Equilibrium states and oscillations for localized two-enzyme kinetics: A model for circadian rhythms

Two models of localized catalysis are presented. In Problem I we study cooperatively coupled enzymes bound to membranes separated from each other. In Problem II the interaction of a membrane bound with a soluble (homogeneously distributed on a finite interval) enzyme is considered, with non-linearity in the bulk solution. One of the models is developed to describe cellular circadian rhythms at the molecular level.     

Three different examples of enzymatic bioconversion in liquid membrane reactors

Three different examples of enzyme emulsions are presented. The enzymes are immobilized in liquid surfactant membranes. The effect of the organic membrane phase is discussed as well as the influence of the membrane composition on the transport of substrates and products through the membrane. An enzyme emulsion system for the production of l-leucine with continuous co-factor regeneration is described. It is not necessary to increase the molecular weight of the co-factor by linking it to a soluble high molecular weight compound (e.g., PEG), since the coenzyme cannot pass the liquid membrane without a suitable carrier. Also, a product (6-APA) can be enriched in the internal phase of the liquid membrane. The separation effect is not based on differences in molecular weight, but on the chemical behavior of the substances to be separated.     

Membrane coarctation by calcium as a regulator for bound enzymes

The enzyme activity of spherical membranes formed by conjugates of trypsin and chymotrypsin with a polycarboxylic polymer decreases with increasing Ca²⁺ concentration in the surrounding solution. This phenomenon is reversible and attributed to the coarctation of the membrane structure rather than to changes in the intrinsic behavior of the bound enzymes. Coarctation decreases the swelling and increases the virtual cross-linking of the membrane so that the diffusion rate of the substrate to the catalytic sites is reduced. As a result the overal enzymic activity decreases and the observed reaction departs from the Michaelis-Menten kinetics. The activity of the trypsin conjugate decreases with increasing Ca²⁺ concentration unlike that of trypsin in free solution, because the effect of membrane coarctation masks the enhancement of tryptic activity by Ca²⁺. The physical and chemical properties of these polycarboxylic membranes, which contain about 40% enzyme protein, resemble those of some cell membranes such as erythrocyte ghosts. The results suggest that a similar indirect regulation of the activity of bound enzymes via membrane coarctation by Ca²⁺ or other multivalent metal ions may occur in living systems also.     

Isolation of the outer acrosomal membrane from bull sperm.

A procedure is described for subcellular fractionation of bull sperm which allows the isolation of outer acrosomal membrane without the use of detergent. After washing to remove seminal plasma contaminants, the acrosomal membrane is removed by homogenization and separated on a two-step sucrose gradient. The isolated membranes have been characterized by light and electron microscopy and enzyme analysis. While the acrosomal enzymes hyaluronidase and acrosin are bound to the isolated membranes, they represent only a small percentage of the total activity and therefore do not provide reliable marker enzymes for this fraction. Subcellular fractionation of sperm also yields information on the solubility of acrosomal enzymes. Two types of acrosomal enzymes have been identified on the basis of their distribution in gradient fractions. Both alpha-fucosidase and beta-N-acetyl glucosaminidase are concentrated in the soluble fraction of the gradient. In contrast, over 70% of the acrosin and hyaluronidase activity remains associated with the sperm pellet. These differences in solubility of these enzymes may reflect differences in their function in fertilization.     

Direct analysis of retinal dehydrogenase activity on an electroblotting membrane following separation by non-denaturing two-dimensional electrophoresis

The reaction from retinal to retinoic acid catalyzed by retinal dehydrogenase on a polyvinylidene difluoride (PVDF) membrane was examined using laser desorption ionization time of flight mass spectrometry (LDI-TOF MS) when the enzyme was separated by non-denaturing two-dimensional electrophoresis (2-DE), transferred onto the membrane, and stained without impairing the enzyme activity. Furthermore, the enzyme was analyzed by de novo sequencing using electrospray ionization tandem mass spectrometry (ESI-MS/MS) after proteins from mouse liver were separated by non-denaturing 2-DE, blotted onto the membrane, and stained. The results indicated that the reported methods could be applied for the direct examination of changes in retinoid catalyzed by enzymes on such membranes.     

Transient response of bienzyme electrodes

A mathematical model of the transient response of amperometric bienzyme electrodes with a consecutive cyclic and parallel substrate conversion is developed. At high catalytic activity the kinetic behavior of consecutive and parallel conversion is close to the substance diffusion through the inert membrane, and the kinetics of cyclic conversion are 3.54 times slower. At low substrate conversion rates the electrodes' response is markedly retarded. Mathematical modeling results are compared with the experimental data on the kinetic behavior of amperometric enzyme electrodes in the membranes of which the consecutive and cyclic conversions of glucose and nicotinamide adenine dinucleotide, respectively, take place.     

Enzyme Activities in Polarized Cell Membranes

The theoretical pH dependence of enzyme activities in membranes of low dielectric constant is estimated. It is shown that in biological membranes some types of enzymes may attain a limiting pH sensitivity such that an increment of only 0.2 pH unit (sufficient to induce action potentials in squid axons) causes a relative activity change of over 25%. The transients of enzyme activity generated by membrane depolarization and by pH increments in the bathing solution are discussed in relation to the transients of nervous excitation.     

Bienzyme system for the biocatalyzed deposition of polyaniline templated by multiwalled carbon nanotubes: a biosensor design

A novel method based on covalent attachment of two enzymes, glucose oxidase (GOD) and horseradish peroxide (HRP), onto carboxylic-derived multiwalled carbon nanotubes (MWNTs) for the deposition of electroactive polyaniline (PANI) under ambient conditions is described. Ultraviolet-visible spectroscopy, Fourier-transform infrared (FTIR) spectroscopy, and transmission electron microscopy were used to characterize the assembling of bienzyme and the morphology of PANI|MWNTs. Under the bienzyme biocatalytic condition, a head-to-tail structure of PANI templated by MWNTs was formed. The voltammetric characteristics of the resulting biosensor were investigated by cyclic voltammetry in the presence of glucose. The current response of PANI was linearly related to glucose concentration between 0.05 and 12.0mM with a correlation coefficient of 0.994. The synergistic performance of bienzyme, highly efficient polymerization, and templated deposition provide a general platform for the synthesis of nanowires and nanocircuits, the construction of bioelectronic devices, and the design of novel biosensors.     

Recovery of biocatalysis products from reversed micellar reaction media: a preliminary evaluation of membrane extractors.

It has been demonstrated that ultrafiltration membranes of sufficiently low molecular weight cutoff can be used to retain reversed micelles and their hosted enzymes, while permitting the recovery of lipophilic products of enzymatically-catalysed, synthesis reactions in a stripping solution on the other side of the membrane. Calculations indicate that hollow fibre membranes having the same rejection characteristics and solvent resistance as the flat sheet membranes, will provide an attractive and efficient means for the recovery of these biosynthesis products; currently, such membrane modules are not available commercially.     

Immobilization of a thermostable α-amylase, Termamyl, onto nitrocellulose membrane by Cibacron Blue F3GA dye binding

Highly porous nitrocellulose membranes were prepared by a solvent casting technique for the first time to immobilize α-amylase. An affinity dye, namely Cibacron Blue F3GA (CB), was incorporated covalently within the structure. The nitrocellulose–CB derivatized membranes were used for the immobilization of a starch degrading enzyme, α-amylase. Optimum conditions of immobilization for highest apparent activity were determined as pH 6.0, temperature 50°C and initial enzyme concentration 0.317 KNU/l. Under these optimum conditions, maximum enzyme immobilization yield was around 21% of the initial amount of the enzyme in the solution. Performance of free and immobilized enzymes at the same amount was compared for repeated runs. Up to the third use, immobilized enzyme showed higher activity than that of free enzyme mainly due to higher enzyme concentration in the membrane structure, then the apparent activity decreased gradually. However, when regenerated by switching pH to cause contraction/expansion of the structure, the membrane showed the highest activity, almost 2.5 times than that of the free enzyme. This unusual feature along with inexpensive cost may well make the nitrocellulose membrane an economical material for industrial application in glucose syrup production.     

Cl- -HCO3- dependent ATPase in gills of freshwater and seawater adapted eels (Anguilla anguilla L.)

The gills of both seawater and freshwater adapted eels have an ATPase activity which is stimulated by anions in the presence of Mg2+. Plasma membranes were distinguished from mitochondrial membranes with specific enzyme markers, the membrane fractions separated on a discontinuous sucrose gradient, and the ATPase activity of the plasma membranes studied. Activation by the anions of Cl- or HCO3- followed Michaelis-Menten kinetics and was competitively inhibited by SCN-. The Cl- and HCO3- activation characteristics were determined: no differences between the plasma membrane ATPase activities of freshwater and seawater-adapted fishes were observed. Maximal activity measurements after solubilization of the enzymes by Triton X 100 confirmed these findings. The function of a membrane anion-dependent ATPase in the brachial epithelium of euryhaline fish is discussed.     

Enzymic characteristics of fat globule membranes from bovine colostrum and bovine milk

Fat globule membranes have been isolated from bovine colostrum and bovine milk by the dispersion of the fat in sucrose solutions at 4 degrees C and fractionation by centrifugation through discontinuous sucrose gradients. The morphology and enzymic characteristics of the separated fractions were examined. Fractions comprising a large proportion of the total extracted membrane were thus obtained having high levels of the Golgi marker enzymes UDP-galactose N-acetylglucosamine beta-4-galactosyltransferase and thiamine pyrophosphatase. A membrane-derived form of the galactosyltransferase has been solubilized from fat and purified to homogeneity. This enzyme is larger in molecular weight than previously studied soluble galactosyltransferases, but resembles in size the galactosyltransferase of lactating mammary Golgi membranes. In contrast, when fat globule membranes were prepared by traditional procedures, which involved washing the fat at higher temperatures, before extraction, galactosyltransferase was not present in the membranes, having been released into supernatant fractions, When the enzyme released by this procedure was partially purified and examined by gel filtration, it was found to be of a degraded form resembling in size the soluble galactosyltransferase of milk. The release is therefore attributed to the action of proteolytic enzymes. Our observations contrast with previous biochemical studies which suggested that Golgi membranes do not contribute to the milk fat globule membrane. They are, however, consistent with electron microscope studies of the fat secretion process, which indicate that secretory vesicle membranes, derived from the Golgi apparatus, may provide a large proportion of the fat globule membrane.     

Isolation of the outer acrosomal membrane from bull sperm

A procedure is described for subcellular fractionation of bull sperm which allows the isolation of outer acrosomal membrane without the use of detergent. After washing to remove seminal plasma contaminants, the acrosomal membrane is removed by homogenization and separated on a two-step sucrose gradient. The isolated membranes have been characterized by light and electron microscopy and enzyme analysis. While the acrosomal enzymes hyaluronidase and acrosin are bound to the isolated membranes, they represent only a small percentage of the total activity and therefore do not provide reliable marker enzymes for this fraction.Subcellular fractionation of sperm also yields information on the solubility of acrosomal enzymes. Two types of acrosomal enzymes have been identified on the basis of their distribution in gradient fractions. Both α-fucosidase and β-N-acetyl glucosaminidase are concentrated in the soluble fraction of the gradient. In contrast, over 70% of the acrosin and hyaluronidase activity remains associated with the sperm pellet. These differences in solubility of these enzymes may reflect differences in their function in fertilization.     

Bienzyme HRP-GOx-modified gold nanoelectrodes for the sensitive amperometric detection of glucose at low overpotentials

Gold nanotubular electrode ensembles were prepared by using electroless deposition of the metal within the pores of polycarbonate track-etched membranes. Mono-enzyme (GOx) and monolayer/bilayer bienzyme (GOx/HRP) bioelectrodes were prepared by immobilizing the enzymes onto gold nanotubes surfaces modified with mercaptoethylamine. Batch amperometric responses to glucose for the different bioelectrodes were determined and compared. The response of the two geometries (monolayer and bilayer) of the bienzyme electrodes was shown to vary with regard to sensitivity at detection potentials above 0V. On the contrary, at detection potentials below 0V, no noticeable influence of the configuration of the bienzyme on the response intensity was observed. The mono-enzyme (650 microAmM-1 in benzoquinone (BQ) at -0.8 V versus Ag/AgCl) and the two bienzyme bioelectrodes (+/-400 microAmM-1 in hydroquinone (H2Q) at -0.2V versus Ag/AgCl) display remarkable sensitivities compared to a classical GOx-modified gold macroelectrode (13 microAmM-1 in BQ at -0.8 V versus Ag/AgCl). A remarkable feature of the bienzyme electrodes is the possibility to detect glucose at very low applied potentials where the noise level and interferences from other electro-oxidizable compounds are minimal. Another important characteristic of the monolayer bienzyme electrode is the possible existence of a direct electronic communication between HRP and the transducer surface.     

Glycosylated proline-rich peptide of human parotid saliva. Circular dichroism study.

The direct monitoring of sugars such as lactose, maltose, saccharose is not only useful at the applied point of view but also at the fundamental point of view for studying enzymology, especially in microbiology and fermentation. Benzyme systems were extensively used in solution for analytical applications in industry and medicine. The progress in the field of immobilization of bienzyme systems [1-3], especially within membranes [4-5], makes possible the production of new analytical devices. From the studies dealing with concentration profiles in artificial enzyme membranes [14], evidence was obtained for a well defined relationship between the local concentration of a metabolite and concentration of the first substrate in the bulk solution. In the described systems a substrate is transformed into glucose within a membrane, the glucose is then transformed in gluconic acid with a local oxygen consumption. The local pO2 level is linked to the glucose oxidase velocity, which is only linked to the glucose production, that is to say to the concentration of the first substrate. The enzyme electrode is based on the transformation of kinetic phenomena (reaction rates) into absolute values (local concentrations) through the diffusion-reaction coupling process. The manufacture of magnetic enzyme electrodes [6] allows convenient use of the active sensors. The pO2 electrode has some adventages, namely the specificity based on the selectivity of the gas permeable membrane and the linear relationship between the oxygen and the output of the electrode. pCO2, pH, ion electrodes give a logarithmic response as a function of the concentration. The grafting of a multienzyme system on a sensor allows a study of sequential systems in a defined context with a measurement of the local concentration of the metabolites. The tool is useful for both kinetics [4] and regulation studies [5].     

Submitochondrial localization and asymmetric disposition of two peripheral cyclic nucleotide phosphodiesterases.

There are two distinct cyclic AMP phosphodiesterases associated with the liver mitochondrion: one with the outer membrane and one with the inner membrane. No activity is associated with the lysosomal fraction. Both of the enzymes are peripheral proteins and can be released from the membranes by high-ionic-strength treatment. Treatment of intact mitochondria with trypsin and insoluble trypsin localizes these enzymes to the cytosol-facing surface of their respective membranes. The enzymes differ in regard to sedimentation coefficient, thermostability and susceptibility to inactivation by trypsin. Both enzymes degrade cyclic AMP and cyclic GMP. Whereas the outer-membrane enzyme displays Michaelis kinetics and appears to be a low-affinity enzyme, the inner-membrane enzyme displays kinetics indicative of apparent negative co-operativity.     

Covalent binding of enzymes to synthetic membranes containing acrylamide units, using formaldehyde

Synthetic membranes containing 10% acrylamide units were subjected to activation with formaldehyde at pH 7.5 and 45 degrees C. Trypsin, invertase, and urease were bound to this activated membrane and the kinetic properties of immobilized enzymes were studied. The permeability of the membrane for distilled water manifests certain differences depending on the enzyme bound. The membranes with immobilized enzymes stored at 4 degrees C in a moist state showed no change in their activity for 6 months. The membrane with immobilized invertase has preserved its activity even after 20 operations with 2% sucrose solution at 25 degrees C. The proposed method of binding enzymes to synthetic membranes containing acrylamide groups, through the introduction of N-hydroxymethyl groups, possesses several advantages with respect to the activation of the membrane in a one-step reaction with cheap and accessible reagent, high operative stability of the immobilized enzymes, no danger of bacterial rotting, and long shelf life of the membrane.     

Distribution of immobilized enzymes on porous membranes

In this article, the results from a theoretical and experimental investigation of enzyme immobilization in porous membranes are reported. A theoretical model of the immobilization process, which accounts for restricted diffusion of enzyme in the pores of the membrane, has been developed. The model predicts the effect of immobilization kinetics and time of immobilization on the enzyme distribution in the pores of the membrane. The immobilization of glucose oxidase and glucose oxidase-biotin conjugate on porous alumina membranes was experimentally investigated. Enzyme uptake data was correlated to the theory to determine the rate constant of imobilization and the distribution of the enzyme in the pore. Immobilization studies were carried out for enzyme adsorption and for enzyme attachment by covalent coupling. The distribution of enzyme was experimentally studied by assembling five membranes in the diffusion cell. Following immobilization, the membranes were separated and each was assayed for activity. The amount of active enzyme present in each membrane yielded a discrete distribution that compared well with that predicted by theory. (c) 1992 John Wiley & Sons, Inc.     

Plasma membranes from Candida tropicalis grown on glucose or hexadecane. I. Isolation, identification and purification.

Plasma membranes from Candida tropicalis grown on glucose or hexadecane were isolated using a method based on the difference in surface charge of mitochondria and plasma membranes. After mechanical disruption of the cells, a fraction consisting of mitochondrial and plasma membrane vesicles was obtained by differential centrifugation. Subsequently the mitochondria were separated from the plasma membrane vesicles by aggregation of the mitochondria at a pH corresponding to their isoelectric point. Additional purification of the isolated plasma membrane vesicles was achieved by osmolysis. Surface charge densities of mitochondria and plasma membranes were determined and showed substrate-dependent differences. The isolated plasma membranes were morphologically characterized by electron microscopy and, as a marker enzyme, the activity of Mg2+-dependent ATPase was determine. By checking for three mitochondrial marker enzymes the plasma membrane fractions were estimated to be 94% pure with regard to mitochondrial contamination.     

Permeability of artificial lipid membranes to some enzymes

The permeability of artificial lipid membranes for six enzymes, e.g. RNAse, trypsin, amylase, aldolase, invertase and alkaline phosphatase, was studied. The permeability coefficient values for these enzymes were calculated. It was shown that the penetration process consists of several steps: adsorption of enzyme on the membrane surface, diffusion of enzyme molecules through the lipid layer and enzyme desorption into the surrounding solution. The results obtained suggest that the diffusion of the enzyme molecules through the lipid layer is the limiting step of the penetration process.