Rapid and efficient proteolysis through laser-assisted immobilized enzyme reactors

In this report, laser radiation (808nm) for the first time was employed to enhance the efficiency of proteolysis through immobilized enzyme reactor (IMER). IMER based monolithic support was prepared in the fused-silica capillary via a simple two-step procedure including acryloylation on trypsin surface and in situ aqueous polymerization/immobilization. The feasibility and high efficiency of the laser-assisted IMER were demonstrated by the digestion of bovine serum albumin (BSA), cytochrome c (Cyt-c) and β-casein. The digestion process was achieved in 60s. The peptides were identified by MALDI-TOF-MS, yielding the sequence coverage of 33% for BSA, 73% for Cyt-c and 22% for β-casein. The comparisons between the in-solution digestion and on IMER reaction with/without laser assistance were made. To further confirm its efficiency in proteome analysis, the laser-assisted IMER was also applied to the analysis of one fraction of human serum sample through two-dimensional (2-D) separation of strong anion exchange/reversed-phase liquid chromatography (SAX/RPLC). After a database search, 49 unique peptides corresponding to 5 proteins were identified. The results showed that the laser-assisted IMER provides a promising platform for the high-throughput protein identification.     

Efficient Proteolysis of Glycoprotein Using a Hydrophilic Immobilized Enzyme Reactor Coupled with MALDI-QIT-TOF-MS Detection and μHPLC Analysis

A hydrophilic immobilized enzyme reactor (IMER) containing trypsin was prepared and applied in the proteolysis of glycoproteins. Glycoproteins including horseradish peroxidase, asialofetuin, and fetuin were used to evaluate the performance of the hydrophilic IMER for the glycoprotein digestion. The digested products were detected by matrix-assisted laser desorption/ionization quadruple ion trap time-of-flight mass spectrometry and micro-high-performance liquid chromatography. The hydrophilic IMER showed higher enzymatic digestion efficiency compared with conventional in-solution digestion. The digestion time could be reduced from 16 h to several minutes. Furthermore, using microwaves as a heat source, the reproducibility of the hydrophilic IMER was evaluated and this IMER could be recycled for at least ten times without obvious loss of enzyme activity. The hydrophilic IMER provides a promising tool for high-throughput glycoproteome analysis.     

Development of an In-Line Enzyme Reactor Integrated into a Capillary Electrophoresis System

The goal of this paper was to develop an in-line immobilized enzyme reactor (IMER) integrated into a capillary electrophoresis platform. In our research, we created the IMER by adsorbing trypsin onto the inner surface of a capillary in a short section. Enzyme immobilization was possible due to the electrostatic attraction between the oppositely charged fused silica capillary surface and trypsin. The reactor was formed by simply injecting and removing trypsin solution from the capillary inlet (~1–2 cms). We investigated the factors affecting the efficiency of the reactor. The main advantages of the proposed method are the fast, cheap, and easy formation of an IMER with in-line protein digestion capability. Human tear samples were used to test the efficiency of the digestion in the microreactor.     

High throughput tryptic digestion via poly (acrylamide-co-methylenebisacrylamide) monolith based immobilized enzyme reactor

A poly (acrylamide-co-methylenebisacrylamide) (poly (AAm-co-MBA)) monolith was prepared by thermal polymerization in the 100 or 250 μm i.d. capillary. The monolithic support was activated by ethylenediamine followed by glutaraldehyde. Trypsin was then introduced to form an immobilized enzyme reactor (IMER). The prepared IMER showed a reliable mechanical stability and permeability (permeability constant K = 2.65 × 10⁻¹³ m²). With BSA as the model protein, efficient digestion was completed within 20 s, yielding the sequence coverage of 57%, better than that obtained from the traditional in-solution digestion (42%), which took about 12 h. Moreover, BSA down to femtomole was efficiently digested by the IMER and positively identified by matrix assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS). To test the applicability of IMER for complex sample profiling, proteins extracted from Escherichia coli were digested by the IMER and further analyzed by nanoreversed phase liquid chromatography-electrospray ionization-mass spectrometry (nanoRPLC-ESI-MS/MS). In comparison to in-solution digestion, despite slightly fewer proteins were positively identified at a false discovery rate (FDR) of ∼1% (333 vs 411), the digestion time used was largely shortened (20 s vs 24 h), implying superior digestion performance for the high throughput analysis of complex samples.     

Trypsin immobilization on an ethylenediamine-based monolithic minidisk for rapid on-line peptide mass fingerprinting studies

The aim of this work was to develop a trypsin-based micro-immobilized enzyme reactor prepared on a monolithic ethylenediamine BIA Separations CIM (convective interaction media) minidisk. The micro-immobilized enzyme reactor (IMER) was integrated in a liquid chromatography system hyphenated to electrospray ionization tandem mass spectrometry to carry out on-line protein digestion and identification. The performance of this IMER was compared with that obtained using a previously developed bioreactor prepared on a conventional CIM ethylenediamine disk and with that of the commercially available Poroszyme immobilized trypsin cartridge. In this work, we showed how different proteins were identified with good recoveries using a digestion time of 10 min only.     

Preparing a metal-ion chelated immobilized enzyme reactor based on the polyacrylamide monolith grafted with polyethylenimine for a facile regeneration and high throughput tryptic digestion in proteomics

Initially, a poly (glycidyl methacrylate-co-acrylamide-co-methylenebisacrylamide) monolith was prepared in the 100 μm i.d. capillary, and then was grafted with polyethylenimine (Mw, ∼25,000) for adsorbing Cu²⁺, followed by chelating trypsin. As a result, efficient digestion for BSA (100 ng/μL) was completed within 50 s via such immobilized enzyme reactor (IMER); yielding 47% sequence coverage by matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS) analysis. Compared with the conventional method for preparing the metal-ion chelated IMER, the regeneration of such IMER can be achieved facilely by the respective 30 min desorption and re-adsorption of trypsin, and 51% sequence coverage was obtained for 50 s BSA digestion after regeneration. BSA down to femtomole was also efficiently digested by the prepared regenerable IMER. Meanwhile, after the consecutive digestion of myoglobin and BSA, there was not any mutual interference for both during MALDI-TOF MS identification, indicating the low nonspecific adsorption of such regenerable IMER. To test the applicability of regenerable IMER for complex sample profiling, proteins (150 ng) extracted from Escherichia coli were digested within 80 s by the regenerable IMER and further analyzed by nanoreversed phase liquid chromatography–electrospray ionization–mass spectrometry successfully, showing its practicability for the high throughput analysis of complex samples.     

Evaluation of various immobilized enzymatic microreactors coupled on-line with liquid chromatography and mass spectrometry detection for quantitative analysis of cytochrome c

An in-line procedure for protein analysis using a trypsin-based immobilized enzymatic reactor (IMER) coupled to LC-MS/MS has been developed. Various IMERs were synthesized and characterized by estimating the digestion yield of a pattern peptide in UV detection. Laboratory-made IMERs were optimized by studying the effect of different parameters as the nature of the functionalized immobilization support (silica, agarose), the amount of immobilized trypsin and the binding density. The potential of the laboratory-made IMERs were compared with a batch digestion and with a commercial trypsin-based IMER. The laboratory-made IMER based on CNBr-activated Sepharose showed the best performances in terms of digestion yields, digestion time, price and repeatability (RSD<4%). Cytochrome c was then digested on this IMER and used in-line with LC-MS. The target protein was easily recognized by the Mascot database until 17pmol injected.     

Hydrophilic monolith based immobilized enzyme reactors in capillary and on microchip for high-throughput proteomic analysis

A novel kind of hydrophilic monolith based immobilized enzyme reactors (IMERs) was prepared both in UV-transparent capillaries and on glass microchips by the photopolymerization of N-acryloxysuccinimide and poly(ethylene glycol)diacrylate, followed by trypsin immobilization. The performance of capillary IMERs for protein digestion was evaluated by the digestion of myoglobin with the residential time from 12s to 71 s. With μRPLC-ESI-MS/MS analysis, the obtained sequence coverages were all over 80%, comparable to that obtained by in-solution digestion for 12 h. The nonspecific absorption of BSA on monolithic support was evaluated, and no obvious protein residue was observed by a fluorescence assay. Moreover, no carry-over of the digests on the capillary IMER was found after the digestion of myoglobin (24 μg) and BSA (9 μg), which further demonstrated the good hydrophilicity of such matrix. In addition, an integrated microchip-based system involving on-line protein digestion by microchip-based IMER, peptides separation by nanoRPLC and identification by ESI-MS/MS was established, by which a mixture of standard proteins and one RPLC fraction of Escherichia coli extract were successfully identified, indicating that the hydrophilic monolith based IMER might provide a promising tool for high-throughput proteomic analysis.     

Integration of capillary isoelectric focusing with monolithic immobilized pH gradient,immobilized trypsin microreactor and capillary zone electrophoresis for on‐line protein analysis

An integrated platform consisting of protein separation by CIEF with monolithic immobilized pH gradient (M‐IPG), on‐line digestion by trypsin‐based immobilized enzyme microreactor (trypsin‐IMER), and peptide separation by CZE was established. In such a platform, a tee unit was used not only to connect M‐IPG CIEF column and trypsin‐IMER, but also to supply adjustment buffer to improve the compatibility of protein separation and digestion. Another interface was made by a Teflon tube with a nick to couple IMER and CZE via a short capillary, which was immerged in a centrifuge tube filled with 20 mmol/L glutamic acid, to exchange protein digests buffer and keep electric contact for peptide separation. By such a platform, under the optimal conditions, a mixture of ribonuclease A, myoglobin and BSA was separated into 12 fractions by M‐IPG CIEF, followed by on‐line digestion by trypsin‐IMER and peptide separation by CZE. Many peaks of tryptic peptides, corresponding to different proteins, were observed with high UV signals, indicating the excellent performance of such an integrated system. We hope that the CE‐based on‐line platform developed herein would provide another powerful alternative for an integrated analysis of proteins.     

Disparities between immobilized enzyme and solution based digestion of transferrin with trypsin

Trypsin digestion is a major component of preparing proteins for peptide based identification and quantification by mass spectral (MS) analysis. Surprisingly proteolysis is the slowest part of the proteomics process by an order of magnitude. Numerous recent efforts to reduce protein digestion to a few minutes have centered on the use of an immobilized enzyme reactor (IMER) to minimize both trypsin autolysis and vastly increase the trypsin to protein ratio. A central question in this approach is whether proteolysis with an IMER produces the same peptide cleavage products as derived from solution based digestion. The studies reported here examined this question with transferrin; a model protein of known resistance to trypsin digestion. Results from these studies confirmed that a trypsin‐IMER can in fact digest transferrin in a few minutes; providing tryptic peptides that subsequent to MS analysis allow sequence identification equivalent to solution digestion. Although many of the peptides obtained from these two trypsin digestion systems were identical, many were not. The greatest difference was that the trypsin‐ IMER produces (i) numerous peptides bearing multiple lysine and/or arginine residues and (ii) identical portions of the protein sequence were found in multiple peptides. Most of these peptides were derived from five regions in transferrin. These results were interpreted to mean that proteolysis in the case of transferrin occurred faster than the rate at which buried lysine and arginine residues were unmasked in the five regions providing peptides that were only partially digested.     

固定化β-葡萄糖醛酸酶反应器的制备及其在4-甲基亚硝胺基-1-(3-吡啶)-1-丁醇的O-糖苷化合物分析中的应用

采用溶胶-凝胶法,以丙烯酰胺作为单体,制备了基于有机-硅胶杂化整体柱的β-葡萄糖醛酸酶反应器。优化了硅酸甲酯和γ-(甲基丙烯酰氧)丙基三甲氧基硅的物质的量的比、丙烯酰胺和聚乙二醇的用量,以及水浴温度等制备条件,获得了孔隙均匀、通透性良好、机械强度高的有机-硅胶杂化整体柱。采用光学显微镜和扫描电镜表征杂化整体柱。进一步将β-葡萄糖醛酸酶共价键合在整体柱上,以4-甲基亚硝胺基-1-(3-吡啶)-1-丁醇(NNAL)的O-糖苷化合物(NNAL-O-Gluc)为底物研究酶反应器的水解效果,实验结果证明酶反应器在室温条件下的水解效率大大提高,实现了NNAL-O-Gluc高效水解与分析,解决了目前NNAL-O-Gluc分析中前处理水解效率低的问题。     

多层开管毛细管酶反应器的制备及在蛋白质酶切中的应用

以石英毛细管作为酶固定化的载体, 在毛细管内壁上逐步合成树枝形大分子聚酰胺-胺(PAMAM), 再通过交联剂戊二醛将胰蛋白酶直接键合到该大分子的末端氨基上, 并对酶固定化条件进行了优化, 制备了多层酶反应器. 利用该酶反应器对马心细胞色素C等蛋白质进行了酶切, 并对酶切的条件进行了优化. 实验结果表明, 该固定化酶反应器具有较高的酶切效率、良好的重现性和稳定性, 可用于蛋白质组学的研究.     

Rheostatic control of tryptic digestion in a microscale fluidic system

Integrated fluidic systems that unite bottom-up and top-down proteomic approaches have the potential to deliver complete protein characterization. To circumvent fraction collection, as is conducted in current blended approaches, a technique to regulate digestion efficiency in a flow-through system is required. The present study examined the concept of regulating tryptic digestion in an immobilized enzyme reactor (IMER), incorporating mixed solvent systems for digestion acceleration. Using ovalbumin, cytochrome c, and myoglobin as protein standards, we demonstrate that tryptic digestion can be efficiently regulated between complete digestion and no digestion extremes by oscillating between 45 and 0% acetonitrile in the fluid stream. Solvent composition was tuned using programmable solvent waveforms in a closed system consisting of the IMER, a sample delivery stream, a dual gradient pumping system and a mass spectrometer. Operation in this rheostatic digestion mode provides access to novel peptide mass maps (due to substrate unfolding hysteresis) as well as the intact protein, in a reproducible and stable fashion. Although cycle times were on the order of 90 s for testing purposes, we show that regulated digestion is sufficiently rapid to be limited by solvent switching efficiency and kinetics of substrate unfolding/folding. Thus, regulated digestion should be useful in blending bottom-up and top-down proteomics in a single closed fluidic system.     

Immobilized Enzyme Reactor in On-line LC and Its Application in Drug Screening

This study is to give a brief introduction of immobilized enzyme reactor (IMER) in on-line LC and its application in drug screening. The literature of immobilization techniques, immobilization supports and determination of immobilized enzyme activity were reviewed; the application in the drug screening is briefly introduced. It was found that IMER increased the enzymatic stabilization, strikingly shortens reaction time and can be used to perform fast screening of enzyme inhibitor. IMER has wide fields in drug screening application.     

Immobilization of trypsin onto 1,4-diisothiocyanatobenzene-activated porous glass for microreactor-based peptide mapping by capillary electrophoresis: Effect of calcium ions on the immobilization procedure

The immobilization conditions and kinetic behaviour of trypsin, covalently immobilized via the 1,4-diisothiocyanatobenzene (DITC) linker onto aminopropylated controlled pore glass (CPG) particles, have been evaluated to establish a rapid and efficient protocol for fabrication of an immobilized enzyme microreactor (IMER) for protein hydrolysis and subsequent peptide mapping. Addition of calcium ions to either the immobilization reaction solution or hydrolysis assay was studied for a synthetic substrate. Activity was slightly higher when immobilization was carried out in the presence of Ca²⁺ whereas more enzyme could be immobilized in its absence. A protocol requiring less than 3 h was devised to obtain maximal enzymatic activity with the lowest ratio of soluble trypsin to DITC-CPG particles. The resulting immobilized enzyme was found to retain an acceptable percentage (ca. 35%) of its activity after immobilization. The particles were dry-packed into a capillary to make a microscale IMER. Repeatability, reusability and digestion efficiency of the μIMER were investigated for the substrate β-casein using capillary electrophoretic-based peptide mapping. In initial tests, a single device showed reproducible peptide maps for 21 digestions lasting 2 h each, carried out over a period of 2 months. Complete digestion of β-casein could be achieved in a few minutes (86 s residence time in the μIMER followed by a wash step).     

A chemically modified carbon paste electrode with d-lactate dehydrogenase and alanine aminotranferase enzyme sequences for d-lactic acid analysis

An amperometric biosensor was constructed for the analysis of d-lactic acid based on immobilizing d-lactate dehydrogenase(d-LDH), alanine aminotransferase (ALT), NAD(+), a redox polymer and polyethylenimine in carbon paste. The effect of addition of ALT in the paste, using enzyme sequences of ALT/d-LDH, was insignificant for d-lactic acid analysis. The responses of d-lactic acid in ALT/d-LDH paste electrode are the same as those in d-LDH paste electrode. However, the interference effect of pyruvate in the sample can be substantially reduced if sodium glutamate was applied in the carrier solution. When ALT immobilized in control porous glass as an immobilized enzyme reactor (IMER) was mounted in flow injection analysis system with the d-LDH paste electrode as detector for d-lactate analysis, the interference of the pyruvate can be significantly eliminated. The adverse effect of pyruvate in the samples for d-lactic acid analysis was reduced more effectively in ALT IMER with d-LDH electrode than in ALT/d-LDH electrode.     

Specific detection of acetyl-coenzyme A by reversed-phase ion-pair high-performance liquid chromatography with an immobilized enzyme reactor

A selective chromatographic detection system for the determination of acetyl-coenzyme A (CoA) is reported. The short-chain acyl-CoA thioesters were separated by reversed-phase ion-pair high-performance liquid chromatography (HPLC), and then acetyl-CoA was selectively detected on-line with an immobilized enzyme reactor (IMER) as a post-column reactor. Thio-CoA liberated enzymatically from acetyl-CoA was determined spectrophotometrically after reaction with Ellman's reagent in the reagent stream. The IMER with phosphotransacetylase had a substrate specificity sufficient to determine acetyl-CoA and was active and stable in the mobile phase containing methanol and the ion-pair reagent. The calibration graph was linear between 0.2 and 10 nmol, with a detection limit of 0.05 nmol. This HPLC system with detection by IMER allows the selective identification and determination of acetyl-CoA in a mixture of acetoacetyl-CoA and 3-hydroxy-3-methylglutaryl-CoA, which are difficult to separate with ion-pair HPLC.     

Immobilized trypsin systems coupled on-line to separation methods: recent developments and analytical applications

The ability to rapidly and efficiently digest and identify an unknown protein is of great utility for proteome studies. Identification of proteins via peptide mapping is generally accomplished through proteolytic digestion with enzymes such as trypsin. Limitations of this approach consist in manual sample manipulation steps and extended reaction times for proteolytic digestion. The use of immobilized trypsin for cleavage of proteins is advantageous in comparison with application of its soluble form. Enzymes can be immobilized on different supports and used in flow systems such as immobilized enzyme reactors (IMERs). This review reports applications of immobilized trypsin reactors in which the IMER has been integrated into separation systems such as reversed-phase liquid chromatography or capillary electrophoresis, prior to MS analysis. Immobilization procedures including supports, mode of integration into separation systems, and methods are described.     

Epitope extraction technique using a proteolytic magnetic reactor combined with Fourier-transform ion cyclotron resonance mass spectrometry as a tool for the screening of potential vaccine lead peptides

Epitope extraction technique is based on the specific digestion of a target protein followed by immunoaffinity isolation of a specific recognition peptide. This technique, in combination with mass spectrometry, has been efficiently used for epitope identification. The major goal of this work was to utilize newly developed enzyme and immunoaffinity magnetic reactors for the epitope extraction procedure and confirm the efficiency of this improved system for epitope screening of proteins. Alginic acid-coated magnetite microparticles with immobilized TPCK-trypsin provided high working efficiency with low non-specific adsorption, digestion time in minutes and low frequency of missed cleavages. The sensitivity and specificity of tryptic fragmentation of the beta-amyloid-peptide Abeta (1-40) as a model polypeptide was confirmed by Fourier-transform ion cyclotron resonance mass spectrometry analysis. The Sepharose reactor or immunoaffinity magnetic reactors, both with anti-amyloid-beta monoclonal antibodies, were used for specific isolation and identification of target peptides. In this way, the epitope extraction technique combined with mass spectrometric analysis is shown to be an excellent base for molecular screening of potential vaccine lead proteins.     

基于DNA定向固定化技术构建毛细管固定化酶微反应器的研究进展

生物酶影响着物质代谢和质能转换等生命活动,生物体内某些酶的活性变化会导致疾病的发生。发展新型的酶分析方法对深刻理解生物代谢过程、疾病诊断和药物研发等具有重要意义。毛细管电泳（CE）具有分离效率高、分析速度快、操作简单和样品消耗少以及可与多种检测手段联用等优点,在酶分析研究中越来越受到关注。CE酶分析主要包括离线和在线两种模式,其中,固定化酶微反应器与毛细管电泳联用（CE-IMER）的在线酶分析已经成为主要的酶分析方法之一。CE-IMER充分结合了固定化酶和CE的优势,将游离酶固定在毛细管内,不仅可以显著提高酶的稳定性和重复使用性,而且可以实现纳升规模溶液的自动化酶分析,进而显著降低酶分析成本。目前已有大量方法制备IMER用于CE酶分析,然而如何构建性能良好、可再生使用、酶固载量大、自动化程度高的CE-IMER一直是该领域重点研究的问题。DNA定向固定化技术（DDI）可以充分利用DNA分子的碱基互补配对（A-T,C-G）,在温和的生理条件下特异性固定生物大分子。由于短链双螺旋DNA分子具有较强的机械刚性和物理化学稳定性,通过DDI将酶固定在载体表面,有利于降低传质阻力,提高酶与底物的接触能力,进而促进酶促分析过程。该文主要综述了利用DDI构建新型IMER在CE酶分析中的应用现状,并对其未来发展进行了展望。