Effect of concanavalin A on the activity of membrane-bound and detergent-solubilized Mg2+ -ATPase

Plasma membranes were isolated after binding liver and hepatoma cells to polylysine-coated polyacrylamide beads, and the effect of concanavalin A on the membrane-bound Mg2+ -ATPase and the Mg2+ -ATPase solubilized by octaethylene glycol monododecyl ether (C12E8) was studied. In the experiment of membrane-bound Mg2+ -ATPase, plasma membranes were pretreated with Concanavalin A and the activity was assayed. Concanavalin A stimulated the activity of both liver and hepatoma enzymes assayed above 20 degrees C. Concanavalin A abolished the negative temperature dependency characteristic of liver plasma membrane Mg2+ -ATPase. On the other hand, Concanavalin A prevented the rapid inactivation due to storage at -20 degrees C, which was characteristic of hepatoma plasma membrane Mg2+ -ATPase. With solubilized Mg2+ -ATPase from liver plasma membranes, the negative temperature dependency was not observed. Concanavalin A, which was added to the assay medium, stimulated the activity of the enzyme solubilized in C12E8 at a high ionic strength. However, Concanavalin A failed to show any effect on the enzyme solubilized in C12E8 at a low ionic strength. With solubilized Mg2+ -ATPase from hepatoma plasma membranes, Concanavalin A could not prevent the inactivation of the enzyme during incubation at -20 degrees C.     

Inhibition of lymphocyte 5'-nucleotidase by lectins: effects of lectin specificity and cross-linking ability

5'-Nucleotidase, an integral glycoprotein enzyme of the lymphocyte plasma membrane, is inhibited cooperatively by the lectin concanavalin A. Because divalent succinyl-concanavalin A is a poor enzyme inhibitor, both binding and lectin-induced cross-linking of 5'-nucleotidase may be necessary for inhibition. Succinyl-concanavalin A does not compete with concanavalin A for binding to the enzyme; however, maleyl-concanavalin A, another poor inhibitor, competes effectively with the parent lectin. Thus, maleyl-concanavalin A binds to the same site as concanavalin A but causes little inhibition, whereas succinyl-concanavalin A does not bind to this site. The monovalent lectin from Ricinus communis (RCA-60) is a more effective enzyme inhibitor than the related divalent lectin (RCA-120), and inactivation of the second low-affinity sugar binding site on RCA-60 does not abolish inhibition, suggesting that multivalent cross-linking is not required for 5'-nucleotidase inhibition. Peanut and wheat germ agglutinins do not inhibit the enzyme, whereas lectins from lentil, pea, soybean, Griffonia simplicifolia, and Phaseolus vulgaris inhibit 5'-nucleotidase with various degrees of effectiveness. The only lectin showing strong positive cooperativity in its interaction with 5'-nucleotidase is concanavalin A.     

5'-Nucleotidase activity of lymphocyte plasma membranes. Effect of concanavalin A]

The 5'-nucleotidase properties of isolated lymphocyte plasma membranes from young pig mesenteric nodes are described; nucleosides-5'-monophosphates are the substrates of this specific enzyme. Concanavalin A inhibits this enzyme; on the same membranes this mitogen does not affect alkaline phosphatase and activates the membrane bound (Ca2+) ATPase. The 5'-nucleotidase inhibition is due to a specific interaction of Con A with carbohydrate groups of the membrane; its high positive cooperativity suggests that the lectin promotes reorganization of the membrane bound 5'-nucleotidase. Solubilization of the 5'-nucleotidase does not prevent the effect of Con A and the solubilized enzyme is firmly bound by Con A-Sepharose 4B; these results suggest that Con A inhibits the enzyme by a direct interaction and that 5'-nucleotidase can be considered as an eventual receptor for the lectin.     

Effects of con A and other lectins on pure 5'nucleotidase isolated from lymphocyte plasma membranes.

Inhibition of purified or membrane-bound 5′nucleotidase by various lectins was studied in lymphocytes from pig mesenteric lymph nodes. Con A or $\text{Lens culinaris}$ lectin LcH inhibited (75 %) purified 5′nucleotidase by a non-competitive process without cooperativity. Inhibition by these lectins of 5′ nucleotidase activity in whole lymphocytes, plasma membranes (untreated or solubilized) and LcH-receptor fraction displayed high positive cooperativity, reached higher level (90 %) and was of mixed type. An interaction between lectin receptors and 5′nucleotidase accounted for these differences. Wheat germ agglutinin (WGA) and divalent Con A which are not mitogenic for T lymphocytes had no effect on 5′nucleotidase; pokeweed mitogen (PWM), mitogen of T and B cells, was not inhibitor. When membrane proteins were cross-linked by glutaraldehyde, Con A inhibition of whole lymphocyte 5′nucleotidase presented the same properties as the purified enzyme. Possible correlation between 5′nucleotidase inhibition and lymphocyte stimulation is discussed.     

Resolution and reconstitution of Rhodospirillum rubrum pyridine dinucleotide transhydrogenase

The Rhodospirillum rubrum pyridine dinucleotide transhydrogenase system is comprised of a membrane-bound component and an easily dissociable soluble factor. Active transhydrogenase complex was solubilized by extraction of chromatophores with lysolecithin. The membrane component was also extracted from membranes depleted of soluble factor. The solubilized membrane component reconstituted transhydrogenase activity upon addition of soluble factor. Various other ionic and non-ionic detergents, including Triton X-100, Lubrol WX, deoxycholate, and digitonin, were ineffectual for solubilization and/or inhibited the enzyme at higher concentrations. The solubilized membrane component was significantly less thermal stable than the membrane-bound component. None of the pyridine dinucleotide substrate affected the thermostability of the solubilized membrane-bound component, whereas NADP⁺ and NADPH afforded protection to membrane-bound component. NADPH stimulated trypsin inactivation of membrane-bound component to a greater extent than NADP⁺, but inactivation of solubilized membrane component was stimulated to the same extent by both pyridine dinucleotides. The solubilized membrane component appears to have a slightly higher affinity for soluble factor than does the membrane-bound component.Abbreviations AcPyAD⁺ oxidized 3-acetylpyridine adenine dinucleotide - BChl bacteriochlorophyll - C_T-particles chromatophores depleted of soluble transhydrogenase factor and devoid of transhydrogenase activity This work was supported by Grant GM 22070 from the National Institutes of Health, United States Public Health Service. Paper I of this series is R. R. Fisher et al. (1975)     

The effects of phospholipids on the properties of hepatic 5'-nucleotidase

Arrhenius plots of 5'-nucleotidase activity in microsomes or plasma membranes from rat liver exhibited transitions at approximately 35 degrees C. The enzyme was purified from homogenates after solubilization in 2% Triton X-100 and 1% sodium deoxycholate. After the initial steps of the purification, the enzyme was recovered in membranes, as judged by both thin section and freeze-fracture electron microscopy, which contained sphingomyelin, phosphatidylcholine, and phosphatidylethanolamine. The purest fractions of 5'-nucleotidase were enriched approximate 3,000-fold, consisted of similar membranes, but only contained sphingomyelin. Thermal transitions were detected in Arrhenius plots of 5'-nucleotidase after detergent solubilization, in the membranes which contained the three phospholipids, but not in the purified fraction which contained only sphingomyelin; transitions were also detected after reassociation of the purified enzyme with microsomal or plasma membrane lipids and phosphatidylcholine but not with phosphatidylethanolamine. Phosphatidylcholines containing specific fatty acids all affected the energy of activation of 5'-nucleotidase, and the detergent Sarkosyl, which has been shown to dissociate phospholipids from 5'-nucleotidase (Evans, W. H., and Gurd, J. W. (1973) Biochem. J. 133, 189-199), caused a marked decrease in the stability of the enzyme to heating. Inhibition of 5'-nucleotidase by concanavalin A followed by reactivation with alpha-methyl-D-mannoside resulted in linear Arrhenius plots of 5'-nucleotidase activity in membrane fractions, and in lower transition temperatures for the detergent, solubilized enzyme. It is concluded that in situ, 5'-nucleotidase interacts with both sphingomyelin and phosphatidylcholine; the first apparently influences the stability of the enzyme and the second, the energy of activation. In addition, the lipid environment of the enzyme seems to be altered as a result of lectin binding.     

Subcellular distribution and movement of 5''-nucleotidase in rat cells.

1. Cell-surface 5'-nucleotidase was assayed by incubating whole-cell suspensions with 5'[3H]-AMP in iso-osmotic buffer and measuring [3H]adenosine production. The activity of cell-surface 5'-nucleotidase in hepatocytes, adipocytes and lymphocytes isolated from the rat was 15.0, 0.5 and 0.8pmol/min per cell at 37 degrees C respectively. 2. Disruption of the cells by vigorous mechanical homogenization or detergent treatment exposed additional 5'-nucleotidase activity, which represented 52%, 25% and 21% of the total activity in the three cell types respectively. This increase in 5'-nucleotidase activity which occurred when the cells were homogenized was due to a second pool of 5'-nucleotidase within the cell, rather than activation of the cell-surface enzyme. 3. In hepatocytes the intracellular 5'-nucleotidase activity was membrane-bound, indistinguishable from cell-surface 5'-nucleotidase in its inhibition by rabbit anti-(rat liver 5'-nucleotidase) serum and its kinetics with AMP, and was located on the extracytoplasmic face of vesicles within the cell. 4. The cell-surface 5'-nucleotidase of rat hepatocytes was rapidly inhibited when rabbit anti-(rat liver 5'-nucleotidase) serum or concanavalin A was added to the medium at 37 degrees C. Incubation with antiserum for 5 min at 37 degrees C inhibited 83 +/- 3% of the cell-surface enzyme. 5. Incubation of hepatocytes with exogenous antiserum or concanavalin A for 30 min at 37 degrees C resulted in over 50% inhibition of the intracellular enzyme. This inhibition was not prevented by disruption of the cytoskeleton or by ATP depletion. 6. Incubation of hepatocytes with exogenous antiserum or concanavalin A for up to 2h at 0 degrees C caused little or no inhibition of the intracellular enzyme, but over 75% inhibition of the cell-surface enzyme. 7. When surface-inhibited hepatocytes were washed and resuspended in buffer at 37 degrees C, 5'-nucleotidase was observed to redistribute from the intracellular pool to the cell surface.     

Transmembrane modulation of the concanavalin A inhibition of 5'-nucleotidase is not due to a direct association of the enzyme with the cytoskeleton

The inhibition of the cell surface enzyme 5'-nucleotidase by concanavalin A is being studied as a model for understanding transmembrane modulation of cell surface functions. Nucleotidase of 13762 MAT-C1 ascites rat mammary adenocarcinoma cells is inhibited by concanavalin A in a noncooperative process. When cells are treated with the cytoplasmic effectors cytochalasins, colchicine, energy poisons, calcium plus ionophore or hypotonic buffers, the concanavalin A inhibition of the enzyme becomes cooperative. 5'-Nucleotidase of isolated MAT-C1 microvilli is also inhibited by concanavalin A in a noncooperative process; however, treatment of the microvilli with the same cytoplasmic effectors does not induce cooperativity. Since previous studies in several systems have suggested an association of nucleotidase with actin-containing microfilaments or the cell cytoskeleton, one explanation for the cooperativity changes is that they result from a change in the association of the enzyme with the cytoskeleton. However, Triton X-100 extractability of nucleotidase is the same for MAT-C1 cells exhibiting cooperative or noncooperative concanavalin A inhibition. Moreover, enzyme from cells exhibiting cooperative inhibition can be extracted into the zwitterionic detergent Zwittergent in a cooperative form, while enzyme exhibiting noncooperative behavior can be extracted into Zwittergent in a noncooperative form. Gel filtration and rate-zonal sucrose density gradient centrifugation showed little discernible size or sedimentation difference between enzyme samples exhibiting noncooperative and cooperative inhibition. These results indicate that changes in the cooperativity of the concanavalin A inhibition of nucleotidase are not a result of changes in the association of the enzyme with the cytoskeleton. These studies emphasize the caution which must be exercised in interpreting the effects of cytoskeletal perturbants on cell surface functions.     

Transmembrane modulation of the concanavalin A inhibition of 5′-nucleotidase is not due to a direct association of the enzyme with the cytoskeleton

The inhibition of the cell surface enzyme 5′-nucleotidase by concanavalin A is being studied as a model for understanding transmembrane modulation of cell surface functions. Nucleotidase of 13762 MAT-C1 ascites rat mammary adenocarcinoma cells is inhibited by concanavalin A in a noncooperative process. When cells are treated with the cytoplasmic effectors cytochalasins, colchicine, energy poisons, calcium plus ionophore or hypotonic buffers, the concanavalin A inhibition of the enzyme becomes cooperative. 5′-Nucleotidase of isolated MAT-C1 microvilli is also inhibited by concanavalin A in a noncooperative process; however, treatment of the microvilli with the same cytoplasmic effectors does not induce cooperativity. Since previous studies in several systems have suggested an association of nucleotidase with actin-containing microfilaments or the cell cytoskeleton, one explanation for the cooperativity changes is that they result from a change in the association of the enzyme with the cytoskeleton. However, Triton X-100 extractability of nucleotidase is the same for MAT-C1 cells exhibiting cooperative or noncooperative concanavalin A inhibition. Moreover, enzyme from cells exhibiting cooperative inhibition can be extracted into the zwitterionic detergent Zwittergent in a cooperative form, while enzyme exhibiting noncooperative behavior can be extracted into Zwittergent in a noncooperative form. Gel filtration and rate-zonal sucrose density gradient centrifugation showed little discernible size or sedimentation difference between enzyme samples exhibiting noncooperative and cooperative inhibition. These results indicate that changes in the cooperativity of the concanavalin A inhibition of nucleotidase are not a result of changes in the association of the enzyme with the cytoskeleton. These studies emphasize the caution which must be exercised in interpreting the effects of cytoskeletal perturbants on cell surface functions.     

The acid phosphatase positive organelles of the Giardia lamblia trophozoite contain a membrane bound cathepsin C activity

We found a dipeptidyl aminopeptidase activity in the parasitic protozoan Giardia lamblia with properties similar to the lysosomal cathepsin C of rat-liver lysosomes. Subcellular fractionation of this parasite indicated that the cathepsin C activity is located in organelles not distinguishable from the ones containing acid phosphatase, a known marker enzyme of Giardia lysosome-like peripheral vesicles. Contrary to the rat lysosomal enzyme, Giardia cathepsin C behaved like a membrane protein. Moreover, the enzyme was not solubilized by Triton X-100 or Triton X-100/SDS at 0 degrees C but could be substantially solubilized by octylglucoside, Triton X-100 at 37 degrees C or by a pretreatment with the cholesterol complexing agent beta-cyclodextrin before the Triton/SDS treatment carried out at 0 degrees C. These observations suggest that binding/anchorage of this enzyme to membranes occurs in cholesterol-rich microdomains.     

Stabilization of soluble active rat liver glucagon receptor

Active glucagon receptor was solubilized with 3-(3-cholamidopropyl)dimethylammonio-1-propanesulfonate (Chaps) from rat liver plasma membranes but rapidly (less than 8 h) lost activity. Either inclusion of 1X Hanks' balanced salt solution in the 3 mM Chaps solubilization buffer or its addition after solubilization increased the percentage of total binding attributable to specific glucagon binding from approximately 10 to greater than 80%; of great importance, it increased the stability from near zero binding at 8 h to 50% binding at 48 h (4 degrees C). Of the Hanks' solution components, either NaCl (137 mM) or CaCl2 (1.26 mM) was effective in increasing specific binding to approximately 70 and 60% respectively: Mg salts were ineffective. Soluble receptor binding activity was assayed by dextran-coated charcoal adsorption of free hormone. The assay is rapid, simple, and reproducible. It is suitable for monitoring receptor activity during purification and molecular characterization. Competition binding studies gave an IC50 value of 10-20 nM (slope factor approximately 1), with or without GTP. Dissociation assays revealed GTP sensitivity when receptors were solubilized either as glucagon-receptor complexes or free receptor. Active glucagon-receptor complexes could be eluted from wheat germ lectin-agarose: neither concanavalin A-agarose nor soybean agglutinin-agarose bind receptor. A glucagon degrading activity which co-solubilized with the receptor but did not require detergent for extraction was distinguishable from the soluble receptor not only by solubility but also by its heat stability (30 degrees C), its inhibition by bacitracin, its affinity for glucagon, its retention of activity for at least 1 week at 4 degrees C, and its size.     

5′-Nucleotidases of retinal rod membranes

5′-Nucleotidase (EC 3.1.3.5) was solubilized from rod membranes with Ammonyx LO and purified by chromatographic methods. A highly sensitive radioassay was developed. The purified enzyme behaved as a homogeneous protein of 75,000 daltons in sodium dodecyl sulfate-polyacrylamide gel electrophoresis and as a protein of 79,000 in gel filtration. Thus, the enzyme does not contain subunits. The K_m values obtained were 1.3 μm for 5′-AMP and 2.3 μm for 5′-GMP. The enzyme was inhibited by concanavalin A, wheat germ agglutinin, and Ricinus communis agglutinin. Rabbit muscle G-actin formed a complex with the enzyme and inhibited its activity. The catalytic site of the enzyme was localized on the internal surface of the disk which, in terms of membrane sidedness, corresponds to the cell surface. A soluble 5′-nucleotidase was extracted from rod membranes with Tris buffer (pH 8.0) containing EGTA in the dark; less enzyme was extracted if the membranes had been exposed to light or incubated with Ca²⁺. The extracted enzyme was partially purified. The enzyme was unstable and lost 50% of its activity in 3 days at 3 °C. The K_m values were 1.3 μm for 5′-AMP and 2.3 μm for 5′-GMP. The enzyme was inhibited by G-actin. A role for the soluble enzyme in the regulation of 5′-GMP in the rod outer segment was suggested.     

Solubilization and reconstruction of microsomal AMP-deaminase from skeletal muscles]

Microsomal AMP-deaminase was solubilized by 0.5 M KCl after treatment of microsomal membranes with 0.12 M KCl. Using disc-electrophoresis in polyacrylamide gel in the presence of sodium dodecyl sulfate one major protein component (mol. weight about 90 000) and three minor ones with molecular weights of 110 000, 80 000, and 60 000 were found in the soluble fraction. In addition to proteins, the fraction was found in the soluble fraction. In addition to proteins, the fraction was found to contain a small amount of phospholipids. The deaminase found in the solution may be reconstructed into the membranes at a decrease in KCl concentration, part of enzyme being bound in the inactive form under excess of the soluble fraction. Deaminase binding to the membranes is unaffected by the changes within the pH range of 6.2--7.8 and temperature range of 4--10 degrees C. It is assumed that AMP-deaminase is bound to other membrane components by electrostatic bonds.     

Acetylcholinesterase is orientated facing the cytoplasmic side in membranes derived from sarcoplasmic reticulum

(1) Microsomal membranes from white rabbit muscle enriched in sarcoplasmic reticulum (SR) were used to investigate the preferential localization of acetylcholinesterase (AChE) in these membranes. (2) Integrity and orientation of the vesicles was assessed by measuring the inulin-inaccessible space of the vesicles and its calcium-loading capacity. (3) Treatment of the membranes with diisopropyl phosphorofluoridate (DFP), an irreversible inhibitor which is free soluble in lipid, produced an almost complete inactivation of AChE. The inhibition was prevented in assays performed with the non-permeant reversible inhibitor BW 284c51 (BW). (4) Similar results were obtained if echothiophate iodide (ECHO), an irreversible and poorly permeant inhibitor, instead of DFP was used. (5) Sedimentation profiles of enzyme solubilized with Triton X-100 from membranes inhibited by DFP after protection with BW showed a minor reduction in the relative proportion of a 4.5 S (G1) form. (6) Treatment of intact or saponin-permeabilized membranes with concanavalin A (ConA) produced enzyme-lectin complexes. In both cases, most of the enzyme was recovered in the sedimented complexes after centrifugation of the Triton-solubilized membranes. (7) Incubation of intact membranes with the antibody AE1 led to the formation of immuno complexes. Sedimentation analyses of the molecular forms of AChE revealed a shift in the sedimentation coefficients, whether the antibody was added before or after solubilization of the enzyme. (8) These results firmly establish an external localization of AChE in SR, most of the protein backbone facing the cytoplasmic side of the membrane.     

The metabolism of neuropeptides. Phase separation of synaptic membrane preparations with Triton X-114 reveals the presence of aminopeptidase N.

The property of solutions of Triton X-114 to separate into detergent-rich and detergent-poor phases at 30 degrees C has been exploited to investigate the identities of the aminopeptidases in synaptic membrane preparations from pig striatum. When titrated with an antiserum to aminopeptidase N (EC 3.4.11.2), synaptic membranes solubilized with Triton X-100 revealed that this enzyme apparently comprises no more than 5% of the activity releasing tyrosine from [Leu]enkephalin. When assayed in the presence of puromycin, this proportion increased to 20%. Three integral membrane proteins were fractionated by phase separation in Triton X-114. Aminopeptidase activity, endopeptidase-24.11 and peptidyl dipeptidase A partitioned predominantly into the detergent-rich phase when kidney microvillar membranes were so treated. However, only 5.5% of synaptic membrane aminopeptidase activity partitioned into this phase, although the other peptidases behaved predictably. About half of the aminopeptidase activity in the detergent-rich phase could now be titrated with the antiserum, showing that aminopeptidase N is an integral membrane protein of this preparation. Three aminopeptidase inhibitors were investigated for their ability to discriminate between the different activities revealed by these experiments. Although amastatin was the most potent (IC50 = 5 X 10(-7) M) it failed to discriminate between pure kidney aminopeptidase N, the total activity of solubilized synaptic membranes and that in the Triton X-114-rich phase. Bestatin was slightly more potent for total activity (IC50 = 6.3 X 10(-6) M) than for the other two forms (IC50 = 1.6 X 10(-5) M). Puromycin was a weak inhibitor, but was more selective. The activity of solubilized membranes was more sensitive (IC50 = 1.6 X 10(-5) M) than that of the pure enzyme or the Triton X-114-rich phase (IC50 = 4 X 10(-4) M). We suggest that the puromycin-sensitive aminopeptidase activity that predominates in crude synaptic membrane preparations may be a cytosolic contaminant or peripheral membrane protein rather than an integral membrane component. Aminopeptidase N may contribute to the extracellular metabolism of enkephalin and other susceptible neuropeptides in the brain.     

A Low-Km 5'-Nucleotidase from Rat Brain Cytosolic Fraction: Purification, Kinetic Properties, and Description of Regulation by a Novel Factor that Increases Sensitivity to Inhibition by ATP and ADP

Abstract: A readily soluble 5'-nucleotidase was purified 1,800-fold from rat brain 105,000- g supernatant. The enzyme showed similarity to the 5'-nucleotidase ectoenzyme of plasma membranes. It exhibited a low K _m for AMP, which was preferred over IMP as substrate. It was inhibited by free ATP and ADP and by α,β-methylene ADP. The enzyme appeared to be a glycoprotein on the basis of its interaction with concanavalin A. It contained a phosphatidylinositol moiety because treatment with phosphatidylinositol-specific phospholipase C increased its hydrophilicity. A single subunit of M_r = 54,300 ± 800 was observed, which is appreciably smaller than published values for the 5'-nucleotidase ectoenzyme or for other low- K _m"soluble" 5'-nucleotidases. The soluble 5'-nucleotidase showed an elution profile on AMP-Sepharose affinity chromatography or on Mono Q ion-exchange chromatography different from that of the brain ectoenzyme. Forty-two percent of the soluble 5'-nucleotidase in brain 105,000- g supernatant did not bind to a Mono Q ion-exchange column because of its interaction with a soluble factor. This factor could be removed by chromatography on concanavalin A-Sepharose. The factor had the novel property of increasing the sensitivity of the purified soluble 5'-nucleotidase toward the inhibitor ATP by 20-fold. This factor was also able to increase the inhibition of brain 5'-nucleotidase ectoenzyme by ATP.     

Effect of concanavalin A on the activity of membrane-bound and detergent-solubilized Mg2+-ATPase

Plasma membranes were isolated after binding liver and hepatoma cells to polylysine-coated polyacrylamide beads, and the effect of concanavalin A on the membrane-bound Mg²⁺-ATPase and the Mg²⁺-ATPase solubilized by octaethylene glycol monododecyl ether (C₁₂E₈) was studied. In the experiment of membranebound Mg²⁺-ATPase, plasma membranes were pretreated with Concanavalin A and the activity was assayed. Concanavalin A stimulated the activity of both liver and hepatoma enzymes assayed above 20°C. Concanavalin A abolished the negative temperature dependency characteristic of liver plasma membrane Mg²⁺-ATPase. On the other hand, Concanavalin A prevented the rapid inactivation due to storage at ?20°C, which was characteristic of hepatoma plasma membrane Mg²⁺-ATPase. With solubilized Mg²⁺-ATPase from liver plasma membranes, the negative temperature dependency was not observed. Concanavalin A, which was added to the assay medium, stimulated the activity of the enzyme solubilized in C₁₂E₈ at a high ionic strength. However, Concanavalin A failed to show any effect on the enzyme solubilized in C₁₂E₈ at a low ionic strength. With solubilized Mg²⁺-ATPase from hepatoma plasma membranes, Concanavalin A could not prevent the inactivation of the enzyme during incubation at ?20°C.     

Particulate carbonic anhydrase in homogenates of human kidney.

About 2% of human kidney carbonic anhydrase (carbonate hydro-lyase, EC 4.2.1.1) has been found in particulate fractions. Its distribution in the particulate fractions obtained by differential centrifugation suggests that it may be concentrated in the brush border. The particulate enzyme is like red cell carbonic anhydrace C in its susceptibility to inhibition by anions. Particulate carbonic anhydrase is firmly bound to the membrane and is not released by incubation at pH 10.6 and 37 degrees C or by addition of Triton X-100 or deoxycholate. In 10% Triton X-100 at pH 11.3 and 37 degrees C, the particulate enzyme is inactivated with a half time of about 20 min, and this is at least an order of magnitude slower than the inactivation of soluble enzymes in the presence or absence of membranes. The soluble enzymes are inactivated within a few minutes at 25 degrees C in 3-4% sodium dodecyl sulfate, but the particulate enzyme is relatively stable under those conditions, and its half-time of inactivation at 14 degrees C with a detergent-protein ratio of 25 was about 24 h. Gel filtration with Ultragel AcA-44 in sodium dodecyl sulfate indicates that the membrane carbonic anhydrase has a molecular weight of less than 66 000, so its stability is not due to association with large membrane fragments or vesicles. These results suggest that the membrane enzyme may be a different isozyme than the soluble carbonic anhydrases. Although present in relatively small amounts, its localization on the membrane could give it functional significance.     

Ordering of bulk membrane lipid or protein promotes activity of plasma membrane Mg2+ATPase

Treatment of liver plasma membranes with phospholipase A2 or high doses of concanavalin A enhances the activity of Mg2+ATPase assayed at temperatures greater than 30 degrees C. The effects of the two treatments are not additive. Both the removal of phospholipids and binding of the lectin increase the degree of polarization of fluorescence of the lipid-soluble fluorophores, diphenylhexatriene and beta-parinaric acid, suggesting that decreased lipid fluidity may activate Mg2+-ATPase. In fact modification of lipid fluidity by reconstitution of phospholipase-treated membranes with phosphatidylcholines of defined fatty acid composition or by addition of cis-vaccenic acid showed a strong inverse correlation between Mg2+ATPase activity and lipid fluidity as monitored by fluorescence polarization. However, despite the ability of concanavalin A to nonspecifically order membrane lipid, its effect on Mg2+ATPase is apparently not mediated in this manner because other enzyme-activating lectins such as Ricinus communis agglutinin and wheat germ agglutinin are without effect on lipid fluidity. The facts that lectins of lower valency than tetravalent native concanavalin A such as divalent succinyl concanavalin A are far less effective in activating the enzyme and that paraformaldehyde treatment also activates suggests that cross-linking of membrane proteins is responsible. Hence, the diminution in activity of this membrane enzyme due to the disordering effect of heat in the physiological temperature range can be counteracted by isothermally increasing the order of either membrane lipid or protein.     

Minimum enzyme unit for Na+/K+-ATPase is the alpha beta-protomer. Determination by low-angle laser light scattering photometry coupled with high-performance gel chromatography for substantially simultaneous measurement of ATPase activity and molecular weight

The oligomeric state of canine renal NA+/K+ -ATPase solubilized by octaethylene glycol n-dodecyl ether (C12E8) was studied by means of low-angle laser light scattering photometry coupled with high-performance gel chromatography (HPGC). At around 0 degree C the solubilized enzyme was separated into the (alpha beta)2-diprotomeric and alpha beta-protomeric protein components with Mr values of 302,000 +/- 10,000 and 156,000 +/- 4,000, respectively, in approximately equal quantities. As the temperature of chromatography was increased toward 20 degrees C, the two protein components converged into a single major component. The Mr of this component depended on the monovalent cation included in the elution buffer, and was 255,000 or 300,000 in the presence of 0.1 M NaCl or 0.1 M KCl, respectively. A computer simulation technique showed that the solubilized enzyme was in a dissociation-association equilibrium of 2 protomers = diprotomer at 20 degrees C, and the difference in apparent Mr of the solubilized enzyme between the two species of monovalent cation was interpreted by an association constant (Ka) in the presence of 0.1 M KCl that was about 50-fold larger than in the presence of 0.1 M NaCl. In order to measure ATPase activity and Mr of the solubilized enzyme simultaneously, a TSKgel G3000SW column had been equilibrated and was eluted with an elution buffer containing 0.30 mg/ml C12E8 and 60 microgram/ml phosphatidylserine (bovine brain) as well as the ligands necessary for the enzyme to exhibit the activity at pH 7.0 and 20 degrees C. The solubilized enzyme was always eluted as a single protein component irrespective of the the amount of the protein applied to the column, ranging between 240 and 10 microgram. The Mr of the protein component, however, decreased from 214,000 and 158,000 with the decrease of the protein amount. The specific ATPase activity, however, remained constant at a level of 64 +/- 4% of that of the membrane-bound enzyme even in the range of protein concentration sufficiently low as to allow the enzyme to exist only in the protomeric form. Thus, the alpha beta-protomer is concluded to be the minimum functional unit for the ATPase activity. The value of Ka obtained from the concentration-dependent dissociation curve was 5 . 10(5) M-1 for the enzyme turning over, and 1.1 . 10(7) M-1 for the enzyme inhibited with ouabain. It was discussed, based on the values of Ka obtained, that the enzyme would exist as the diprotomer or the higher oligomer in the membrane.