 1 serum were added to demembranated sperm while they were swimming in reactivating solution containing 1 mM ATP. The sperm continued to form regularly propagated flagellar bending waves, but the beat frequency decreased gradually with time, the greater part of the change occurring in the first 15 min. The beat frequency after 1 h was a function of the amount of antiserum used, and could be as low as 1 Hz. The waveforms of the treated sperm resembled those of normal reactivated sperm except that the bend angles of both the principal and reverse bends were larger in the proximal portion of flagellum. The ATPase activity and corresponding beat frequency of sperm which had been pretreated with varying amounts of antidynein 1 serum for 15 min at 0 degrees C and then diluted were both decreased as a function of the amount of antiserum added, the ATPase activity of homogenized, nonmotile sperm also decreased upon pretreatment with antiserum, but the percentage decrease was less than for motile sperm. For moderate to low concentrations of antiserum, the rates of reaction with motile and with rigor sperm were almost identical. The overall results suggest that antidynein 1 inhibits the functioning of the dynein arms, probably by blocking the ATPase sites of the dynein 1.     

Subunit specific antisera to the Escherichia coli ATP synthase: effects on ATPase activity, energy transduction, and enzyme assembly

We obtained antisera to each of the five subunits (α, β, γ, δ, and ?) of the F₁ portion of the proton-translocating ATPase from Escherichia coli (ECF₁). No cross-reaction between the antiserum to a given subunit and any of the other four subunits was observed by Ouchterlony immunodiffusion. The α antiserum reacted only with the denatured α chain. Antibodies to either subunit β or subunit γ inhibited the ATPase activity of the enzyme. The ATPase activity of the holoenzyme in the everted membrane vesicles was just as sensitive as purified ECF₁ to inhibition by the anti-β or anti-γ serum. A prolonged digestion of ECF₁ with trypsin removed intact γ from ECF₁, but did not alter the sensitivity of the ATPase to inhibition by the anti-γ serum. Proteolytic fragments were isolated from the trypsinized enzyme. They gave an immunoprecipitation band with the anti-γ serum, but none of the other subunit antisera. The antiδ serum detached ECF₁ from everted membrane vesicles and completely blocked both the ATP- and respiration-dependent pyridine nucleotide transhydrogenase, an energylinked membrane function. The δ antiserum had no effect on the ATPase activity of the ECF₁. The e antiserum stimulated the ATPase activity of purified ECF₁ as shown previously (P. P. Laget and J. B. Smith, Arch. Biochem. Biophys.197, 83, 1979), but strongly inhibited the holoenzyme in membrane vesicles. The α antiserum completely blocked the ATP-driven transhydrogenase. The same antiserum maximally inhibited the respiratory chain-driven reaction by only 35%. These observations indicate that the antiserum selectively affected energy transduction mediated by the ATPase. The protonmotive force generated by substrate oxidation was probably not dissipated by the ? antiserum. Adsorbing the δ or ? antiserum with everted membrane vesicles selectively removed those antibodies that reacted with membrane-bound ATPase. The adsorbed sera still reacted strongly with purified ECF₁, and prevented it from restoring ATP-dependent proton translocation in ECF₁-depleted vesicles. Therefore, it appears that more of the δ and the ? subunit is exposed in the purified ECF₁ molecule than in the membrane-bound enzyme.     

Immunological studies on the beef heart natural ATPase inhibitor: localization of an antigenic determinant in the inhibitor molecule

Antibodies were raised against the beef heart mitochondrial ATPase inhibitor. This antiserum prevented the ability of the ATPase inhibitor to inhibit the F1 ATPase activity. Peptide fragments obtained by enzymatic cleavage of the inhibitor protein were tested by immunoblotting or ELISA for their response to the anti-inhibitor antiserum. An antigenic determinant was located in the sequence spanning His 48 to Lys 58 of the inhibitor molecule.     

Inhibition of Ca2+ uptake into fragmented sarcoplasmic reticulum by antibodies against purified Ca2+, Mg2+-dependent ATPase.

Rabbit antiserum was prepared against a partially purified Ca2+, Mg2+-dependent ATPase [EC 3.6.1.3] of the SR isolated from chicken skeletal muscle. The gamma-globulin fraction of antiserum contained antibodies which combined with the purified ATPase and the SR vesicles. Binding of the antibodies strongly inhibited active transport of Ca2+ ions into the SR, but not passive leakage of Ca2+ ions from the SR. The antibodies scarcely affected the ATPase activity.     

Mechanochemical coupling in eukaryotic flagella

Quantitative analyses of ATP hydrolysis coupled to movement of eukaryotic flagella is important for understanding the relationship between ATP hydrolysis and movement. The difference in ATPase activity between intact motile axonemes (that is the cytoskeletal core of flagella) and homogenized or immotile axonemes has been assumed to be coupled to movement. However, recent findings on rates of steps in the dynein ATPase cycle and the effect of interaction with microtubules on those steps call for reassessment of movement-coupled ATPase. From these studies, it is clear that dynein ATPase activity is not as tightly coupled to interaction with microtubules as myosin ATPase activity is coupled to interaction with actin. The method by which axonemal movement is inhibited will critically affect the interpretation of difference in ATPase activity. If the homogenization or similar methods uncouple dynein, the difference in ATPase activity is not a useful measurement. Greater understanding of the relationship between dynein kinetics and axonemal movement may be obtained by use of conditions and substrates with known effects at specific steps in the dynein mechanochemical cycle and quantitating their effects on movement.     

Properties of the ATPase activity associated with peroxisome-enriched fractions from rat liver: comparison with mitochondrial F1F0-ATPase

Highly purified peroxisomal fractions from rat liver contain ATPase activity (18.8 +/- 0.1 nmol/min per mg, n = 6). This activity is about 2% of that found in purified mitochondrial fractions. Measurement of marker enzyme activities and immunoblotting of the peroxisomal fraction with an antiserum raised against the beta-subunit of mitochondrial ATPase indicates that the ATPase activity in the peroxisomal fractions can not be ascribed to contamination with mitochondria or other subcellular organelles. From the sensitivity of the ATPase present in the peroxisomal fraction towards a variety of ATPase inhibitors, we conclude that it displays both V-type and F-type features and is distinguishable from both the mitochondrial F1F0-ATPase and the lysosomal V-type ATPase.     

Immunological properties of antibodies against Mg(2+)-ATPase from Acholeplasma laidlawii membranes.

In the present study, antibodies were raised against the Mg(2+)-ATPase and the immunological relationships between the enzyme and other ATPase from a variety of biological membranes were determined. The anti Mg(2+)-ATPase antiserum inhibited 85% of the enzyme activity from A. laidlawii membranes. We demonstrate a specific selectivity of Mg(2+)-ATPase antiserum for antigenic determinants of the A. laidlawii membranes. Immunoblot studies of A. laidlawii membrane peptides indicated labeling of five bands, 66KD, 49KD, 34KD, 26KD and 13KD, corresponding to five subunits of the ATPase in A. laidlawii membranes.     

Solubilization of a divalent cation dependent ATPase from dog heart sarcolemma

Heart sarcolemma has been shown to contain an ATPase hydrolizing system which is activated by millimolar concentrations of divalent cations such as Ca²⁺ or Mg²⁺. Although Ca²⁺-dependent ATPase is released upon treating sarcolemma with trypsin, a considerable amount of the divalent cation dependent ATPase activity was retained in the membrane. This divalent cation dependent ATPase was solubilized by sonication of the trypsin-treated dog heart sarcolemma with 1% Triton X-100. The solubilized enzyme was subjected to column chromatography on a Sepharose-6B column, followed by ion-exchange chromatography on a DEAE cellulose column. The enzyme preparation was found to be rather labile and thus the purity of the sample could not be accurately assessed. The solubilized ATPase preparations did not show any cross-reactivity with dog heart myosin antiserum or with Na⁺ + K⁺ ATPase antiserum. The enzyme was found to be insensitive to inhibitors such as ouabain, verapamil, oligomycin and vanadate. The enzyme preparation did not exhibit any Ca²⁺-stimulated Mg²⁺ dependent ATPase activity. Furthermore, the low affinity of the enzyme for Ca^2– (Ka = 0.3 mM) rules out the possibility of its involvement in the Ca²⁺ pump mechanism located in the plasma membrane of the cardiac cell.     

Properties of the ATPase activity associated with peroxisome-enriched fractions from rat liver: comparison with mitochondrial F1F0-ATPase

Highly purified peroxisomal fractions from rat liver contain ATPase activity (18.8 ± 0.1 nmol/min per mg, n = 6). This activity is about 2% of that found in purified mitochondrial fractions. Measurement of marker enzyme activities and immunoblotting of the peroxisomal fraction with an antiserum raised against the β-subunit of mitochondrial ATPase indicates that the ATPase activity in the peroxisomal fractions can not be ascribed to contamination with mitochondria or other subcellular organelles. From the sensitivity of the ATPase present in the peroxisomal fraction towards a variety of ATPase inhibitors, we conclude that it displays both V-type and F-type features and is distinguishable from both the mitochondrial F₁F₀-ATPase and the lysosomal V-type ATPase.     

Purirication and characterization of two forms of DNA-dependent ATPase from yeast

Two forms of DNA-dependent ATPase activity have been purified from yeast extracts. The two ATPases differ from each other in chromatographic properties and heat stabilities but have similar molecular weight and reaction properties. DNA-dependent ATPase I has been purified to near homogeneity, while DNA-dependent ATPase II is only partially purified. The two ATPases from yeast are related structurally since antiserum raised against ATPase I cross-react against ATPase II. Yeast DNA-dependent ATPase I has a native molecular weight of about 68,000 and consists of a single polypeptide chain. ATPase II also sediments on sucrose gradient as a 68,000-dalton protein. Both yeast DNA-dependent ATPases hydrolyze dNTPs and rNTPs to their corresponding nucleoside diphosphates and orthophosphate, but dATP and ATP are preferred substrates. In addition to nucleoside triphosphates, both enzymes require a divalent cation and a polynucleotide for activity. Single-stranded DNAs and polydeoxynucleotides are the most effective co-substrates for yeast DNA-dependent ATPases. Addition of yeast DNA-dependent ATPases to DNA synthesis system containing yeast DNA polymerases does not significantly stimulate the rate of DNA synthesis.     

Energy-dependent changes in the conformation of the epsilon subunit of the chloroplast ATP synthase

Rabbit antiserum raised against the isolated native epsilon subunit of the chloroplast coupling factor 1 activated the ATPase activity of coupling factor 1 in solution by removing the epsilon subunit. Incubation of thylakoid membranes with the antiserum in the dark had no effect on photophosphorylation or on the dithiothreitol-induced Mg2+-ATPase activity. Incubation with the antiserum during illumination, however, strongly inhibited both activities and caused the membranes to become leaky to protons. The results indicate that the formation of a proton gradient across the thylakoid membrane induces a change in conformation of the epsilon subunit of the ATP synthase such that it becomes susceptible to attack and removal by the antibodies. This change may be a part of the mechanism that results in energy-dependent activation of the ATP synthase.     

Glutathione S‐transferase π complexes with and stimulates Na+,K+‐ATPase

Glutathione S‐transferase (GST) was found to complex with the Na⁺,K⁺‐ATPase as shown by binding assay using quartz crystal microbalance. The complexation was obstructed by the addition of antiserum to the α‐subunit of the Na⁺,K⁺‐ATPase, suggesting the specificity of complexation between GST and the Na⁺,K⁺‐ATPase. Co‐immunoprecipitation experiments, using the anti‐α‐subunit antiserum to precipitate the GST‐Na⁺,K⁺‐ATPase complex and then using antibodies specific to an isoform of GST to identify the co‐precipitated proteins, revealed that GSTπ was complexed with the Na⁺,K⁺‐ATPase. GST stimulated the Na⁺,K⁺‐ATPase activity up to 1.4‐fold. The level of stimulation exhibited a saturable dose–response relationship with the amount of GST added, although the level of stimulation varied depending on the content of GSTπ in the lots of GST received from supplier. The stimulation was also obtained when recombinant GSTπ was used, confirming the results. When GST was treated with reduced glutathione, GST activity was greatly stimulated, whereas the level of stimulation of the Na⁺,K⁺‐ATPase activity was similar to that when untreated GST was added. When GST was treated with H₂O₂, GST activity was greatly diminished while the stimulation of the Na⁺,K⁺‐ATPase activity was preserved. The results suggest that GSTπ complexes with the Na⁺,K⁺‐ATPase and stimulates the latter independent of its GST activity. Copyright © 2012 John Wiley & Sons, Ltd.     

Amino acid composition of dynein and comparison with myosin.

A comparison is made between dynein [flagellar ATPase; EC 3.6.1.3], purified from sea urchin sperm flagella, and muscle myosin. The amino acid composition of dynein was found to be statistically different from that of myosin. The same was true of their tryptic fragments retaining ATPase activity, i.e., Fragment A of dynein and heavy meromyosin. At low ionic strength, no superprecipitation took place when ATP was added to a mixture of dynein and actin, and stimulation of the Mg2+-ATPase activity of dynein remained below 50% even when a one-hundred-fold excess of actin was present. No viscosity drop was caused by adding ATP to a solution containing dynein and actin. Anti-myosin antiserum did not react with dynein, while anti-Fragment A antiserum formed no precipit-n line against myosin. Furthermore, the amount of dynein that combined with F-actin was less than one-fifth of the amount of dynein that fully combined with microtubules. These results are consistent with the dissimilarity in enzymatic and other physiocochemical properties of these two proteins.     

Localization and distribution of Microccus lysodeikticus membrane ATPase determined by ferritin labeling

Antiserum to Ca²⁺-activated ATP phosphohydrolase (EC 3.6.1.3) isolated and purified from membranes of Micrococcus lysodeikicus was prepared in rabbits and guinea pigs. The γ-globulin fractions of these antisera reacted with and inhibited ATPase activity in isolated membranes but failed to absorb to intact protoplasts or purified mesosome fractions. ATPase activity was not detectable in the purified mesosomal preparations and trypsin treatment and sonication failed to release any activity. Ferritin conjugated to the γ-globulin fractions of the antiserum reacted with the ATPase particles on the membrane as visualized in negatively stained preparations examined in the electron microscope. Labeled membranes showed a distribution of ferritin very similar to the patterns observed for ATPase particles on untreated membranes. No significant labeling occurred when the ferritin conjugate was reacted with intact protoplasts or mesosome fractions. Thin sections of ferritin-labeled membranes established the asymmetric disposition of the ATPase, with the conjugate visible on only one side of the membrane. The results indicate that the ATPase protein occurs on the inner face of the membrane. All labeling experiments were verified immunologically. When ferritin-labeled membranes were subjected to the selective release procedure used in releasing the ATPase-like particles from the membranes, a complex of ferritin-conjugate associated with the ATPase particles was released. The selective release of ferritin-antibody-enzyme complexes from the membrane opens up a new way of studying the molecular architecture of cell membranes.     

NaCI stress enhances proteolytic turnover of the tonoplast H+-ATPase of Citrus sinensis: appearance of a 35 kDa fragment of subunit A still exhibiting ATP-hydrolysis activity?

Salinity stress caused a decrease in the relative amount of the subunits of the hydrophilic head of the tonoplast H±ATPase from leaf cells of Valencia orange [Citrus sinensis (L.) Osbeck]. In parallel, a 35 kDa polypeptide appeared in the tonoplast, which could be separated from the tono-plast H±ATPase and cross-reacted with an antiserum against the catalytic subunit A of the tonoplast H±ATPase. This polypeptide seems to show ATP hydrolysis activity and is considered to be a product of proteolytic breakdown of subunit A. This indicates an increased turnover of the tonoplast H±ATPase of Valencia orange under salinity stress.     

Noradrenergic β-Adrenoceptor-Mediated Intracellular Molecular Mechanism of Na–K ATPase Subunit Expression in C6 Cells

Rapid eye movement sleep deprivation-associated elevated noradrenaline increases and decreases neuronal and glial Na–K ATPase activity, respectively. In this study, using C6 cell-line as a model, we investigated the possible intracellular molecular mechanism of noradrenaline-induced decreased glial Na–K ATPase activity. The cells were treated with noradrenaline in the presence or absence of adrenoceptor antagonists, modulators of extra- and intracellular Ca⁺⁺ and modulators of intracellular signalling pathways. We observed that noradrenaline acting on β-adrenoceptor decreased Na–K ATPase activity and mRNA expression of the catalytic α2-Na–K ATPase subunit in the C6 cells. Further, cAMP and protein kinase-A mediated release of intracellular Ca⁺⁺ played a critical role in such decreased α2-Na–K ATPase expression. In contrast, noradrenaline acting on β-adrenoceptor up-regulated the expression of regulatory β2-Na–K ATPase subunit, which although was cAMP and Ca⁺⁺ dependent, was independent of protein kinase-A and protein kinase-C. Combining these with previous findings (including ours) we have proposed a working model for noradrenaline-induced suppression of glial Na–K ATPase activity and alteration in its subunit expression. The findings help understanding noradrenaline-associated maintenance of brain excitability during health and altered states, particularly in relation to rapid eye movement sleep and its deprivation when the noradrenaline level is naturally altered.     

Studies of soluble rat liver mitochondrial acid ATPases: II. Structural and immunological properties of ATPase 1

We described previously the existence of a soluble ATPase activity in rat liver mitochondria [1]. The purification and catalytic properties have been described [2]. In a continuation of these experiments, we have studied the immunologic and structural properties of one molecular form of this enzyme: ATPase I.We have prepared the antiserum anti-ATPase I and demonstrated the purity of our enzyme preparation by immunodiffusion and immunoelectrophoresis. An immunohistochemical method also confirmed the localization of ATPase I in the soluble fraction of mitochondria.The molecular weight of ATPase I was measured by G 100 Sephadex gel filtration and was found to be 18,400; electrophoresis on polyacrylamide gels gave a value of 18,600. The pHi of ATPase I was found to be 7,2.Amino acid analysis showed high amounts of aspartic acid, glutamic acid, serine and glycine. The molecular weight calculated from the total amino acid residues was found to be 17,000.Alanine is the NH2 terminal amino acid.The peptide maps obtained after degrading ATPase I with cyanogen bromide or trypsin are in accordance with the methionine, lysine and arginine residues we found in the ATPase I molecule.ATPase I does not appear to be a glycoprotein.     

Immunological dissimilarity in protein component (dynein 1) between outer and inner arms within sea urchin sperm axonemes

The 0.5 M KCl-treatment solubilizes the outer arms from sea urchin sperm axonemes. Approximately 30 percent of A-polypeptide, corresponding to dynein 1 in SDS- polyacrylamide gel, was solubilized by this treatment (as SEA-dynein 1). Electron microscopic observation indicated that the extracted axonemes lacked the outer arms in various degrees. The DEA-dynein 1 was that the extracted axonemes lacked the outer arms in various degrees. The SEA-dyenin 1 was purified and an antiserum against it was prepared in rabbits. The specificity of antiserum to dynein 1 was determined by immunoelectrophoresis and ouchterlony’s double-diffusion test. The anti-dynein 1 serum inhibited ATPase activity of purified SEA-dynein 1 by 95 percent. By the indirect peroxidase-conjugated antibody method, the loci of SEA-dynein 1 within the intact, salt- extracted and mechanically disrupted axonemes were determined to be the outer arms: deposition of electron-dense materials which represents their localization was detected at the distal ends of the outer arms, in the case of intact axonemes. The 5-6 cross- bridge was hardly decorated. No decoration was seen in the salt-extracted axonemes lacking all the outer arms. In disrupted axonemes, which consist of single to several peripheral doublets, electron-dense materials were deposited only on the outer arms. Approximately 73 percent of axonemal ATPase activity sensitive to antiserum was solubilized by repeated salt-extractions. One-half of A-polypeptide (SEA-dynein 1 located at the outer arms) was contained in the pooled extracts. The extracted axonemes contained another half of A-polypeptide (SUA-dynein 1 supposed to locate at the inner arms) and retained 31 percent of axonemal ATPase activity that was almost resistant to antiserum. Solubilized SUA-dynein 1 was immunologically the same as SEA-dynein 1. This result indicates that in situ SUA-dynein 1 did not receive anti-dynein 1 antibodies, coinciding with the result obtained for salt-extracted axonemes lacking all the outer arms by the enzyme-antibody method mentioned above. These observations suggest that immunological dissimilarity in dynein 1 between outer and inner arms but do not tell us that the inner arms do not contain dynein 1.