An electrophoretic method for the detection of chymotrypsin and trypsin activity directly in whole blood

In biomedical research and clinical diagnostics, it is a major challenge to measure disease‐related degradative enzyme activity directly in whole blood. Present techniques for assaying degradative enzyme activity require sample preparation, which makes the assays time‐consuming and costly. This study now describes a simple and rapid electrophoretic method that allows detection of degradative enzyme activity directly in whole blood using charge‐changing fluorescent peptide substrates. Charge‐changing substrates eliminate the need for sample preparation by producing positively charged cleavage fragments that can be readily separated from the oppositely charged fluorescent substrate and blood components by electrophoresis. Two peptide substrates have been developed for pancreatic α‐chymotrypsin and trypsin. For the first substrate, a detection limit of 3 ng for both α‐chymotrypsin and trypsin was achieved in whole rat blood using a 4% agarose gel. This substrate had minimal cross‐reactivity with the trypsin‐like proteases thrombin, plasmin, and kallikrein. For the second substrate (trypsin‐specific), a detection limit of about 10–20 pg was achieved using thinner higher resolution 20 and 25% polyacrylamide gels. Thus, the new charge changing peptide substrates enable a simple electrophoretic assay format for the measurement of degradative enzyme activity, which is an important step toward the development of novel point‐of‐care diagnostics.     

Advances in screening enzyme inhibitors by capillary electrophoresis

Capillary electrophoresis (CE) has attracted lots of attention due to its simplicity, low sample consumption, low solvent volume, high resolution, and high speed. Based on these advantages, it has been widely used in enzyme inhibitor screening. There are two main operation modes on enzyme inhibitor screening: off‐line (precapillary enzyme assays) in which process CE was used as an analytical tool; online (in‐capillary enzyme assays) which combined the sample injection, mix, reaction, separation, and detection within a single run. Additionally, diverse of new materials were introduced to immobilize enzyme, which has been coupled with CE for the study of enzyme activity and its inhibitor screening. This review gives an overview of the developments and applications for the CE‐based enzyme inhibitor screening.     

Capillary electrophoresis as a tool for a cost‐effective assessment of the activity of plant membrane enzyme chlorophyllase

The potential of the CE‐based enzymatic assay has been demonstrated in case of a typical plant membrane enzyme – chlorophyllase. An efficient, automated and rapid semi‐quantitative method has been developed, which allowed us to assess the activity of the enzyme via two strategies. Firstly, a reaction conducted in a vial placed directly on the sample tray was combined with the concomitant separation and detection of reagents. The method was used to monitor the reaction progress. Secondly, an online approach was applied using an electrophoretically mediated mixing. The reaction was performed in?capillary, resulting in an extreme reduction of the reagent amounts required for a single run. Both methods were effective in the assessment of the activity of a membrane enzyme, a member of protein class known to pose experimental difficulties.     

An Excimer Clamp for Measuring Damaged‐Base Excision by the DNA Repair Enzyme NTH1

Direct measurement of DNA repair enzyme activities is important both for the basic study of cellular repair pathways as well as for potential new translational applications in their associated diseases. NTH1, a major glycosylase targeting oxidized pyrimidines, prevents mutations arising from this damage, and the regulation of NTH1 activity is important in resisting oxidative stress and in suppressing tumor formation. Herein, we describe a novel molecular strategy for the direct detection of damaged DNA base excision activity by a ratiometric fluorescence change. This strategy utilizes glycosylase‐induced excimer formation of pyrenes, and modified DNA probes, incorporating two pyrene deoxynucleotides and a damaged base, enable the direct, real‐time detection of NTH1 activity in vitro and in cellular lysates. The probe design was also applied in screening for potential NTH1 inhibitors, leading to the identification of a new small‐molecule inhibitor with sub‐micromolar potency.     

Non‐hybridization single nucleotide polymorphism detection and genotyping assay through direct discrimination of single base mutation by capillary electrophoretic separation of single‐stranded DNA

The significant demands for single nucleotide polymorphism detection and genotyping assays have grown. Most common assays are based on the recognition of the target sequence by the hybridization with its specific probe having the complementary sequence of the target. Herein, a simple, label‐free, and economical non‐hybridization assay was developed for single nucleotide polymorphism detection and genotyping, based on the direct discrimination of single base mutation by simple capillary electrophoresis separation for single‐stranded DNA in an acidic electrophoretic buffer solution containing urea. Capillary electrophoresis separation of single‐base sequential isomers of DNA was achieved due to charge differences resulting from the different protonation properties of the DNA bases. Single nucleotide polymorphism detection and genotyping were achieved by discriminating the electropherogram pattern change, that is, peak number in the electropherogram, obtained by the proposed method. The successful practical application of the proposed method was demonstrated through single nucleotide polymorphism detection and genotyping on a known gene region of 84‐mer, in which guanine to adenine single‐base mutation is commonly observed, using a human hair sample in combination with genomic DNA extraction, polymerase chain reaction amplification, DNA purification from polymerase chain reaction products, and capillary electrophoresis separation.     

Increasing Hybridization Rate and Sensitivity of Bead‐Based Assays Using Isotachophoresis

We present an electrokinetic technique to increase the reaction rate and sensitivity of bead‐based assays. We use isotachophoresis (ITP) to preconcentrate and co‐focus target molecules and beads into a single ITP zone. The process achieves rapid mixing, stirring, and strongly increases the binding reaction rate. We demonstrate our assay with quantitative detection of 24 nt single‐stranded DNA over a dynamic range of three orders of magnitude and multiplexed detection of ten target species per sample. We show that ITP can achieve approximately the same sensitivity as a well‐stirred standard reaction in 60‐fold reduced reaction time (20 min versus 20 h). Alternately, compared to standard reaction times of 30 min, we show that 20 min ITP hybridization can achieve 5.3‐fold higher sensitivity.     

Simultaneous determination of thymidylate and thymidine diphosphate by capillary electrophoresis as a rapid monitoring tool for thymidine kinase and thymidylate kinase activities

A simple and rapid capillary electrophoretic method was developed for the simultaneous determination of thymidylate (TMP) and thymidine 5'-diphosphate (TDP) in enzyme assays without using radioactive-labeled substrates. Prior to electrophoretic separation, addition of acetonitrile and sodium chloride to the assay solution and brief centrifugation are recommended for the purpose of sample cleanup and sample stacking. The separation of micromolar TMP and TDP from millimolar adenosine 5'-triphosphate (ATP) was performed at 25 degrees C using sodium tetraborate as the background electrolyte. Under the optimal condition, a good separation with high efficiency was achieved in 6 min. Several parameters affecting the separation were studied, including the pH of electrolyte, the applied voltage, and acetonitrile-salt sample stacking. The fronting of the ATP peak resulting from the interference of magnesium ion in the enzyme assay buffer was suppressed by the addition of sodium ethylenediaminetetraacetate to the sample solution. Using deoxyadenylate as an internal standard, the linear range of the method was 5-200 microM, and the concentration limits of detection of TMP and TDP were 2.6 and 3.8 microM, respectively. Application of the proposed method for simultaneous determination of TMP and TDP in enzyme assays was demonstrated by the activity assays of thymidine kinase and thymidylate kinase from white spot syndrome virus. This is a sensitive, nonradioactive method for thymidine kinase and thymidylate kinase assays.     

Focusing and stabilization of bis‐intercalating dye–DNA complexes for high‐sensitive CE‐LIF DNA analysis

Multiple labeling of nucleic acids by intercalative dyes is a promising method for ultrasensitive nucleic acid assays. The properties of the fast dissociation and instability of dye–DNA complexes may prevent from their wide applications in CE‐LIF nucleic acid analysis. Here, we describe an optimum CE focusing method by using appropriately paired sample and separation buffers, Tris‐glycine buffer and Tris‐glycine‐acetic acid buffer. The developed method was applied in both uncoated and polyacrylamide coated fused‐silica capillary‐based CE‐LIF analysis while the sample and separation buffers were conversely used. The complexes of intercalative dye benzoxazolium‐4‐pyridinium dimer and dsDNA were greatly focused (separation efficiency: 1.8 million theoretical plates per meter) by transient isotachophoresis mechanism in uncoated capillary, and moderately focused by transient isotachophoresis in combination of field amplified sample stacking and further stabilized by the paired buffer in polyacrylamide coated capillary. Based on the developed focusing strategy, an ultrasensitive DNA assay was developed for quantitation of calf thymus dsDNA (from 0.02 to 2.14 pM). By the use of an excitation laser power as low as 1 mW, the detection limits of calf thymus dsDNA (3.5 kb) are 7.9 fM in concentration and 2.4×10^?22 mol (150 molecules) in mass. We further demonstrate that the non‐gel sieving CE‐LIF analysis of DNA fragments can be enhanced by the same strategy. Since the presented strategy can be applied to uncoated and coated capillaries and does not require special device, it is also reasonable to extend to the applications in chip‐based CE DNA analysis.     

Electrokinetic supercharging preconcentration prior to CGE analysis of DNA: Sensitivity depends on buffer viscosity and electrode configuration

Aiming to high sensitivity DNA analysis by CGE, electrokinetic supercharging (EKS) approach was adopted in this article. EKS is known as an online preconcentration technique that combines electrokinetic sample injection (EKI) with transient ITP (tITP). Herein, two factors of buffer viscosity and electrode configuration were studied to further improve EKS performance. An ultralow‐viscosity Tris‐Boric acid‐EDTA (TBE) buffer solution, consisted of 2% low‐molecular‐weight hydroxypropyl methyl cellulose (HPMC) and 6% mannitol and with pH 8.0 adjusted by boric acid, was applied. The boric acid would make a complex with mannitol and generates borate polyanion, which acts as the leading ion for tITP process. The new electrode configuration, a Pt ring around capillary, was modified on Agilent CE system to lead large amount sample introduction during EKS. The standard DNA sample of φX174/HaeIII digest was used to evaluate the qualitative and quantitative abilities of the proposed strategy. The 170 000‐fold highly diluted sample at concentration of 3.0 ng/mL was enriched by EKS and detected by normal UV detection method. The obtained LOD of the weakest peak of 72 bp fragment was around 7.7 pg/mL, apparently improved more than 10 000‐fold in comparison with conventional CGE with UV detection.     

Voltage‐programming‐based capillary gel electrophoresis for the fast detection of angiotensin‐converting enzyme insertion/deletion polymorphism with high sensitivity

A voltage‐programming‐based capillary gel electrophoresis method with a laser‐induced fluorescence detector was developed for the fast and highly sensitive detection of DNA molecules related to angiotensin‐converting enzyme insertion/deletion polymorphism, which has been reported to influence predisposition to various diseases such as cardiovascular disease, high blood pressure, myocardial infarction, and Alzheimer's disease. Various voltage programs were investigated for fast detection of specific DNA molecules of angiotensin‐converting enzyme insertion/deletion polymorphism as a function of migration time and separation efficiency to establish the effect of voltage strength to resolution. Finally, the amplified products of the angiotensin‐converting enzyme insertion/deletion polymorphism (190 and 490 bp DNA) were analyzed in 3.2 min without losing resolution under optimum voltage programming conditions, which were at least 75 times faster than conventional slab gel electrophoresis. In addition, the capillary gel electrophoresis method also successfully applied to the analysis of real human blood samples, although no polymorphism genes were detected by slab gel electrophoresis. Consequently, the developed voltage‐programming capillary gel electrophoresis method with laser‐induced fluorescence detection is an effective, rapid analysis technique for highly sensitive detection of disease‐related specific DNA molecules.     

Simultaneous determination of deoxycytidine diphosphate and deoxycytidine triphosphate by capillary electrophoresis with transient isotachophoretic stacking: a sensitive monitoring method for ribonucleotide reductase activity

A simple and rapid capillary electrophoretic method was developed for simultaneous determination of sub‐micromolar 2′‐deoxycytidine 5′‐diphosphate (dCDP) and 2′‐deoxycytidine 5′‐triphosphate (dCTP) levels in enzyme assays without using radioactively labeled substrates. The separation was performed at 25°C using MES in the BGE as the terminating ion, the chloride ions in the sample buffer as the leading ion, and PEG 4000 in the BGE as the EOF suppressor for sample stacking by transient isotachophoresis (tITP). Several parameters affecting the separation were investigated, including the pH of the BGE, the concentration of sodium chloride in the sample buffer, and the concentrations of MES and PEG 4000 in the running buffer. Good separation with high separation efficiency was achieved within 6 min under optimal conditions. In comparison with the simple CZE method, the present tITP‐CZE method enabled a 150‐fold increase in the injection time without any decrease in resolution and the sensitivity was enhanced up to two orders of magnitude with the new method. The linear range of the method was 0.1–10 μM for dCDP and dCTP. The limits of detection of dCDP and dCTP were 85 and 73 nM, respectively. The proposed method was successfully applied for the activity assay of ribonucleotide reductase from Hep G2 and Sf9 cells.     

Enzyme activity electrophoresis: development and applications

The development of rocket enzyme activity electrophoresis for the detection and quantification of various proteinases, lipases and pectinases is presented. Rocket enzyme activity electrophoresis is more sensitive than the radial diffusion assay and often enables distinction between qualitatively different enzymes present in the same samples, whereas the radial diffusion assay only provides information on the overall enzyme activity. However, calibration and optimization of the enzyme activity electrophoretic assay have to be performed for each new enzyme-substrate system to be analyzed. Some of the common pitfalls in the development of new enzyme activity electrophoretic assays are presented. Enzyme activity electrophoresis can be applied in combination with other electrophoretic assays. Particularly the combination of enzyme activity electrophoresis with various immunoelectrophoretic methods can provide detailed information on the enzymes studies.     

Multiplex detection of endonucleases by using a multicolor gold nanobeacon

A highly sensitive and selective assay based on a novel enzyme‐responsive multicolor gold nanobeacon has been developed for the multiplex detection of endonucleases, a group of very important nucleases. The nanobeacon takes advantage of the high specificity of DNA cleavage reactions combined with the unique fluorescence‐quenching property of gold nanoparticles (AuNPs). To prepare the nanobeacon, three hairpin DNA reporters, each labeled at the 5′ terminus with a fluorescent dye (i.e., fluorescein amidite (FAM), carboxy‐X‐rhodamine (ROX), cyanine dye (Cy5)), that respond to one of three different endonucleases are co‐assembled at the surface of AuNPs (15 nm). This assembly brings the dyes into very close proximity with the AuNP, which leads to significant quenching of the fluorescence due to the nanosurface energy‐transfer (NSET) effect. When the nanobeacon is exposed to the targeted endonucleases, specific DNA cleavage occurs and pieces of DNA fragments are released from the AuNP surface along with the fluorescent dye, which results in the fluorescence recovery that provides the basis for a quantitative measurement of endonuclease activity. Three endonucleases, namely HaeIII, EcoRI, and EcoRV, were studied as the proof‐of‐concept analytes. These endonucleases in homogeneous mixture solutions were simultaneously quantified by the proposed assay with high sensitivity and specificity. The limits of detection obtained were in the range of 5.0×10^?4 U mL^?1 to 1.0×10^?3 U mL^?1 of endonuclease; these limits are at least 100 times more sensitive than the previously reported endonuclease assays. Endonuclease inhibitors impair the DNA cleavage, so it is anticipated that the present method has great potential for screening inhibitors of endonucleases. To demonstrate this application, the inhibitory effects of certain anticancer drugs on HaeIII, EcoRI, and EcoRV activities were studied. The present protocol proved to be sensitive, reliable, and easy to carry out.     

Ultrasensitive assay of O-GlcNAc transferase using capillary electrophoresis-laser induced fluorescence

O-linked N-acetylglucosamine (O-GlcNAc) transferase (OGT) is directly associated with the level of O-GlcNAc glycosylation of biomolecules and various diseases, and it is expected to be a promising potential new therapeutic target. Here, we develop a robust and sensitive method for OGT assay based on capillary electrophoresis-laser induced fluorescence (CE-LIF) method. AF-488-modified peptide containing serine active group is designed as substrate for OGT-catalyzed reaction, and nonradioactive UDP-GlcNAc is employed as sugar donor to perform O-GlcNAc glycosylation modification. The enzyme activity of OGT is measured by quantitative determination of glycosylated peptide produced by the reaction. Large volume sample stacking technique for sample injection and a unique fluorescence collection system for LIF detection are adopted to greatly enhance the detection sensitivity, thus a low limit of detection down to 0.23 pM for OGT detection is achieved. The method is successfully applied to detect OGT activity in clinical blood samples with satisfactory accuracy. Our study provides a simple, accurate, and sensitive method with great potential application in clinical diagnosis of O-GlcNAc-related diseases.     

A High‐Throughput Mass Spectrometric Enzyme Activity Assay Enabling the Discovery of Cytochrome P450 Biocatalysts

Assaying for enzymatic activity is a persistent bottleneck in biocatalyst and drug development. Existing high‐throughput assays for enzyme activity tend to be applicable only to a narrow range of biochemical transformations, whereas universal enzyme characterization methods usually require chromatography to determine substrate turnover, greatly diminishing throughput. We present an enzyme activity assay that allows the high‐throughput mass‐spectrometric detection of enzyme activity in complex matrices without the need for a chromatographic step. This technology, which we call probing enzymes with click‐assisted NIMS (PECAN), can detect the activity of medically and biocatalytically significant cytochrome P450s in cell lysate, microsomes, and bacteria. Using this approach, a cytochrome P450_BM3 mutant library was successfully screened for the ability to catalyze the oxidation of the sesquiterpene valencene.     

High-performance capillary electrophoretic analysis of chloramphenicol acetyl transferase activity.

This study highlights the potential utility of high-performance capillary electrophoresis (HPCE) for monitoring enzyme activity. Free-zone capillary electrophoresis is used to rapidly and reproducibly analyze the activity of the bacterial enzyme chloramphenicol acetyl transferase (CAT) which converts the substrates acetyl coenzyme A (CoA) and chloramphenicol to acetyl chloramphenicol and CoA. The results of this study indicate that HPCE may be an excellent tool for studying enzyme activities since it has several advantages over standard single parameters assays, most notably, the ability to monitor both loss of substrate and appearance of products simultaneously. Conditions have been identified for optimal separation of the substrate (chloramphenicol) from the products (acetylated derivatives). This presents a unique potential of HPCE for the analysis of enzymatic reactions that may be applied to areas of analytical research presently utilizing enzymatic reactions. One such analytical method is the CAT assay used for analysis of gene promoter activity. In this study, HPCE is shown to yield similar quantitative results with nonradiolabelled substrate in a fraction of the time. HPCE has several advantages over standard techniques including speed of analysis, no need for radiolabelled substrate, small sample volumes, high sensitivity/resolution and excellent quantitative capabilities.     

Insight in DNA Repair of UV‐induced Pyrimidine Dimers by Chromatographic Methods

UV‐induced formation of pyrimidine dimers in DNA is a major deleterious event in both eukaryotic and prokaryotic cells. Accumulation of cyclobutane pyrimidine dimers and pyrimidine (6‐4) pyrimidone photoproducts can lead to cell death or be at the origin of mutations. In skin, UV induction of DNA damage is a major initiating event in tumorigenesis. To counteract these deleterious effects, all cell types possess DNA repair machinery, such as nucleotide excision repair and, in some cell types, direct reversion. Different analytical approaches were used to assess the efficiency of repair and decipher the enzymatic mechanisms. We presently review the information provided by chromatographic methods, which are complementary to biochemical assays, such as immunological detection and electrophoresis‐based techniques. Chromatographic assays are interesting in their ability to provide quantitative data on a wide range of damage and are also valuable tools for the identification of repair intermediates.     

Rapid Detection of Irreversible Acetylcholineasterase Inhibitor by Mass Spectrometry Assay

Here we developed a rapid method to detect acetylcholinesterase (AChE) activity by matrix‐assisted laser desorption/ionization Fourier transform mass spectrometry (MALDI‐FTMS) for screening irreversible AChE inhibitors. Due to its good salt‐tolerance and low sample consumption, MALDI‐FTMS could facilitate rapid detection, especially detection in real application. AChE activity was determined through calculating abundance of substrate and product in mass spectrometry. By this approach, we investigated the relation of organophosphorous (OP) concentrations and AChE inhibition. Shown in different inhibition curves from different OP pesticides, enzyme inhibitions still kept good correlation with concentration of OPs. Finally, this AChE‐inhibited method was applied to screen whole bloods of four decedents and discuss their death reason. In contrast to healthy persons, three of decedents showed low AChE activity, and probably died for irreversible AChE inhibitors. Through the following detecting in GC‐MS/MS, the possible death reason of these three decedents was confirmed, and another decedent actually died for sumicidin, a non‐AChE inhibitor. It demonstrated that screening irreversible AChE inhibitors by detecting enzyme activity in MALDI‐FTMS provided fast and accurate analysis results and excluded another toxicants not functioning on AChE. This method offered alternative choices for indicating the existence of enzyme inhibitors.     

DNA purification from crude samples for human identification using gradient elution isotachophoresis

Gradient elution isotachophoresis (GEITP) was demonstrated for DNA purification, concentration, and quantification from crude samples, represented here by soiled buccal swabs, with minimal sample preparation prior to human identification using STR analysis. During GEITP, an electric field applied across leading and trailing electrolyte solutions resulted in isotachophoretic focusing of DNA at the interface between these solutions, while a pressure‐driven counterflow controlled the movement of the interface from the sample reservoir into a microfluidic capillary. This counterflow also prevented particulates from fouling or clogging the capillary and reduced or eliminated contamination of the delivered DNA by PCR inhibitors. On‐line DNA quantification using laser‐induced fluorescence compared favorably with quantitative PCR measurements and potentially eliminates the need for quantitative PCR prior to STR analysis. GEITP promises to address the need for a rapid and robust method to deliver DNA from crude samples to aid the forensic community in human identification.     

Enzymatic/Immunoassay Dual‐Biomarker Sensing Chip: Towards Decentralized Insulin/Glucose Detection

Performing bioassay formats based on enzyme and antibody recognition reactions with a single detection chip remains an unmet challenge owing to the different requirements of such bioassays. Herein, we describe a dual‐marker biosensor chip, integrating enzyme and antibody‐based assays for simultaneous electrochemical measurements of insulin (I) and glucose (G). Simultaneous G/I sensing has been realized by addressing key fabrication and operational challenges associated with the different assay requirements and surface chemistry. The I immunosensor relies on a peroxidase‐labeled sandwich immunoassay, while G is monitored through reaction with glucose oxidase. The dual diabetes biomarker chip offers selective and reproducible detection of picomolar I and millimolar G concentrations in a single microliter sample droplet within less than 30 min, including direct measurements in whole blood and saliva samples. The resulting integrated enzymatic‐immunoassay biosensor chip opens a new realm in point‐of‐care multiplexed biomarker detection.