Effect of vanadate, molybdate, and azide on membrane-associated ATPase and soluble phosphatase activities of corn roots

The effects of vanadate, molybdate, and azide on ATP phosphohydrolase (ATPase) and acid phosphatase activities of plasma membrane, mitochondrial, and soluble supernatant fractions from corn (Zea mays L. WF9 × MO17) roots were investigated. Azide (0.1-10 millimolar) was a selective inhibitor of pH 9.0-ATPase activity of the mitochondrial fraction, while molybdate (0.01-1.0 millimolar) was a relatively selective inhibitor of acid phosphatase activity in the supernatant fraction. The pH 6.4-ATPase activity of the plasma membrane fraction was inhibited by vanadate (10-500 micromolar), but vanadate, at similar concentrations, also inhibited acid phosphatase activity. This result was confirmed for oat (Avena sativa L.) root and coleoptile tissues. While vanadate does not appear to be a selective inhibitor, it can be used in combination with molybdate and azide to distinguish the plasma membrane ATPase from mitochondrial ATPase or supernatant acid phosphatase.

Vanadate appeared to be a noncompetitive inhibitor of the plasma membrane ATPase, and its effectiveness was increased by K⁺. K⁺-stimulated ATPase activity was inhibited by 50% at about 21 micromolar vanadate. The rate of K⁺ transport in excised corn root segments was inhibited by 66% by 500 micromolar vanadate.

     

A proton-translocating adenosine triphosphatase is associated with the peroxisomal membrane of yeasts

The association of an ATPase with the yeast peroxisomal membrane was established by both biochemical and cytochemical procedures. Peroxisomes were purified from protoplast homogenates of the methanol-grown yeast Hansenula polymorpha by differential and sucrose gradient centrifugation. Biochemical analysis revealed that ATPase activity was associated with the peroxisomal peak fractions which were identified on the basis of alcohol oxidase and catalase activity. The properties of this ATPase closely resembled those of the mitochondrial ATPase of this yeast. The enzyme was Mg²⁺-dependent, had a pH optimum of approximately 8.5 and was sensitive to N,N-dicyclohexylcarbodiimide (DCCD), oligomycin and azide, but not to vanadate. A major difference was the apparent K _m for ATP which was 4–6 mM for the peroxisomal ATPase compared to 0.6–0.9 mM for the mitochondrial enzyme.Cytochemical experiments indicated that the peroxisomal ATPase was associated with the membranes surrounding these organelles. After incubations with CeCl₃ and ATP specific reaction products were localized on the peroxisomal membrane, both when unfixed isolated peroxisomes or formaldehyde-fixed protoplasts were used. This staining was strictly ATP-dependent; in controls performed i) in the absence of substrate, ii) in the presence of glycerol 2-phosphate instead of ATP, or iii) in the presence of DCCD, staining was invariably absent. Similar staining patterns were observed in subcellular fractions and protoplasts of Candida utilis and Trichosporon cutaneum X4, grown in the presence of ethanol/ethylamine or ethylamine, respectively.Abbreviations MES 2-(N-Morpholino)ethanesulfonic acid - DCCD N,N-dicyclohexylcarbodiimide     

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.     

ATPase and Proton Pumping Activities in Cotyledons and other Phloem-Containing Tissues2Ricinus communis

ATPase activity was investigated in phloem-containing tissuesof Ricinus communis in relation to its proposed role in phloemloading. Cytochemical staining of cotyledons revealed an ATP-hydrolysingactivity on the plasma membrane of the sieve tube/companioncell complex. Microsomal fractions prepared from cotyledonsand main veins contained a Mg²⁺-dependent ATPase activity whichshowed low stimulation by KC1 particularly at pH 6.5. The pHoptimum was at pH 8.5 to 90, although the effect of azide indicatedthe presence of mitochondrial ATPase. At pH 6.5, the cited optimumfor plasma membrane ATPase, the activity showed strong inhibitionby PCMBS, vanadate and DCCD. A high pyrophosphatase activitywas observed at pH 8.5. Acidification of the medium by intactcotyledons was increased by fusicoccin and inhibited by PCMBS,NEM and vanadate. Proton pumping by microsomal vesicles as measuredby quinacrine fluorescence was also inhibited by PCMBS, NEMand vanadate. Sucrose uptake by cotyledon discs showed stronginhibition by PCMBS, NEM and CCCP but was little affected byvanadate. Sucrose uptake varied with the developmental stageof the cotyledons and this correlated with microsomal ATPaseactivity measured at pH 6.5, although the precise cellular originof this activity is not certain. The results are discussed inrelation to the role of ATPase activity and proton pumping inphloem loading. Key words: ATPase, phlocm loading, proton pumping, Ricinus communis, sucrose     

V- AND P-TYPE Ca2+-STIMULATED ATPases IN A CALCIFYING STRAIN OF PLEUROCHRYSIS SP. (HAPTOPHYCEAE)

Coccolithophorids are marine unicellular algae characterized by their ability to carry out controlled, subcellular calcification. The biochemical and kinetic features of membrane-bound Ca²⁺-stimulated ATPases have been examined. Membranes and organelles from axenic cultures of Pleurochrysis sp. (CCMP299) were isolated by means of sucrose density centrifugation. High levels of Ca²⁺-stimulated ATPase were detected in chloroplasts, Golgi apparatus, plasma membrane, and coccolith vesicles. The sensitivity of the enzyme activity in the organelles and membranes was assessed with pharmacologic agents that are known to be specific for the several isoforms of Ca²⁺-stimulated ATPase. The Ca²⁺-stimulated ATPase activity in the Golgi and coccolith vesicle preparations was sensitive to nitrate, thiocyanate, and sodium azide and insensitive to vanadate, cyclopiazonic acid, and thapsigargin. ATP-dependent H⁺ movement, but not ⁴⁵Ca²⁺ transport, across the coccolith vesicle was demonstrated. The Ca²⁺-stimulated ATPase in the plasma membrane preparation was sensitive to vanadate. ATP-dependent, vanadate-sensitive efflux of ⁴⁵Ca²⁺ was demonstrated for microsomal material derived from gradient-isolated plasma membrane. Polypeptides from isolated Golgi and coccolith vesicle preparations cross-reacted to an antibody raised against a subunit of the oat root proton pump, whereas polypeptides from the chloroplast preparations did not cross-react. These findings show that a V-type Ca²⁺-stimulated ATPase is located on the coccolith vesicle membrane and a P-type Ca²⁺-stimulated ATPase is located on the plasma membrane.     

Characterization of reconstituted plasma membrane H+-ATPase from maize roots

Corn ( Zea mays L.) plasma membranes from KI-washed microsomal fractions were further purified by isopycnic sucrose density centrifugation. An examination of separated fractions indicated that vesicles with nitrate-insensitive proton transport copurified with fractions containing vanadate-sensitive ATPase activity. The ATPase in purified plasma membrane was reconstituted into liposomes by a detergent dilution technique using deoxycholate. The reconstituted ATPase exhibited characteristics similar to those of the native enzyme. However, reconstituted preparations showed an enhanced sensitivity to vanadate, a diminished phosphatase activity and a high specific rate of ATP-dependent H⁺-transport. Apparent K_i values of reconstituted and native enzymes with respect to vanadate were 20 and 50 μ M , respectively; the KJ value of the H+-pumping of reconstituted ATPase was 30 μ M. The proton pumping of reconstituted vesicles could be discharged rapidly by p -trifluoromethoxyphenyl hydrazone (FCCP), hexokinase and vanadate. The hydrolysis of Mg-ATP by both native and reconstituted ATPases obeyed simple Michaelis-Menten plots with a K_m between 0.5 and 0.6 m M. The reconstituted ATPase retained a pH profile similar to that of native enzyme with a maximum of pH 6.5.     

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.     

Characterization of the plasma membrane ATPase of Saccharomyces cerevisiae

1. The distribution of ATPase and several marker enzymes was examined after differential and sucrose gradient centrifugation of yeast homogenates. 2. An ATPase activity not sensitive to oligomycin is found exclusively associated with a particulate fraction equilibrating at densities of 1.23-1.25. This particulate material shows the chemical and enzymatic characteristics of the yeast plasma membrane. 3. The pH optimum of the plasma membrane ATPase is 5.6, as compared with 8.5 for the mitochondrial ATPase. In addition to oligomycin, the enzyme is not sensitive to other inhibitors of the mitochondrial ATPase as azide, dicyclohexylcarbodiimide and the mitochondrial ATPase inhibitor protein. It is inhibited by p-chloromercuryphenyl sulfonate, fluoride, quercetin and by the antibiotic Dio-9 but is not affected by ouabain. 4. The plasma membrane ATPase shows a high affinity for ATP (Km = 0.1 mM) and is very specific for this compound, hydrolyzing other nucleotide triphosphates less than 25% as rapidly. No activity was detected with ADP. 5. The enzyme requires a divalent cation for activity and Mg2+ is the most effective. It is not significantly stimulated by K+ or bicarbonate and Ca2+ is inhibitory. 6. The activity cannot be assayed in intact cells unless they are permeabilized with toluene. This suggest that the active site is on the cytoplasmic side of the plasma membrane.     

Identification and properties of an ATPase in vacuolar membranes of Neurospora crassa

Using a vacuolar preparation virtually free of contamination by other organelles, we isolated vacuolar membranes and demonstrated that they contain an ATPase. Sucrose density gradient profiles of vacuolar membranes show a single peak of ATPase activity at a density of 1.11 g/cm3. Comparison of this enzyme with the two well-studied proton-pumping ATPases of Neurospora plasma membranes and mitochondria shows that it is clearly distinct. The vacuolar membrane ATPase is insensitive to the inhibitors oligomycin, azide, and vanadate, but sensitive to N,N'-dicyclohexylcarbodiimide (Ki = 2 microM). It has a pH optimum of 7.5, requires a divalent cation (Mg2+ or Mn2+) for activity, and is remarkably unaffected (+/- 20%) by a number of monovalent cations, anions, and buffers. In its substrate affinity (Km for ATP = 0.2 mM), substrate preference (ATP greater than GTP, ITP greater than UTP greater than CTP), and loss of activity with repeated 1 mM ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid washes, the vacuolar membrane ATPase resembles the F1F0 type of ATPase found in mitochondria and differs from the integral membrane type of ATPase in plasma membranes.     

Selective production of sealed plasma membrane vesicles from red beet (Beta vulgaris L.) storage tissue

Modification of our previous procedure for the isolation of microsomal membrane vesicles from red beet (Beta vulgaris L.) storage tissue allowed the recovery of sealed membrane vesicles displaying proton transport activity sensitive to both nitrate and orthovanadate. In the absence of a high salt concentration in the homogenization medium, contributions of nitrate-sensitive (tonoplast) and vanadate-sensitive (plasma membrane) proton transport were roughly equal. The addition of 0.25 M KCl to the homogenization medium increased the relative amount of nitrate-inhibited proton transport activity while the addition of 0.25 M KI resulted in proton pumping vesicles displaying inhibition by vanadate but stimulation by nitrate. These effects appeared to result from selective sealing of either plasma membrane or tonoplast membrane vesicles during homogenization in the presence of the two salts. Following centrifugation on linear sucrose gradients it was shown that the nitrate-sensitive, proton-transporting vesicles banded at low density and comigrated with nitrate-sensitive ATPase activity while the vanadate-sensitive, proton-transporting vesicles banded at a much higher density and comigrated with vanadate-sensitive ATPase. The properties of the vanadate-sensitive proton pumping vesicles were further characterized in microsomal membrane fractions produced by homogenization in the presence of 0.25 M KI and centrifugation on discontinuous sucrose density gradients. Proton transport was substrate specific for ATP, displayed a sharp pH optimum at 6.5, and was insensitive to azide but inhibited by N'-N-dicyclohexylcarbodiimide, diethylstilbestrol, and fluoride. The Km of proton transport for Mg:ATP was 0.67 mM and the K0.5 for vanadate inhibition was at about 50 microM. These properties are identical to those displayed by the plasma membrane ATPase and confirm a plasma membrane origin for the vesicles.     

Plasma membrane vesicles of opposite sidedness from soybean hypocotyls by preparative free-flow electrophoresis

Absolute orientations (sidedness) of plasma membrane vesicles obtained in highly purified fractions by preparative free-flow electrophoresis and by aqueous two-phase partition were determined based on ATPase latency and morphological criteria. Free-flow electrophoresis yielded two plasma membrane fractions. One, the least electronegative and designated fraction `E,' was pure plasma membrane. The other, more electronegative and designated fraction `C,' was heavily contaminated by various other cellular membranes. Plasma membrane vesicles from both fraction C and fraction E partitioned into the upper phase with aqueous two-phase partitioning. Purified plasma membrane obtained from microsomes by two-phase partition (upper phase) when subjected to free-flow electrophoresis also yielded two fractions, one fraction co-migrated with fraction C and another fraction co-migrated with fraction E. Both fractions exhibited an ATPase activity sensitive to vanadate and insensitive to nitrate and azide. ATPase activity was used as a structure-linked latency marker for the inner membrane surface. Concanavalin A binding (linked to peroxidase) was used as an imposed electron microscope marker for the outer membrane surface. Fraction E vesicles showed low ATPase latency (two-fold or less) and weak reactivity with concanavalin A peroxidase. In contrast, fraction C vesicles were characterized by much greater latencies upon detergent treatment (sevenfold) and a strong reaction with concanavalin A peroxidase. Two-phase partition as the initial procedure for plasma membrane isolation, yielded mixtures of vesicles of both inside out and right-side out orientation. Free-flow electrophoresis resolved the plasma membrane isolates into vesicles from fraction C which were right-side out (cytoplasmic side in), and vesicles from fraction E which were wrong-side out (cytoplasmic side out). Therefore, the two methods used in series, provided highly purified membrane preparations of apparently homogenous vesicles of opposite known absolute orientations.     

The isolation of plasma membrane and characterisation of the plasma membrane ATPase from the yeast Candida albicans

Plasma membrane ghosts were isolated from Candida albicans ATCC 10261 yeast cells following stabilisation of spheroplasts with concanavalin A, osmotic lysis and Percoll density gradient centrifugation. Removal of extrinsic proteins with NaCl and methyl alpha-mannoside gave increased ATPase and chitin synthase specific activities in the resultant plasma membrane fraction. Sonication of this fraction yielded unilamellar plasma membrane vesicles which exhibited ATPase and chitin synthase specific activities of 4.5-fold and 3.0-fold, respectively, over those of the plasma membrane ghosts. ATPase activity in the membrane ghosts was optimal at pH 6.4, showed high substrate specificity (for Mg X ATP) and was inhibited 80% by sodium vanadate but less than 4% by oligomycin and azide. The effects of a range of other inhibitors were also characterised. Temperature effects of ATPase activity were marked, with a maximum at 35 degrees C. Breaks in the Arrhenius plot, at 12.2 degrees C and 28.9 degrees C, coincided with endothermic heat flow peaks detected by differential scanning calorimetry. ATPase was solubilised from the plasma membranes with Zwittergent in the presence of glycerol and phenylmethylsulphonyl fluoride and partially purified by glycerol density gradient centrifugation. The solubilised enzyme hydrolysed Mg X ATP at Vmax = 20 mumol X min-1 X mg-1 in the presence of phospholipids, with optimal activity at pH 6.0--6.5.     

Immunological detection of the mitochondrial F1-ATPase alpha subunit in the matrix of rat liver peroxisomes. A protein involved in organelle biogenesis?

Rat liver peroxisomes contain in their matrix the alpha-subunit of the mitochondrial F1-ATPase complex. The identification of this protein in liver peroxisomes has been achieved by immunoelectron microscopy and subcellular fractionation. No beta-subunit of the mitochondrial F1-ATPase complex was detected in the peroxisomal fractions obtained in sucrose gradients or in Nycodenz pelletted peroxisomes. The consensus peroxisomal targeting sequence (Ala-Lys-Leu) is found at the carboxy terminus of the mature alpha-subunit from bovine heart and rat liver mitochondria. Due to the dual subcellular localization of the alpha-subunit and to the structural homologies that exist between this protein and molecular chaperones [(1990) Biol. Chem. 265, 7713-7716] it is suggested that the protein should perform another functional role(s) in both organelles, plus to its characteristic involvement in the regulation of mitochondrial ATPase activity.     

Purification and properties of H+-translocating, Mg2+-adenosine triphosphatase from vacuolar membranes of Saccharomyces cerevisiae

H+-translocating, Mg2+-ATPase was solubilized from vacuolar membranes of Saccharomyces cerevisiae with the zwitterionic detergent N-tetradecyl-N,N-dimethyl-3-ammonio-1-propanesulfonate and purified by glycerol density gradient centrifugation. Partially purified vacuolar membrane H+-ATPase, which had a specific activity of 18 units/mg of protein, was separated almost completely from acid phosphatase and alkaline phosphatase. The purified enzyme required phospholipids for maximal activity and hydrolyzed ATP, GTP, UTP, and CTP, with this order of preference. Its Km value for Mg2+-ATP was determined to be 0.21 mM and its optimal pH was 6.9. ADP inhibited the enzyme activity competitively, with a Ki value of 0.31 mM. The activity of purified ATPase was strongly inhibited by N,N'-dicyclohexylcarbodiimide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide, tributyltin, 7-chloro-4-nitrobenzoxazole, diethylstilbestrol, and quercetin, but was not affected by oligomycin, sodium azide, sodium vanadate, or miconazole. It was not inhibited at all by antiserum against mitochondrial F1-ATPase or mitochondrial F1-ATPase inhibitor protein. These results indicated that vacuolar membrane H+-ATPase is different from either yeast plasma membrane H+-ATPase or mitochondrial F1-ATPase. The vacuolar membrane H+-ATPase was found to be composed of two major polypeptides a and b of Mr = 89,000 and 64,000, respectively, and a N,N'-dicyclohexylcarbodiimide binding polypeptide c of Mr = 19,500, whose polypeptide composition was also different from those of either plasma membrane H+-ATPase or mitochondrial F1-ATPase of S. cerevisiae.     

Plasma membrane ATPase of sugarbeet

A membrane fraction enriched with magnesium-dependent ATPase activity was isolated from sugarbeet (Beta vulgaris L.) taproot by a combination of differential centrifugation, extraction with KI and sucrose density gradient centrifugation. This activity was inhibited by vanadate, N,N′-dicyclohexylcarbodiimide and diethylstilbestrol, but was insensitive to molybdate, azide, oligomycin, ouabain, and nitrate, suggesting enrichment in plasma membrane ATPase. The enzyme was substrate specific for ATP, had a pH optimum of 7.0, but showed little stimulation by 50 mM KCl. The sugarbeet ATPase preparation contained endogenous protein kinase activity which could be reduced by extraction of the membranes with 0.1% (w/v) sodium deoxycholate. Reduction of protein kinase activity allowed the demonstration of a rapidly turning over phosphorylated intermediate on a M_r 105000 polypeptide, most likely representing the catalytic subunit of the ATPase. Phosphorylation was magnesium dependent, sensitive to diethylstilbestrol and vanadate but insensitive to oligomycin and azide. Neither the ATPase activity nor phosphoenzyme level were affected by combinations of sodium and potassium in the assay. These results argue against the presence of a synergistically stimulated NaK-ATPase at the plasma membrane of sugarbeet.     

Some properties of membrane-bound, solubilized and reconstituted into liposomes H+-ATPase of vacuoles of Saccharomyces carlsbergensis

Vacuoles of yeast grown in peptone medium possessed high ATPase activity (up to 1 mumol X mg protein-1 X min-1). Membrane-bound and solubilized ATPase activities were insensitive to vanadate and azide, but were inhibited by NO-3 . K+ and cyclic AMP stimulated both membrane-bound and solubilized ATPase activities. Dio-9 activated the membrane form of vacuolar ATPase 1.5-2-fold and did not affect the solubilized enzyme. Solubilized and partially purified vacuolar ATPase was reconstituted with soy-bean phospholipids by a freeze-thaw procedure. ATPase activities in native vacuoles and proteoliposomes were stimulated effectively by Dio-9, the protonophore FCCP and ionophores valinomycin and nigericin. ATP-dependent H+ transport into proteoliposomes was also shown by quenching of ACMA fluorescence. Vacuolar and partially purified ATPase preparations possessed also GTPase activity. Unlike ATPase, however, GTPase was not incorporated as a proton pump into liposomes.     

Preparation of right-side-out plasma membrane vesicles from Penicillium cyclopium: a critical assessment of markers.

A plasma membrane fraction was obtained by the combined use of differential centrifugation and aqueous polymer two-phase partitioning techniques. Vanadate-inhibited ATPase and glucan synthase activities were highly enriched in this fraction, although the presence of ATPase activity which was not inhibited by vanadate, nitrate, molybdate, anyimycin A or azide was also detected. Other intracellular membrane marker activities were present at very low or undetectable levels. A further separation step using Percoll density gradient centrifugation resulted in the separation of a fraction which exclusively contained vanadate-inhibited ATPase activity, and was enriched with silicotungstic-acid-staining membrane material. Latency tests performed on the plasma membrane markers showed that the membrane vesicles were in the right-side-out orientation.     

Isolation and partial characterization of chick brain synaptic plasma membranes.

An isolation procedure for synaptic plasma membranes from whole chick brain is reported that uses the combined flotation-sedimentation density gradient centrifugation procedure described by Jones and Matus (Jones, D. H. and Matus, A. I. (1974) Biochim. Biophys. Acta 356, 276-287) for rat brain. The particulate of the osmotically shocked and sonicated crude mitochondrial fraction was used for a flotation-sedimentation gradient step. Four fractions were recovered from the gradient after 30 min centrifugation. The fractions were identified and characterized by electron microscopy and by several markers for plasma membrane and other subcellular organelles. Fraction 2 was recovered from the 28.5-34% (w/v) sucrose interphase and contained the major part of the activities of the neuronal plasma membrane marker enzymes. The specific activities of the (Na+ +K+)-activated ATPase (EC 3.6.1.3), acetylcholinesterase (EC 3.1.1.7) and 5'-nucleotidase (EC 3.1.3.5) were, respectively, 4.5, 2.0 and 1.2 times higher than in the homogenate. However, Fraction 2 also contained considerable amounts of activities of putative lysosomal and microsomal markers in addition to lower amounts of mitochondrial and myelin markers. Although no prepurification of synaptosomes from the crude mitochondrial fraction was performed, the synaptic plasma membranes obtained showed many properties analogous to similar preparations from rat brain described in recent years.     

Evidence for a KCl-Stimulated, Mg-ATPase on the Golgi of Corn Coleoptiles

Membranes of corn (Zea mays, cv Trojan 929) coleoptiles were fractionated by sucrose density gradient centrifugation and the locations of organelles were determined using marker enzymes and electron microscopy. Latent IDPase (or UDPase) was selected as the Golgi marker and UDPG-sterol glucosyl transferase was selected as the plasma membrane (PM) marker, because they were clearly separable from markers for the other organelles. Golgi-rich and PM-rich fractions were studied in relation to their ATPase activities. The pH optimum of the KCl, Mg²⁺-ATPase of the PM-rich fraction from a step gradient was 6.0 to 6.5, while the Golgi-rich fraction had peaks at pH 6.0 to 6.5 and pH 7.5. It is hypothesized that the peak at pH 6.0 to 6.5 for the Golgi-rich fraction is due to PM-contamination, while the peak at pH 7.5 represents the activity of a Golgi ATPase. To reduce PM contamination, Golgi-rich fractions obtained from step or rate-zonal gradients were recentrifuged isopycnically on linear sucrose gradients. The distribution of KCl, Mg²⁺-ATPase activity was measured at pH 6.5 and 7.5. The pH 6.5 ATPase was coincident with UDPG-sterol glucosyl transferase, a PM marker, while the pH 7.5 ATPase overlapped with latent UDPase, a Golgi marker. These results provide strong evidence for a KCl, Mg²⁺-ATPase, active at pH 7.5, associated with the Golgi membranes of corn coleoptiles.