Development of electrophoretically mediated microanalysis method for the kinetics study of flavin‐containing monooxygenase in a partially filled capillary

Moment equations for partial filling capillary electrophoresis

Moment equations were developed for partial filling CE systems, in which solute dissolution phenomena by spherical molecular assemblies or intermolecular interactions take place. Because experimental conditions of partial filling CE are divided into five categories on the basis of the magnitude relationship between the migration velocity of solute molecules and that of molecular assemblies or ligand molecules, the moment equations were systematically developed for each case by using the Einstein equation for diffusion and the random walk model. In order to demonstrate the effectiveness of the moment equations, they were applied to the analysis of partial filling CE behavior, which is correlated with dissolution phenomena of small solute molecules into spherical molecular assemblies as specific examples. Simulation results only in the case that the migration velocity of solute molecules is faster than that of molecular assemblies were represented in this paper. Detailed explanations about the derivation procedure of the moment equations and the simulation results in other cases can be found in the Supporting Information. The moment equations are theoretical bases for applying partial filling CE to the study on solute permeation kinetics at the interface of spherical molecular assemblies and on reaction kinetics of intermolecular interactions.

Kinetic study on solute permeation at the interface of molecular aggregates by partial filling capillary electrophoresis

Moment analysis method using partial filling CE was developed for the kinetic study on solute permeation at the interface of spherical molecular aggregates. Moment equations for partial filling CE were developed by classifying CE systems into five categories according to the migration velocities of solute and molecular aggregate. The method was applied to the study on the dissolution of electrically neutral solutes into SDS micelles. Elution peaks were measured by partial filling CE while changing the concentration of SDS and the filling ratio of SDS micellar zone to the capillary (ϕ_M ). Partition equilibrium constants (K_p ) and rate constants of interfacial solute permeation of SDS micelles (k_in and k_out ) were determined from the first absolute and second central moments of the elution peaks by using the moment equations. Their values were comparable irrespective of ϕ_M and were almost the same as those previously measured by complete filling CE. The positive correlation of K_p with the hydrophobicity of the solutes was explained in terms of the change in k_in and k_out . It was demonstrated that the moment analysis method using partial filling CE is effective for studying solute permeation kinetics at the interface of spherical molecular aggregates.

Study of aldehyde oxidase by micellar electrokinetic chromatography separation of O6 -benzylguanine and 8-oxo-O6 -benzylguanine

A separation method for O⁶ -benzylguanine (O⁶ -BG) and 8-oxo-O⁶ -benzylguanine (8-oxo-O⁶ -BG) is developed by using MEKC. This study includes the optimization of separation and incubation parameters for both off-line and on-line procedures. The BGE consisted of 25 mM sodium phosphate buffer-methanol (70:30, v/v), apparent pH 7.4, in which SDS and methyl-β-cyclodextrin were dissolved yielding final concentrations of 50 and 15 mM, respectively. Separations were performed at 15 kV using an untreated fused-silica capillary (40 cm length, effective length is 30 cm) with the detection wavelength at 195 nm. The capillary was kept at 15°C. Good performances were demonstrated for the repeatability and linearity. The LOQ was determined to be 14 μM for 8-oxo-O⁶ -BG (S/N = 10). The accuracy values showed a bias of +7.9% for 50 μM and -7.0% for 100 μM. Premix and transverse diffusion of laminar flow profiles (TDLFP) methods were used for on-line mixing and reaction of the substrate O⁶ -BG with aldehyde oxidase. Both procedures were successful in mixing as well as subsequent separation of the substrate and the metabolite, while the repeatability of TDLFP (14.7% (n = 3)) was much better than the premix technique.

Evaluation of immobilized hFMO3 on magnetic nanoparticles by capillary zone electrophoresis

Aim: In this paper, we developed a method to immobilize human flavin-containing monooxygenase-3 (hFMO3) using glutaraldehyde as a cross-linker onto amino-functionalized magnetic nanoparticles. Materials & methods: All the analyses were done using capillary electrophoresis coupled with a diode array detector using clozapine as a substrate. Results: The apparent Km with clozapine as substrate and inhibition of hFMO3 by methimazole were explored for immobilized hFMO3 and were found to be comparable to literature values. The immobilized enzyme could be used three-times continuously at 37°C with no loss in enzyme activity. Conclusion: A method to immobilize hFMO3 on magnetic nanoparticles has been described and evaluated in terms of enzyme activity, inhibition, pH stability and reusability.

Capillary electrophoretic enzyme assays

In the past years, capillary electrophoresis has become a frequently used technique for enzyme assays due to the high separation efficiency and versatility as well as small sample size and low consumption of chemicals. The capillary electrophoresis assays can be divided into two general categories: pre-capillary (or offline) assays and in-capillary (or online) assays. In pre-capillary assays, the incubation is performed offline and substrate(s) and product(s) are subsequently analyzed by capillary electrophoresis. In in-capillary assays enzyme reaction and separation of the analytes are performed inside the same capillary. In such assays the enzyme is either immobilized or in solution. The latter techniques is also referred to as electrophoretically mediated microanalysis (EMMA) indicating that the individual steps of the incubation as well as analysis are performed via electrophoretic phenomena. This chapter describes both techniques using the deacetylation of acetyl-lysine residues in model peptides by sirtuin enzymes as well as the hydrolysis of acetylthiocholine by acetylcholinesterase as examples.

LC-ESI-MS method for the monitoring of Abl 1 tyrosine kinase

A liquid chromatography-electrospray ionization-mass spectrometric (LC-ESI-MS) method was developed and validated to study Abl 1 tyrosine kinase. An online desalting system was adopted, and a transformation of the ratio of product to substrate instead of a deuterated internal standard was introduced to calculate the concentration of product. In this study, the substrate used was Abltide (KKGEAIYAAPFA-NH₂). The detection was performed by selected ion monitoring (SIM) mode via positive ESI interface. Chromatographic separation was achieved on a C₁₈ column using an isocratic mobile phase system. The limit of quantification (LOQ) was 10nM for the product and 25 nM for the substrate. The simple ratios of product to substrate maintained a linear relationship (R²=0.9997) over the ratio of 0-50% product. Intra- and inter-day precision was less than 10% and accuracy was from -1.6 to +5.3%. The validated method was applied to the Abl 1 kinase kinetic study and the K(m) and V(max) constants obtained for Abltide were 34.78 μM and 5.563 μmol/mg/min and for adenosine triphosphate (ATP) were 43.61 μM and 5.906 μmol/mg/min. The enzymatic reaction of Abl 1 tyrosine kinase belongs to ternary-complex mechanism.

New development in in-capillary electrophoresis techniques for kinetic and inhibition study of enzymes

Enzymes are often quantified by measuring their biological activity. Capillary electrophoresis is gaining its position in this field due to the ongoing trend to miniaturize biochemical assays. The aim of this work was to compare pre-capillary (off-line) and in-capillary electrophoresis techniques for studying enzymatic activity. The β-galactosidase (β-Gal) was chosen as a model enzyme. Each technique was optimized independently in order to decrease analyte consumption (to few tens of nanoliters), incubation time (to few seconds) and analysis time (below 1 min). Several experimental parameters (ionic strength of the background electrolyte (BGE) and of the incubation buffer, incubation time, injected volumes, …) were optimized by following peak efficiencies, resolution and repeatability. To monitor the performance of each technique, the catalytic constants (V(max) and K(m)) of 4-nitro-phenyl-d-galactopyranoside (PNPG) hydrolysis by β-Gal as well as the inhibition constants (K(i) and IC(50)) by a competitive inhibitor 2-nitrophenyl-1-thio-β-d-thiogalactopyranoside (ONPTG) were determined. The results obtained were cross compared and were also evaluated by comparison to a standard spectrophotometric method. EMMA proved to be the best technique in terms of sample consumption and speed. The short-end injection was successfully used which speeded-up electrophoretic analysis (<0.8 min). It is a very powerful tool for studying enzymatic inhibition. Usually, the inhibitor is injected in the capillary mixed to the substrate especially when both have similar mobilities. We show in this work, for the first time, that combining at-inlet reaction with EMMA-CE allows enzyme inhibition to be realized without any prior mixing of the substrate and the inhibitor. This approach is very interesting for screening inhibitors, rapidly and without excessive substrate consumption.

Advances in capillary electrophoretic enzyme assays

In recent years, capillary electrophoresis (CE) has become a frequently used tool for enzyme assays due to its well-recognized advantages such as high separation efficiency, short analysis time, small sample and chemicals consumption. The published applications cover all aspects of enzyme characterization and analysis including the determination of the enzyme activity, substrate and modulator characterization and identification, as well as the investigation of enzyme-mediated metabolic pathways of bioactive molecules. The CE assays may be classified into two general categories: (1) pre-capillary assays where the reactions are performed offline followed by CE analysis of the substrates and products and (2) online assays when the enzyme reaction and separation of the analytes are performed in the same capillary. In online assays, the enzyme may be either immobilized or in solution. The latter is also referred to as electrophoretically mediated microanalysis (EMMA). The present review will highlight the literature of CE-based enzyme assays from 2006 to November 2009. One section will be devoted to applications of microfluidic devices.

Enantioselective in-line and off-line CE methods for the kinetic study on cimetidine and its chiral metabolites with reference to flavin-containing monooxygenase genetic isoforms

An in-line screening and an off-line chiral CE method were developed to determine the stereoselectivity of flavin-containing monooxygenase (FMO) isoforms using cimetidine (CIM) as a substrate. The S-oxygenation of CIM was investigated using achiral chemical oxidants and (human supersomes) enzymatic metabolism procedures. In the off-line setup, the chiral selector sulfobutylether-beta-CD was chosen to separate the CIM S-oxide (CSO) metabolites. The electrophoretic migration order of CSO was confirmed to be (+) before (-) through the use of single enantiomers obtained by preparative chromatography. For the electrophoretically mediated microanalysis method, the in-line enzymatic reaction was performed in 100 mM phosphate reaction buffer (pH 8.3), whereas 50 mM phosphate buffer with 30 mM chiral selector (pH 2.5) was used as a BGE. During the screening of FMO isoenzymes by the electrophoretically mediated microanalysis method, formation of the new chiral center on the CIM sulfur was found to be stereoselective. FMO1 produces more (-)-CSO-enantiomer, while FMO3 generates mainly (+)-CSO-enantiomer. On the other hand, FMO5 shows no activity. The kinetic constants of FMO1 and FMO3 were measured by the off-line method. A K(m)=4.31 mM for the formation of the (+)-CSO-enantiomer and a K(m)=4.56 mM for the (-)-CSO-enantiomer are reported for the first time for FMO1.