以寡聚组氨酸为配基的高效亲和色谱研究

亲和色谱在所有色谱分离中选择性最高.以组氨酸为配基的亲和介质(Affinitymedia)对免疫球蛋白IgG具有亲和力,显示了良好的分离效果[1];以组氨酸为配基的亲和色谱分离纯化IgG的机理[2]以及组氨酸亲和色谱分离IgG亚基也已有报道[3].组氨酸配基亲和色谱法具有简单、有效和价廉等特点,在免疫化学、临床分析及血液制品的生产等方面均有良好的应用前景.本文分别以含1,3,5个组氨酸残基的小肽为配基,合成了系列亲和介质,并对其亲和色谱行为进行了评价,研究了不同链长的寡聚组氨酸与IgG的亲和相互作用.1　实验部分1.1　固相肽合成　采用Fmoc肽合…     

固载蛋白A交联聚甲基丙烯酸缩水甘油酯连续床亲合色谱柱的制备及性能考察

采用沉淀聚法“原位”（in-situ)聚合合成了交联聚甲基丙烯酸缩水甘油酯连续床色谱柱,对其进行化学改性后,分别得到含有11个碳原子间隔臂以及不含间隔臂键合了蛋白A的高效亲合色谱柱。考察了这两种色谱介质的性能,结果表明含有间隔臂的介质有一定的疏水性;对传统制备蛋白配基的亲合色谱介质的合成路线进行了改进;采用不含间隔臂的亲合柱测定了人血浆中人免疫球蛋白G（HIgG)的含量,所测得的定量标准曲线线性相关系数达到0．999;考察了流速对合成的连续床色谱柱柱压的影响,当流速高达9．0mL/min时,柱压也仅为6．5MPa;采用pH梯度对HIgG的不同亚基进行了分离。     

非极性毛细管电色谱原位柱的阳离子表面活性剂动态修饰

毛细管电色谱是在毛细管中依靠电渗流来驱动流动相 ,同时溶质与固定相发生相互作用的一种色谱分离模式 ,它有高效液相色谱的高选择性 ,同时兼具毛细管电泳的高效性 [1] .传统电色谱柱是将HPLC填料装入毛细管 ,但由于装柱困难且易产生气泡而在一定程度上阻碍了电色谱的发展 [2～ 4 ] .通过柱内合成的方法直接在毛细管中制成连续床毛细管电色谱柱 ,可避免两端烧塞 . 1 995年 Svec等 [5,6]首次将连续床层色谱柱用于毛细管电色谱 ,此后 ,有关毛细管中原位合成连续床电色谱柱的方法得到了应用 [7～ 11] .为了使原位合成电色谱柱能产生电渗流 ,…     

谷胱甘肽亲和色谱介质的制备及对谷胱甘肽硫转移酶蛋白的纯化

融合表达系统能够为目标蛋白质提供一个用于亲和色谱纯化的标签蛋白,同时可以改善目标蛋白质的可溶性等性质,谷胱甘肽S转移酶(GST)融合蛋白表达系统就是其中的一种。然而,该系统纯化所采用的亲和色谱介质的制备技术被国外一些生物制品大公司所垄断。鉴于此,本实验室通过悉心研究,摸索出一套较成熟的亲和色谱介质的制备方法。     

苯二酚异构体的高效液相色谱化学发光检测法研究

高效液相色谱作为一种有效的分离手段已被用于酚类化合物的分析 ,紫外检测法 [1～ 3] 、电化学检测法[3,4 ] 等已用于苯二酚异构体的测定 ,但苯二酚异构体的化学发光检测法尚未见文献报道 .前文 [5] 结果表明 ,苯二酚异构体等对鲁米诺诱导的化学发光具有很强的抑制作用 .基于此 ,本文将高效液相色谱与化学发光技术联用 ,首次建立了苯二酚异构体的高效液相色谱化学发光检测法 .该法灵敏度高 ,选择性好 ,为酚类物质的测定提供了一条新的途径 .1　实验部分1 .1　仪器与试剂　 FIA- 2 4 0 0型流动注射分析仪 (中国科学院信通科学仪器公司 ) ;G…     

基于电化学聚合固定抗体的电化学发光免疫分析法检测人免疫球蛋白

基于电化学聚合在金电极表面固定兔抗人免疫球蛋白G抗体与人免疫球蛋白G及标记有Ru(bpy)2+3 的羊抗人免疫球蛋白G抗体之间发生特异性免疫反应,形成三明治结构,成功建立了用于测定人血清中免疫球蛋白G的电化学发光(ECL)免疫技术.利用此方法测定人免疫球蛋白G含量,浓度在50 μg/L～2 mg/L范围内与电化学发光强度呈良好的线性关系,线性回归方程为y(a. u.)=48.41+0.09x(μg/L) (n=7);检出限为20 μg/L (3σ).测得正常人血清中免疫球蛋白G平均含量为11.2 g/L ,结果令人满意.     

从组合化学肽库中筛选亲和配基

在亲和色谱研究中 ,建立适合于某种分离对象的亲和色谱体系的关键是寻找适合的亲和配基 .小肽亲和配基具有性质稳定、合成简单、价格低及生物相容性好等特点[1] ,但这类配基也存在着亲和力弱或选择性低的缺点 .因此 ,如何寻找小肽配基以及如何提高小肽配基的亲和力和选择性的问题引起了人们的关注与重视 [1～ 3 ] .组合化学法是一种快速制备大量相关或同类化合物的革新性的方法 [4 ] ,组合肽库包括噬菌体展示肽库和合成肽库 ,这两类肽库均可用于小肽配基的筛选与优化 [1,5] .组合化学法尽管有效 ,但以小肽为目的物进行筛选时 ,往往因肽 -肽…     

白蛋白在以染料为配基的醋酸纤维滤棒上的等温吸附行为(英文)

 以醋酸纤维滤棒为基质 ,染料CibacronBlueF3GA为配基 ,合成了一种新的染料亲和介质 ;分别以牛血清白蛋白 (BSA)和人血清白蛋白 (HSA)为对象 ,用静态法进行了吸附实验 ,得到了相应的亲和等温吸附曲线 ;对曲线按Langmuir模型和Freundlich模型分别进行拟合 ;结果表明 ,醋酸纤维滤棒染料亲和介质对BSA和HSA的等温吸附遵循Freundlich模型。采用该亲和介质装柱并分离实际样品人血浆 ,可得到纯化的人血清白蛋白。     

电喷雾质谱动力学方法测定磷酰化丙丙二肽的气相质子亲和能

自 1 98 4年 Yamashita等[1] 提出电喷雾质谱技术 ( ESI-MS)以来 ,它已成为现代生物学研究的重要工具 ,已被用于蛋白 [2 ]和寡聚核苷酸序列 [3 ]的测定、蛋白折叠途径表征 [4 ]、非共轭复合物检测 [5]及酶催化反应的定量研究 [6 ]等 .前文 [7]研究发现 ,氨基酸和小肽的氮端磷酰化使其在快原子轰击质谱和电喷雾质谱正离子模式下峰强明显增强 ,表现出很强的增敏效应 .这一现象可能在蛋白质组学质谱小肽序列的测定中得到应用 .因此 ,阐明其产生机理非常重要 .一个可能的机理是磷酰化基团的引入增加了氨基酸和小肽的气相质子亲和能 ( Proton …     

高分子类型MONOLITH材料的制备技术及其作为亲和色谱固定相用于分离生物大分子的应用

高分子类型MONOLITH材料（也称整体柱,连续床）是近些年来发展迅速的一种新型的以高分子为基质的整体型多孔材料,由于其内部独特的三维连续相互贯通的多孔结构,在诸多应用领域越来越受到研究者的关注,尤其被认为是分离过滤领域的一个历史性突破。与硅基质MONOLITH材料相比,高分子类型的MONOLITH材料具有制备工艺简单、生物相容性好、化学稳定性高和表面化学性质易调控等特点,因此作为亲和色谱的固定相在生物大分子的分离分析上具有更大的优势。本综述重点总结了高分子类型MONOLITH材料的制备方法及其最新研究进展,并论述了近5年来其作为亲和色谱固定相用于分离生物大分子的应用进展。     

应用于全氟辛烷磺酸萃取富集的全氟癸基修饰毛细管硅胶整体柱的制备及应用

利用溶胶-凝胶法,经过烷氧基硅烷的水解、硅羟基的缩聚、凝胶化、陈化、中孔制备、干燥和表面修饰等步骤制备了全氟癸基修饰的毛细管硅胶整体柱。采用该整体柱对全氟辛烷磺酸(PFOS)进行萃取富集,考察其富集特性和效率,并与传统的C18毛细管硅胶整体柱进行对比。结果表明,全氟癸基修饰毛细管硅胶整体柱(15 cm×75 μm)对PFOS具有更高的吸附量和更好的富集选择性,其平均吸附量可以达到75 ng;样品中PFOS的质量浓度为0.25 mg/L时,富集倍数平均可以达到29倍。此全氟癸基修饰毛细管硅胶整体柱对PFOS具有良好的萃取富集性能,可用于水质中痕量PFOS的萃取富集。     

单分散非多孔交联聚甲基丙烯酸环氧丙酯微球作为亲和色谱载体的研究

单分散、非多孔聚甲基丙烯酸环丙酯生球机械强度高,表面的环基易于修饰与键合,非常适宜于生物大分子的快速分离、纯化。对其表面环氧基浓度、非特异性地性能等进行了表征;并以胰蛋白酶抑制剂为配基,制备了胰蛋白酶抑制剂－交联聚甲基丙烯权环氧丙酯亲和色柱,考察了胰蛋白酶等蛋白南的亲和色谱行为,表明该基质适宜用作亲和色谱载体。提出以添加１％乙腈的方法,可有癣地消除此类载体的弱非特异性吸附,使人血清白蛋白的回收率     

蛋白A高效亲和膜色谱法测定人血浆中免疫球蛋白G的含量

 研究了蛋白Ａ高效亲和膜色谱对水溶液及人血浆中人免疫球蛋白Ｇ（ＨＩｇＧ）的特异性吸附和定量测定。方法具有较高的精确度和较好的重复性：ＨＩｇＧ标样５次重复进样的相对标准偏差为１．５％，人血浆样品３次重复进样的相对标准偏差为３．６％；所测得的定量标定曲线的线性相关系数达到０．９９９３；不含己二胺间隔臂的亲和介质的非特异性吸附极低，基本检测不出来。快速实验中，一次分析可在０．５ｍｉｎ内完成。实验表明，利用所建立的方法对人血浆中的ＨＩｇＧ进行定量测定可以得到较为满意的结果。     

On-line concentration of peptides and proteins with the hyphenation of polymer monolithic immobilized metal affinity chromatography and capillary electrophoresis

An iminodiacetic acid (IDA)-type adsorbent is prepared at the one end of a capillary by covalently bonding IDA to the monolithic rods of macroporous poly(glycidyl methacrylate-co-ethylene dimethacrylate). Cu(II) is later introduced to the support via the interaction with IDA. By this means, polymer monolithic immobilized metal affinity chromatography (IMAC) materials are prepared. With such a column, IMAC for on-line concentration and capillary electrophoresis (CE) for the subsequent analysis are hyphenated for the analysis of peptides and proteins. The reproducibility of such a column has been proved good with relative standard deviations (RSDs) of dead time of less than 5% for injection-to-injection and 12% for column-to-column (n = 3). Through application on the analysis of standard peptides and real protein samples, such a technique has shown promising in proteome study.     

Separation of peptides on mixed mode of reversed-phase and ion-exchange capillary electrochromatography with a monolithic column

The mixed mode of reversed phase (RP) and strong cation-exchange (SCX) capillary electrochromatography (CEC) based on a monolithic capillary column has been developed. The capillary monolithic column was prepared by in situ copolymerization of 2-(sulfooxy)ethyl methacrylate (SEMA) and ethylene dimethacrylate (EDMA) in the presence of porogens. The sulfate group provided by the monomer SEMA on the monolithic bed is used for the generation of the electroosmotic flow (EOF) from the anode to the cathode, but at the same time serves as a SCX stationary phase. A mixed-mode (RP/SCX) mechanism for separation of peptides was observed in the monolithic column, comprising hydrophobic and electrostatic interaction as well as electrophoretic migration at a low pH value of mobile phase. A column efficiency of more than 280,000 plates/m for the unretained compound has been obtained on the prepared monoliths. The relative standard deviations observed for t(0) and retention factors of peptides were about 0.32% and less than 0.71% for ten consecutive runs, respectively. Effects of mobile phase compositions on the EOF of the monolithic column and on the separation of peptides were investigated. The selectivity on separation of peptides in the monolithic capillary column could be easily manipulated by varying the mobile phase composition.     

Novel Polymer Monolithic Column for Hydrophilic Compounds

A hydrophilic polymer-based monolithic column was prepared from water-soluble crosslinking agents for liquid chromatography. The column media were prepared with a diacrylate monomer, aqueous polyethylene glycol, methanol, and a water-soluble radical initiator. A fused silica capillary column, which was significantly modified by vinyl groups, was utilized as the outer column in order to control polymer shrinkage. We optimized the modification of the capillary column, composition of the monomer and porogen, and polymerization condition. The optimized column exhibited high hydrophilicity and achieved the baseline separation of nucleobases by using only a buffered solution as the mobile phase. Additionally, another column prepared from binary water-soluble crosslinking agents exhibited lower nonspecific adsorption of several proteins. Basically, we would show the possibility of a new type of polymer monolith prepared from water-soluble crosslinker and water-soluble porogenic solvent, and they can be used for chromatographic separation without non-specific hydrophobic interaction.     

Efficient protein digestion with peptide separation in a micro-device interfaced to electrospray mass spectrometry

A highly efficient protein digestion device has been fabricated using commercially available immobilized trypsin on agarose beads, packed into a silica capillary and connected either directly to an electrospray mass spectrometer via a 'microtight T' connector, from which aqueous acetic acid (0.2%) was pumped, or via a monolithic column connected to the mass spectrometer ion source. Six proteins with molecular mass ranging from 2848 to 77703 Da were digested completely using this system. In the second set of experiments a short monolithic separation column was placed after the immobilized trypsin capillary and partial separation of the generated peptides was obtained. The detection limits were increased from the micromol to pmol range by utilization of this separation column. Gradient elution, using a binary HPLC pump and a flow splitter, was used to optimize the peptide separation. This provided significantly enhanced resolution of the tryptic peptides but increased the analysis time to 30 minutes.     

Multidimensional system enabling deglycosylation of proteins using a capillary reactor with peptide-N-glycosidase F immobilized on a porous polymer monolith and hydrophilic interaction liquid chromatography–mass spectrometry of glycans

A reactor with immobilized peptide-N-glycosidase F on a monolithic polymer support in a capillary has been developed that allows fast and efficient release of N-linked glycans from immunoglobulin G molecules. Two different monolithic scaffolds based on poly(glycidyl methacrylate-co-ethylene dimethacrylate) and poly(butyl methacrylate-co-ethylene dimethacrylate) were prepared. A multistep photografting process was used to reduce non-specific adsorption of proteins and to obtain support containing reactive azlactone functionalities enabling the preparation of highly active immobilized peptide-N-glycosidase F. Performance of these reactors was determined through glycan release from several glycoproteins including ribonuclease B, chicken albumin, and human immunoglobulin G and their detection by matrix-assisted laser desorption-ionization/time-of-flight mass spectrometry. The optimized reactor was integrated into a multidimensional system comprising on-line glycan release and their separation via hydrophilic interaction liquid chromatography followed by electrospray ionization/time-of-flight mass spectrometry detection. Using the optimized monolithic reactor with immobilized peptide-N-glycosidase F, human immunoglobulin G was deglycosylated at room temperature in 5.5 min to an extent similar to that achieved with soluble enzyme after 24 h at 37 °C.