Primary photosynthetic reactions in isolated chloroplasts fixed by glutaric aldehyde]

The primary photosynthetic reactions in isolated pea chloroplasts with the structures fixed by increasing concentrations of glutaric aldehyde were studied. It was shown that under chloroplast fixation by 5--25 mM of glutaric aldehyde, a significant inhibition of processes responsible for energy transformation in biological membranes was observed. The highest sensitivity was observed for the phosphorylation reactions, photo-induced changes in absorption at 520 nm, photo-induced quenching of atebrin fluorescence and slow component of delayed light emission. The photo-induced proton uptake was found to be less sensitive to fixation by glutaric aldehyde. It was also shown that on chloroplast fixation the extent of the steady-state P700 oxidation and the lifetime of the photosystem I and II chlorophyll fluorescence are both increased, a fact is indicating of loss in the effectiveness of light energy transfer from the antenna molecules to the reaction centres. Presumably the conformational changes play an essential role at the initial steps of light energy transformation.     

Streptokinase immobilization in insoluble carriers, and properties of the immobilized protein

Immobilization of streptokinase was performed by bromine cyan-activated cellulose and by aminoethyl cellulose using glutaric aldehyde and N-cyclohexyl-N'-[2-(4-morpholinyl)-ethyl-carbodiimide. The specific activator activity of the immobilized streptokinase is 70-100% of that of free streptokinase. In multiple application of the immobilized protein preparations streptokinase obtained by bromine cyan-activated cellulose is the most stable: it retains more than 40% of initial activity after 10 repeated applications. The immobilized streptokinase is shown to be more thermostable as compared to the soluble one.     

Effect of chemical modification on thermal stability of horseradish peroxidase]

Soluble preparations of horse radish peroxidase are obtained by means of its amino groups modification with glutaric aldehyde, maleic anhydride and inert proteins including albumin. The enzyme activity is found to decrease under the modification with glutaric aldehyde and to be unchanged at all other cases. Thermal stability of the enzyme preparations obtained is studied within the temperature range from 56 to 80 degrees C. Thermostability of glutaric aldehyde-modified peroxidase is approximately 2.5-fold decreased at 56 degrees C. Thermostability of other preparations exceeds the stability of native peroxidase in 25--90 times at 56 degrees C. Thermodynamic parameters of activation for the process of irreversible thermoinactivation of native and modified enzyme are calculated. A strong compensation effect between activation enthalpy and entropy values is observed, which were changed in 1.5--2 times, while the free activation energy is changed by 2--3 kcal/mol only. Possible mechanism of the change of the enzyme thermal stability under its chemical modification is discussed.     

Second set method for determining the immunogenicity of heart valves

The "second set" method was used on inbred rats to study immunogenicity of the heart valves treated with a proteolytic enzyme and glutaric aldehyde and to compare it with immunogenicity of the valves treated with glutaric aldehyde alone according to Hancock's method. The valves treated by the enzyme and 0.2-0.5% glutaric aldehyde did not lead to the body sensitization in contrast to the valves exposed to 0.5% glutaric aldehyde alone. During transplantation of the latter ones, there were signs of the immunologic response on the part of the recipients and calcification of valvular tissue 70 days after subcutaneous implantation. It is assumed that pretreatment with the enzyme makes it possible to appreciably reduce immunogenicity of the heart valves.     

Isolation and characteristics of immobilized aminoacylase from Streptoverticillium olivoreticuli

Immobilization of aminoacylase from Streptoverticillium olivoreticuli by incorporation into acrylamide gel has been investigated. The data showed that the process should be carried out at constant pH. Thermal inactivation of the immobilized enzyme under the reaction conditions was studied. The kinetics of enzymatic stereospecific deacylation of N-acetyl-DL-phenylalanine was analyzed. The results of this study may be used in the synthesis of amino acid enantiomers.     

Isolation and Characterization of Immobilized Aminoacylase from Streptoverticillium olivoreticuli

Immobilization of aminoacylase from Streptoverticillium olivoreticuli by incorporation into acrylamide gel has been investigated. The data showed that the process should be carried out at constant pH. Thermal inactivation of the immobilized enzyme under the reaction conditions was studied. The kinetics of enzymatic stereospecific deacylation of N-acetyl-DL-phenylalanine was analyzed. The results of this study may be used in the synthesis of amino acid enantiomers.     

Production of fibrous materials, containing an immobilized proteolytic enzyme and urea]

Immobilization of cellulose and polyacrylic acid on a grafted copolymer increased significantly the stability of proteolytic enzymes to inactivation by urea. Materials containing immobilized proteolytic enzymes and urea and displaying a combined biological activity were obtained.     

E. coli penicillin amidase. Physico-chemical properties of the enzyme covalently bound to the 2-(3'-amino-4'-methoxyphenyl)-sulfonylethyl ester of cellulose]

The effect of the procedure of the enzyme binding with the carrier on the properties of the heterogenous catalyst obtained by covalent binding of penicillinamidase (PA) with cellulose 2-(3'-amino-4'-methoxyphenyl)-sulphonylethyl ether by means of the bifunctional reagent, i.e. glutaric aldehyde was studied. It was shown that the amount of the bound enzyme increased with a rise in the amount of the enzyme taken for the binding, while the binding efficiency characterizing the part of the active enzyme in the total amount of the bound PA decreased practically 2 times. The use of the enzyme preparations with different purify levels for the binding provided differentiation of the effects resulting in the activity loss on immobilization. In other words it provided separate estimation of the inactivation effect of the matrix and the immobilization procedure, as well as the interaction of the enzyme molecules with each other and other protein molecules.     

Bromoacetophenone as an affinity reagent for human liver aldehyde dehydrogenase

Human liver aldehyde dehydrogenase isozymes E1 and E2 (EC 1.2.1.3) are both completely and irreversibly inactivated by bromoacetophenone (2-bromo-1-phenylethanone). Steady-state kinetics with both acetophenone and chloroacetophenone indicated interaction with the same enzyme form as the aldehyde substrate. Saturation kinetics with chloroacetophenone and bromoacetophenone indicated interaction at a specific site on the enzyme surface and gave a dissociation constant similar to that from steady-state kinetics, suggesting that the same processes were being observed by both methods and that the active site may be involved. Protection against inactivation was afforded by chloral and NAD together. Stoichiometry of inactivation showed the first 2 equiv per tetramer to abolish the majority of catalytic activity; 4 equiv inactivated both isozymes with complete loss of esterase, NAD-stimulated esterase, and dehydrogenase activities. Peptide mapping of enzyme modified with [carbonyl-14C]bromoacetophenone of CNBr digests (E1) and tryptic digests (E1 and E2) showed one peptide to be preferentially labeled. The above results together with the similarity of bromoacetophenone to the substrate benzaldehyde suggest bromoacetophenone may react with a residue in the active site of aldehyde dehydrogenase. Amino acid analysis of the labeled E1 tryptic fragment indicated reaction with a different peptide from that with which iodoacetamide reacts.     

Haloenol lactones as inactivators and substrates of aldehyde dehydrogenase

Human aldehyde dehydrogenase (EC 1.2.1.3) isozymes E1 and E2 were irreversibly inactivated by stoichiometric concentrations of the haloenol lactones 3-isopropyl-6(E)-bromomethylene tetrahydro-pyran-2-one and 3-phenyl-6(E)-bromomethylene tetrahydro-pyran-2-one. No inactivation occurred with the corresponding nonhalogenated enol lactones. Both the dehydrogenase and esterase activities were abolished. Activity was not regained on dialysis or treatment with 2-mercaptoethanol. The inactivation was subject to substrate protection: NAD afforded protection which increased in the presence of the aldehyde-substrate competitive inhibitor chloral. Saturation kinetics gave positivey-axis intercepts, allowing the determination of binding constants. Inactivation stiochiometry determined with¹⁴C-labeled 3-(1-naphthyl)-6(E)-iodomethylene tetrahydropyran-2-one was found to correspond to the active-site number. The nonhalogenated lactone, 3-(1-naphthyl)-6(E)-methylene tetrahydropyran-1-one was shown to be a substrate for aldehyde dehydrogenase via its esterase function. Inactivation and enzymatic hydrolysis occurred within a similar time frame. Opening of the lactone ring to form enzyme-acyl intermediate with active site cysteine appears to be a necessary prerequisite to inactivation, since halogen in the lactone ring is nonreactive. Thus, the inactivation of aldehyde dehydrogenase by haloenol lactones is mechanism-based. Inactivation by haloenol lactones occurs in a manner analogous to that of chymotrypsin with which aldehyde dehydrogenase shares esterase activity and binding of haloenol lactones at the active site.     

Effect of various methods of immobilization on stability of a microbial biosensor based on Pseudomonas rathonis T during detection of surfactants

The operating and storage stability of a receptor element of an amperometric biosensor based on the Pseudomonas rathonis strain T capable of degrading surfactants was tested. Microbial cells were immobilized by incorporation in gels (agar, agarose, and calcium-alginate), polyvinyl alcohol membrane, adhesion to the chromatographic paper GF/A, or by the cross-linking induced by glutaric aldehyde. Incorporation of microbial cells in agar gel provides the long-standing conservation of their activity and viability during measurements of high concentrations of surfactants and allows the receptory element of the biosensor to be rapidly recovered after the measurements.     

Effect of various methods of immobilization on the stability of a microbial biosensor for surfactants based onPseudomonas rathonis T

The operating and storage stability of a receptor element of an amperometric biosensor based on thePseudomonas rathonis strain T capable of degrading surfactants was tested. Microbial cells were immobilized by incorporation in gels (agar, agarose, and calcium-alginate), polyvinyl alcohol membrane, adhesion to Chromatographic paper GF/A, or by cross-linking induced by glutaric aldehyde. Incorporation of microbial cells in agar gel provides long-standing conservation of their activity and viability during measurements of high concentrations of surfactants and allows the receptor element of the biosensor to be rapidly recovered after measurements.     

Immobilization of actin and myosin.

Using glutaric dialdehyde, the muscle proteins myosin, actin, actomyosin and heavy meromyosin subfragment-1 (S-1) have been immobilized on capron fibers. The ATPase activity of myosin and its capability to interact with actin have been preserved whereas the ATPase activity of its subfragment decreased significnatly. Immobilization on capron fibers changes the pH dependence of the ATPase activity of myosin and of S-1 shifting the maximum towards the acid zone (pH 5.5) and increases the thermal stability of the enzyme. Calcium ions produce a stimulatory effect on ATPase; Mg2+ions yield no effect on myosin and S-1 but enhance the activity in the case of immobilized actomyosin though to a lesser degree than the ions of Ca2+. Immobilized actin retains its ability to form actomyosin complex.     

Purification and characterization of glutathione reductase from corn mesophyll chloroplasts

Differences in the apparent molecular weights of the subunits of glutathione reductase (EC 1.6.4.2) from pea chloroplasts and corn mesophyll chloroplasts have been recently reported. In order to more fully describe the differences between the enzymes from these two sources, glutathione reductase from the mesophyll chloroplasts of corn seedlings ( Zea mays L. cv. G-4507) has been purified 200-fold by affinity chromatography using adenosine 2',5'-disphosphate agarose. The purified enzyme had a specific activity of 26 μmol NADPH oxidized (mg protein)^-1 min^-1. The native enzyme had a relative molecular weight of 190 ± 30 kDa and exhibited polypeptides of 65, 63, 34, and 32 kDa when separated on sodium dodecylsulfate-polyacrylamide gels. Comparisons of the results from electroblotting, native molecular weight and subunit molecular weight analyses suggest that the enzyme exists as a heterotetramer. Optimal enzyme activity was obtained at pH 8 in N-2-hydroxyethyl-piperazine-N'-2-ethanesulfonic acid (HEPES-NaOH) buffer. The sulfhydryl reagent, n -ethylmaleimide, inhibited enzymatic activity when incubated in the presence of NADPH while no inhibition was detected with oxidized glutathione in the incubation mixture. Reduced glutathione (5 m M ) inactivated the enzyme by 50%. This inactivation followed first order kinetics with a rate constant of 0.0028 s^-1. The enzyme was also inactivated by NADPH. The inactivation reached ca 90% within 30 min and followed first order kinetics with a rate constant of 0.0015 s^-1.     

Regulation of fructose-1,6-bisphosphatase activity in intact chloroplasts. Studies of the mechanism of inactivation

1. The aim of this work was to investigate the mechanism of dark inactivation of fructose-1,6-bisphosphatase (D-fructose-1,6-bisphosphate 1-phosphohydrolase, EC 3.1.3.11) in isolated intact chloroplasts of Triticum aestivum.

2. Dark inactivation of the enzyme, which was rapid under aerobic conditions, was prevented under anaerobic conditions when chloroplasts were incubated in the absence of an electron acceptor. Electron acceptors such as oxaloacetate readily brought about inactivation under anaerobic conditions whether chloroplasts were illuminated or in the dark. Inactivation of the enzyme also occurred if illuminated or darkened anaerobic chloroplasts were exposed to oxygen.

3. Pyocyanine, which catalyses a cyclic electron flow around Photosystem I, also caused inactivation of the enzyme in illuminated, anaerobic chloroplasts.

4. It is proposed that the activity of fructose-1,6-bisphosphatase is regulated by the availability of electrons, and thus by electron acceptors, and that dark inactivation may occur by a direct reversal of the activation process.     

Design of immobilized enzyme reactors for the continuous production of fructose syrup from whey permeate

Biocatalyst inactivation is inherent to continuous operation of immobilized enzyme reactors, meaning that a strategy must exist to ensure a production of uniform quality and constant throughput. Flow rate can be profiled to compensate for enzyme inactivation maintaining substrate conversion constant. Throughput can be maintained within specified margins of variation by using several reactors operating in parallel but displaced in time. Enzyme inactivation has been usually modeled under non-reactive conditions, leaving aside the effect of substrate and products on enzyme stability. Results are presented for the design of enzyme reactors under the above operational strategy, considering first-order biocatalyst inactivation kinetics modulated by substrate and products. The continuous production of hydrolyzed-isomerized whey permeate with immobilized lactase and glucose isomerase in sequential packed-bed reactors is used as a case study. Kinetic and inactivation parameters for immobilized lactase have been determined by the authors; those for glucose isomerase were taken from the literature. Except for lactose, all other substrates and products were positive modulators of enzyme stability. Reactor design was done by iteration since it depends on enzyme inactivation kinetics. Reactor performance was determined based on a preliminary design considering non-modulated first-order inactivation kinetics and confronted to such pattern. The new pattern of inactivation was then used to redesign the reactor and the process repeated until reactor performance (considering modulation) matched the assumed pattern of inactivation. Convergence was very fast and only two iterations were needed.     

Effects of weak solutions of aldehydes on EEG changes in rats

Alternations of EEG have been investigated after single intraarterial infusion of formaldehyde, glutaric aldehyde and its mixture in 50 adult male rats. The dissolved solutions of aldehydes were shown to have complicated inhibitive activity which consists of two phases. The first phase of EEG inhibition rapidly develops and it isn't very long in its duration. The second one is much more durable. Formaldehyde causes the first phase of inhibition in general, though glutaric aldehyde promotes especially the appearance of the second phase. The mixture of two aldehydes demonstrates synergic activity which is shown as significant increase of EEG inhibition as compared to individual inhibitive activity of aldehydes. The inhibitive influence of aldehydes is fully reversible, nonspecific and doesn't cause post-experimental disorders. The highest effect of brain protection from ischaemia damages coincides with development of maximum inhibition of specific brain functions during the second phase of EEG depression.     

Light-induced generation of membrane potential in intact chloroplasts suspended in H2O or D2O media

The membrane potential changes induced by short flashes and continuous light were investigated in isolated chloroplasts of Peperomia metallica suspended in H2O- or D2O media. The potential generated in H2O-suspended chloroplasts by a single turnover flash is approximately two times lower than the maximal level of potential induced by continuous light. The photoelectric response of D2O-suspended chloroplasts differs from that of H2O-suspended chloroplasts by an increased amplitude and a prolonged phase of the potential rise. Te dark decay of the potential proceeds 2-3 times slower in the D2O-suspended chloroplasts as compared to the H2O-suspended chloroplasts. The magnitude of the flash-induced potential is somewhat lower for the chloroplasts in D2O than for the chloroplasts in the H2O medium. The results obtained suggest that the substitution of H2O for D2O results in a decrease of the ionic conductance and an increase of stability of thylakoid membranes. It was shown that the rise of electrical potential under continuous illumination proceeds in two stages. The difference kinetics of membrane potential changes are observed under conditions of separate activity of two systems of photosynthesis.     

Chemical modification of human aldehyde dehydrogenase by physiological substrate

Employing 3,4-dihydroxyphenylacetaldehyde (dopal) as a substrate for human aldehyde dehydrogenase (aldehyde:NAD+ oxidoreductase, EC 1.2.1.3) in anaerobic conditions, inactivation of both cytoplasmic E1 and mitochondrial E2 isozymes during catalysis has been observed. Incorporation of 14C-labelled dopal has been demonstrated by retention of label following denaturation and exhaustive dialysis and by peptide mapping following tryptic digestion. Incorporation of label gave linear plots vs. activity remaining with up to two molecules incorporated per molecule of enzyme and 30% activity remaining. Further incorporation (up to 16 molecules) occurred, but was non-linear when plotted vs. activity remaining. Protection against activity loss during incorporation of the first two molecules was afforded by NAD, NADH, chloral, and by chloral and NAD together, the last being the most effective. Saturation kinetics gave y-axis intercepts, suggesting interaction at a specific point on the enzyme surface. The Ki value from saturation kinetics was the same as that from the slope replot in catalytic reaction. Peptide mapping of tryptic digests showed that a single peptide was labelled, confirming specificity of interaction. Even in the absence of complete inactivation, the results suggest that reaction with the first two molecules occurs at some point on the enzyme surface important for enzyme activity. The possibility of such a reaction occurring in vivo is discussed.     

Gas-liquid Chromatographic Separation of Amine Enantiomers as Diastereoisomeric Chrysanthemoylamide Derivatives

An immobilized chloroplast film, prepared by immobilizing spinach chloroplasts in 2 wt% agar gel, was attached to a SnO₂ optically transparent electrode to obtain the immobilized chloroplast film electrode. The immobilized chloroplast film electrode worked as a photoanode under illumination in the presence of methyl viologen, which was an electron carrier from chloroplasts to the SnO₂ optically transparent electrode. Water photolysis for producing hydrogen by a photoelectrochemical cell using the immobilized chloroplasts film electrode was successfully achieved. A smooth platinum electrode was used as a cathode to produce hydrogen. The pH and temperature of the anolyte were kept at 7.8 and 25°C. Optimizations of the concentrations of methyl viologen and chlorophyll in the immobilized chloroplast film were studied. The optimum thickness for the immobilized chloroplast film was about 0.8 mm. The immobilized chloroplasts had higher storage stability than that of isolated chloroplasts and they retained more than 50% of the initial activities of photosystem I and photosystem II after 10 days when they were stored at 4°C in the dark. It was conceived from the relationship between the photocurrent and the photosystem I and II activities that the main cause for the decrease in the photocurrent was the photochemical inactivation of photosystem II.