Photocontrol of affinity chromatography. I. Trypsin purification by photosensitive soybean trypsin inhibitor (STI) gel

Soybean trypsin inhibitor (STI) was immobilized on the agarose gel modified with spiropyran compound (spiropyran gel), and photocontrolled binding and releasing of trypsin was examined. The STI-spiropyran gel showed reverse photochromism. Trypsin was bound on the STI-spiropyran gel in the dark and released with visible light irradiation. The optimum conditions for photocontrolled binding and releasing of trypsin were pH 6.6 and the buffer concentration of 0.05 m. Approximately 60–80% of bound trypsin was released with visible light irradiation. The activity of released trypsin was the same as that of native trypsin. Approximately 21-fold purification of trypsin was performed with the STI-spiropyran gel column.     

Photocontrol of immobilized trypsin activity

Trypsin was coupled on an agarose gel which was modified with a spiropyran compound. The trypsin–spiropyran (agarose) gel showed reverse photochromism. The activity of the trypsin–spiropyran gel in the dark was 12% of that of native trypsin, and it was higher than that under visible light. The apparent Michaelis constant of the trypsin–spiropyran gel in the dark was larger than that under visible light. On the other hand, the maximum velocity in the dark was higher than that under visible light. The optimum pH of the trypsin–spiropyran gel in the dark was the same as that under visible light. Immobilized trypsin was stable in the pH range from 3 to 9. The trypsin–spiropyran gel was more stable against heat than the native trypsin.     

Effect of asparaginase on cell membranes of sensitive and resistants mouse lymphoma cells

Summary High concentrations ofEscherichia coli asparaginase (80 U/ml) altered the binding of concanavalin A (Con A) to L 5178Y murine lymphoma cells that are sensitive to the cytotoxic action of this enzyme. Incubation of the asparaginase sensitive line in asparagine-free media or media containingAcinetobacter glutaminase-asparaginase did not alter the Con A binding of these cells.Escherichia coli asparaginase had no effect on Con A binding of two asparaginase resistant L5178Y cell lines that were isolate and maintained in asparagine depleted or asparaginase containing medium. TheE. coli asparaginase preparation inhibited protein and glycoprotein biosythesis to comparable degrees. It did not have proteolytic or glycolytic activity.Escherichia coli asparaginases did not alter the binding of wheat germ, soybean or ricin agglutinins to any of these cell lines. These data suggest that high concentration ofE. coli asparaginase have a specific effect on the Con A receptor in the sensitive line. Results of the lecting binding studies were presented at the Federation meeting in Atlanta, GA, 1981. This work was supported by U.S. Public Health Service Grant CA20061, the Midwest Athletes Against Childhood Cancer Fund, and the Burroughs Wellcome Fund.     

Photo control of enzyme activity of alpha-amylase.

Photo control of enzyme activity was performed by attaching a photochromic spiropyran compound to α-amylase. Modified α-amylase exhibited reverse photochromism in water: a colored form in the dark and a colorless form under light irradiation, which indicated that bound spiropyran possessed a hydrophilic structure (an open-ring form) in the dark and a hydrophobic structure (a closed-ring form) under light irradiation. The activity of modified α-amylase under light irradiation was extremely retarded as compared with that determined in the dark. The photo-induced change of the activity reversibly occurred in accordance with the photochromism of bound spiropyran. The mechanism of the photo control is discussed.     

Physical characterization and diel dynamics of different fractions of extracellular polysaccharides in an axenic culture of a benthic diatom

The excretion of extracellular polymeric substances (EPS) by an axenic culture of the benthic diatom Cylindrotheca closterium was investigated. Two sequential extraction steps proved to be suficient to remove the bulk of the EPS present. Soluble EPS was recovered by a simple centrifugation step and represented a fraction that was not or was only loosely associated with diatom cells. For the extraction of bound EPS, different procedures were compared. The best results were obtained using distilled water as extraction solvent (1?h, 30?°C). The sugars that were recovered using this procedure were typically associated with aggregates of diatoms. In addition to the distinct differences in localization of the different types of EPS, their temporal dynamics differed in relation to the light–dark cycle. Soluble EPS were continuously released into the medium at a rate of 1.6?pg?cell^?1?day^?1. In contrast, the production of bound EPS was highly light-dependent. In the dark, this bound EPS rapidly disappeared, probably as the result of its utilization by the diatoms.     

Plasma membrane association and preliminary characterization of Drosophila sperm surface glycosidases

Previous studies have identified β‐N‐acetylglucosaminidase (GlcNAc'ase) and α‐mannosidase activities on the Drosophila melanogaster sperm surface which may have a role in fertilization. The aim of this study was to investigate their linkage to the sperm plasma membrane. We verified that glycosidases are not peripherally adsorbed to the cell surface by evaluating their resistance to release by KI, by buffered salt solutions of high ionic strength or alkaline buffers. Glycosidases were released from the sperm surface by detergents and, only to a minor extent, by mild proteolysis. Differential detergent solubilization pointed out that Triton X‐114 was the most effective releasing agent for GlcNAc'ase and CHAPS for mannosidase. No activity was released from the membrane by a phosphatidylinositol‐specific phospholipase C (PI‐PLC). The released forms were quite hydrophilic in phase separation experiments with Triton X‐114. This finding indicates the presence of a hydrophobic domain limited to a single transmembrane helix or/and the presence of an extensive glycosilation. The use of a Con‐A binding assay demonstrated that both the enzymes are glycosilated. The molecular weight of the released glycosidases estimated by gel filtration was 158 kDa for GlcNAc'ase and 317 kDa for mannosidase. These results suggest that Drosophila melanogaster GlcNAc'ase and mannosidase are mannosylated integral membrane proteins that would function as exoenzymes with their active sites accessible in the extracellular space. Mol. Reprod. Dev. 52:166–173, 1999. © 1999 Wiley‐Liss, Inc.     

Extracellular Asparaginase from Candida utilis,Its Properties as Glycoprotein and Antitumor Activities

Purified Candida asparaginase was proved to be homogeneous by gel filtration, ultra-centrifugation and disc electrophoresis. The enzyme was found to have properties as glycoprotein containing mannose. The ratio of mannose to protein was 1 to 2 in purified enzyme. Specific activity was 5500 units per nag of protein. Isoelectric point was pH 4 to 4.5 and sedimentation coefficient was found to be about 8.2 S. Antitumor activity of Candida asparaginase was inferior to E. coli enzyme. It was thought as the reason why the Candida asparaginase had less affinity to l-asparagine and it was cleared faster from the blood than E. coli asparaginase.     

PARTIAL CHARACTERIZATION OF A PUTATIVE 110kDa MYOSIN FROM THE GREEN ALGACHARA CORALLINABYIN VITROBINDING OF FLUORESCENT F-ACTIN

Using the binding of heterologous, rhodamine phalloidin-labelled F-actinin vitro, two F-actin binding proteins were identified in protein extracts from the green algaChara corallinaafter fractionation by anion exchange chromatography. The first protein, a putative myosin, released laterally bound F-actin at ATP-concentrations as low as 1μm ; equivalent concentrations of ADP were not effective. Binding of F-actin was inhibited by the sulfhydryl-alkylating agent N-ethylmaleimide (NEM). Binding of F-actin was also abolished by a monoclonal anti-myosin (J14) previously used for immunodetection and immunolocalization in internodal cells (Groliget al., 1988,Eur J Cell Biol 47 : 22–31). Immunoblotting with J14 detected a 110kDa polypeptide only in those protein fractions that had revealed ATP-sensitive binding of F-actin. The putative myosin bound with mediocre affinity to immobilized calmodulin and free Ca²⁺-concentration made no difference to this binding affinity. In contrast to the putative myosin, the second, less abundant protein revealed ATP-insensitive and end-wise binding to the microfilament and was not recognized by the anti-myosin antibody.     

Superoxide dismutase catalyzes activation of synaptosomal soluble guanylate cyclase from rat brain

The hydrogen ion changes resulting from the photolysis of the rod visual pigment, rhodopsin, were investigated at acidic pH (5.2–6.5). After light-induced proton uptake, slow proton release occurred both in the dark and in the light. It was found that the amount of proton release in the dark was not equal to that in the light; about 0.9 proton remained bound to rhodopsin bleached in the dark, while all the bound protons were released in the light. Furthermore, the time course of proton release in the dark is not related to the decay of metarhodopsin II₃₈₀, but is closely related to the formation of metarhodopsin III₄₆₅.     

Photoresponsive polypeptides: Photochromism and conformation of poly (L-glutamic acid) containing spiropyran units

Spirobenzopyran units were bound to the side chains of poly (L -glutamic acid) and partially methylated poly(L -glutamate)s. The modified polymers were found to exhibit “reverse photochromism” in hexafluoro-2-propanol (HFP), so the samples kept in the dark were characterized by an intense absorption band in the visible range of the spectrum, which was completely erased upon exposure to sunlight or irradiation at 500–550 nm. The CD spectra showed that the macromolecules adopted a random coil conformation in the dark, whereas the bleached solutions after exposure to light displayed the typical CD pattern of the α-helix. The back reaction in the dark was accompanied by the progressive decrease of the helix content and recovery of the original disordered conformation. The photoinduced conformational changes resulted in large and reversible viscosity variations. When spiropyran side chains were converted to “spiropyran salts” of trifluoroacetic acid, the system was still photochromic, but the macromolecules were disordered both in the dark and light conditions. However, when appropriate amounts of methanol were added as a cosolvent to the HFP solutions, the system responded to light, giving reversible variations of the α-helix content. Irradiation at appropriate solvent compositions allowed modulation of the extent of the photoresponse. © 1993 John Wiley & Sons, Inc.     

Changes in protein kinase and protein phosphatase properties during the cycle of asparaginase activity in Leptosphaeria michotti

Regulation of the cyclic activity of asparaginase (obtained as a purified protein complex) by a reversible auto-phosphorylation process has been previously reported in the fungus Leptosphaeria michotii (West) Sacc. In the present study, the protein complex was purified in the presence of either a mixture of 3 protein phosphatase inhibitors (fluoride, vanadate and molybdate) or EGTA, during the cycle of asparaginase activity, and the protein kinase and protein phosphatase activities characterized. (I) At the phase of increasing asparaginase activity, a Ca²⁺/calmodulin-dependent kinase activity was identified by (a) its inhibition by calmidazolium, reversed by calmodulin, and its inhibition by EGTA, but not by poly(Glu/Tyr 4:1)n. dichloro-(ribofuranosyl)-benzimidazole or polylysine (b) an increasing level of calmodulin bound to the complex, as estimated by enzyme-linked immunosorbent assay (ELISA). (2) At the phase of decreasing asparaginase activity, the Ca²⁺-calmodulin-dependent kinase activity disappeared and a little calmodulin remained associated with the complex: phosphorylation of the complex was increased several-fold by 1 nM okadaic acid and 25 nM inhibitor-2, and was not affected by EGTA, indicating a protein phosphatase-2A-like activity. (3) When asparaginase activity was low, a little calmodulin was bound to the complex. The kinase could phosphorylate casein and phosvitin. was inhibited by poly(Glu/Tyr 4:1)n. dichloro-(ribofuranosyl)-benzimidazole and heparin, stimulated by polylysine and not affected by calmidazolium or EGTA, just as a casein kinase 2. A Ca²⁺-dependent but calmodulin-independent protein phosphatase activity, not affected by okadaic acid and inhibitor-2. was then identified. We postulate the presence in the complex, of (a) only one protein kinase and one protein phosphatase, whose properties could change during the cycle of asparaginase activity: (b) two Ca²⁺/-binding proteins: first calmodulin, which could bind to Ca²⁺ and the casein kinase-2 form to give a Ca²⁺/calmodulin-dependent kinase, which could become Ca²⁺/calmodulin-independent following an auto-phosphorylation process: second a protein homologous to calmodulin, able to bind to the protein phosphatase-2A catalytic subunit to give a protein phosphatase-2B catalytic subunit.     

Chloroplast membrane conformational changes measured by chemical modification

The chemical modification reagents iodoacetic acid (primarily sulfhydryl group directed) and acetic anhydride (primarily amino group directed) were used to monitor chloroplast thylakoid membrane conformational changes. The incorporation of [³H]-iodoacetate and [³H]acetic anhydride showed the following pattern: (i) There was an increased level of binding of iodoacetate in the light compared to the dark or light plus 2,4-dichlorophenyl-1,1-dimethyl urea (DCMU) conditions. A 30 to 50% increase, from about 1.0 to 1.3–1.5 nmol/mg of Chl in iodoacetate incorporation, was found; 30–50% less acetic anhydride was bound in the light than in the dark or light plus DCMU state, typical values being near 15 nmol of acetic anhydride bound/mg of Chl in the dark and 10 nmol/mg of Chl in the light, (ii) The incorporation pattern for both reagents indicated that Photosystem II-dependent proton release is required to elicit the differential binding. Evidence for this is: (a) Cyclic electron flow and proton accumulation, mediated by phenazine methosulfate in the presence of a Photosystem II inhibitor (DCMU), did not induce either the extra binding of iodoacetate or the decrease in binding of acetic anhydride; (b) in chloroplasts made deficient in water oxidation by NH₂OH treatment, electron flow from I^?, an alternate Photosystem II electron donor, to methyl viologen did not induce the differential binding, whereas with the proton-donating donor, diphenyl carbazide, Photosystem II electron flow did elicit the differential binding, (iii) Uncouplers of phosphorylation (nigericin plus valinomycin) had no affect on the differential binding of either reagent, consistent with the hypothesis that it is not simply a transmembrane proton gradient that potentiates the conformational change, but rather an intramembrane reaction between protons released by Photosystem II and certain membrane components. The lack of uncoupler effect also suggests that the conformational change does not involve the coupling factor complex, at least not in the same sense as for the coupling factor conformational changes detected by tritium exchange (I. J. Ryrie and A. T. Jagendorf, 1971, J. Biol. Chem.246, 582–588) or N-ethyl maleimide binding (R. E. McCarty et al., 1972, J. Biol. Chem.247, 3048–3051). (iv) The decrease in acetic anhydride binding in the light was independent of the structural state of the chloroplast. Stacked and unstacked (by low salt) grana membranes showed similar light-dependent decreases in acetic anhydride binding. The results with these modification reagents support earlier conclusions about a Photosystem II-linked conformational change based on work with diazonium benzenesulfonic acid (R. Giaquinta et al., 1975, Biochemistry14, 4392–4396).     

Summary

The plasma membrane H⁺-ATPase in higher plants has been implicated in nutrient uptake, phloem loading, elongation growth and establishment of turgor. Although a C-terminal regulatory domain has been identified, little is known about the physiological factors involved in controlling the activity of the enzyme. To identify components which play a role in the regulation of the plant H⁺-ATPase, a fusicoccin responsive yeast expressing Arabidopsis plasma membrane H⁺-ATPase AHA2 was employed. By testing the fusicoccin binding activity of yeast membranes, the C-terminal regulatory domain of AHA2 was found to be part of a functional fusicoccin receptor, a component of which was the 14–3-3 protein. ATP hydrolytic activity of AHA2 expressed in yeast internal membranes was activated by all tested isoforms of the 14–3-3 protein of yeast and Arabidopsis, but only in the presence of fusicoccin, and activation was prevented by a phosphoserine peptide representing a known 14–3-3 protein binding motif in Raf-1. The results demonstrate that the 14–3-3 protein is an activator molecule of the H⁺-ATPase and provides the first evidence of a protein involved in activation of plant plasma membrane H⁺-ATPase.     

Flow cytometry to identify cell types to which enzymes bind. Effect of lactic dehydrogenase virus on enzyme binding

Flow cytometry was used to measure the binding of enzymes (i.e. lactate dehydrogenases 1 and 5, malate dehydrogenase, and asparaginase) to cells. Of the four enzymes studied, asparaginase showed the greatest binding. Single color analysis revealed that asparaginase bound best to preparations enriched in macrophages, and dual color analysis showed that the binding was to macrophages. Studies on continuous cell lines revealed that asparaginase bound to one mouse macrophage line, but not to another or to murine fibroblasts. Inoculation of mice with lactic dehydrogenase virus, a virus that infects macrophages, decreased the in vivo clearance of asparaginase from the circulation and the in vitro binding of asparaginase to peritoneal macrophages. It is concluded that flow cytometry can be used to study the binding of enzymes to cells, to identify the cell type to which the enzyme binds, and to measure changes in the capacity of cells to bind enzymes.     

Enzymatic properties and application of L-asparaginase–collagen membrane

The activity of the L -asparaginase–collagen membrane was 3.4 U/mg membrane (5.8 U/cm² membrane) and the activity yield was 29%. The apparent Michaelis constant of the asparaginase–collagen membrane was 5.9 × 10^?3M. The operational half-life of the immobilized asparaginase column was 35–40 days. The L -asparaginase–collagen membrane retained 90% of its original activity after ethylene oxide gas sterilization. The dried membrane stored at room temperature retained its original activity for five months, and the membrane stored in 0.05M phosphate buffer (pH 8.0) retained its original activity for one week at 37°C. The L -asparaginase–collagen membrane tanned with 1% glutaraldehyde was stable against proteolytic enzymes. Complete degradation of L -asparagine by the L -asparaginase–collagen membrane occurred at a low concentration. The L -asparagine in dog blood plasma was completely degraded within 20 min by the extracorporal shunt using the L -asparaginase–collagen membrane.     

Diurnal variation of asparaginase in developing pea leaves

Levels of asparaginase activity from developing pea leaves (Pisum sativum) were found to change on a daily basis, increasing during the light period and decreasing in the dark. During extended periods of light, high levels of activity were maintained, while prolonged dark reduced activity to a low value. Half-expanded leaves exhibited the greatest change in activity over the photoperiod. Very young or mature leaves displayed little or no diurnal variation in asparaginase activity.     

Binding of ethidium to bacteriophage T7 and T7 deletion mutants

Equilibrium binding of ethidium, quantitated by fluorescence enhancement, to DNA packaged in bacteriophage T7 and T7 deletion mutants has been compared with the binding of this dye to DNA released from its capsid (free DNA). During achievement of apparent equilibrium binding, no change in bacteriophage T7 structure occurred, by the criterion of agarose gel electrophoresis. However, excessive incubation with ethidium bromide caused detectable changes in bacteriophage structure, a possible explanation of disagreements in similar studies previously performed with T-even bacteriophages. Scatchard plots for packaged DNA had a curvature greater than the previously demonstrated [Bresloff, J. L. & Crothers, D. M. (1981) Biochemistry 20 , 3547–3553] curvature for free DNA. By treating plots for packaged DNA as though they were biphasic, it was found that binding to most sites occurred with an apparent association constant (K_ap) 3.3–4.3 times lower than the K_ap of free DNA. The number of these sites increased significantly as the density of packaged DNA was decreased by use of the deletion mutants. Values of ΔH° for these sites were negative and equal to the ΔH° for free DNA; values of ΔS° were positive and about half the ΔS° for free DNA. A second class of sites, roughly 1.2% of the total, had a significantly higher K_ap and more negative ΔH° than those of the majority of sites.     

Role of γ‐glutamyltranspeptidase in the pathogenesis of Helicobacter pylori infection

γ‐Glutamyltranspeptidase and asparaginase have been shown to play important roles in Helicobacter pylori colonization and cell death induced by H. pylori infection. In this study, the association of γ‐glutamyltranspeptidase and asparaginase was elucidated by comparing activities of both deamidases in H. pylori strains from patients with chronic gastritis, gastric and duodenal ulcers, and gastric cancer. γ‐Glutamyltranspeptidase activities in H. pylori strains from patients with gastric cancer were significantly higher than in those from patients with chronic gastritis or gastric ulcers. There was a wide range of asparaginase activities in H. pylori strains from patients with gastric cancer and these were not significantly than those from patients with other diseases. To identify the contributions of γ‐glutamyltranspeptidase and asparaginase to gastric cell inflammation, human gastric epithelial cells (AGS line) were infected with H. pylori wild‐type and knockout strains and inflammatory responses evaluated by induction of interleukin‐8 (IL‐8). IL‐8 response was significantly decreased by knockout of the γ‐glutamyltranspeptidase‐encoding gene but not by knockout of the asparaginase‐encoding gene. Additionally, IL‐8 induction by infection with the H. pylori wild‐type strain was significantly decreased by adding glutamine during infection. These findings indicate that IL‐8 induction caused by γ‐glutamyltranspeptidase activity in H. pylori is mainly attributable to depletion of glutamine. These data suggest that γ‐glutamyltranspeptidase plays a significant role in the chronic inflammation caused by H. pylori infection.