Intravascularly administered crosslinked immunoprecipitates of gulonolactone oxidase are toxic and rapidly cleared from the circulation

Glutaraldehyde crosslinked, immunoprecipitated gulonolactone oxidase, injected intraperitoneally, has significant catalytic activity and is capable of providing long-term therapeutic benefit for the enzyme deficiency disease scurvy. The enzyme is tolerated even in repetitive doses. In the present study, however, we have found that when administered intra-arterially this modified enzyme is quite toxic even in single doses. Prior to administration the enzyme complex was filtered through a 5-microns filter. When administered intravascularly the enzyme is not nearly as active catalytically. In spite of this, activity can be detected in vivo as an elevation of plasma ascorbic acid and prolonged survival of guinea pigs fed without the vitamin. Following administration both activity and the enzyme complex are rapidly removed from the circulation. Liver and spleen are largely responsible for this uptake. Because of its toxicity intra-arterial injection of this form of the enzyme does not appear suitable for enzyme therapy.     

Simple kinetic models explaining critical phenomena in enzymatic reactions with isomerization of the enzyme and substrate

Kinetic models for enzyme reactions are considered which take into account enzyme and substrate isomerization. Application of graph-theoretic methods allows to reveal fragments in schemes which may induce multiple stead-states or concentrational selfoscillations. The role of substrate isomers in the inhibition of enzyme isomers to produce critical phenomena is considered. The boundaries of parameter domains for critical phenomena are estimated. It is shown that the controlled change in concentrations of substrate and enzyme isomers may be important in regulation of enzyme systems, if different enzyme isomers are inhibited mainly by different substrate isomers. The models are used for interpretation of possible critical phenomena in the open reaction catalyzed by lactate dehydrogenase. It is shown that lactate dehydrogenase may act as a trigger in carbohydrate metabolism by changing "critically" its activity in relation to changes in pH and pyruvate fluxes. Slow enzyme inhibition by enolpyruvate is suggested as a possible reason for glycolytic oscillations.     

Biosensoren für die Lebensmittelindustrie

Biosensors are obtaining an increasing significance for analytical purposes as well as for on-line monitoring and control in biotechnological processes [1]. In the special field of food industry enzyme and microbial biosensors are suited. With enzyme sensors one can analyse in mostly high specific reactions many substances – microbial sensors normally are unspecific. But they have the advantage of high stability and there is no necessity of enzyme isolation and purification. On the basis of the manifold of microbial metabolic pathways one can expect a wider range of application for microbial sensors, much more as existent for enzyme sensors. This paper is dealing with a microbial aspartam sensor.     

Studies on a 2,3-diaminopropionate: ammonia-lyase from a Pseudomonad.

2,3-Diaminopropionate:ammonia-lyase, an induced enzyme in a Pseudomonas isolate, has been purified 40-fold and found to be homogeneous by disc gel electrophoresis and by ultracentrifugation. Some of its properties have been studied. The optimum pH and temperature for activity are 8 and 40 degrees C, respectively. The enzyme shows a high degree of substrate specificity, acting only on 2,3-diaminopropionate; the D-isomer is only one-eighth as effective as the L-form. L-Homoserine and DL-cystathionine are not substrates, and 3-cyanolalanine does not inhibit its activity. It is a pyridoxal phosphate enzyme which requires free enzyme sulphhydryls for activity. The Km values for L-2,3-diaminopropionate and pyridoxal phosphate are 1mM and 25 muM, respectively. The molecular weight of the enzyme is about 80 000 as determined by gel filtration. On treatment with 0.5M urea or guanidine by hydrochloride, the enzyme dissociates into inactive subunits with an approximate molecular weight of 45 000. One mole of the active enzyme binds one mole of pyridoxal phosphate. The bacterial enzyme seems to be quite different in many of its properties from the rat liver enzyme which also exhibits the substrate specificity of cystathionine gamma-lyase.     

A novel procedure for the preparation and characterization of catalytically active fatty acid synthetase immobilized on sepharose beads

A novel procedure for immobilization of enzymatically active fatty acid synthetase is presented. The enzyme is coupled to a Sepharose 4B matrix containing covalently attached antibodies which recognize, and bind specifically to, the thioesterase domain of this polyfunctional enzyme. A continuous flow system is described for assay of the immobilized enzyme. Fatty acid synthetase activity apparently is not limited by movement of substrates through the Nernst diffusion layer surrounding the matrix particles, since normal Michaelis-Menten kinetics are observed and reaction rates are independent of flow rate. The Km values for acetyl-CoA and malonyl-CoA, the pH/activity profile, and the reaction products are essentially the same as for the freely soluble enzyme, although the specific activity is lower by about 55%. The preparation and characterization of immobilized subunits of the enzyme could provide a valuable approach for studying the role of structural and functional subunit interactions in the enzyme. In addition, the immobilized enzyme offers a model for studying the properties of this enzyme in a highly structured environment such as might exist in vivo, permitting study of both physical and functional interactions of fatty acid synthetase with other lipogenic enzymes.     

The theoretical analysis of kinetic behaviour of “hysteretic” allosteric enzymes V. Relaxation kinetics of dissociating enzyme systems

The expressions for relaxation time as a function of enzyme and specific ligand concentration are deduced for dissociating enzyme system 2p ? P (P is enzyme oligomer which is able to dissociate reversibly forming two identical halves p). It is assumed that ligand binding sites are equivalent and independent in each oligomeric enzyme form and the equilibrium between oligomeric forms develops rather slowly in comparison with the rate of the binding of the ligand. The kinetics of relaxation of the dissociating enzyme system 2p ? P with progressive change of the rate constants for association of oligomeric form p has been analysed in graphic form. The situations when one of the oligomeric enzyme forms is not able to bind the ligand are also considered. The principles of the analysis of relaxation kinetics of dissociating enzyme systems 2p ? P are discussed.     

Inactivation of bacterial D-amino acid transaminases by the olefinic amino acid D-vinylglycine.

D-Vinylglycine (2-amino-3-butenoate) functions as a transamination substrate and irreversible inactivator of the homogeneous pyridoxal phosphate-dependent D-amino acid transaminases from Bacillus subtilis and Bacillus sphaericus. In the absence of alpha-ketoglutarate as co-substrate, vinyl-glycine causes little if any inactivation of either enzyme; in the presence of excess alpha-ketoglutarate, both enzymes are inactivated with pseudo-first order kinetics. The limiting rate constant for inactivation of the B. sphaericus enzyme is 1.9 min-1, for the B. subilis enzyme it is 0.36 min-1. The number of catalytic events before inactivation is about 450 for the B. sphaericus enzyme and about 800 for the B. subtilis enzyme; that is, about 0.2% inactivation in each catalytic cycle for the former enzyme and 0.15% for the latter. Comparisons are made with the L-aspartate amino-transferase from pig heart which is inactivated completely in one catalytic cycle and the L-alanine aminotransferase which is not inactivated in many cycles. Comparisons are also made between the likely mode of D-transaminase inactivation produced by vinylglycine and the mode of inactivation induced by beta-chloro-D-alanine.     

A cis-proline to alanine mutant of E. coli aspartate transcarbamoylase: kinetic studies and three-dimensional crystal structures

The only cis-proline residue in Escherichia coli aspartate transcarbamoylase has been replaced by alanine using site-specific mutagenesis. The Pro268-->Ala enzyme exhibits a 40-fold reduction in enzyme activity and decreased substrate affinity toward carbamoyl phosphate and aspartate compared to the corresponding values for the wild-type enzyme. The concentration of the bisubstrate analogue N-phosphonacetyl-L-aspartate (PALA) required to activate the mutant enzyme to the same extent as the wild-type enzyme is significantly increased. The heterotropic effects of ATP and CTP upon the Pro268-->Ala enzyme are also altered. Crystal structures of the Pro268-->Ala enzyme in both T- and R-states show that the cis-peptidyl linkage between Leu267 and Ala268 is maintained. However, the tertiary structure of both the catalytic and regulatory chains has been altered by the amino acid substitution, and the mobility of the active-site residues is increased for the R-state structure of Pro268-->Ala enzyme as comparison with the wild-type R-state structure. These structural changes are responsible for the loss of enzyme activity. Thus, Pro268 is required for the proper positioning of catalytically critical residues in the active site and is important for the formation of the high-activity high-affinity R-state of E. coli aspartate transcarbamoylase.     

Purification and biochemical characterization of recombinant rat liver phenylalanine hydroxylase produced in Escherichia coli.

Phenylalanine hydroxylase, important in phenylalanine metabolism in mammals, is regulated through short-term (activation) and long-term (induction) mechanisms. To help elucidate the structure-function relationships involved in the activation of this enzyme, we have isolated and characterized full-length cDNA clones to rat phenylalanine hydroxylase. Recombinant rat phenylalanine hydroxylase was placed into an expression vector in Escherichia coli. The enzyme has been purified to homogeneity and its physical and catalytic properties have been characterized. The molecular weight and the fluorescence emission spectrum of the recombinant enzyme were identical to those of the native enzyme. The recombinant enzyme could be activated by incubation with phenylalanine or lysolecithin or by phosphorylation, as is the rat liver enzyme. The extent of activation is the same as that for the native enzyme in each case except for phenylalanine, which activates the recombinant enzyme only 5- to 10-fold rather than the 15- to 30-fold activation observed with the native enzyme. The kinetic constants determined for the recombinant enzyme are also essentially the same as those reported for the native enzyme. We conclude that this enzyme is essentially identical to the native enzyme and should be very useful in the future study of this important hydroxylase.     

Effect of N-bromosuccinimide modification on dihydrofolate reductase from a methotrexate-resistant strain of Escherichia coli. Activity, spectrophotometric, fluorescence and circular dichroism studies.

When dihydrofolate reductase from a methotrexate-resistant strain of Escherichia coli B, MB 1428, is treated with approximately a 5 mol ratio of N-bromosuccinimide (NBS) to enzyme at pH 7.2 and assayed at the same pH, there is a 40% loss of activity due to the modification of 1 histidine residue and possibly 1 methionine residue before oxidation of tryptophan occurs. The initial modification is accompanied by a shift of the pH for maximal enzymatic activity from pH 7.2 to pH 5.5 Upon further treatment with N-bromosuccinimide, the activity is gradually reduced from 60 to 0% as tryptophan residues become oxidized. An NBS to enzyme mole ratio of approximately 20 results in 90% inactivation of the enzyme. When the enzyme is titrated with NBS in 6 M guanidine HCl, 5 mol of tryptophan react per mol of enzyme, a result in agreement with the total tryptophan content as determined by magnetic circular dichroism. The 40% NBS-inactivated sample posses full binding capacity for methotrexate and reduced triphosphopyridine nucleotide, and the Km values for dihydrofolate and TPNH are the same as for the native enzyme. After 90% inactivation, only half of the enzyme molecules bind methotrexate, and the dissociation constant for methotrexate is 40 nM as compared to 4 nM for native enzyme in solutions of 0.1 M ionic strength, pH 7.2 Also, TPNH is not bound as tightly to the modified enzyme-methotrexate complex as to the unmodified enzyme-methotrexate complex. Circular dichroism studies indicate the 90% NBS-inactivated enzyme has the same alpha helix content as the native enzyme but less beta structure, while the 40% inactivated enzyme is essentially the same as the native enzyme. Protection experiments were complicated by the fact that NBS reacts with the substrates and cofactors of the enzyme. Although protection of specific residues was not determined, it was clear that TPNH was partially protected from NBS reaction when bound to the enzyme, and the enzyme, and the enzyme was not inactivated by NBS until the TPNH had reacted.     

Immobilized invertase

Invertase is a commercially important enzyme used for the hydrolysis of sucrose. The hydrolysis of sucrose yields an equimolar mixture of glucose and fructose, known as invert syrup, is widely used in food and beverage industries. This enzyme is also used for the manufacture of artificial honey, plasticizing agents used in cosmetics, pharmaceutical and paper industries as well as enzyme electrodes for the detection of sucrose. Immobilization of invertase and its biotechnological applications are reviewed.     

On the mechanism of ketogenesis and its control. Purification, kinetic mechanism and regulation of different forms of mitochondrial acetoacetyl-CoA thiolases from ox liver.

1. Two mitochondrial forms of acetoacetyl-CoA thiolases designated as enzyme A and enzyme B were crystallized from ox liver. They could be shown to be homogenous by polyacrylamide gel electrophoresis. 2. In direction of acetoacetyl-CoA cleavage enzyme A shows a double competitive substrate inhibition when acetoacetyl-CoA is varied at different fixed CoA concentrations. With enzyme B a parallel kinetic pattern is obtained when acetoacetyl-CoA is varied at different fixed CoA concentrations. In direction of acetoacetyl-CoA synthesis both enzymes show linear reciprocal plots of initial velocities against acetyl-CoA concentrations in absence of CoA. These initial velocity kinetics in the forward and in the reverse direction are in accordance with a ping-pong mechanism of reaction for both enzymes involving an acetyl-S-enzyme as intermediate. 3. Under saturating concentrations of substrate, the ratios of acetoacetyl-CoA synthesis/aceto-acetyl-CoA cleavage is 0.31 for enzyme A and 0.08 for enzyme B. The maximum velocity in direction of acetoacetyl-CoA synthesis of enzymes A and B are 0.43 mumol X min-1 X unit thiolase-1 and 0.10 mumol X min-1 X unit thiolase-1, respectively. 4. Both enzymes show nearly the same affinity for acetyl-CoA. The Km values are 91 muM (enzyme A) and 80 muM (enzyme B). 5. Coenzyme A and acetoacetyl-CoA both act as inhibitors in direction of acetoacetyl-CoA synthesis: coenzyme A is a nonlinear competitive inhibitor of both enzymes. Acetoacetyl-CoA exerts a negative cooperativity on enzyme A (nH = 0.63) and is a competitive inhibitor for enzyme B (Ki = 1.6 muM). 6. The catalytic and regulatory properties of the acetoacetyl-CoA thiolases A and B are discussed in terms of their proposed role in regulating ketogenesis. Intracellular fluctuations of acetoacetyl-CoA/3-hydroxybutyryl-CoA ratios, resulting in a suspension of inhibition of both enzymes at high NADH/NAD ratios, are postulated as a control mechanism of ketogenesis in addition to mechanisms already known.     

Comparison of the subsite specificity of the mammalian neutral endopeptidase 24.11 (enkephalinase) to the bacterial neutral endopeptidase thermolysin

A comparison has been made of the specificity of the mammalian neutral metalloendopeptidase, endopeptidase 24.11, with that of the bacterial neutral metalloendopeptidase thermolysin. A series of synthetic oligopeptides which have previously been studied as substrates for thermolysin and used in computer modeling were examined as substrates for the mammalian enzyme. It was found that P1, P2, and P'3 subsite interactions in the mammalian enzyme, although similar to those found in thermolysin, are less restrictive spatially and are considerably less dependent on hydrophobic interactions. This difference was maximally expressed with the synthetic substrate dansyl-D-alanylglycylnitrophenylalanylglycine which is a substrate for the mammalian enzyme, but not for the bacterial enzyme. A comparison of substrates in the free acid form with their corresponding amides showed that binding to the mammalian enzyme is dependent in part on an ionic interaction between the substrate carboxylate group and the enzyme. Such an ionic interaction was not observed with the bacterial enzyme.     

Identification of denatured enzyme proteins in sodium dodecyl sulfate polyacrylamide gels

A simple modification of the immunological sandwich method of Muilerman et al. for the identification of denatured enzyme proteins in sodium dodecyl sulfate-polyacrylamide gels is described, enabling the method to be used in principle for any enzyme whose activity is not inhibited by binding to antibodies. An immunological sandwich consisting of denatured enzyme, antibodies, and native enzyme is formed on a nitrocellulose filter blot of the gel, the filter is divided into strips, and each strip is tested for enzyme activity. The presence of enzyme activity serves to identify the region in the gel containing denatured enzyme protein. Experiments with human lysosomal alpha-glucosidase as a model system are described. The method was applied to identify a protein of Mr 125,000 as the main component with UDPgalactose pyrophosphatase activity in a partially purified preparation of the enzyme from rat liver.     

Immobilization of catalytically active thromboxane synthase

Thromboxane synthase has been immobilized on phenyl-Sepharose beads by adsorption. The immobilized enzyme is catalytically active and has a slightly lower apparent Km for PGH2 than the detergent-solubilized enzyme. However, both imidazole- and pyridine-based inhibitors are equally effective in inhibiting the immobilized and solubilized enzyme preparations. Although the immobilized enzyme appears to be less stable than the solubilized enzyme it is sufficiently stable to be used as a model for studying the properties of the enzyme.     

Regulation and degradation of HMGCo-A reductase

The enzyme, 3-hydroxy-3-methylglutaryl coenzyme A reductase (HMGR) controls the biosynthesis of cholesterol. Hypercholesterolemia and atherosclerosis are critical health risk factors. One way of controlling these risk factors is to manipulate regulation as well as degradation of HMGR. At present, a class of compounds called statins, which are HMGR inhibitors, are used for the treatment of hypercholesterolemia. However, statins suffer major setbacks as their use produces more adverse reactions than the desirable one of inhibiting the enzyme. Genetically engineered forms of HMGR are also studied in primitive life forms like bacteria, but detailed investigation of this enzyme in human systems is certainly required. Extensive studies have been made on the regulatory aspects of this enzyme, but no breakthrough is conspicuous in the clinical background to find an alternative treatment for hypercholesterolemia. The immediate need is to find an alternate way of regulating degradation of the enzyme. This review presents the importance of regulation and degradation of the HMGR enzyme in different systems to gain possible insight into alternative schemes for regulating this enzyme and, if these exist, the feasibility of extending them same to studies in mammalian systems. A high degree of similarity exists between mammalian and yeast HMGR. Detailed studies reported on the regulation and degradation of the yeast enzyme also throw more light on the mammalian system, leading to a better understanding of ways of controlling hypercholesterolemia.     

D-alpha-Hydroxyglutarate dehydrogenase of Rhodospirillum rubrum.

D-alpha-Hydroxyglutarate dehydrogenase of R. rubrum grown anaerobically in the light was partially purified and some properties were investigated. 1. The enzyme catalyze stoichiometrically the dehydrogenation reaction of D-alpha-hydroxyglutarate into alpha-oxoglutarate, coupled with the reduction of 2, 6-dichlorophenolindophenol. 2. Cytochrome c2, cytochrome c, and ferricyanide are effective as electron acceptors with the crude enzyme but not with the purified one, whereas NAD+ and NADP+ are completely ineffective. The enzyme is thought to play a role in the electron transport system of the organism. 3. D-alpha-Hydroxyglutarate is virtually the sole substrate for the enzyme. The apparent activity against L-alpha-hydroxyglutarate is presumed to be due to contamination of the L-isomer sample with the D-isomer. The enzyme shows barely detectable activity against both isomers of malate and virtually no activity against DL-lactate and glycolate. 4. Both isomers of malate and oxalate, which are presumably substrate analogues, inhibit the enzyme activity. 5. The enzyme is not an inducible enzyme but rather is a constitutive one for R. rubrum, unlike from the enzyme of Pseudomonas putida which is an inducible enzyme for the catabolism of lysine.     

Enzyme degradation during drying

During drying of food materials a multitude of chemical reactions and/or physical changes may occur. In this article attention is focused on one of these, namely, inactivation of enzymes during drying. The prediction of enzyme retention during drying is of interest to the pharmaceutical industry for the production of dry enzyme preparations and to the food processing industry in drying operations of food materials containing enzymes. In this article calculated enzyme retentions are presented for different drying histories and shapes of drying particles. In the numerical calculations it is assumed that enzyme degradation kinetics are first-order reactions, of which reaction constants are known as a function of temperature and water concentration in the drying material. From the calculations, conclusions can be drawn about conditions favorable for high enzyme retentions, or for high enzyme degradations.     

Altering lipase activity and enantioselectivity in organic media using organo-soluble bases: Implication for rate-limiting proton transfer in acylation step

With the hydrolytic resolution of (R,S)-naproxen 2,2,2-trifluoroethyl esters via a partially purified papaya lipase (PCPL) in water-saturated isooctane as the model system, the enzyme activity, and enantioselectivty is altered by adding a variety of organo-soluble bases that act as either enzyme activators (i.e., TEA, MP, TOA, DPA, PY, and DMA) or enzyme inhibitors (i.e., PDP, DMAP, and PP). Triethylamine (TEA) is selected as the best enzyme activator as 2.24-fold increase of the initial rate for the (S)-ester is obtained when adding 120 mM of the base. By using an expanded Michaelis-Menten mechanism for the acylation step, the kinetic analysis indicates that the proton transfer for the breakdown of tetrahedral intermediates to acyl-enzyme intermediates is the rate-limiting step, or more sensitive than that for the formation of tetrahedral intermediates when the enzyme activators of different pKa are added. However, no correlation for the proton transfers in the acylation step is found when adding the bases acting as enzyme deactivators.     

Study of properties of NADP malate dehydrogenase from corn leaves]

Kinetic properties of purified chloroplast isoenzyme of the "malic" enzyme from corn leaves were studied. The enzyme had optimum activity at pH 8.0 and 36 degrees C. Under standart conditions the Michaelis constants for the "malic" enzyme with Mn2+ as cofactor are 0.091 mM for malate and 0.04 mM for NADP. In case of Mg2+ as cofactor they are 0.66 and 0.02 mM respectively. Respective Km values for the cofactors Mn2+ and Mg2+ are 0.018 and 0.091 mM. The activity of the "malic" enzyme was inhibited by reduced NADP and NAD, ATP, ADP, fructose-1,6-diphosphate, oxaloacetic, oxalic, glyoxylic, glycolic and alpha-ketoglutaric acids, as well as by phosphate anions and pyrophosphate. The inhibitory effect of all metabolites and ions is more pronounced in case of Mn, rather than Mg, used as cofactors for the reaction. A possibility of metabolic regulation of NADP-"malic" enzyme activity in the leaves of C4-plants, is discussed.