Cobalt-ion chelate affinity chromatography for the purification of brain neutral alpha-D-mannosidase and its separation from acid alpha-D-mannosidase.

A method is described for the purification of neutral alpha-D-mannosidase and its separation from acid alpha-D-mannosidase from monkey brain by utilizing Co2+ chelate affinity chromatography. The neutral enzyme, which selectively bound to the metal-ion chelate column, was elutable by Tris at pH 7.5 and gave over 80-fold purification in a single step with 100% recovery.     

Ca2+-mediated activation of phosphofructokinase in perfused rat heart.

Perfusion of the isolated rat heart with Ca2+ concentrations exceeding 3 mM activated phosphofructokinase and phosphorylase, and decreased the concentration of cyclic AMP. Half-maximal activation of phosphofructokinase occurred at 5 mM-CaCl2; significant activation of phosphorylase did not occur until the concentration of CaCl2 exceeded 12 mM. The time course for the activation of phosphofructokinase at 12 mM-CaCl2 indicated that maximal activation occurred within 2 min; when the perfusion-medium Ca2+ concentration was re-adjusted to 3 mM, the phosphofructokinase activity returned to pre-activation values within 30 s. The addition of Ca2+ to extracts of heart did not activate phosphofructokinase. The activation of phosphofructokinase by sub-maximal doses of adrenaline and Ca2+ were not additive. The activation of phosphofructokinase by 1 microM-adrenaline + 10 microM-propranolol and by 1 microM-isoprenaline was inhibited by high concentrations of K+ (22-56 mM). The activation of phosphofructokinase by 1 microM-adrenaline + 10 microM-propranolol, 12 mM-CaCl2 and by 1 microM-isoprenaline was blocked by the slow Ca2+-channel blocker nifedipine. These findings suggest that both the beta- and alpha-adrenergic mechanisms for the activation of rat heart phosphofructokinase involve an increase in the myoplasmic Ca2+ concentration. This increase may result from an inhibition of Ca2+ efflux or a stimulation of Ca2+ influx.     

Ca2+-mediated activation of human erythrocyte membrane Ca2+-ATPase

Ca2+-ATPase of human erythrocyte membranes, after being washed to remove Ca2+ after incubation with the ion, was found to be activated. Stimulation of the ATPase was related neither to fluidity change nor to cytoskeletal degradation of the membranes mediated by Ca2+. Activation of the transport enzyme was also unaffected by detergent treatment of the membrane, but was suppressed when leupeptin was included during incubation of the membranes with Ca2+. Stimulation of the ATPase by a membrane-associated Ca2+-dependent proteinase was thus suggested. Much less 138 kDa Ca2+-ATPase protein could be harvested from a Triton extract of membranes incubated with Ca2+ than without Ca2+. Activity of the activated enzyme could not be further elevated by exogenous calpain, even after treatment of the membranes with glycodeoxycholate. There was also an overlap in the effect of calmodulin and the Ca2+-mediated stimulation of membrane Ca2+-ATPase. While Km(ATP) of the stimulated ATPase remained unchanged, a significant drop in the free-Ca2+ concentration for half-maximal activation of the enzyme was observed.     

Characterization of a novel alpha-D-mannosidase from rat brain microsomes

A new alpha-D-mannosidase has been identified in rat brain microsomes. The enzyme was purified 70-100-fold over the microsomal fraction by solubilization with Triton X-100, followed by ion exchange, concanavalin A-Sepharose, and hydroxylapatite chromatography. The purified enzyme is very active towards mannose-containing oligosaccharides and has a pH optimum of 6.0. Unlike rat liver endoplasmic reticulum alpha-D-mannosidase and both Golgi mannosidases IA and IB, which have substantial activity only towards alpha 1,2-linked mannosyl residues, the brain enzyme readily cleaves alpha 1,2-, alpha 1,3-, and alpha 1,6-linked mannosyl residues present in high mannose oligosaccharides. The brain enzyme is also different from liver Golgi mannosidase II in that it hydrolyzes (Man)5GlcNAc and (Man)4GlcNAc without their prior N-acetylglucosaminylation. Moreover, the facts that the ability of the enzyme to cleave GlcNAc(Man)5GlcNAc, the biological substrate for Golgi mannosidase II, is not inhibited by swainsonine, and that p-nitrophenyl alpha-D-mannoside is a poor substrate provide further evidence for major differences between the brain enzyme and mannosidase II. Inactivation studies and the co-purification of activities towards various substrates suggest that a single enzyme is responsible for all the activities found. In view of these results, it seems possible that, in rat brain, a single mannosidase cleaves asparagine-linked high mannose oligosaccharide to form the core Man3GlcNAc2 moiety, which would then be modified by various glycosyl transferases to form complex type glycoproteins.     

Rapid Ca2+-mediated activation of Rap1 in human platelets.

Rap1 is a small, Ras-like GTPase whose function and regulation are still largely unknown. We have developed a novel assay to monitor the active, GTP-bound form of Rap1 based on the differential affinity of Rap1GTP and Rap1GDP for the Rap binding domain of RalGDS (RBD). Stimulation of blood platelets with alpha-thrombin or other platelet activators caused a rapid and strong induction of Rap1 that associated with RBD in vitro. Binding to RBD increased from undetectable levels in resting platelets to >50% of total Rap1 within 30 s after stimulation. An increase in the intracellular Ca2+ concentration is both necessary and sufficient for Rap1 activation since it was induced by agents that increase intracellular Ca2+ and inhibited by a Ca2+-chelating agent. Neither inhibition of translocation of Rap1 to the cytoskeleton nor inhibition of platelet aggregation affected thrombin-induced activation of Rap1. In contrast, prostaglandin I2 (PGI2), a strong negative regulator of platelet function, inhibited agonist-induced as well as Ca2+-induced activation of Rap1. From our results, we conclude that Rap1 activation in platelets is an important common event in early agonist-induced signalling, and that this activation is mediated by an increased intracellular Ca2+ concentration.     

Ca2+-mediated activation of phosphoenolpyruvate carboxykinase occurs via release of Fe2+ from rat liver mitochondria

The addition of calcium chloride to rat liver homogenates resulted in activation of phosphoenolpyruvate carboxykinase by as much as 50%. The enhanced activity was inhibited by quinolinic acid; it was not additive with activation by FeCl2, and stimulation was prevented by 1,10-phenanthroline. Activation by calcium was lost when the particulate fractions of liver were removed, but an activating system could be reconstituted with isolated mitochondria, purified P-enolpyruvate carboxykinase, and purified ferroactivator. Iron-loaded mitochondria were more responsive to calcium than controls. A release of Fe2+ from washed mitochondria could be detected spectrophotometrically when 25-75 nmol of Ca/mg of protein were added to the mitochondrial suspension. If Ca2+ was buffered with ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, the threshold of Ca2+ necessary for release of Fe2+ was approximately 10(-7) M, with peak response between 5 X 10(-7) and 10(-6) M. Total Fe2+ detected was normally 20-30 pmol of Fe2+/mg of protein. The synthetic activator of P-enolpyruvate carboxykinase, 3-aminopicolinic acid, as well as other picolinic acid derivatives, is capable of withdrawing Fe2+ associated with the mitochondrial fraction; after incubation with mitochondria, 3-aminopicolinate will activate phosphoenolpyruvate carboxykinase in the absence of exogenous metal.     

Purification and characterization of neutral alpha-mannosidase that is activated by Co2+ from Japanese quail oviduct

An alpha-mannosidase was purified from the magnum section of Japanese quail oviduct by ammonium sulfate precipitation, DEAE-Sephacel chromatography, Sephacryl S-300 chromatography, mannan-Sepharose 4B chromatography, and hydroxyapatite chromatography. The purified alpha-mannosidase (referred to as neutral alpha-mannosidase) showed a single band on polyacrylamide gel with or without sodium dodecyl sulfate. Its molecular weight was found to be 330,000 by gel chromatography. Neutral alpha-mannosidase hydrolyzed p-nitrophenyl alpha-D-mannopyranoside and the pyridylamino derivative of Man alpha 1-6(Man alpha 1-3)Man alpha 1-6(Man alpha 1-3)Man beta 1-4GlcNAc beta 1-4GlcNAc (Km value was 3 mM). Mannosyl alpha 1-2 linkages in the pyridylamino derivative of Man alpha 1-2 Man alpha 1-6(Man alpha 1-2Man alpha 1-3)Man alpha 1-6(Man alpha 1-2Man alpha 1-2Man alpha 1-3)Man beta 1-4GlcNAc beta 1-4GlcNAc were hardly hydrolyzed. Its optimum pH was found to be 7.0. The activity of the enzyme was activated by CO2+, and was potently inhibited by Cu2+, Hg2+, swainsonine, and 1-deoxymannojirimycin.     

Purification and characterization of a calcium-activated neutral protease from monkey brain and its action on neuropeptides

A calcium-activated neutral protease was purified from Japanese monkey brain by ammonium sulfate fractionation and sequential column chromatographies monitored by assay of caseinolytic activity. The purified enzyme gave a single protein band on non-denaturing polyacrylamide gel electrophoresis, and consisted of two subunits with molecular weights of 74,000 and 20,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme required millimolar order calcium ions for activation, and was optimally active at pH 7.5-8.0. Upon incubation with various neuropeptides as substrates, the enzyme preferentially cleaved the peptide bonds with Arg, Lys, or Tyr at the P1 position and an amino acid residue with a bulky aliphatic side chain, such as Leu, Val, or Ile, at the P2 position. The hydrolytic activity toward neuropeptides as well as casein was strongly inhibited by various thiol protease inhibitors. These results suggested that the brain calcium-activated neutral protease may participate in the degradation of neuropeptides in vivo.     

Purification and characterization of arylamidase from monkey brain.

Arylamidase [EC3.4.11.2] was isolated from monkey brain extract and purified about 2100-fold in approximately 11% yield by a six-step procedure comprising extraction from monkey brain homogenate, ammonium sulfate fractionation, first hydroxylapatite chromatography, DEAE-cellulose chromatography, Sephadex G-200 gell filtration and second hydroxylapatite chromatography. The enzyme showed a single band on polyacrylamide disc electrophoresis and consisted of a single polypeptide chain, as judged by disc electrophoresis in the presence of sodium dodecyl sulfate. The enzyme was strongly inhibited by PCMB, TPCK, and puromycin. Puromycin competitively inhibited the enzyme and the Ii value was about 5 x 10(-7)M. Treatment with EDTA resulted in a loss of enzyme activity. The enzyme activity was restored by addition of Zn2+, Co2+, Mn2+. Among various amino acid beta-naphthylamides, L-alanine beta-naphthylamide was most rapidly hydrolyzed and N-carbobenzoxyl-L-leucine beta-naphthylamide was not hydrolyzed by this enzyme preparation. The molecular weight of the enzyme was 92,000 as determined by gel filtration on Sephadex G-200.     

Isolation and properties of alpha-D-mannosidase from human kidney.

Alpha-D-Mannosidase activity exists in three forms that can be separated by DEAE-cellulose chromatography, alpha-D-Mannosidase was isolated from human kidney in a homogeneous state, and was purified 2100-fold, with p-nitrophenyl alpha-D-mannoside as substrate. The purified alpha-D-mannosidase was practically free from all other glycosidases tested. The Km of the synthetic substrate with the enzyme was 1 X 10(-3) M and the pH optimum 4.5. It was inhibited by heavy metals, sodium dodecyl sulphate, urea and compounds that react with the thiol groups, and was activated by Zn2+, Na+, 2-mercaptoethanol, human albumin and gamma-globulin. The mol. wt. of the enzyme was estimated to be 180 000 +/- 4500. After pretreatment with 2-mercaptoethanol and sodium dodecyl sulphate, alpha-D-mannosidase dissociated into subunits of mol. wts. of 58 000 +/- 600 and 30 000 +/- 380 respectively. Subunits of the same molecular weights were also obtained after the enzyme was heated at 100 degrees C.     

A novel neutral protease(s) from monkey liver.

A novel neutral protease(s), which is presumably membrane-bound, was found in monkey liver using heat-denatured casein as a substrate and was separated from other major catheptic proteases by successive procedures of gel filtration on Ultrogel AcA 22, solubilization by deoxycholate and gel filtration on Sepharose 6B. The enzyme(s) showed maximal activity at pH 8.0, and was strongly inhibited by DFP and PMSF. Many other reagents tested, including TPCK, TLCK, pCMB, iodoacetic acid, and EDTA, were without marked effect on the activity. Activation of the enzyme(s) by NaCl was not observed.     

Ca2+-dependent neutral proteinase from human erythrocytes: activation by Ca2+ ions and substrate and regulation by the endogenous inhibitor

Ca2+-dependent neutral proteinase purifies from human erythrocytes as an inactive proenzyme, that can be converted in an active low Ca2+ requiring form either by high concentrations of Ca2+ (0.1-1 mM) in the absence of the substrate, or by low concentrations of Ca2+ (1-5 microM) in the presence of digestible substrates. Activation requires dissociation to constituent inactive proenzyme subunits which are then converted to the active proteinase species still retaining their monomeric structure. The activation process produced by high Ca2+ concentrations is controlled by the endogenous inhibitor which also dissociates into constituent subunits in order to exert its inhibitory effect. An additional regulation of the activated proteinase involves an autoproteolytic process, Ca2+ and substrate dependent, producing enzyme inactivation.     

Ca(2+)-mediated interaction between negatively charged and neutral liposomes.

In the present work it is shown that large unilamellar lecithin/cholesterol liposomes are able to sequester small negatively charged liposomes in the presence of divalent cations. Evidence is presented suggesting that the sequestration occurs via the formation of membrane invaginations transformed further into intraliposomal vesicles.     

Intracellular mediators regulate CD2 lateral diffusion and cytoplasmic Ca2+ mobilization upon CD2-mediated T cell activation.

CD2 is a T cell surface glycoprotein that participates in T cell adhesion and activation. These processes are dynamically interrelated, in that T cell activation regulates the strength of CD2-mediated T cell adhesion. The lateral redistribution of CD2 and its ligand CD58 (LFA-3) in T cell and target membranes, respectively, has also been shown to affect cellular adhesion strength. We have used the fluorescence photobleaching recovery technique to measure the lateral mobility of CD2 in plasma membranes of resting and activated Jurkat T leukemia cells. CD2-mediated T cell activation caused lateral immobilization of 90% of cell surface CD2 molecules. Depleting cells of cytoplasmic Ca2+, loading cells with dibutyric cAMP, and disrupting cellular microfilaments each partially reversed the effect of CD2-mediated activation on the lateral mobility of CD2. These intracellular mediators apparently influence the same signal transduction pathways, because the effects of the mediators on CD2 lateral mobility were not additive. In separate experiments, activation-associated cytoplasmic Ca2+ mobilization was found to require microfilament integrity and to be negatively regulated by cAMP. By directly or indirectly controlling CD2 lateral diffusion and cell surface distribution, cytoplasmic Ca2+ mobilization may have an important regulatory role in CD2 mediated T cell adhesion.     

The reversible activation by Mn2+ ions of the Ca2+-requiring neutral proteinase of human erythrocytes

Mn2+ (50 microM) satisfies the requirement for activity of the purified Ca2+-dependent neutral proteinase from human erythrocytes. Unlike the activation by Ca2+ [E. Melloni et al. (1984) Biochem. Int. 8, 477-489], the effect of Mn2+ is fully reversible and does not involve autodigestion of the native 80-kDa catalytic subunit. However, the native dimeric proenzyme (procalpain), which contains both the 80-kDa subunit and a smaller 30-kDa subunit, is not activated by Mn2+ alone but also requires the presence of micromolar concentrations of Ca2+. Under these conditions, 40% of the maximum activity is expressed without dissociation of the 80- and 30-kDa subunits. Mn2+, but not micromolar Ca2+, can also partially satisfy the metal requirement of the native 80-kDa subunit isolated after dissociation of the heterodimer. This activity is further enhanced by the addition of 5 microM Ca2+, which is ineffective in the absence of Mn2+. After procalpain is converted to active calpain by incubation with Ca2+ and substrate [S. Pontremoli et al. (1984) Biochem. Biophys. Res. Commun. 123, 331-337] full activity is observed with 5 microM Mn2+, which now substitutes completely for Ca2+. Activation of procalpain by Mn2+ represents a new mechanism for modulation of the Ca2+-dependent proteinase activity.     

Characteristics of the activation by dithiothreitol and Fe2+ of tryptophan hydroxylase from the rat brain

The preincubation of tryptophan hydroxylase extracted from various areas of the central nervous system of the rat with 30 mM dithiothreitol and 50 M ferrous ammonium sulfate under nitrogen atmosphere resulted in a persistent increase of its activity. Studies on the enzyme characteristics indicated that this activation was associated with a doubling in itsV _max and a shift (from 7.6 to 7.2) of the optimal pH for its activity. In contrast, the molecular weight and the apparent affinities of tryptophan hydroxylase for its pterin cofactor and for tryptophan were not significantly altered by the preincubation with dithiothreitol and ferrous ammonium sulfate. Since this treatment did not prevent the stimulatory effects of various compounds (phosphatidylserine, ATP and Mg²⁺, Ca²⁺) on tryptophan hydroxylase activity, this might be a good procedure to activate this enzyme with only minor changes in its regulatory properties.