Alkaline serine proteinase from Thermomonospora fusca YX. Stability to heat and denaturants.

The serine proteinase isolated from Thermomonospora fusca YX shows considerable thermal stability up to 80 degrees C, and progressive inactivation occurs at higher temperatures. Lyotropic salts affected the thermal stability of the enzyme at 85 degrees C, suggesting that disruption of hydrophobic interactions play an important role in the decreased thermal stability of the enzyme above 80 degrees C. Thermal stability is highly pH-dependent; above pH 6.0-6.5 there is a sharp decrease in the stability of the enzyme, reflecting increased autolysis. Although some stabilization occurs upon increasing ionic strength, Ca2+ binding does not appear to play a role in thermal stability. Denaturants, i.e. 8 M-urea, 6 M-guanidinium chloride or 1% SDS, had no significant effect on the activity of the enzyme after 24 h at 25 degrees C.     

A pH-dependent activation-inactivation equilibrium in glutamate dehydrogenase of Clostridium symbiosum.

1. On transferring Clostridium symbiosum glutamate dehydrogenase from pH 7 to assay mixtures at pH 8.8, reaction time courses showed a marked deceleration that was not attributable to the approach to equilibrium of the catalysed reaction. The rate became approximately constant after declining to 4-5% of the initial value. Enzyme, stored at pH 8.8 and assayed in the same mixture, gave an accelerating time course with the same final linear rate. The enzyme appears to be reversibly converted from a high-activity form at low pH to a low-activity form at high pH. 2. Re-activation at 31 degrees C upon dilution from pH 8.8 to pH 7 was followed by periodic assay of the diluted enzyme solution. At low ionic strength (5 mM-Tris/HCl), no re-activation occurred, but various salts promoted re-activation to a limiting rate, with full re-activation in 40 min. 3. Re-activation was very temperature-dependent and extremely slow at 4 degrees C, suggesting a large activation energy. 4. 2-Oxoglutarate, glutarate or succinate (10 mM) accelerated re-activation; L-glutamate and L-aspartate were much less effective. 5. The monocarboxylic amino acids alanine and norvaline appear to stabilize the inactive enzyme: 60 mM-alanine does not promote re-activation, and, as substrates at pH 8.8 for enzyme stored at pH 7, alanine and norvaline give progress curves showing rapid complete inactivation. 6. Mono- and di-nucleotides (AMP, ADP, ATP, NAD+, NADH, NADP+, CoA, acetyl-CoA) at low concentrations (10(-4)-10(-3) M) enhance re-activation at pH 7 and also retard inactivation at pH 8.8. 7. The re-activation rate is independent of enzyme concentration: ultracentrifuge experiments show no changes in molecular mass with or without substrates. 8. The activation-inactivation appears to be due to a slow pH-dependent conformational change that is sensitively responsive to the reactants and their analogues.     

Stabilization of penicillin G acylase from Escherichia coli: site-directed mutagenesis of the protein surface to increase multipoint covalent attachment

Three mutations on the penicillin acylase surface (increasing the number of Lys in a defined area) were performed. They did not alter the enzyme's stability and kinetic properties; however, after immobilization on glyoxyl-agarose, the mutant enzyme showed improved stability under all tested conditions (e.g., pH 2.5 at 4 degrees C, pH 5 at 60 degrees C, pH 7 at 55 degrees C, or 60% dimethylformamide), with stabilization factors ranging from 4 to 11 compared with the native enzyme immobilized on glyoxyl-agarose.     

Thiol-dependent changes in the properties of rat liver sulphotransferases

1. Two enzymes (A and B) which catalyse the sulphation of p-nitrophenol and l-tyrosine methyl ester have been isolated from female rat livers. One of these enzymes (A) also catalyses the sulphation of dehydroepiandrosterone. 2. The K(m) values for the sulphation of p-nitrophenol and l-tyrosine methyl ester by enzyme B at pH7.5 are 1.5mum and 2.9mm respectively. 3. Enzyme B is oxidized on keeping at 0 degrees C when the K(m) and V(max.) values for the sulphation of p-nitrophenol are increased approx. 200-fold and fourfold respectively. This oxidized preparation of enzyme B fails to catalyse the sulphation of l-tyrosine methyl ester. 4. When the oxidized form of enzyme B is kept at 0 degrees C and low ionic strength then further forms of p-nitrophenol sulphotransferase are produced having even lower affinities for the sulphate acceptor. 5. The K(m) value for adenosine 3'-phosphate 5'[(35)S]-sulphatophosphate is not affected during storage of the enzyme under these conditions. 6. Prolonged storage of enzyme B at low ionic strength leads to a considerable degree of polymerization of p-nitrophenol sulphotransferase and l-tyrosine methyl ester sulphotransferase. 7. The changes in the kinetic properties and molecular size of enzyme B during storage are reversed by dithiothreitol.     

Physical characteristics of hyaluronate binding to the surface of simian virus 40-transformed 3T3 cells

The binding of labeled hyaluronate to the surface of Simian virus 40-transformed 3T3 cells was studied as a function of 1) pH, 2) ionic strength, 3) temperature, and 4) molecular weight of the hyaluronate. Binding occurred over a wide range of pH values with optima at pH 7 and at less than pH 4. Binding at low pH was eliminated at high ionic strength whereas that at physiological pH was enhanced, with a maximum at 0.5 M NaCl. The enhancement of binding at pH 7 was reversible and independent of the particular salt used. Scatchard plot analysis showed that increasing the ionic strength resulted in both a decrease in the dissociation constant (Kd) and an increase in the amount bound at saturation (Bmax). Temperature also influenced the binding of hyaluronate to the cell surface. The amount bound at low temperatures (0 degrees C) was 3 to 5 times that bound at high temperatures (40 degrees C) with a sharp transition occurring at 18 degrees C, the temperature of phase transition of the plasma membrane. The temperature effect was primarily a change in the Bmax and was reversible. Finally the molecular weight of the ligand influenced the binding. High molecular weight preparations of hyaluronate had a higher binding affinity (lower Kd) and a lower Bmax than did smaller molecular weight preparations.     

Changes in the quaternary structure of phosphoenolpyruvate carboxylase induced by ionic strength affect its catalytic activity

Phosphoenolpyruvate carboxylase from maize leaves dissociated into dimers and/or monomers when exposed to increasing ionic strength (e.g. 200-400 mM NaCl) as indicated by gel filtration experiments. Changes in the oligomerization state were dependent on pH, time of preincubation with salt and protein concentration. A dissociation into dimers and monomers was observed at pH 8, while at pH 7 dissociation into the dimeric form only was observed. Exposure of the enzyme to higher ionic strength decreased the activity in a time-dependent manner. Turnover conditions and glucose 6-phosphate protected the carboxylase from the decay in activity, which was faster at pH 7 than at pH 8. The results suggest that changes in activity of the enzyme, following exposure to high ionic strength, are the consequence of dissociation. Tetrameric and dimeric forms of the phosphoenolpyruvate carboxylase seemingly reveal different catalytic properties. We suggest that the distinct catalytic properties of the different oligomeric species of phosphoenolpyruvate carboxylase and changes in the equilibrium between them could be the molecular basis for an effective regulation of metabolite levels by this key enzyme of C4 plants.     

Immobilized preparation of cold-adapted and halotolerant Antarctic beta-galactosidase as a highly stable catalyst in lactose hydrolysis

A cold-active beta-galactosidase of Antarctic marine bacterium Pseudoalteromonas sp. 22b was synthesized by an Escherichia coli transformant harboring its gene and immobilized on glutaraldehyde-treated chitosan beads. Unlike the soluble enzyme the immobilized preparation was not inhibited by glucose, its apparent optimum temperature for activity was 10 degrees C higher (50 vs. 40 degrees C, respectively), optimum pH range was wider (pH 6-9 and 6-8, respectively) and stability at 50 degrees C was increased whilst its pH-stability remained unchanged. Soluble and immobilized preparations of Antarctic beta-galactosidase were active and stable in a broad range of NaCl concentrations (up to 3 M) and affected neither by calcium ions nor by galactose. The activity of immobilized beta-galactosidase was maintained for at least 40 days of continuous lactose hydrolysis at 15 degrees C and its shelf life at 4 degrees C exceeded 12 months. Lactose content in milk was reduced by more than 90% over a temperature range of 4-30 degrees C in continuous and batch systems employing the immobilized enzyme.     

Specific binding of the cAMP receptor protein of Escherichia coli to the lactose operon promoter

The nitrocellulose filter binding assay has been used to study effects of pH, temperature, ionic strength and magnesium ions on the specific binding of the cyclic adenosine 3',5'-monophosphate (cAMP) receptor protein (CAP) to the promoter of the lactose (lac) operon of Escherichia coli. The pH has a significant effect on binding with the greatest amount of specific binding appearing at pHs near 7 with a gradual decrease in binding as the pH is increased to 8. Specific binding was observed at temperatures of 22 degrees C and 37 degrees C but not at 4 degrees C. The specific binding was also found to be a function of the concentration of magnesium acetate and potassium chloride, being dependent on the specific cation present, the total ionic strength, and the concentration of the CAP protein. All binding decreases as the ionic strength, increases, but this decrease occurs at a lower ionic strength in magnesium acetate than in potassium chloride. In a double label experiment the filter assay demonstrates that the cAMP-CAP complex preferentially binds to the wild-type lac promoter in the presence of a lac promoter mutated at the CAP binding site. Based on these results and comparisons with other experiments reported in the literature, buffer conditions that approximate the physiological state of a cell appear to be best for studying the interaction between CAP and the lactose promoter in vitro.     

Enzyme immobilization on colloidal liquid aphrons (CLAs): the influence of system parameters on activity

The novel technique of immobilization of beta-galactosidase on colloidal liquid aphrons (CLAs) was investigated. CLAs are oil-in-water macroemulsions stabilised by a mixture of ionic and nonionic surfactants. Enzyme retention was found to be unaffected by changes in bulk phase pH and ionic strength, indicating that beta-galactosidase immobilization was due primarily to hydrophobic interactions. However, by varying the polarity of the internal solvent core, and the charge of the surfactants used in the formation of the CLAs, it was found that immobilization could be improved to almost 100% under certain conditions indicating that electrostatic interactions also affected immobilization to a lesser degree. Upon immobilization, it was found that there was a shift in the pH optimum of the enzyme, with the immobilized enzyme showing a broader range, and a maximal activity at higher pH. The immobilized beta-galactosidase displayed normal Michaelis-Menten dependence on substrate concentration, whilst also exhibiting superactivity for increased substrate concentrations. Activation energy was determined for the CLA immobilized enzyme, and it was found to decrease indicating that a conformational change had occurred that may account for the observed increase in activity. Finally, although the temperature profile of the immobilized enzyme was similar to the free enzyme, it was very stable, with a potential half-life of 3.6 years at 30 degrees C.     

Immobilization of yeast cells containing beta-galactosidase

Cultural conditions optimum for beta-galactosidase production by Saccharomyces anamensis are pH 4.5, temperature 26 +/- 2 degrees C, and 30 h of incubation period. Addition of lactose at 24 h fermentation greatly increase the level of enzyme. Optimum pHl, temperature, pH stability, and thermostability of yeast beta-galactosidase are negligibly affected by immobilization. The K(m) values of enzyme in the native and immobilized cells are 102mM and 148mM, respectively. Glucose noncompetitively inhibits the enzyme activity. Addition of substances such as dithioerythritol, glutathione, and bovine serum albumin to the native cell during assay procedure and immobilized cell prior to immobilization have stimulatory effects on enzyme activity. Metal ions like Ca(2+), Mg(2+) enhance the beta-galactosidase activity for both intact and bound cells. Immobilized cells retain 68.6% of the beta-galactosidase activity of intact cells and there is no significant loss of activity on storage at 4 degrees C for 28 days.     

Effect of deproteinization on the in situ chromatin staining with 7-aminoactinomycin D

The possibility of use of 7-amino-actinomycin D (7aAMD)--fluorescent analog of actinomycin D--as a specific dye for DNA staining in the suspended cells was studied by means of laser flow-cytometry. The optimal conditions for staining were obtained: 7aAMD concentration 10(-5) M, pH 7, staining time 20 min, 37 degrees C, ionic strength 0.15 M Na+. In this case the fluorescent signal is proportional to the DNA amount and coefficient of variation is about 0.03. The influence of the stepwise extraction of the proteins from chromatin also was studied. In the course of the salt deproteinization the fluorescence intensity gradually rose thus showing the increase of the binding sides-number. The deproteinization of cells nuclei by 0.1 HCl increased the number of binding sites 2.5 times more. It was shown that the incubation of cells with RNAse at elevated ionic strength (0.3-0.7 M NaCl) leads to an additional increase of the cell fluorescence and produces no effect at low and normal ionic strength. The deproteinizing effect of RNAse and its possible mechanism is discussed.     

Enzyme immobilization using a cellulose-binding domain: properties of a beta-glucosidase fusion protein.

Using molecular genetic techniques, a fusion protein has been produced which contains the cellulose-binding domain (CBD) of an exoglucanase (Cex) from Cellulomonas fimi fused to a beta-glucosidase (Abg) from Agrobacterium sp. The CBD functions as an affinity tag for the simultaneous purification and immobilization of the enzyme on cellulose. Binding to cellulose was stable for prolonged periods at temperatures from 4 degrees C to at least 50 degrees C, at ionic strengths from 10 mM to greater than 1 M, and at pH values below 8. The fusion protein can be desorbed from cellulose with distilled water or at pH greater than 8. Immobilized enzyme columns of the fusion protein bound to cotton fibers exhibited stable beta-glucosidase activity for at least 10 days of continuous operation at temperatures up to 37 degrees C. At higher temperatures, the bound enzyme lost activity. The thermal stability of the fusion protein was greatly improved by immobilization. Immobilization did not alter the pH stability. Except for its ability to bind to cellulose, the properties of the fusion protein were virtually the same as those of the native enzyme.     

Characterization of an adenosine 3'':5''-cyclic monophosphate phosphodiesterase from baker''s yeast. Its binding to subcellular particles, catalytic properties and gel-filtration behaviour.

1. The 3':5'-cyclic AMP phosphodiesterase in the microsomal fraction of baker's yeast is highly specific for cyclic AMP, and not inhibited by cyclic GMP, cyclic IMP or cyclic UMP. Catalytic activity is abolished by 30 micrometer-EDTA. At 30 degrees C and pH8.1, the Km is 0.17 micrometer, and theophylline is a simple competitive inhibitor with Ki 0.7 micrometer. The pH optimum is about 7.8 at 0.25 micrometer-cyclic AMP, so that over the physiological range of pH in yeast the activity changes in the opposite direction to that of adenylate cyclase [PH optimum about 6.2; Londesborough & Nurminen (1972) Acta Chem. Scand. 26, 3396-3398].2. At pH 7.2, dissociation of the enzyme from dilute microsomal suspensions increased with ionic strength and was almost complete at 0.3 M-KCl. MgCl2 caused more dissociation than did KCl or NaCl at the same ionic strength, but at low KCl concentrations binding required small amounts of free bivalent metal ions. In 0.1 M-KCl the binding decreased between pH 4.7 and 9.3. At pH 7.2 the binding was independent of temperature between 5 and 20 degrees C. These observations suggest that the binding is electrostatic rather than hydrophobic. 3. The proportion of bound activity increased with the concentration of the microsomal fraction, and at 22 mg of protein/ml and pH 7.2 was 70% at I0.18, and 35% at I0.26. Presumably a substantial amount of the enzyme is particle-bound in vivo. 4. At 5 degrees C in 10 mM-potassium phosphate, pH 7.2, the apparent molecular weight of KCl-solubilized enzyme decreased with enzyme concentration from about 200 000 to 40 000. In the presence of 0.5M-KCl, a constant mol.wt. of about 55 000 was observed over a 20-fold range of enzyme concentrations.     

Analysis of the conformation and stability of human bronchial lysozyme by circular dichroism.

1. Human bronchial lysozyme was isolated from nonpurulent secretions and studied by circular dichroism (CD) spectroscopy for its conformational properties. 2. The two negative bands at 208 and 222 nm indicated that the peptide chain adopted an alpha-helical structure in physiological conditions. 3. The molecule was stable at pH 1.0 but not at pH 12.0. 4. Increasing ionic strength by adding NaCl up to 1 M did not change the CD spectra. 5. Complete unfolding of the molecule by guanidinium chloride was obtained only at the concentration of 6 M. 6. Bronchial lysozyme was also denatured by sodium dodecyl sulphate. 7. The molecule was stable when mild reduction was performed at 37 degrees C for 30 min but was completely unfolded after heating at 100 degrees C for 3 min.     

The pH and temperature dependence of the activity of the high Km cyclic nucleotide phosphodiesterase of bakers' yeast

The hydrolysis of adenosine 3':5'-monophosphate by the high Km cyclic nucleotide phosphodiesterase of bakers' yeast was studied over a range of temperature and pH at I = 0.17. The effects of ionic strength and MgCl2 concentration were studied at pH 7.7 and 30 degrees C. Km and Vmax were insensitive to changes in the MgCl2 concentration between 1 and 30 mM, implying that this enzyme (which does not require free divalent metal ions) does not discriminate between free cyclic AMP- and the Mg-cyclic AMP+ complex. Vmax decreased below pH 6.8 because of protonation of a group required in the basic form in the enzyme x substrate complex. On the basis of its pK (5.46 at 30 degrees C) and delta H (23 kJ/mol) this group was tentatively identified as imidazole. Vmax/Km decreased above pH 6.8 because of ionization of a group required in the acid form in the free enzyme, with a pK of 7.88 at 30 degrees C and a delta H of about 13 kJ/mol. Several possibilities exist for the identity of this group, the most likely being a second imidazole, sulfhydryl, or a water molecule bonded to tightly bound zinc. At pH 7.90, log Vmax and log Km both changed linearly with 1/T (between 12 degrees C and 37 degrees C) with enthalpies of 47 and 55 kJ/mol, respectively. Consequently, at low enough cyclic AMP concentration, the rate of reaction at pH 7.90 decreases slightly when the temperature is increased. This is also true at higher pH, but in the physiological pH range (6.4 to 7.5) Vmax/Km and, therefore, the rate of reaction at very low cyclic AMP concentration were nearly independent of temperature. Under physiological conditions, the Km approaches the upper limit of in vivo cyclic AMP concentrations in yeast, and at normal in vivo cyclic AMP concentrations the pH optimum is within or below the physiological range of pH in yeast.     

Thermal unfolding of dodecameric glutamine synthetase: inhibition of aggregation by urea.

Thermal unfolding of dodecameric manganese glutamine synthetase (622,000 M(r)) at pH 7 and approximately 0.02 ionic strength occurs in two observable steps: a small reversible transition (Tm approximately 42 degrees C; delta H approximately equal to 0.9 J/g) followed by a large irreversible transition (Tm approximately 81 degrees C; delta H approximately equal to 23.4 J/g) in which secondary structure is lost and soluble aggregates form. Secondary structure, hydrophobicity, and oligomeric structure of the equilibrium intermediate are the same as for the native protein, whereas some aromatic residues are more exposed. Urea (3 M) destabilizes the dodecamer (with a tertiary structure similar to that without urea at 55 degrees C) and inhibits aggregation accompanying unfolding at < or = 0.2 mg protein/mL. With increasing temperature (30-70 degrees C) or incubation times at 25 degrees C (5-35 h) in 3 M urea, only dodecamer and unfolded monomer are detected. In addition, the loss in enzyme secondary structure is pseudo-first-order (t1/2 = 1,030 s at 20.0 degrees C in 4.5 M urea). Differential scanning calorimetry of the enzyme in 3 M urea shows one endotherm (Tmax approximately 64 degrees C; delta H = 17 +/- 2 J/g). The enthalpy change for dissociation and unfolding agrees with that determined by urea titrations by isothermal calorimetry (delta H = 57 +/- 15 J/g; Zolkiewski M, Nosworthy NJ, Ginsburg A, 1995, Protein Sci 4: 1544-1552), after correcting for the binding of urea to protein sites exposed during unfolding (-42 J/g). Refolding and assembly to active enzyme occurs upon dilution of urea after thermal unfolding.     

Purification and characterization of a thermotolerant beta-galactosidase from Thermomyces lanuginosus.

A new inducible intracellular beta-galactosidase (EC 3.2.1.23) of the thermophilic fungus Thermomyces lanuginosus was purified by fractional salt precipitation, hydrophobic interaction, and anion exchange chromatography. The first 22 amino acid residues were determined by N-terminal sequencing. Electrophoretic investigations revealed a dimeric enzyme with a molecular mass of 75 to 80 kDa per identical subunit and an isoelectric point of 4.4 to 4.5. The native beta-galactosidase was identified as a glycoprotein by the enzyme-linked immunosorbent assay technique. The beta-galactosidase activity was optimal at pH 6.7 to 7.2, and the enzyme displayed stability between pH 6 and 9. It was completely stable at pH 6.8 and 47 degrees C for 2 h. After 191 h at 50 degrees C, the remaining beta-galactosidase activity of an enzyme fraction after salt precipitation was 58%. The beta-galactosidase hydrolyzed p- and o-NO2-phenyl-beta-D-galactopyranoside, lactose, lactulose, MeOH-beta-D-galactopyranoside, phenyl-beta-D-galactopyranoside, and p-NO2-phenyl-alpha-L-arabinopyranoside. The kinetic constants (Km) measured for p- and o-NO2-phenyl-beta-D-galactopyranoside and beta-lactose were 4.8, 11.3, and 18.2 mM, respectively.     

Structural Stability of Streptococcal Serum Opacity Factor

Streptococcal serum opacity factor (SOF) is a protein that clouds the plasma of multiple mammalian species by disrupting high density lipoprotein (HDL) structure. Intravenous infusion of low dose SOF (4 µg) into mice reduces their plasma cholesterol concentrations?~?40% in 3 h. Here we investigated the effects of pH, ionic strength, temperature, and denaturation with guanidinium chloride (GdmCl) on SOF stability and its reaction vs HDL. SOF stability was tested by pre-incubation of SOF at various temperatures, pH’s, and GdmCl concentrations and measuring the SOF reaction rate at pH 7.4 and 37?°C. SOF retained activity at temperatures up to 58?°C, at pH 4 to 10, and in 8.5 M GdmCl after being returned to standard buffer conditions. The effects of GdmCl, pH, and ionic strength on the SOF reaction rates were also measured. SOF was inactive at GdmCl?≥?1 M; SOF was most active at pH 5, near its isoelectric point and at an ionic strength of 3 (in NaCl). These data reveal that SOF is a stable protein and suggest that its activity is determined, in part, by the effects of pH and ionic strength on its overall charge relative to that of its reaction target, HDL.