Micrococcus lysodeikticus membrane ATPase. Effect of trypsin on stimulation of a purified form of the enzyme and idenfification of its natural inhibitor.

A soluble purified form of Micrococcus lysodeikticus ATPase (form BAT, from strain B, active, trypsin-stimulated) was stimulated 100% by trypsin and this stimulation was inhibited by preincubation of the protease with phenyl methyl sulphonylfluoride. This form of the enzyme was also stimulated 125-150% by filtration on Sephadex G-200. Analysis by sodium dodecyl sulphate-gel electrophoresis showed that stimulation of this form of M. lysodeikticus ATPase was always accompanied by the disappearance of a subunit of mol. wt. 25000 (epsilon subunit). It suggests that this subunit is the natural inhibitor of M. lysodeikticus ATPase. In the case of ATPase stimulation by trypsin, a partial and limited degradation of the alpha subunit was also observed. The interaction between the epsilon subunit and the rest of the ATPase complex was reversibly affected by pH, suggesting its non-covalent nature.     

Micrococcus lysodeikticus ATPase: Purification by preparative gel electrophoresis and subunit structure studied by urea and sodium dodecylsulfate gel electrophoresis

Micrococcus lysodeikticus ATPase was purified by preparative gel electrophoresis after its “shock wash” release from the membrane. The method afforded the highest yield of pure protein in the minimum time as compared with former purification procedures. The pure protein had a specific activity of 7 μmol P_i·min^?1·mg^?1 with incubation times not longer than 3 min, 345 000 mol. wt and was not stimulated by trypsin. By gel electrophoresis at alkaline pH (8.5) in 8 M urea or in sodium dodecylsulfate, the ATPase revealed a complex pattern with two major subunits (α and β) and two minor ones (γ and δ). The non-identity between the major subunits was demonstrated.     

Effects of trypsin treatment on the structure and function of solubilized coupling factor-latent ATPase from Mycobacterium phlei.

The effect of trypsin treatment on the solubilized coupling factorlatent ATPase from Mycobacterium phlei was studied. Maximal stimulation of ATPase activity by trypsin is accompanied by a decrease of about 20,000 daltons in molecular weight and a complete loss of the ability to rebind to depleted membranes. There is also conversion of the A subunit of the latent enzyme to an A″ form via an A′ intermediate. The increase in ATPase activity, loss of coupling factor activity, and loss of rebinding capacity changed in a different manner in response to partial degrees of trypsin activation, indicating that each of these functions may have a different structural requirement.     

Immunochemistry of membrane F1-Adenosine triphosphatase fromMicrococcus lysodeikticus. Role of the alpha subunit

The membrane-bound ATPase activity from two substrains ofMicrococcus lysodeikticus, designated as A and B, was inhibited by antibodies raised against the two forms of purified F₁-ATPase. Form B of the enzyme, which behaved as a poorer immunogen than form A, also showed less reactivity as an antigen, independent of the physical state of the F₁-ATPase form. Antibodies were raised against the two major subunits ( and ) isolated fromM. lysodeikticus F₁-ATPase form A, which was the most stable form of the enzyme. Anti-(-subunit) serum strongly inhibited the ATPase activity of membrane-bound ATPase but showed little inhibition of the purified, soluble F₁-ATPase. The anti-(-subunit) serum inhibited the soluble F₁-ATPase, but to a lesser extent than the membrane-bound enzyme. In any event, the effect of anti- antibodies on the membrane-bound ATPase was smaller than that of anti- antibodies. It was postulated that the subunit ofM. lysodeikticus F₁-ATPase plays an essential and regulatory role in the expression of the immunochemical properties of the protein.     

Membrane adenosine triphosphatase of Micrococcus lysodeikticus. Isolation of two forms of the enzyme complex and correlation between enzymatic stability,latency and activity.

Summary Two new forms of the plasma membrane ATP-ase ofMicrococcus lysodeikticus NCTC 2665 were isolated from a sub-strain of the microorganism by polyacrylamide gel electrophoresis. One of them had a mol.wt of 368,000 and a very low specific activity (0.80 µ mol.min^–1.mg protein^–1) that could not be stimulated by trypsin. This form has been called B^I (strain B, inactive). If the electrophoresis was carried out in the presence of reducing agents (i.e., dithiothreitol) and the pH of the effluent maintained at a value of 8.5 another form of the enzyme was obtained. This had a mol.wt of 385,000 and a specific activity of 2.5–5.0 µ mol.min^–1.mg protein^–1 that could be stimulated by trypsin to 5–10 µ mol.min^–1.mg protein^–1. This preparation of the ATPase has been called form B_A (strain B, enzyme active). The subunit composition of both forms has been studied by sodium dodecyl sulphate and urea gel electrophoresis and compared to that of the enzyme previously purified from the original strain (form A). The three forms of the enzyme had similar and subunits, with mol.wt of about 50,000 and 30,000 dalton, respectively. They also had in common the component(s) of relative mobility 1.0, whose status as true subunit(s) of the enzyme remains yet to be established. However, subunit, that had a mol.wt of about a 52,500 in form A (Andreu et al. Eur. J. Biochem. (1973) 37, 505–515), had a mol.wt similar to in form B_I and about 60,000 in form B_A. Furthermore B_A usually showed two types of this subunit ( and) and an additional peptide chain () with a mol.wt of about 25,000 dalton. This latter subunit seemed to account for the stimulation by trypsin of form B_A.Forms B_A could be converted to B_I by storage and freezing and thawing. Conventional protease activity could not be detected in any of the purified ATPase forms and addition of protease inhibitors to form B_A failed to prevent its conversion to form B_I. The low activity form (B_I) was more stable than the active forms of the enzyme and also differed in its circular dichroism. These results show thatM. lysodeikticus ATPase can be isolated in several forms. Although these variations may be artifacts caused by the purification procedures, they provide model systems for understanding the structural and functional relationships of the enzyme and for drawing some speculations about its functionin vivo.     

Biosynthetic approach to the structure of F1-ATPase (BF1 factor) from Micrococcus lysodeikticus membranes: in vivo labeling of the polypeptides and study of their relationship

The F₁-ATPase or BF₁ factor was purified from Micrococcus lysodeikticus substrain B grown in a synthetic medium in the presence of tritiated amino acids. When analyzed in sodium dodecyl sulfate-7% polyacrylamide gels, the fresh purified preparation contained α, β, γ subunits (referred as the intrinsic subunits) and two other polypeptides (designated as X and component of relative mobility 1.0) whose status as subunits remains to be established. This overall polypeptide composition was similar to that of the F₁-ATPase isolated from the same strain grown in complex medium (J. Carreira, J. M. Andreu, M. Nieto, and E. Muñoz., 1976 Mol. Cell. Biochem.10, 67–76). The distribution of ³H-labeled amino acids into purified F₁-ATPase and its constituent polypeptides under different stages of growth was used to investigate the biosynthetic relationship between the different polypeptides. The incorporation of amino acids into purified BF₁ factor was slower than that of cytoplasmic and other membrane proteins. In isotope-dilution and chase experiments, F₁-ATPase showed one of the slowest rates of decay of the incorporated label. These results point out that F₁-ATPase of M. lysodeikticus undergoes slower turnover than the overall cytoplasmic and membrane proteins. Pulse and chase experiments allowed us to conclude that the α, β, γ subunits and the components of relative mobility 1.0 are independent with differences in their turnover and therefore do not bear any apparent relation as precursors-products. The two major subunits represent seemingly the “core” of ATPase, the β subunit behaving like the most stable component. On the other hand, the γ subunit appears to be synthesized independently from this α + β complex.     

Oligomycin-sensitive ATPase of Submitochondrial Particles from Corn

To test the hypothesis (Plant Physiology 59: 155-157) that monocotyledons contain a unique oligomycin-insensitive ATPase, we prepared submitochondrial particles and a soluble fraction from sonicated corn mitochondria (Zea mays L. cv. Earliking). Although the ATPase activity of the whole sonicate was relatively insensitive to oligomycin, the corn submitochondrial particles possessed an ATPase activity that was nearly completely inhibited by oligomycin, and was activated by trypsin. This ATPase is similar to that from other sources (plants, animals, and microorganisms). The soluble fraction also contained an active ATPase, which was inhibited by azide and stimulated by sodium chloride and trypsin. The soluble fraction differed from other F₁-ATPases in that it was cold-stable.     

Purification and properties of the latent F1-ATPase of Micrococcus lysodeikticus

The latent coupling factor (F₁)-ATPase of Micrococcus lysodeikticus has been purified to homogeneity as determined by a number of criteria including, non-denaturing polyacrylamide gel electrophoresis, crossed immunoelectrophoresis and analytical ultracentrifugation. By inclusion of 1 mM phenylmethyl sulfonyl fluoride, a serine protease inhibitor, in the shock-wash step of release of F₁ from the membranes, the spontaneous activation of both crude and purified ATPase by endogenous membrane protease(s) can be prevented, thereby yielding a highly latent ATPase preparation. Equilibrium ultracentrifugation of the latent ATPase gave a molecular weight of 400 000. The ATPase contained five different subunits α, β, γ, δ, and ? and their molecular weights determined by SDS-polyacrylamide gel electrophoresis were 60 000, 54 000, 37 000, 27 000 and 9000, respectively. The subunit composition was determined with ¹⁴C-labelled, F₁-ATPase prepared from cells grown on medium containing [U-¹⁴C]-labelled algal protein hydrolysate. Within the limitations of this method the results tentatively suggest a subunit composition of 3 : 3 : 1 : 1 : 3.     

Cyclic AMP stimulation of membrane phosphorylation and Ca2+-activated,Mg2+-dependent ATPase in cardiac sarcoplasmic reticulum

Ca²⁺-activated ATPase (EC 3.6.1.15) in canine cardiac sarcoplasmic reticulum was stimulated 50–80% by cyclic adenosine 3′ : 5′-monophosphate. The relationship of this stimulation to cyclic AMP-dependent membrane phosphorylation with phosphoester bands was studied. Cyclic AMP stimulation of ATPase activity was specific for Ca²⁺-activated ATPase and was half-maximal at about 0.1 μM which is similar to the concentration required for half-maximal stimulation of membrane phosphorylation by endogenous cyclic AMP-stimulated protein kinase (EC 2.7.1.37). Cyclic AMP stimulation of Ca²⁺-activated ATPase was calcium dependent and maximal at calculated Ca²⁺ concentrations of 2.0 μM. Cyclic AMP-dependent Ca²⁺-activated ATPase correlated well with the cyclic AMP-dependent membrane phosphorylation of which 80% was 20 000 molecular weight protein identified by sodium dodecyl sulfate discontinuous polyacrylamide gel electrophoresis. In trypsin-treated microsomes, cyclic AMP did not stimulate Ca²⁺-activated ATPase or phosphorylation of the 20 000 molecular weight membrane protein. An endogenous calcium-stimulated protein kinase (probably phosphorylase b kinase) with an apparent K_m for ATP of 0.21–0.32 mM was present and appeared to be involved in the cyclic AMP-dependent phosphorylation of the 20 000 molecular weight protein which was calcium dependent. Cyclic guanosine 3′ : 5′-monophosphate did not inhibit any of the stimulatory effects of cyclic AMP. These data suggest that the cyclic AMP stimulation of Ca²⁺-activated ATPase in cardiac sarcoplasmic reticulum is mediated by the 20 000 molecular weight phosphoprotein product of a series of kinase reactions similar to those activating phosphorylase b.     

Purification and functional properties of the DCCD-reactive proteolipid subunit of the H+-translocating ATPase from Mycobacterium phlei

Interaction of N,N′-dicyclohexylcarbodiimide (DCCD) with ATPase of Mycobacterium phlei membranes results in inactivation of ATPase activity. The rate of inactivation of ATPase was pseudo-first order for the initial 30–65% inactivation over a concentration range of 5–50 μM DCCD. The second-order rate constant of the DCCD-ATPase interaction was k = 8.5·10⁵ M^?1·min^?1. The correlation between the initial binding of [¹⁴C]DCCD and 100% inactivation of ATPase activity shows 1.57 nmol DCCD bound per mg membrane protein. The proteolipid subunit of the F₀F₁-ATPase complex in membranes of M. phlei with which DCCD covalently reacts to inhibit ATPase was isolated by labeling with [¹⁴C]DCCD. The proteolipid was purified from the membrane in free and DCCD-modified form by extraction with chloroform/methanol and subsequent chromatography on Sephadex LH-20. The polypeptide was homogeneous on SDS-acrylamide gel electrophoresis and has an apparent molecular weight of 8000. The purified proteolipid contains phosphatidylinositol (67%), phosphatidylethanolamine (18%) and cardiolipin (8%). Amino acid analysis indicates that glycine, alanine and leucine were present in elevated amounts, resulting in a polarity of 27%. Cysteine and tryptophan were lacking. Butanol-extracted proteolipid mediated the translocation of protons across the bilayer, in K⁺-loaded reconstituted liposomes, in response to a membrane potential difference induced by valinomycin. The proton translocation was inhibited by DCCD, as measured by the quenching of fluorescence of 9-aminoacridine. Studies show that vanadate inhibits the proton gradient driven by ATP hydrolysis in membrane vesicles of M. phlei by interacting with the proteolipid subunit sector of the F₀F₁-ATPase complex.     

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.     

Membrane ATPase of Escherichia coli K 12 Selective solubilization of the enzyme and its stimulation by trypsin in the soluble and membrane-bound states

ATPase (EC 3.6.1.3) of Escherichia coli has been solubilized from two morphologically distinct membranes (vesicles and “ghosts”). Maximum ATPase release is attained with 3 mM EDTA in NH₄HCO₃, pH 9.0, and depends on protein concentration. After solubilization, the total enzyme activity is increased by 300% with respect to the membrane-bound enzyme. The released soluble ATPase accounts for more than 90% of this activity. Its specific activity is at least 10 times higher than the original value. Membrane treatment with buffers of various ionic strengths without EDTA and detergents is less selective. The molecular sieving properties (gel electrophoresis and Sephadex G-200 filtration) confirm the soluble nature of the preparation. A molecular weight close to 300 000 has been estimated for it.The membrane-bound ATPase is stimulated by trypsin by 70–100%. Most of the soluble ATPase maintains a trypsin activation of the same order. Exceptions are the preparations obtained at high protein dilution and extracted with sodium dodecyl sulphate and deoxycholate. The soluble ATPase is more labile than the membrane-bound enzyme. Its sensitivity to different temperatures depends upon protein concentration and pH during storage. Inactivation seems to result from dissociation and/or proteolysis.We suggest an ATPase link to the membrane through ionic divalent cation bridges. We also suggest that the enzyme possesses self-regulatory properties which would account for trypsin stimulation.     

Immunochemical analysis of Micrococcus lysodeikticus (luteus) F1-ATPase and its subunits

The F₁-ATPase from Micrococcus lysodeikticus has been purified to 95% protein homogeneity in this laboratory and as all other bacterial F₁s, possesses five distinct subunits with molecular weights ranging from 60 000 to 10 000 (Huberman, M. and Salton, M.R.J. (1979) Biochim. Biophys. Acta 547, 230–240). In this communication, we demonstrate the immunochemical reactivities of antibodies to native and SDS-dissociated subunits with the native and dissociated F₁-ATPase and show that: (1) the antibodies generated to the native or SDS-dissociated subunits react with the native molecule; (2) all of the subunits comprising the F₁ are antigenically unique as determined by crossed immunoelectrophoresis and the Ouchterlony double-diffusion techniques; (3) antibodies to the SDS-denatured individual δ- and ?-subunits can be used to destabilize the interaction of these specific subunits with the rest of the native F₁; and (4) all subunit antibodies as well as anti-native F₁ were found to inhibit ATPase activity to varying degrees, the strongest inhibition being seen with antibodies to the total F₁ and anti-α- and anti-β-subunit antibodies. The interaction of specific subunit antibodies may provide a new and novel way to study further and characterize the catalytic portions of F₁-ATPases and in general may offer an additional method for the examination of multimeric proteins.     

Characteristics and Regulatory Properties of the H+-ATPase in a Plasma Membrane Fraction Purified from Arabidopsis thaliana

The aqueous two-phase partitioning technique was utilized to isolate a plasma membrane (PM) fraction from etiolated seedlings of Arabidopsis thaliana. The purification procedure adopted yielded a fraction highly enriched in PM as compared to inner membranes, with a recovery of about 30%, as judged from the activities of PM markers such as vanadate-sensitive ATPase, FC binding and UDP-glucose sterol glucosyltransferase. The purified PM fraction displayed vanadate-sensitive H⁺ pumping activity. Its purity was confirmed by the biochemical characteristics of its ATPase activity assayed in the absence of Ca²⁺: sensitivity to vanadate (IC₅₀ ca. 1 μM), Mg²⁺-dependence, insensitivity to molybdate, oligomycin and nitrate, pH optimum at 6.6. The PM H⁺-ATPase activity was stimulated by fusicoccin and by a controlled treatment of the PM with trypsin. In both cases stimulation was much stronger on the activity assayed at pH 7.5 than on the activity at pH 6.6. Moreover, neither fusicoccin nor the treatment with trypsin stimulated the portion of activity (30 to 40% at pH 7.5) which decayed upon preincubation of the PM in assay medium without ATP.     

The detergent-soluble maltose transporter is activated by maltose binding protein and verapamil

The maltose transporter FGK2 complex of Escherichia coli was purified with the aid of a glutathione S-transferase molecular tag. In contrast to the membrane-associated form of the complex, which requires liganded maltose binding protein (MBP) for ATPase activity, the purified detergent-soluble complex exhibited a very high level of ATPase activity. This uncoupled activity was not due to dissociation of the MalK ATPase subunit from the integral membrane protein MalF and MalG subunits. The detergent-soluble ATPase activity of the complex could be further stimulated by wild-type MBP but not by a signaling-defective mutant MBP. Wild-type MBP increased the V_max of the ATPase 2.7-fold but had no effect on the K_m of the enzyme for ATP. When the detergent-soluble complex was reconstituted in proteoliposomes, it returned to being dependent on MBP for activation of ATPase, consistent with the idea that the structural changes induced in the complex by detergent that result in activation of the ATPase are reversible. The uncoupled ATPase activity resembled the membrane-bound activity of the complex also with respect to sensitivity to NaN₃, as well as a mercurial, p-chloromercuribenzosulfonic acid. Verapamil, a compound that activates the ATPase activity of the multiple drug resistance P-glycoprotein, activated the maltose transporter ATPase as well. The activation of this bacterial transporter by verapamil suggests that a structural feature that is conserved among both eukaryotic and prokaryotic ATP binding cassette transporters is responsible for this activation.     

Association of a thioredoxin-like protein with chloroplaast coupling factor (CF1).

The δ subunit isolated from chloroplast coupling factor (CF₁) preparations partially replaced thioredoxin in the dithiothreitol-linked activation of chloroplast fructose 1,6-bisphosphatase. The δ subunit fraction also stimulated the dithiothreitol-dependent ATPase of heated CF₁ in a manner analogous to that obseryed with each of the three thioredoxins isolated from spinach leaves (thioredoxins f, m, and c). The δ subunit used in most of these experiments was obtained from CF₁ that had been isolated by a newly devised procedure based on acid precipitation.     

ATPase Activity of Pea Cotyledon Submitochondrial Particles: ACTIVATION, SUBSTRATE SPECIFICITY, AND ANION EFFECTS

Submitochondrial particles freshly prepared by sonication from pea cotyledon mitochondria showed low ATPase activity. Activity increased 20-fold on exposure to trypsin. The pea cotyledon submitochondrial particle ATPase was also activated by “aging” in vitro. At pH 7.0 addition of 1 millimolar ATP prevented the activation. ATPase of freshly prepared pea cotyledon submitochondrial particles had a substrate specificity similar to that of the soluble ATPase from pea cotyledon mitochondria, with GTPase > ATPase. “Aged” or trypsin-treated particles showed equal activity with the two substrates. NaCl and NaHCO₃, which stimulate the ATPase but not the GTPase activity of the soluble pea enzyme, were stimulatory to both the ATPase and GTPase activities of freshly prepared submitochondrial particles. However, they were stimulatory only to the ATPase activity of trypsin-treated or “aged” submitochondrial particles. In contrast, the ATPase activity of rat liver submitochondrial particles was stimulated by HCO₃⁻, but inhibited by Cl⁻, indicating that Cl⁻ stimulation is a distinguishing property of the pea mitochondrial ATPase complex.     

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.     

Phosphorylation and dephosphorylation of the regulatory subunit of cyclic 3′,5′-monophosphate-dependent protein kinase (type II) in vivo and in vitro

A phosphorylated regulatory subunit of cyclic AMP-dependent protein kinase (type II) was purified to homogeneity from inorganic [³²P]phosphate-injected rats.A new method of measuring the phosphorylation reaction was developed. It was found that this regulatory subunit was phosphorylated in cells and comprised 60, 82 and 55% of the total regulatory subunit in brain, heart and liver cytosol fractions from rats, respectively.Dephosphorylation was stimulated by cyclic nucleotides. The K_a values for cyclic AMP and cyclic IMP were 0.30 and 1.0 μM, respectively. Purified phosphoprotein phosphatase could dephosphorylate the regulatory subunit and this reaction was also stimulated by cyclic nucleotides with similar K_a values. The inhibitors of phosphoprotein phosphatase, NaF and ZnCl₂, protected against dephosphorylation unless ADP or cyclic AMP were present.     

The epsilon Subunit of the Chloroplast Coupling Factor 1 from Euglena gracilis: A Possible Role in Controlling ATPase Activity

The coupling factor from chloroplasts (CF₁) of Euglena gracilis Z strain is an active ATPase in situ, and its activity cannot be increased by treatment with trypsin or heating as is the case with the CF₁ from other sources. The smallest subunit of CF₁, the ε subunit, is supposed to be involved in controlling the ATPase activity. We have devised a simple technique for rapid and large-scale isolation of this subunit. The ε subunit from Euglena CF₁, although having only a limited inhibitory effect on Euglena CF₁, drastically inhibited the ATPase activity of heat-activated spinach CF₁. The inhibition of spinach CF₁ could be reversed by passage through Sephadex G-50 or by a second heat activation. An antibody to the ε subunit of Euglena CF₁ cross-reacted only weakly with CF₁ from spinach, Sorghum, Kalanchoë, or Anacystis nidulans, but reacted well with whole Euglena CF₁ in addition to its ε subunit. The antibody increased the ATPase activity of Euglena and Anacystis CF₁ and of unactivated or partially activated spinach CF₁. The results suggest that the function of the ε subunit in Euglena CF₁ is similar to its function in CF₁ from other sources. The data also suggest that changes induced in spinach CF₁ by activation involves modifications in subunits other than the ε one.