单分散大孔亲水弱阳离子交换填料的制备及其对鱼精蛋白的分离纯化

以自制的5.0 μm单分散大孔亲水交联聚甲基丙烯酸环氧丙酯(PGMA/EDMA)微球为基质,对其表面进行化学改性,合成弱阳离子交换色谱填料(WCX)。详细考察了该填料对标准蛋白质的分离性能、表面亲水性能、稳定性和重现性以及流速对蛋白保留的影响。实验结果表明,该色谱填料对蛋白的分离性能、重现性及稳定性良好;在流速为3 mL/min时,采用线性梯度洗脱,6 min内可分离4种标准碱性蛋白质,以溶菌酶测定的该填料的动力学吸附容量为29.86 mg/g。将其用于鱼精蛋白的分离纯化,经反相高效液相色谱测定纯化后鱼精蛋白的纯度为99.2%;与商品Shodex IEC SP-825强阳离子交换色谱柱比较,纯化结果几乎一样。     

Synthesis of Monodisperse Poly（glycidylmethacrylate-co-ethylene dimethacrylate） Beads and Their Application in Separation of Biopolymers

Introduction Since 19541 the polymeric separation media has attracted much attention due to their chemical stability over the entire pH range. The rigid, highly cross-linked styrene copolymers were first used for chromatography by Moore.2 The macroporous copolymers currently available are not only chemically stable but also more resistant to mechanical forces prevailing in a column and therefore are comparable to the traditional packings based on silica gel. Most polymer separation media are …     

高温二维液相色谱系统的构建及其评价

在二维液相色谱中, 第二维的分离速度是制约其发展的重要因素. 升高色谱柱温度可以有效降低流动相粘度, 加快溶质在两相间的传质速率, 有效加快分析速度. 以离子交换色谱法(WAX)为第一维分离模式和反相色谱法(RP)为第二维分离模式, 十通阀和两个捕集柱为接口, 通过将第二维色谱柱温度升高到80 ℃和提高流量到3 mL/min, 构建了高温WAX/RP二维液相色谱系统. 以4种标准蛋白的酶解物为样品评价系统的分离性能, 第一维共有33个馏分被捕集并导入到第二维分析, 高温二维液相色谱系统识别出187个色谱峰.     

Preparation of High‐capacity,Monodisperse Polymeric Weak Cation Exchange Packings Using Surface‐initiated Atom Transfer Radical Polymerization and Its Chromatographic Properties

A novel stationary phase for weak cation exchange (WCX) chromatography was prepared by "grafting from" strategy. Surface initiated atom transfer radical polymerization (ATRP) of acrylic acid (AA) was conducted in toluene medium, starting from the macromolecule initiators of poly(4‐vinylbenzyl chloride‐co‐divinylbenzene) (P_CMS/DVB) beads. The amounts of poly(acrylic acid) grafted chains with different ATRP formulations were calculated based on the elemental analyses. The poly(acrylic acid) grafted beads obtained with different ATRP formulations were tried as chromatographic packings in the separation of proteins by ion‐exchange chromatography. The effect of the poly(acrylic acid) grafted chain lengths on P_CMS/DVB beads for the separation of proteins was investigated in details. Simultaneously, characterization of the column was investigated as ion chromatographic stationary phase for the separation of inorganic cations. The results show that poly(acrylic acid) grafted columns had excellent performance for separation of proteins and inorganic cations. The highest of the dynamic capacity of the column was 35.55 mg/mL. The columns were provided with high column efficiency.     

Preparation and characterization of a novel dual‐retention mechanism mixed‐mode stationary phase with PEG 400 and succinic anhydride as ligand for protein separation in WCX and HIC modes

A novel dual‐retention mechanism mixed‐mode stationary phase based on silica gel functionalized with PEG 400 and succinic anhydride as the ligand was prepared and characterized by infrared spectra and elemental analysis. Because of the ligand containing PEG 400 and carboxyl function groups, it displayed hydrophobic interaction chromatography (HIC) characteristic in a high‐salt‐concentration mobile phase, and weak cation exchange chromatography (WCX) characteristic in a low‐salt‐concentration mobile phase. As a result, it can be employed to separate proteins with both WCX and HIC modes. The resolution and selectivity of the stationary phase was evaluated under both HIC and WCX modes with protein standards, and its performance was comparable to that of conventional ion‐exchange chromatography and HIC columns. The results indicated that the novel dual‐retention mechanism column, in many cases, could replace two individual WCX and HIC columns as a ‘2D column’. In addition, the mixed retention mechanism of proteins on this ‘2D column’ was investigated with stoichiometric displacement theory for retention of solute in liquid chromatography in detail in order to understand why the dual‐retention mechanism column has high resolution and selectivity for protein separation under WCX and HIC modes, respectively. Based on this ‘2D column’, a new 2DLC technology with a single column was developed. It is very important in proteome research and recombinant protein drug production to save column expense and simplify the processes in biotechnology. Copyright © 2013 John Wiley & Sons, Ltd.     

Synthesis of non-porous poly(glycidylmethacrylate-co-ethylenedimethacrylate) beads and their application in separation of biopolymers

The monodisperse, 5.0 μm non-porous poly(glycidylmethacrylate-co-ethylenedimethacrylate) (P_GMA/EDMA) beads were prepared by a single-step swelling and polymerization method. The seed particles prepared by dispersion polymerization exhibited good absorption of the monomer phase. Based on this media, a weak cation exchange (WCX) stationary phase for high performance liquid chromatography (HPLC) was synthesized by a new chemical modification method. The prepared resin has advantages of biopolymer separation, high column efficiency, low column backpressure, high protein mass recovery and good resolution for proteins. The measured bioactivity recovery for lysozyme was 97 ± 5%. The dynamic protein loading capacity of the synthesized WCX packings was 20.5 mg/g. Four proteins were completely separated in 3.0 min using the synthesized WCX stationary phase. The experimental results show that the obtained WCX resin has very weak hydrophobicity. The WCX resin was also used for the rapid separation and purification of lysozyme from egg white in 3.0 min with only one step. The purity and specific bioactivity of the purified lysozyme was found more than 95% and 70.264 IU/mg, respectively.     

高效阳离子交换法分离纯化蛋清中的溶菌酶

 建立了用高效阳离子交换分离纯化蛋清中溶菌酶的新方法 ,讨论了纯化的工艺条件。蛋清样品匀浆后 ,用氯化钠初步纯化 ,然后用弱阳离子交换柱XIDACE WCX分离。结果表明 ,被纯化的溶菌酶和杂蛋白得到很好分离。经活性检测 ,溶菌酶过柱后的活性回收率为 10 7% ,蛋白的比活为 15 4 6 7U/mg ,纯化倍数提高了 5 6倍。用尺寸排阻 (SEC)鉴定 ,得到的溶菌酶呈均一性。该法较传统软基质低压离子交换分离速度快 ,纯化效率高。     

单分散树脂基质的弱阳离子交换色谱固定相的制备及其在生物大分子分离中的应用研究

采用分散聚合法制备种子和“一步种子溶胀聚合法”制备了粒径为6~15 μm的单分散多孔氯甲基苯乙烯-二乙烯苯微球。该微球经化学改性后得到一种亲水性良好的新型高效弱阳离子交换色谱固定相。详细考察了该固定相的表面亲水性、对标准蛋白的分离性能和盐的种类对蛋白质保留行为的影响。考察结果表明该固定相是一种性能优异的弱阳离子交换色谱固定相。将其应用于鸡蛋清中溶菌酶的快速分离纯化,纯化后的溶菌酶纯度高于96%,比活高达71184 U/mg。     

强阳离子交换色谱分离多肽混合物的条件优化

以酵母全蛋白提取液的胰蛋白酶切产物为研究对象,对多维色谱分离中常用的强阳离子交换色谱的分离条件,包括上样量、盐的种类、调节缓冲液pH值的酸的种类及有机溶剂的比例进行了考察和比较。结果表明,在强阳离子交换色谱分离线性上样量范围内,在氯化铵溶液作为流动相,用磷酸调节流动相缓冲液pH值至2.7,且流动相中乙腈的体积分数为30%条件下进行梯度洗脱时,可获得最佳的分离结果。本结果可为采用二维色谱-质谱策略分析多肽混合物时的第一维强阳离子交换色谱分离条件的选择提供有益的参考。     

Chromatographic properties of zirconia-based stationary phases for ion exchange chromatography having surface bound cationic functions

A series of non-porous, microspherical zirconia-based stationary phases with surface bound cationic functions have been introduced and evaluated in ion exchange chromatography of proteins and small acidic solutes. Different surface modification procedures were evaluated in the covalent attachment of weak, strong or hybrid anion exchange moieties on the surface of non-porous zirconia micropar-ticles. N,N-Diethylaminoethanol (DEAE) was used as the weak anion exchange ligand while glycidyltrimethylammonium chloride, which was covalently attached to poly(vinyl alcohol) layer (PVAN) on the zirconia surface, constituted the strong anion exchange moiety. Partially quaternarized poly(ethyleneimine) hydroxyethylated (PEI) was used as the hybrid type of anion exchange coating. DEAE-zir-conia microparticles acted as purely cation exchange stationary phases toward basic proteins indicating the predominance of electron donor-electron acceptor interaction (EDA) with surface exposed zirconium sites as well as cation exchange mechanism via electrostatic interaction with unreacted and unshielded hydroxyl groups. PVAN-zirconia stationary phase exhibited anion exchange chromatographic properties toward acidic proteins, but EDA interaction has stayed as an important contributor to solute retention despite the presence of a relatively thick layer of poly(vinyl alcohol) on the surface of the zirconia particles. The modification of zirconia surface with partially quaternarized PEI proved to be the most effective approach to minimize Lewis acidic metallic properties of the support. In fact, PEI-zirconia stationary phase operated as an anion exchanger toward acidic proteins and other small acidic solutes.     

“Click chemistry” preparation of WCX packings for protein separation

Click chemistry was applied to immobilize three kinds of alkyne-carboxylic acids onto azide-modified silica gel to prepare three novel stationary phases for weak cation exchange chromatography(WCX).The developed protocol combines the benefits of operational simplicity,exceptionally mild conditions and high surface loadings.Six kinds of standard proteins were separated completely on the novel packings.Compared with commercial WCX columns,the three kinds of novel WCX packings prepared by click chemistry approach have better resolution and selectivity.Lysozyme was purified successfully from egg white with the novel WCX column by one step.The purity was more than 97%and a high specific activity was achieved to be 81,435 U/mg.The results illustrate the potential of click chemistry for preparation of stationary phase for IEC.     

Preparation of a weak anion exchange/hydrophobic interaction dual‐function mixed‐mode chromatography stationary phase for protein separation using click chemistry

In this study, 3‐diethylamino‐1‐propyne was covalently bonded to the azide‐silica by a click reaction to obtain a novel dual‐function mixed‐mode chromatography stationary phase for protein separation with a ligand containing tertiary amine and two ethyl groups capable of electrostatic and hydrophobic interaction functionalities, which can display hydrophobic interaction chromatography character in a high‐salt‐concentration mobile phase and weak anion exchange character in a low‐salt‐concentration mobile phase employed for protein separation. As a result, it can be employed to separate proteins with weak anion exchange and hydrophobic interaction modes, respectively. The resolution and selectivity of the stationary phase were evaluated in both hydrophobic interaction and ion exchange modes with standard proteins, respectively, which can be comparable to that of conventional weak anion exchange and hydrophobic interaction chromatography columns. Therefore, the synthesized weak anion exchange/hydrophobic interaction dual‐function mixed‐mode chromatography column can be used to replace two corresponding conventional weak anion exchange and hydrophobic interaction chromatography columns to separate proteins. Based on this mixed‐mode chromatography stationary phase, a new off‐line two‐dimensional liquid chromatography technology using only a single dual‐function mixed‐mode chromatography column was developed. Nine kinds of tested proteins can be separated completely using the developed method within 2.0 h.     

IEX/RP二维液相色谱中弱保留组分收集模式的构建及系统评价

以十通阀和捕集柱接口形式,构建了弱阴离子交换/反相(WAX/RP)二维液相色谱分离系统.通过将第一维离子交换色谱分析中的前部集中洗脱出的弱保留组分收集后单独分析,剩余样品进一步采用二维液相色谱分析,可以有效避免第二维色谱柱对特殊样品局部集中流出导致的第二维分离超柱容量问题,提高了系统的整体分离能力.使用4种蛋白胰蛋白酶酶解后的多肽样品评价该系统,在不分流的系统中共检测到115个峰.对第一维分离的前15 min分流后得到的组分单独分析,共识别出58个峰,后续的二维分离中共得到78个峰.2种方法相比,第二种方法检测峰数增加了21个,一些低丰度的组分在弱保留组分收集后被识别.     

Online capillary weak cation exchange enrichment hyphenated to nanospray mass spectrometry for quantitation of a basic pegvisomant derived peptide

A multidimensional LC–MS/MS configuration is described for targeted quantitation of a highly basic peptide chemically derived from pegvisomant as a surrogate for the intact protein. The method developed for an immunogenicity assay employed orthogonal separation of the target peptide commencing with flowing microgram quantities of total digests from a protein G extraction of human serum through a weak cation exchange (WCX) monolithic trap column. The basic peptide of interest was retained on the WCX column. Following a washing procedure, peptides were eluted with acetic acid and retained on a down-stream reverse phase trap compatible with online nanoflow LC–MS/MS. Such a LC configuration including the use of other sorbents such as strong cation exchange media is proposed as an enabling tool in assay development for quantitative protein bioanalysis by LC–MS/MS.     

On-Line multitasking analytical proteomics: how to separate, reduce, alkylate and digest whole proteins in an on-Line multidimensional chromatography system coupled to MS

An on-Line multidimensional system has been developed, consisting of pH gradient strong anion exchange chromatography of native proteins in the first dimension with subsequent trapping and on-column reduction/alkylation on C4 trap columns and RP separation of the alkylated proteins in the second dimension followed by on-column tryptic digestion and electrospray MS detection. The system was evaluated using model proteins and a human urine sample. Compared to the commonly used in-solution alkylation method, the developed on-column method provides an equivalent efficiency. The recovery from the C4 trap columns of the alkylated proteins relative to the native state was from 94 to 102%. On-column tryptic digestion was satisfactory for many, but not for all proteins. The whole analytical procedure was performed on-Line with packed capillary columns for a total time of 320 min for the first ion exchange fraction, with additional 60 min for each subsequent fraction.     

Cation exchange/hydrophobic interaction monolithic chromatography of small molecules and proteins by nano liquid chromatography†

In this study, vinyl phenyl boronic acid modified lauryl methacrylate‐based monolithic column was successfully prepared for cation exchange/hydrophobic interaction monolithic chromatography of small molecules and proteins in nano LC. The polymeric mixture consisted of lauryl methacrylate, vinyl phenyl boronic acid as cation exchanger, ethylene dimethacrylate as cross‐linker, polyethylene glycol and methanol as binary porogenic solvent, and azobisisobutyronitrile as initiator. The resulting monolith showed good permeability and mechanical stability. Different ratios of monomer and porogens were used for optimizing the properties of the column. The monolithic column performance with respect to hydrophobic and cation exchange interactions was assessed by the separation a series of alkyl benzenes and anilines, respectively. cis‐Diol‐containing compounds such as phenols were also utilized to evaluate the retention behaviors of the vinyl phenyl boronic acid modified monolithic column. The monolithic column showed cation exchange interactions in the separation of aniline compounds. Theoretical plate number up to 52 000 plates/m was successfully achieved. The prepared monolith was further applied to the proteins with different acetonitrile content.     

Synthesis of monodisperse poly(chloromethylstyrene-co-divinylbenzene) beads and their application in separation of biopolymers

The monodisperse, porous poly(chloromethylstyrene-co-divinylbenzene) beads of 7.9 microm were prepared by a single-step swelling and polymerization method. The seed particles prepared by dispersion polymerization exhibited good absorption of the monomer phase. Based on this media, a weak cation-exchange (WCX) stationary phase for HPLC was synthesized by a new chemically modified method. The prepared resin has advantages of biopolymer separation, high column efficiency, low column backpressure, high protein mass recovery, and good resolution for proteins. The dynamic protein-loading capacity of the synthesized WCX packings was 18.2 mg/g. Five proteins were separated in 3.0 min using the synthesized WCX stationary phase. The experimental results show that the obtained WCX resin has very weak hydrophobicity. The WCX resin was also used for the rapid separation and purification of lysozyme from egg white in 5.0 min with only one step. The purity and specific bioactivity of the purified lysozyme were found to be more than 93% and 70 245 U/mg, respectively.     

Preparation of weak cation exchange packings for chromatographic separation of proteins using "click chemistry'

"Click chemistry" is defined as a class of robust and selective chemical reactions affording high yields and is tolerant to a variety of solvents (including water), functional groups, and air. In this study, click chemistry was used as an effective strategy for coupling three alkyne-carboxylic acids onto the azide-silica to obtain three novel stationary phases of weak cation exchange chromatography, which were characterized with FTIR and elemental analysis. Six kinds of standard proteins, such as myoglobin, RNase A, RNase B, cytochrome C, α-chymotrypsin A, and lysozyme, were separated completely with the three novel weak cation exchange chromatography stationary phases. Compared with commercial weak cation exchange chromatography columns, the three kinds of novel weak cation exchange chromatography packings prepared by click chemistry approach have better resolution and selectivity. The mass recovery of more than 97% was obtained for all the tested proteins, and the bioactivity recovery of lysozyme on the prepared column was determined to be 96%. In addition, lysozyme was purified successfully from egg white with the novel weak cation exchange chromatography column by one step. The purity was more than 97% and a high specific activity was achieved to be 81 435 U/mg. The results illustrate the potential of click chemistry for preparing stationary phase for ion-exchange chromatography.     

Refolding of reduced/denatured bovine pancreatic insulin with ion-exchange chromatography coupled with MALDI-TOF MS

The refolding of the reduced/denatured insulin from bovine pancreas as the model protein was investigated with weak anion exchange chromatography(WAX) coupled with MALDI-TOF MS.The results indicated that the disulfide bonds almost cannot be formed correctly with the common mobile phase by WAX.However,with the urea gradient elution and in the presence of GSSG/ Cyst as the ratio 1:6 in the mobile phase employed,the disulfide exchange of reduced/denatured insulin can be accelerated resulting in forming the ...     

Preparation of weak cation exchange packings based on monodisperse poly(chloromethylstyrene‐co‐divinylbenzene) particles and its chromatographic properties

Monodisperse poly (chloromethylstyrene‐co‐divinylbenzene) particles were firstly prepared by a two‐step swelling method. Based on this media, one kind of weak cation ion exchange packings was prepared. It was demonstrated that the prepared packings have comparative advantages for biopolymer separation with high column efficiency, low interstitial volume and low column backpressure, and have good resolution to proteins. The effects of salt concentration and pH of mobile phase on protein retentions were investigated. The properties of the weak cation ion exchange packings were evaluated by the unified retention model for mixed‐mode interaction mechanism in ion exchange and hydrophobic interaction chromatography.