Adsorption Equilibrium and Kinetics of Egg-White Proteins on Immobilized Metal Ion Affinity Gels for Designing Fractionation

Designing an Immobilized Metal ion Affinity (IMA) chromatographic process on large scale demands a thorough understanding to be developed regarding the adsorption behaviour of proteins on metal loaded IMA (IMA-M(II)) gels and the characteristic adsorption parameters to be evaluated. This research investigation illustrates the significance of these aspects for the proposed fractionation of chicken egg-white proteins on these gels. Consequently, a systematic investigation of the adsorption characteristics of three chicken egg-white proteins viz., ovalbumin, conalbumin and lysozyme on Cu(II) and Ni(II) loaded IMA gels, iminodiacetate (IDA) and tris(2-aminoethyl)amine (TREN), has been undertaken. These gels differ in their selectivity towards the proteins of interest under the identical sets of experimental conditions. While TREN-Ni(II) was selective only for lysozyme, IDA-Cu(II), IDA-Ni(II) and TREN-Cu(II) showed varying affinities for all the three proteins. The equilibrium and kinetic data were analysed using various theoretical models and adsorption parameters were quantified. On the basis of these investigations, various strategies have been proposed for the efficient large-scale fractionation of chicken egg-white proteins on these gels.     

Comparison of three methods for fractionation and enrichment of low molecular weight proteins for SELDI-TOF-MS differential analysis

In most diseases, the clinical need for serum/plasma markers has never been so crucial, not only for diagnosis, but also for the selection of the most efficient therapies, as well as exclusion of ineffective or toxic treatment. Due to the high sample complexity, prefractionation is essential for exploring the deep proteome and finding specific markers.In this study, three different sample preparation methods (i.e., highly abundant protein precipitation, restricted access materials (RAM) combined with IMAC chromatography and peptide ligand affinity beads) were investigated in order to select the best fractionation step for further differential proteomic experiments focusing on the LMW proteome (MW inferior to 40,000 Da). Indeed, the aim was not to cover the entire plasma/serum proteome, but to enrich potentially interesting tissue leakage proteins. These three methods were evaluated on their reproducibility, on the SELDI-TOF-MS peptide/protein peaks generated after fractionation and on the information supplied.The studied methods appeared to give complementary information and presented good reproducibility (below 20%). Peptide ligand affinity beads were found to provide efficient depletion of HMW proteins and peak enrichment in protein/peptide profiles.     

Efficient refolding of a hydrophobic protein with multiple S-S bonds by on-resin immobilized metal affinity chromatography

The efficient refolding of recombinant proteins produced in the form of inclusion bodies (IBs) in Escherichia coli still is a complicated experimental problem especially for large hydrophobic highly disulfide-bonded proteins. The aim of this work was to develop highly efficient and simple refolding procedure for such a protein. The recombinant C-terminal fragment of human alpha-fetoprotein (rAFP-Cterm), which has molecular weight of 26 kDa and possesses 6 S-S bonds, was expressed in the form of IBs in E. coli. The C-terminal 7× His tag was introduced to facilitate protein purification and refolding. The refolding procedure of the immobilized protein by immobilized metal chelating chromatography (IMAC) was developed. Such hydrophobic highly disulfide-bonded proteins tend to irreversibly bind to traditionally used agarose-based matrices upon attempted refolding of the immobilized protein. Indeed, the yield of rAFP-Cterm upon its refolding by IMAC on agarose-based matrix was negligible with bulk of the protein irreversibly stacked to the resin. The key has occurred to be using IMAC based on silica matrix. This increased on-resin refolding yield of the target protein from almost 0 to 60% with purity 98%. Compared to dilution refolding of the same protein, the productivity of the developed procedure was two orders higher. There was no need for further purification or concentration of the renatured protein. The usage of silica-based matrix for the refolding of immobilized proteins by IMAC can improve and facilitate the experimental work for difficult-to-refold proteins.     

基于液相色谱-串联质谱技术的磷酸化蛋白质组学分析

本文运用稳定同位素双甲基化标记技术、固定相金属离子螯合层析(IMAC)技术并结合液相色谱-串联质谱法研究了仙台病毒感染引起的宿主细胞磷酸化蛋白质组变化。实验发现定量的4 289个磷酸化肽段有~20%的蛋白质磷酸化位点发生了显著变化;通路富集分析表明哺乳动物雷帕毒素靶蛋白(mTOR)通路和剪接体(Spliceosome)通路可能参与宿主细胞对病毒的应答;通过对显著变化磷酸化肽段进行基序分析,发现了9个代表性的磷酸化修饰位点基序。本研究方法对于深入解析抗病毒天然免疫信号通路提供了新线索。     

Protein digestion and phosphopeptide enrichment on a glass microchip

This work describes an integrated glass microdevice for proteomics, which directly couples proteolysis with affinity selection. Initial results with standard phosphopeptide fragments from β-casein in peptide mixtures showed selective capture of the phosphorylated fragments using immobilized metal affinity chromatography (IMAC) beads packed into a microchannel. Complete selectivity was seen with angiotensin, with capture of only the phosphorylated form. On-chip proteolysis, using immobilized trypsin beads packed into a separate channel, was directly coupled to the phosphopeptide capture and the integrated devices evaluated using β-casein. Captured and eluted fragments were analyzed using both capillary electrophoresis (CE) and capillary liquid chromatography/mass spectrometry (cLC/MS). The results show selective capture of only phosphopeptide fragments, but incomplete digestion of the protein was apparent from multiple peaks in the CE separations. The MS analysis indicated a capture bias on the IMAC column for the tetraphosphorylated peptide fragment over the monophosphorylated fragment. Application to digestion and capture of a serum fraction showed capture of material; however, non-specific binding was evident. Additional work will be required to fully optimize this system, but this work represents a novel sample preparation method, incorporating protein digestion on-line with affinity capture for proteomic applications.     

增强型绿色荧光蛋白的色谱分离和纯化

增强型绿色荧光蛋白(EGFP)是生物领域常用的标记物。在前期成功克隆表达EGFP的基础上,本实验建立了两步分离纯化EGFP的色谱方法,并验证其分离纯化效果,检验EGFP的活性。首先用金属螯合亲和色谱柱HisTrap HP对EGFP的重组菌体破碎上清液进行初步分离,再用葡聚糖凝胶排阻色谱柱Sephadex G-10 HR对其进行脱盐纯化。采用丙烯葡聚糖凝胶排阻色谱柱Sephacryl S-300 HR和十二烷基磺酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE)检测分离纯化后的EGFP纯度。最后通过荧光分光检测器和非变性聚丙烯酰胺凝胶电泳(Native-PAGE)验证分离纯化后的EGFP是否具有荧光活性。结果表明该方法可以简便快速地分离纯化EGFP,纯度超过98%,同时保持了EGFP的荧光活性。     

固定金属离子亲和色谱--蛋白质分离的方法、原理、特性和应用

介绍了固定金属离子亲和色谱法(IMAC)的方法原理、金属螯合柱的制备、固定金属离子与蛋白质的相互作用以及影响这些作用的因素、不同色谱条件下各种作用力对蛋白质保留值的贡献、蛋白质的洗脱原理和IMAC在蛋白质分离纯化中的应用,论述了IMAC的特点、不足、克服的方法和今后应解决的问题。     

基于天冬氨酸的固定化金属离子亲和色谱材料用于磷酸化肽选择性富集

采用点击化学的方法将自然界中的天冬氨酸(aspartic acid)键合到硅球上(命名为Click Asp),并将Fe3+配位到Click Asp上,合成固定金属离子亲和色谱(IMAC)材料(Fe3+-Click Asp);采用红外光谱、X射线电子能谱和扫描电镜等表征证明Fe3+-Click Asp成功合成。将此IMAC材料用于蛋白质酶解液和牛奶中的磷酸化肽的富集,实现了磷酸化肽的高选择性富集。本研究为磷酸化蛋白质组学提供了新材料和新方法。     

High-performance liquid chromatographic fractionation and characterization of fulvic acid

High-performance immobilized metal ion affinity chromatography (HP-IMAC) was used to fractionate humic substances (HS) based on their affinity for the immobilized copper(II) ion using acidic and glycine eluents. The work was carried out with two naturally occurring aqueous fulvic acids and commercially available Suwannee River fulvic acid. The IMAC-fractionated HS were then characterized by reversed-phase high-performance liquid chromatography (RP-HPLC) and size exclusion chromatography. The results showed that the affinity HS fraction eluted first using an acidic pH=2 eluent exhibited a relatively high hydrophilic character, whereas the fraction eluted later using a glycine eluent exhibited both a higher hydrophobic character and larger molecular size. On the other hand, the HS fraction with no affinity for the immobilized copper had low molecular size. The affinity of the HS fraction for copper(II) increased with increasing molecular weight. Based on the composite results of three different HS, it is evident that strong relationships exist between affinity, molecular weight, and hydrophilic/hydrophobic properties during the HP-IMAC fractionation. The results presented here have significance for understanding the nature of chemical interactions at the molecular level between dissolved organic matter and trace metals. IMAC, coupled with other liquid chromatographic strategies, is a promising tool for chemical fractionation and characterization of HS.     

Molecular Dynamics Simulations of Metal Ion Binding to the His‐tag Motif

In our previous study, we have observed that the chelation of various metal ions to the His‐tag motifs mostly involves the i and i+2 His residues for Ni²⁺, Cu²⁺, Zn²⁺ and Co²+. In the present study, various 200 ps molecular dynamics simulations were further conducted to investigate the chelating pathway of various metal ions to the His‐tag motif with 6 His residues (His‐tag6) and the binding affinities of these metal binding pockets towards these metal ions. The results indicate that His‐tag6 with the chelated metal ion located in positions His(2,4) or His(3,5) exhibits the strongest affinity for Ni²+ and Cu²+.K⁺ was found to be preferred to chelate in His(1,3) and His(3,5) coordinations. However, Fe³+ was found to have higher affinity towards His(1,3) and His(2,4) binding pockets. Our results also suggest that Ni²⁺ exhibits the highest binding affinity towards His‐tag6 over the other metal ions. Most of the structural variations of the His‐tag6 motif were from the Histidyl side chains during metal ion binding. In addition, there is an inverse linear correlation between the final chelated distance and the charge/volume ratio of metal ion. There is a negative correlation between the metal binding affinity and the averaged potential energy generated from the MD simulations.