Junfeng Ma

Organic−Inorganic Hybrid Silica Monolith Based Immobilized Trypsin Reactor with High Enzymatic Activity

A novel kind of immobilized trypsin reactor based on organic-inorganic hybrid silica monoliths has been developed. With the presence of cetyltrimethyl ammonium bromide (CTAB) in the polymerization mixture, the hybrid silica monolithic support was prepared in a 100 microm i.d. capillary by the sol-gel method with tetraethoxysilane (TEOS) and 3-aminopropyltriethoxysilane (APTES) as precursors. Subsequently, the monolith was activated by glutaraldehyde, and trypsin was covalently immobilized. By monitoring the reaction of a decapeptide, C-myc (EQKLISEEDL), the enzymatic activity of the immobilized trypsin was calculated, and the results showed that the digestion speed was about 6600 times faster than that performed in free solution. The performance of such a microreactor was further demonstrated by digesting myoglobin, with the digested products analyzed by microflow reversed-phase liquid chromatography coupled with tandem mass spectrometry (microRPLC-MS/MS). With a stringent threshold for the unambiguous identification of the digests, the yielding sequence coverage for on-column digestion was 92%, the same as that obtained by in-solution digestion, whereas the residence time of myoglobin in the former case was only 30 s, about 1/1440 of that performed in the latter case (12 h). Moreover, such an immobilized trypsin reactor was also successfully applied to the digestion of a mixture of model proteins and proteins extracted from E. coli.

Recent advances in immobilized enzymatic reactors and their applications in proteome analysis.

Immobilized enzymatic reactors recently have drawn much attention because of the striking advantages, such as high substrate turnover rate and ease in coupling with the separation and detection systems. Carrier materials, which have great effects on the development of the immobilized enzymatic reactors, have always being the focus of study. In this paper, the contributions, mainly in the last 5 years, on the enzymatic reactors and their applications in proteome study are reviewed, with some newly developed inorganic and organic carriers for enzyme immobilization described in details. Moreover, the hyphenation of immobilized enzymatic reactors with the separation and identification systems is also summarized. By reviewing these achievements, it could be seen that enzymatic reactors have very bright future, especially in proteome analysis.

Organic-Inorganic Hybrid Silica Monolith Based Immobilized Titanium Ion Affinity Chromatography Column for Analysis of Mitochondrial Phosphoproteome

A novel kind of immobilized metal affinity chromatography (IMAC) column based on organic-inorganic hybrid silica monolith has been developed. The monolithic support was prepared in a 250 microm i.d. capillary by the sol-gel method with tetraethoxysilane (TEOS) and 3-aminopropyltriethoxysilane (APTES) as precursors. Subsequently, amine groups were functionalized by glutaraldehyde, and then activated with (aminomethyl) phosphonic acid, followed by Ti(4+) chelation. By such a hybrid silica monolithic Ti(4+)-IMAC column, 15 phosphopeptides were effectively isolated from the digest mixture of alpha-casein and BSA with the molar ratio as low as 1:200, illustrating its superior selectivity. With a synthetic phosphorylated peptide, YKVPQLEIVPNSpAEER, as the sample, the loading capacity and recovery of the Ti(4+)-IMAC monolithic column were measured to be 1.4 micromol/mL and 69%, respectively. Such an IMAC monolithic column was further applied to enrich phosphopeptides from rat liver mitochondria. In total, 224 unique phosphopeptides, corresponding to 148 phosphoprotein groups, were identified by duplicate nanoRPLC-LTQ MS/MS/MS runs with a false-positive rate of less than 1% at the peptide level. These results demonstrate that the hybrid silica monolith based Ti(4+)-IMAC column might provide a promising tool for large-scale phosphopeptide enrichment, facilitating the in-depth understanding of the biological functions of phosphoproteomes.

Effects of compatibilizing agent and in situ fibril on the morphology, interface and mechanical properties of EPDM/nylon copolymer blends

Abstract The effect of several compatibilizers on mechanical property and morphology of ethylene–propylene diene monomer rubber (EPDM)/nylon copolymer (PA) blends was investigated. A significant reduction of dispersed phase dimension was observed when chlorinated polyethylene (CPE) was added to EPDM/PA blend, due to interaction that exists between CPE and PA. Based on differential thermal analysis, dynamic mechanical thermal analysis, scanning electron microscopy and transmission electron microscopy characterization, a speculative description of configuration was proposed to interpret the morphological investigation made on these blends. Cold milling of molten EPDM/PA/CPE blend gives rise to in situ fibril rubber compound, which can be mixed with curatives and statically vulcanized to give reinforced rubber compositions. Compared with vulcanized conventional rubber short fiber composites, the compositions show notably different elongation properties. The reason was given. It was shown that mechanical property of EPDM/PA/CPE blend could be improved by adding only a small amount of PA fibrils (i.e. 10%), which is different to that of conventional rubber short fiber composite. Based on above analysis, three forms of structures were proposed to discuss the relationship between the morphologies and mechanical properties. The studies of mechanical properties show that the materials obtained possess useful strength and excellent heat resistance.

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.

Efficient proteolysis using a regenerable metal-ion chelate immobilized enzyme reactor supported on organic-inorganic hybrid silica monolith.

A metal‐ion chelate immobilized enzyme reactor (IMER) supported on organic–inorganic hybrid silica monolith was developed for rapid digestion of proteins. The monolithic support was in situ prepared in a fused silica capillary via the polycondensation between tetraethoxysilane hydrolytic sol and iminodiacetic acid conjugated glycidoxypropyltrimethoxysilane. After activated by Cu2+, trypsin was immobilized onto the monolithic support via metal chelation. Proteolytic capability of such an IMER was evaluated by the digestion of myoglobin and BSA, and the digests were further analyzed by microflow reversed‐phase liquid chromatography with ESI‐MS/MS. Similar sequence coverages of myoglobin and BSA were obtained by IMER, in comparison to those obtained by in‐solution digestion (91 versus 92% for 200 ng myoglobin, and 26 versus 26% for 200 ng BSA). However, the digestion time was shortened from 12 h to 50 s. When the enzymatic activity was decreased after seven runs, the IMER could be easily regenerated by removing Cu2+ via EDTA followed by trypsin immobilization with fresh Cu2+ introduced, yielding the equal sequence coverage (26% for 200 ng BSA). For ∼5 μg rat liver extract, even more proteins were identified with the immobilized trypsin digestion within 150 s in comparison to the in‐solution digestion for 24 h (541 versus 483), demonstrating that the IMER could be a promising tool for efficient and high‐throughput proteome profiling.

Integrated Device for Online Sample Buffer Exchange, Protein Enrichment, and Digestion

An integrated sample treatment device, composed of a membrane interface and a monolithic hybrid silica based immobilized enzymatic reactor (IMER), was developed for the simultaneous sample buffer exchange, protein enrichment, and online digestion, by which for the sample buffer, the acetonitrile content was reduced to approximately 1/10 of the initial one, and the pH value was adjusted from approximately 3.0 to approximately 8.0, compatible for online trypsin digestion. Furthermore, the signal intensity of myoglobin digests was improved by over 10 times. Such an integrated device was successfully applied to the online treatment of three protein eluates obtained by reverse-phase liquid chromatography (RPLC) separation, followed by further protein digest analysis with microreverse-phase liquid chromatography-electrospray ionization-tandem mass spectrometry (microRPLC-ESI-MS/MS). The experimental results showed that the performance of such an integrated sample treatment device was comparable to that of the traditional offline sample treatment method, including lyophilization and in-solution digestion. However, the consumed time was reduced to 1/192. All these results demonstrate that such an integrated sample treatment device could be further online coupled with protein separation, peptide separation, and identification, to achieve high-throughput proteome analysis.

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) m(2)). With BSA as the model protein, efficient digestion was completed within 20s, yielding the sequence coverage of 57%, better than that obtained from the traditional in-solution digestion (42%), which took about 12h. 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 (20s vs 24 h), implying superior digestion performance for the high throughput analysis of complex samples.

Online Integration of Multiple Sample Pretreatment Steps Involving Denaturation, Reduction, and Digestion with Microflow Reversed-Phase Liquid Chromatography−Electrospray Ionization Tandem Mass Spectrometry for High-Throughput Proteome Profiling

A facile integrated platform for proteome profiling was established, in which native proteins were online denatured and reduced within a heater, digested with an immobilized trypsin microreactor, and analyzed by microflow reversed-phase liquid chromatography with electrospray ionization tandem mass spectrometry (microRPLC-ESI-MS/MS). In comparison to the traditional off-line urea denaturation protocol, even more unique peptides were obtained by online heating in triplicate (14 +/- 2 vs 11 +/- 2 for myoglobin and 16 vs 12 +/- 1 for BSA) within a significantly shortened pretreatment time of approximately 3.5 min (including 1 min of thermal denaturation and reduction and approximately 2.5 min of microreactor digestion). Moreover, proteins with concentrations ranging from 50 ng/mL (approximately 6 fmol) to 1 mg/mL (approximately 120 pmol) were positively identified by the online system. Such a platform was further successfully applied for analyzing the soluble fraction of mouse liver extract. Of all the 367 proteins identified from samples pretreated by the urea protocol and online heating, approximately 40% were overlapped, showing the partial complementation of both approaches. All these results demonstrate that the online integrated platform is of great promise for high-throughput proteome profiling and improved identification capacity for low-abundance proteins with a minute sample amount.

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.