Location of a dicyclohexylcarbodiimide-reactive glutamate residue in the Neurospora crassa plasma membrane H+-ATPase

The proton pump (H+-ATPase) found in the plasma membrane of the fungus Neurospora crassa is inactivated by dicyclohexylcarbodiimide (DCCD). Kinetic and labeling experiments have suggested that inactivation at 0 degrees C results from the covalent attachment of DCCD to a single site in the Mr = 100,000 catalytic subunit (Sussman, M. R., and Slayman, C. W. (1983) J. Biol. Chem. 258, 1839-1843). In the present study, when [14C]DCCD-labeled enzyme was treated with the cleavage reagent, N-bromosuccinimide, a single major radioactive peptide fragment migrating at about Mr = 5,300 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis was produced. The fragment was coupled to glass beads and partially sequenced by automated solid-phase Edman degradation at the amino terminus and at an internal tryptic cleavage site. By comparison to the DNA-derived amino acid sequence for the entire Mr = 100,000 polypeptide (Hager, K., and Slayman, C. W. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 7693-7697), the fragment has been identified as arising by cleavage at tyrosine 100 and tryptophan 141. Covalently incorporated [14C]DCCD was released at a position corresponding to glutamate 129. The DCCD-reactive glutamate is located in the middle of the first of eight predicted transmembrane sequences. When the sequence surrounding the DCCD site is compared to that surrounding the DCCD-reactive residue of two other proton pumps, the F0F1-ATPase and cytochrome c oxidase, no homology is apparent apart from an abundance of hydrophobic amino acids.     

Ion Effects on the H+-Translocating Adenosine Triphosphatase and Pyrophosphatase Associated with the Tonoplast of Chora corallina

H⁺-translocating ATPase and pyrophosphatase (PPase) associatedwith the tonoplast of Chara corallina were isolated with theaid of a perfusion technique, and the effects of ions on theiractivities were studied. All the alkali metal cations testedstimulated the ATPase and ATPdependent H⁺ pumping activitiesonly by 10 to 40%. Anions, on the other hand, strongly affectedthe activities. Potassium salts of Cl^- and Br^- stimulated them,while F^- and NO₃^- inhibited them. By contrast, the H⁺-translocatingPPase was insensitive to anions but sensitive to cations. Theorder of cation stimulation was Rb⁺=K⁺>Cs⁺>Na⁺=Li⁺>choline⁺.NO₃^- (50 mil), thought to be a specific inhibitor of the tonoplast-typeH⁺-ATPase, inhibited the ATPdependent H⁺ pumping almost completelybut the ATPase activity by only about 50%. Na⁺ inhibited thePP₁-dependent H⁺ pumping (I_5O=5OmM) in the presence of 50 mMKCl but not the ATP-dependent one. The PPase was more sensitiveto F^- (I₅₀=400µM) than the ATPase. Both the H⁺-ATPaseand the H⁺-PPase required Mg²⁺ for their activities, althoughan excess was inhibitory to both. The different sensitivitiesof the PP₁-dependent and the ATP-dependent H⁺- pumping enzymesto ions correspond to the tonoplast enzymes of higher plantsand may be used as "markers" to distinguish between these enzymesin characean cells (Received October 2, 1987; Accepted May 18, 1988)     

Characterization of the H Translocating Adenosine Triphosphatase and Pyrophosphatase of Vacuolar Membranes Isolated by Means of a Perfusion Technique from Chara corallina

Sealed tonoplast vesicles were isolated from single cells of Chara corallina with the aid of an intracellular perfusion technique in combination with a 3/10% Percoll two step gradient centrifugation. The isolated tonoplast fraction was free from plasmalemma and chloroplasts, and showed no activities of cytochrome c oxidase, and latent IDPase, but had about 10% of the NADH-cytochrome c reductase activity. The vesicles had both ATPase and PPase activities, which could be stimulated in the presence of 10 micromolar gramicidin by 170 and 130%, respectively, demonstrating the existence of sealed vesicles. Furthermore, ATP- and PPi-dependent H⁺ pumping through the membrane into the vesicles was shown. Both ATPase and PPase had pH optima around pH 8.5. At the physiological pH, 7.3, they still had more than 80% of their maximal activities. Ammonium molybdate, azide, and vanadate had no or little effect on the activities of both enzymes or their associated H⁺ pumping activities. N,N′-dicyclohexylcarbodiimide inhibited the ATPase strongly (I₅₀ = 20 micromolar) but the PPase only weakly. The ATPase was also more sensitive to N-ethylmaleimide than the PPase. 4,4′-Stilbenedisulfonic acid affected both enzyme activities and their associated H⁺ pumping activities. This is in contrast to the H⁺-PPase of higher plants which is 4,4′-stilbenedisulfonic acid insensitive.     

Identification and characterization of an {alpha}-mannosidase from Trypanosoma cruzi

In this report we describe the first purification and characterizationof the acid -mannosidase from the human parasite Trypanosomacruzi. The purified enzyme exhibited a native mol. wt of 240000 Da and is apparently composed of four identical subunitsof mol. wt 58 000 Da. Each of the four subunits contains oneN-linked high-mannose-type oligosaccharide. The -mannosidaseexhibited a pH optimum of 3.5 and a pI of 5.9. This low pH optimumand the ability of swainsonine to inhibit its activity suggestthat the -mannosidase is a lysosomal enzyme. Antibodies againstthe T.cruzi enzyme did not react with mammalian lysosomal -mannosidaseand, conversely, antibody against a rat lysosomal -mannosidasedid not react with the T.cruzi enzyme. Thus, the T.cruzi enzymeappears to be distinct from its mammalian counterpart. -mannosidase lysosomal enzyme Trypanosoma cruzi     

Acetic acid esters and permeable weak acids induce active proton extrusion and extension growth of coleoptile segments by lowering the cytoplasmic pH

In Avena coleoptile segments a decrease of cytoplasmic pH activates energy-dependent H⁺ extrusion into the apoplast, thereby triggering extension growth. This sequence of events cannot be inhibited by cycloheximide and is induced by the following conditions and compounds. (i) A short anaerobic treatment of coleoptile segments results in the formation of lactic acid and an intracellular decrease of pH. For a period of 20 min after transfer to normal air, the growth rate is up to six times higher than the rate before anaerobiosis. (ii) Similarly, incubation of segments with CN^– (0.1 mM) in the presence of oxygen causes and accumulation of lactic acid and a fall in cell-sap pH. After removing CN^– a growth burst occurs. (iii) Higher concentrations of permeable acids (10 mM in buffer pH 5.8) induce extension growth. This growth is O₂-dependent and therefore differs from the acid growth, which can be triggered under anaerobic conditions by acid buffers of pH5 via the direct increase of cell-wall plasticity. (iv) A short application of CO₂-saturated buffer (pH 5.8) causes CO₂-induced elongation growth; after a 3-min pulse the growth rate is enhanced for about 15 min. (v) Lipophilic esters of acetic acid or propionic acid, such as naphthylacetate, naphthylpropionate, phenylacetate, benzylacetate induce elongation growth. These compounds, when taken up into the cell, are hydrolized by esterases; the acids released lower the cytoplasmic pH (shown by the pH indicator, fluorescein). The highest esterase activity was found in a microsomal membrane fraction of coleoptiles. While the carboxyester-induced extension growth is completely inhibited under anoxia, the initial acidification of the bathing solution can still be observed. This decrease in external pH is obviously the result of ester hydrolysis, caused by damaged cells, and is not the result of pH changes within the cell-wall compartment. It is suggested that a fast uptake of carboxyesters and the shift in equilibrium caused by their internal hydrolysis leads to a continuous formation of acids which lowers the cytoplasmic pH and activates the ATP-dependent H⁺ extrusion. In most experiments fusicoccin (a diacetic acid ester) acts similarly to naphthylacetate and the other carboxyesters, although quantitative differences exist. Therefore, it is possible that fusicoccin is effective partly on the basis of its ester characteristic. The effects observed are discussed with regard to the very narrow pH optimum of plasma-membrane H⁺-ATPases exhibiting their highest levels of activity at pH 6.5 (Hager and Biber 1984, Z. Naturforsch. C 39, 927–937).Abbreviations CHM cycloheximide - DMO dimethadione (5.5-dimethyl-2,4-oxazolidinedione) - FC fusicoccin - IAA indole-3-acetic acid - Mes 2-(N-morpholino)ethanesulfonic acid - NA (or )-naphthylacetate (acetic acid-1(or-2-)naphthylester) - NAA (or )-naphthaleneacetic acid - PA phenylacetate (acetic acid phenylester)     

Covalent and noncovalent receptor-glucocorticoid complexes preferentially bind to the same regions of the long terminal repeat of murine mammary tumor virus proviral DNA

Dexamethasone 21-mesylate, an irreversible antiglucocorticoid in HTC cells, forms a covalent receptor-steroid complex which can be activated in cell-free systems. The molecular basis of its antiglucocorticoid activity is unknown; it might result from altered DNA sequence preferences and/or affinities of the covalent receptor-steroid complex. To test this hypothesis, the affinities of both covalent receptor-antagonist and noncovalent receptor-agonist complexes for defined DNA sequences were measured in a DNA binding competition assay. This assay requires neither purified complexes nor large quantities of DNA, yet it provides quantitative comparisons of the affinities of different double-stranded DNAs for binding receptor-steroid complexes. In this assay, activated covalent receptor-dexamethasone 21-mesylate complexes in crude cytosol bound to calf thymus DNA and cloned subregions of the long terminal repeat (LTR) of murine mammary tumor virus (MMTV) proviral DNA with approximately the same relative affinities as did noncovalent receptor-dexamethasone complexes. Both types of complex exhibited similar orders of preferential binding to DNA sequences. LTR subregions, as well as the entire LTR, were 2-20 times more potent competitors than calf thymus DNA. Cloned sequences from the 3' terminus of the LTR were more effective competitors than either the entire LTR or comparably sized DNAs from the 5' terminus. The DNA sequences with the greatest affinities for both covalent and noncovalent complexes are located within the region of -221 to -67. These studies support the theory that recognition by regulatory elements of specific DNA sequences upstream of responsive genes is an integral step of hormone action.(ABSTRACT TRUNCATED AT 250 WORDS)