Lectin-induced inhibition of plasma membrane 5′-nucleotidase: Sensitivity of purified enzyme

To determine whether the lectin-induced inhibition of plasma membrane 5′-nucleotidase resulted from direct interaction of the lectin with the enzyme or indirectly from a membranous change due to lectin binding to other membrane glycoproteins, the enzyme was purified and its sensitivity tested in the absence of other membrane components. A 5000 fold purification was achieved by solubilization in Lubrol PX followed by gel filtration (Sephadex G-100), anion exchange (DEAE-Biogel A) and selective adsorption (hydroxylapatite) chromatography. The purified enzyme was even more sensitive to inhibition by high concentrations of concanavalin A, wheat germ agglutinin or Rincinus communis agglutinin than was the membrane-bound enzyme indicating that inhibition is due to direct binding of the lectins to the glycoprotein enzyme itself. Divalent succinyl Con A inhibited neither form of the enzyme suggesting the need for crosslinking for inhibition by the native lectin. The purified enzyme could not be activated by low concentrations of lectins which stimulated the membrane bound enzyme.     

A new method for the determination of ligand dissociation rate constant of carboxyhemoglobin.

Concanavalin A (Con A) treatment of plasma membrane-enriched fractions from lactating mammary gland causes an activation of Mg⁺⁺-ATPase and an inactivation of 5′-nucleotidase. Both effects can be prevented by the presence of α-methylmannoside, and both exhibit cooperativity with Hill coefficients near 2. The cooperativity may arise from Con A effects on subunit interactions of the enzymes or by clustering of the enzyme molecules in the membrane, possibly induced by Con A. Investigations of these systems should be useful for developing an understanding of modes of action of Con A in complex phenomena.     

Interactions of lectins with membrane glycoproteins effects of concanavalin A on 5′-nucleotidase

Concanavalin A causes a biphasic modification of the activity of the plasma membrane enzyme 5′-nucleotidase. The first stimulatory phase occurs from 0 to 0.05 μM concanavalin A, the second inhibitory phase at higher concentrations. The curve relating binding of ¹²⁵I-labelled concanavalin A and concentration of native lectin is similarly biphasie. The two phases likely result from occupation of distinct families of binding sites. When the enzyme is extracted from the membrane, the stimulatory phase disappears. Thus, the high affinity binding sites responsible for this phase depend upon the intact membrane structure while the others do not.     

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.     

The thermodynamic parameters of the interaction of concanavalin A with glycosyl-free liposomes: a microcalorimetric study

The nonspecific interaction of the mitogenic lectin Concanavalin A (Con A) with glycosyl-free liposomes of various composition has been investigated by microcalorimetric titration measurements. The results obtained show the following features of main interest: (1) the affinity constants (K_a) of the interaction of Con A with liposomal bilayers are in the order of magnitude 10⁵–10⁶M^?1. The reaction enthalpies (ΔH) are positive, and small (approximately 0.1 KJ mol^?1 lipid), compared to the free energy terms (?ΔG = 30–40 KJ mol^?1 lipid). All lectin–lipid interactions are strongly entropy-controlled (ΔH/TΔS < 1.0). These thermodynamic features are characteristic for hydrophobic interaction processes. (2) The liposomal head-group charge does not significantly affect the lipid-affinity of Con A. Electrostatic forces thus appear to play a minor role in lectin–lipid interactions. (3) The lipid affinity of Con A is sensitive to the fluidity of the liposomal bilayers, increasing with increasing fluidity. Below the gel to liquid-crystal phase transition temperature, the lectin binding to liposomal bilayers is inhibited. (4) The binding isotherms, corresponding to the interaction of Con A with liposomes, composed of tightly packed, saturated phospholipids, exhibit pronounced positive cooperativity. This phenomenon is absent in the binding curves, corresponding to the interaction of Con A with more fluid liposomal bilayers. (5) The Con A specific inhibitor α-D -methylmannopyranoside (50 mM) drastically increases the molar reaction enthalpy. The K_a term is significantly reduced in presence of the inhibitor sugar. Urea induces analogous changes in the thermodynamic parameters of the lectin–lipid interaction. The effects of α-D -methylmannopyranoside are thus not Con A specific, but are attributable to solvent effects. (6) It was shown that the binding of one Con A molecule affects a large number (approximately 1000) of phospholipid molecules in the liposomal bilayer. (7) The affinity constants (K_a) of the interaction of Con A with glycosyl-free lipids are smaller by a factor of approximately 10, compared to the K_a terms, reported for Con A binding to biological membranes. The presence of glycosidic receptor groups thus controls the specificity of lectin–membrane interactions, whereas the nonspecific lectin–lipid interactions appear to represent the main driving force for the strong attachment of the lectin to membrane surfaces.     

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.     

Absence of 5′-nucleotidase in porcine polymorphonuclear leucocyte membranes

A fraction enriched in plasma membranes from porcine polymorphonuclear leucocytes, isolated by sucrose density centrifugation was shown to possess considerable AMP hydrolysing activity (150 nmol/min per mg protein). However all of this activity could be inhibited using excess $\text{p-}\text{nitrophenyl}$ phosphate in the incubation medium. Furthermore the hydrolysis of AMP by the membrane was unaffected by the 5′-nucleotidase inhibitor α,β-methyleneadenosine diphosphate and by the lectin concanavalin A, another potent inhibitor of 5′-nucleotidase. An antibody against mouse liver 5′-nucleotidase also did not inhibit the activity. These results suggest that the hydrolysis of AMP by porcine polymorph membranes is not accomplished by a specific 5′-nucleotidase and the necessity for distinguishing between true 5′-nucleotidase and non-specific phosphatase activity is discussed.     

Concanavalin A induced activity change in yeast PM-bound NADH-HCF(III) oxidoreductase

The activity of plasma membrane bound redox enzyme, NADH-HCF(III) oxidoreductase, in wild and mutant strains of the yeast Saccharomyces cerevisiae is modulated by Con A in a dose-dependent manner. The solubilized activity is enhanced at lower concentration and inhibited at higher concentration of Con A. The enzyme in mutant strain is more sensitive to inhibition. The activation of enzyme by Con A is suppressed in the presence of either alpha-methyl-D-mannoside or 2-deoxy-D-glucose, indicating the glycoproteic nature of enzyme as well as the resulting conformational change due to interaction with Con A as the factor for modulated activities. This was supported by recording the decrease in K(m) value of enzyme with respect to substrate NADH in the presence of lower concentration of Con A. The purified enzyme was more sensitive to lectin stimulation and, on the basis of comparative stimulatory effects of Con A and PSA on activity, it is likely that mannosyl moiety in enzyme is involved in binding the lectins to cause enzymic activation.     

Studies on the alkaline phosphatase and 5'-nucleotidase of Dictyostelium discoideum.

The alkaline phosphatase and 5′-nucleotidase activities of Dictyostelium discoideum are due to two distinct enzymes. Both enzymes are membrane bound, but over 90% of the 5′-nucleotidase activity is solubilized when the crude membrane fraction of the cell is treated with phospholipase C under conditions that release only 10% of the alkaline phosphatase.Part of the alkaline phosphatase activity can be detected in whole cells, suggesting that some of the enzyme molecules are located on the exterior surface of the plasma membrane. In contrast very low 5′-nucleotidase activity can be detected in whole cells. When membrane preparations, isolated from cells that had been surface labeled with ¹²⁵I, were subjected to sedimentation equilibrium on sucrose density gradients, the majority of the ¹²⁵I-radioactivity cosedimented with the alkaline phosphatase and 5′-nucleotidase activites, suggesting that both enzymes are plasma membrane components.The two enzymes have distinctly different pH optima, but otherwise their properties are remarkably similar. Both enzymes are inhibited by cyanide, sulfhydryl inhibitors and sulfhydryl reagents, although in each case the 5′-nucleotidase is slightly more susceptible. Both enzymes are inhibited by the levamisole analogue, R 8231, but the alkaline phosphatase is inhibited to a somewhat greater extent. Both enzymes are activated by incubation at 50 °C but inactivated by higher temperatures.The two enzymes increase in activity at identical times during differentiation, suggesting that they are under coordinate developmental control.     

5′-Nucleotidase activity of isolated mature rat cardiac myocytes

Specific location of 5′-nucleotidase in the heart has been uncertain, some authors citing evidence for an exclusively non-myocyte location, while other data point to the existence of cytoplasmic and membrane-bound fractions. Single myocytes isolated from mature rat heart, and free of endothelial or interstitial cells, have been used to establish that muscle cells of the myocardium are rich in 5′-nucleotidase, exhibiting activity sufficient to account for the total myocardial content of this enzyme. All 5′-nucleotidase is accessible to extracellular AMP. Inhibitors of 5′-nucleotidase and adenosine transport have been used to establish that only the adenosine component of adenine nucleotides is taken up by myocytes, but hydrolysis of AMP by 5′-nucleotidase does not commit the adenosine formed to transport across the sarcolemmal membrane. Myocytes also have ecto-phosphatases which hydrolyse ADP and ATP.     

5′-Nucleotidase from bovine brain cortex: effect of solubilization on enzyme kinetics and modulation

The kinetic characteristics and the EDTA inhibition of microsomal 5′-nucleotidase from bovine brain cortex were studied and compared with the properties of the enzyme solubilized with Lubrol WX. The K_m value after enzyme solubilization was not significantly different from that of the membrane-bound enzyme. Likewise, di- and trinucleotides performed a similar competitive inhibition of the two forms of the enzyme. In contrast, divalent cations inhibited the intact microsomal enzyme activity at the same concentrations in which they increased the soluble-enzyme activity. The solubilization of microsomal 5′-nucleotidase did not change the progressive and irreversible character of the EDTA inhibition, but the mechanism of the irreversible inhibition was different. The addition of divalent metal cations did not affect the irreversibility of either inhibition, even though the effect on the residual activities was different. The Arrhenius plot of the 5′-nucleotidase activity in intact microsomal fraction exhibited a well-defined break at 31 ± 0.1°C, whereas that of the solubilized enzyme was a straight line. It is concluded then that microsomal 5′-nucleotidase from bovine brain cortex does not require the membrane environment to express its activity, although the influence of this lipidic environment was evident in the differences observed in the enzyme activity modulation by EDTA, cations and temperature.     

Cellular binding sites for insulin in rat liver

A study of the sites of insulin binding in subcellular fractions of rat liver is reported. A method for the isolation of liver plasma membranes, which permits one to follow quantitatively the distribution of all the parameters of interest, was modified and applied to the study of the cellular topography of insulin binding. The insulin-binding capacity did not follow closely the enzyme marker (5′-nucleotidase) for plasma membranes when differential centrifugation schemes were used, and the divergence from this marker was more prominent when separations were performed on discontinuous sucrose gradients. A significant amount of insulin binding capacity was always present in fractions with higher density than those containing the majority of 5′-nucleotidase. Results of studies on linear sucrose gradients have disclosed in some of the purified membrane fractions small but consistent differences in density of the insulin binding, and plasma membrane particles. It is suggested that there may be several types of intracellular membranes to which insulin can bind besides the plasma membranes.     

Guinea pig skeletal muscle 5′-nucleotidase

ATP, UTP, GTP, and CTP were found to be powerful competitive inhibitors of 5′-nucleotidase partially purified from guinea pig skeletal muscle, the concentrations required for 50% inhibition being 1.25 uM, 5.5 uM, 10 uM and 27.5 uM respectively with 5′-AMP as substrate. The enzyme does not require divalent cations. Furthermore magnesium, calcium and cobalt ions added in large excess with respect to nucleoside triphosphates did not completely relieve the inhibition, indicating that the complexes nucleoside triphosphates-divalent cations are also inhibitors. Using specific optical assays to follow the dephosphorylation of AMP, GMP and IMP it was found that the hydrolysis of each 5′-mononucleotide is competitively inhibited by other 5′-mononucleotides. The regulation of skeletal muscle 5′-nucleotidase supports the hypothesis of its role in the mechanism of muscular contraction.     

Plasma Membrane Glycoproteins of Ciona intestinalis Spermatozoa that Interact with the Egg1

In the ascidian Ciona intestinalis the species-specific interaction between the spermatozoon and the egg occurs between the vitelline coat (VC) of the egg and the plasma membrane of the apical part of the head of the spermatozoa. Concanavalin A (Con A)-binding sites are present on this area of the sperm surface. We used Con A to identify and isolate the spermatozoon plasma membrane components that may be involved in the interaction with the VC. These glycoproteins have been identified on SDS-PAGE of a sperm membrane fraction (SMF) enriched with the extermal proteins, after incubation of the gel with ³H-Con A. Affinity chromatography on Con A-agarose has been used for the purification of sperm plasma membrane proteins with and affinity for the lectin. The biological activity of the Con A-retained fraction was determined with binding and fertilization assays.     

Phagocytosis of collagen fibrils by periosteal fibroblasts in long bone explants. Effect of concanavalin A

In an attempt to determine whether phagocytosis of collagen by fibroblasts involves binding of the fibril to the plasma membrane, the effect of the lectin concanavalin A (Con A) was studied in an in vitro model system. Metacarpal bone rudiments from 19-day-old mouse fetuses were incubated with varying concentrations of the lectin. Quantitative electron microscopic analysis indicated that Con A caused a dose-related increase in the amount of phagocytosed collagen fibrils in periosteal fibroblasts, suggesting either an enhanced uptake or a decreased intracellular breakdown of fibrils. Since a Con A-inducible increase was not seen in the combined presence of both the lectin and the proteinase inhibitor leupeptin, which is known to inhibit the intracellular digestion of phagocytosed fibrillar collagen, it is unlikely that Con A stimulated phagocytosis. Based on the finding that Con A interfered with the digestion of a synthetic substrate by the collagenolytic lysosomal enzyme cathepsin B it is suggested that the augmentation of intracellular fibrillar collagen under the influence of the lectin was due to a decreased intracellular digestion. Since Con A did not inhibit the uptake of collagen fibrils by the fibroblasts it is concluded that Con A-inhibitable binding sites for collagen molecules are unlikely to be involved in phagocytosis of collagen fibrils by fibroblasts.     

Membrane-bound 5′-nucleotidase inhibitor in Ehrlich ascites tumour cells and newborn mouse liver

5′-Nucleotidase activity in Ehrlich ascites tumour cells was undetectable. The cell homogenate, when mixed with adult mouse liver homogenate, inhibited the 5′-nucleotidase activity of the latter, without affecting is p-nitrophenyl phosphate-hydrolysing activity. The inhibitor activity was enriched (6.8-fold) in a membrane fraction which was enriched in (Na⁺ + K⁺)-ATPase (14-fold) and alkaline phosphatase (8-fold). 5′-Nucleotidase activity in this membrane fraction could be detected only after separating the inhibitor activity from the enzyme on Sephadex G-50. The inhibitor activity was decreased by 27% when heat-treated, 33% when treated with 6 M urea and was almost completely lost when treated with trypsin. It was dialysable from a tubing with a molecular exclusion limit of 10 000, but was retained in a tubing with an exclusion limit of 3000. From these results we conclude that a small molecular weight protein inhibitor(s) of 5′-nucleotidase is present in the plasma membrane of Ehrlich ascites tumour cells. Also, the presence of such an inhibitor in the newborn mouse liver but not in the adult liver suggests that it may have some role in cellular ageing and cancer.     

Effect of phagocytosis on guinea pig granulocyte membrane markers

The internalization of membrane markers during phagocytosis was followed in guinea pig granulocytes as a function of the extent of particle ingestion. The plasmalemma was carefully labeled with diazotized ³⁵S-sulfanilate, or by treatment with periodate and sodium ³H-borohydride. These treatments provided general membrane markers. More specific markers used were 5′-nucleotidase, neuraminidase-releasable membrane sialate, and concanavalin A binding sites. In all cases except the last, internalization of membrane was directly determined on isolated phagosomes; disappearance of binding sites from the cell surface was followed in the last instance. Both phagosomal levels and disappearance from the surface were measured in the case of 5′-nucleotidase, permitting balance studies. Phagocytosis was determined as uptake of paraffin emulsions labeled with Oil-Red 0. “Marker/particle” ratios were determined as the percent external marker internalized per mg paraffin ingested. The “marker/particle” ratios for cells with chemically labeled membranes were considered to reflect random internalization of membrane entities. Colchicine had no effect on those ratios. Internalization of 5′-nucleotidase and neuraminidase-releasable sialate gave “marker/particle” ratios similar to those of the random markers, and these increased in the presence of colchicine. Concanavalin A binding sites did not appear to be removed from the cell surface in the absence of colchicine, but disappearance was observed in its presence. Control experiments indicated that these changes due to colchicine must be very cautiously interpreted. Our results differ from those obtained by others, and the reasons due to species, cell type, experimental design, etc. are discussed. Maximal particle uptake was computed to require internalization of one-fifth to one-third of the total external membrane of the cells—based on the assumption of random internalization of markers.     

Use of a concanavalin A polymer to isolate right side-out vesicles of purified plasma membranes from eukariotic cells

We have purified two plasma membrane populations using a Concanavalin A polymer. It was assumed that vesicles retained by the polymer were right side-out, whereas vesicles not retained were inside-out. 5′-nucleotidase and (Na⁺ + K⁺) stimulated Mg⁺⁺ ATPase activities were at least two fold higher in inside-out than in right side-out vesicles, though recovered total activity was about 80 % for both enzymes together. Moreover, Concanavalin A modified 5′-nucleotidase activity of right side-out vesicles according to the dose used.     

Effect of Erythropoietin on the interaction of Concanavalin A with rat erythrocytes

Effect of Erythropoietin (Ep) on the interaction of Concanavalin A (Con A) with rat erythrocytes was studied using ¹²⁵I-labelled Con A. Binding of Con A to erythrocytes was dependent on time and cell concentration. Starvation caused an elevation of the lectin binding capacity of red cells which again came down towards the normal level on Ep administration to starved rats. Binding of Con A to erythrocytes decreased linearly with increasing concentration of Ep. Specificity of binding was confirmed by inhibition studies with -methyl-D-mannopyranoside (Me Man) Cells from the starved rats compared to those from normal and Ep treated animals were less prone to inhibition by this sugar analog. Positive cooperative binding of Con A to rat erythrocyte was observed at low concentration of Con A but was absent at higher lectin concentrations. Starvation caused an increase in the number of binding sites per cell which returned to normal level after Ep treatment. Under identical conditions, binding affinities were not much changed in these cells. Cells from the starved animals were more susceptible to agglutination compared to those from normal and Ep-treated rats. Microviscosity and cholesterol/phospholipid ratio of red cell membrane decreased in the starved animals which retraced its way back towards the normal level after Ep treatment.