Dual-function monolithic enzyme reactor based on dopamine/graphene oxide coating for simultaneous protein enzymatic hydrolysis and glycopeptide enrichment.

A new dual-function enzyme reactor was prepared based on a dopamine/graphene oxide coated boron affinity monolithic column, which can be used for simultaneous protein enzymatic hydrolysis and glycopeptide enrichment. Firstly, a boron affinity monolithic column was prepared as the carrier for enzyme reactor. Secondly, the monolithic column was coated with dopamine/graphene oxide to provide higher specific surface area for the increase in the amount of trypsin bound. Then, dopamine can self-polymerize under alkaline conditions to produce multiple reaction sites. By the Schiff base reaction and Michael addition reaction with amino, sulfhydryl groups to trypsin, enzyme were immobilized on the boron affinity monolithic carrier. The enzyme activity was characterized by kinetic parameters maximum rate (Vmax) of the enzyme reaction and Michaelis constant (Km). Km of the dual-function enzyme reactors doped with PDA/GO and without PDA/GO were 34.37 and 120.93 mM, Vmax were 1.35 and 3.35 mM/min, respectively. The performance of the dual-function enzyme reactor was evaluated by protein extraction of mouse liver. After digested by the dual-function enzyme reactor, the number of peptides was 4,801, which was 960 more than the number of peptides in the solution digestion. At the same time, the dual-function enzyme reactor displayed the ability to capture cis-dihydroxy compounds specificly. A total of 55 glycopeptides were enriched in the dual-functional enzyme reactor, corresponding to 33 glycoproteins. The dual-function enzyme reactor provided repeatable performance and robust with long-term storage.

Tune the Fluorescence and Electrochemiluminescence of Graphitic Carbon Nitride Nanosheets by Controlling the Defect States.

The effects of defect states on the fluorescence (FL) and electrochemiluminescence (ECL) properties of graphite phase carbon nitride (g-CN) are systematically investigated for the first time. The g-CN nanosheets (CNNSs) obtained at different condensation temperatures are used as the study models. It can be found that all the CNNSs have two kinds of defect states, one is originated from the edge of CNNSs (labeled as CN-defect) and the other is attributed to the partially carbonization regions (labeled as C-defect). Both two kinds of defect states substantially affect the luminescent properties of CNNSs. Both the FL and ECL signals of CNNSs contain a band gap emission and two defect emissions. For the FL of CNNSs, decreasing the density of defect states can increase efficiently the FL quantum yield, while increasing the density of defect states can make the FL spectra red shift. For the ECL of CNNSs, increasing the density of CN-defect states and decreasing the density of C-defect states are greatly important to improve the ECL activity. This work provides a deep insight into the FL and ECL mechanisms of g-CN, and is of significance in tuning the FL and ECL properties of g-CN. Also, it will greatly promote the applications of CNNSs based on the FL and ECL properties.

Construction of a microfluidic platform integrating online protein fractionation, denaturation, digestion, and peptide enrichment.

Microfluidic system with multi-functional integration of high-throughput protein/peptide separation ability has great potential for improving the identification capacity of biological samples in proteomics. In this paper, a sample treatment platform was constructed by integrating reversed phase chromatography, immobilized enzyme reactor (IMER) and imprinted monolith through a microfluidic chip to achieve the online proteins fractionation, denaturation, digestion and peptides enrichment. We firstly synthesized a poly-allyl phenoxyacetate (AP) monolith and a lysine-glycine-glycine (KGG) imprinted monolith separately, and investigated in detail their performance in fractionating proteins and extracting KGG from the protein digests of MCF-7 cell. The removal percentage of 94.6% for MCF-7 cell protein and the recovery of 90.8% for KGG were obtained. The number of proteins and peptides identified on this microfluidic platform was 2,004 and 8,797, respectively, which was 2.8-fold and 3.0-fold higher than that of untreatment sample. The time consumed by this platform for a sample treatment was about 9.6 h, less than that of conventional method (approximate 13.3 h). In addition, this platform can enrich some peptide fragments containing KGG based on imprinted monolith, which can be served for the identification of ubiquitin-modified proteomics. The successful construction of this integrated microfluidic platform provides a considerable and efficient technical tool for simultaneous identification of proteomics and post-translational modification proteomics information.

Integrated microfluidic chip for on-line proteome analysis with combination of denaturing and rapid digestion of protein.

A microfluidic platform based on the integration of denaturation and online immobilized enzyme reactor (IMER) digestion for protein pretreatment was first developed on a glass chip. The design of three inlet channels and two groups of snake channel in glass chip can allow the protein solution, the reducing reagent and the alkylating agent to be simultaneously injected into the chip channel and ensured the reaction solution on-line efficient mixing and sufficient reacting. By thiol-ene click chemistry, the capillary-based and glass chip-based trypsin IMER on the surface of poly(trimethylolpropane trimethacrylate) monolith were fabricated. The wide range of flow rate tolerance (0.8-5.0 µL/min), and the acceptable reproducibility (RSD% = 3.1%, n = 5) and stability (13.8% decrease of enzyme activity in 2 months) indicated the feasibility of using IMER for online digestion of proteins. Compared with the solution denaturation-offline IMER digestion, the integrated microfluidic platform of chip denaturation-chip IMER and chip denaturation-online IMER have comparable protein identification ability for mouse liver protein with a similar number of protein (798 or 826 vs. 843) and unique peptides (3923 or 4593 vs. 3916). More importantly, the easy and fast digestion of protein samples and possible combination with MS revealed that this microfluidic platform can be a potential method for rapid proteomics analysis.

Ultra-high quantum yield ultraviolet fluorescence of graphitic carbon nitride nanosheets.

Graphitic carbon nitride (g-CN) nanosheets (CNNs) with an ultra-high quantum yield (80.1%) ultraviolet fluorescence (FL) were prepared. The effects of the lateral size and the polymerization temperature on the optical properties of CNNs have been studied. The ultraviolet FL was proved to have originated from the isolated melem units according to the density functional theory calculation and mass spectra. The obtained CNNs are further used as a pH probe due to the dependence of the FL signal on the pH of the solution.

Ionic liquid-capped graphene quantum dots as label-free fluorescent probe for direct detection of ferricyanide.

Despite complex molecular and atomic doping, efficient post-functionalization strategies for graphene quantum dots (GQDs) are of key importance to control the physicochemical properties and broaden the practical applications. With ionic liquid as specific modification agents, herein, the preparation of ionic liquid-capped GQDs (IL-GQDs) and its application as label-free fluorescent probe for direct detection of anion were reported. Hydroxyl-functionalized GQDs that could be easily gram-scale synthesized and possessed single-crystalline were chosen as the model GQDs. Also, the most commonly used ionic liquids, water-soluble 1-butyl-3-methyl imidazolium tetrafluoroborate (BMIMBF4) was chosen as the model IL. Under the ultrasonic treatment, BMIMBF4 easily composited with GQDs to form IL-GQDs. The synthesized IL-GQDs were characterized by atomic force microscopy (AFM), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS) and fluorescence (FL) spectrum. After successful combination with IL, the excitation-independent photoluminescence behavior of GQDs presented almost no change, whereas, the anion responsiveness of IL-GQDs drastically improved, which afforded the IL-GQDs a sensitive response to Fe(CN)63-. Based on the strong fluorescence quench, a facile and sensitive detection of Fe(CN)63- was achieved. A wide linear range of 1.0×10-7 to 2.5×10-3moll-1 with a low detection limit of 40 nmol l-1 was obtained. As the composition and properties of IL and GQDs could be easily tuned by varying the structure, ionic liquids-capped GQDs might present promising potential for their applications in sensing and catalysis.