共价有机骨架功能材料及其在糖肽选择性富集中的应用

蛋白质糖基化是生物体中最重要的翻译后修饰手段之一,糖蛋白/糖肽的有效分离和富集成为目前糖蛋白组学研究的首要问题.对于复杂的生物样本,糖蛋白的数量较少,酶解后大量高丰度非糖基化修饰肽的存在,使得低丰度糖肽的检测更加困难.因此,需要一些手段来有效地富集糖肽以提高其检测丰度,发展高选择性的糖肽富集材料及方法就成为在分子水平上...     

半胱氨酸基麦芽糖修饰亲水硅胶的制备及其对糖肽的富集

糖蛋白与糖肽在复杂生物体系中丰度一般较低,为了在糖蛋白质组学研究中深入和全面分析鉴定糖基化位点与糖链,通常需要进行富集前处理操作。该文设计并合成了一种半胱氨酸基麦芽糖修饰亲水硅胶分离介质(Cys-Mal@SiO_2),将其装填入固相萃取柱中制备新型亲水固相萃取柱。在以人免疫球蛋白G酶解液为样品进行富集鉴定时,Cys-Mal@SiO_2鉴定糖肽的质谱信号强度和信噪比比半胱氨酸修饰硅胶(Cys@SiO_2)、麦芽糖修饰硅胶(Mal@SiO_2)和商品化ZIC-HILIC更高。在复杂的鼠肝蛋白质提取物的糖蛋白质组学分析中,Cys-Mal@SiO_2共鉴定出1 551条糖肽,属于466个糖蛋白的906个N-糖基化位点,比Cys@SiO_2和Mal@SiO_2鉴定糖肽数、蛋白质数和N-糖基化位点数分别多211、67、127个和289、76、193个。将Cys-Mal@SiO_2成功应用于低丰度糖肽的选择性富集与鉴定,在糖蛋白质组学研究中体现出良好的应用潜力。     

氧化石墨烯固定化凝集素的制备及在糖蛋白/糖肽富集中的应用

生物体内蛋白质的糖基化修饰调控着细胞识别、细胞黏附和迁移以及免疫应答等多种生理过程,并与多种人类重大疾病的发生、发展密切相关。因此对蛋白质糖基化修饰的鉴定,不仅能够为生物学机理研究提供重要信息,对疾病诊断标志物和治疗靶标的发现也至关重要。然而在复杂生物体系中,大多数糖蛋白为低丰度蛋白质,其含量与现有质谱仪器的检测灵敏度之间存在较大差距,所以对含有不同糖型结构的糖蛋白进行全面/高效的富集,是实现高灵敏度糖蛋白鉴定的必由之路。凝集素富集作为一种有效的糖蛋白富集方法,已在糖蛋白质组学研究中得到了广泛的应用。针对现有凝集素功能化材料存在负载量偏低以及富集效率有限等问题,我们制备了两种以氧化石墨烯(GO)为载体的新型固定化凝集素,利用GO比表面积大,功能基团含量高,分散性、化学稳定性好等特点,实现了高负载量的凝集素固定(GO-ConA 2.073 mg/mg, RSD=1.0%; GO-WGA 1.908 mg/mg, RSD=0.14%)。同时考察了材料的可重复使用性与稳定性:每隔3天测一次同一GO-lectin材料对对应糖蛋白的富集效果,可以看出材料合成两周内富集效果都>200 μg/mg。将该GO-lectin成功应用于糖蛋白、糖肽的选择性富集,在糖蛋白质组学研究中体现出良好的应用潜力。     

基于ConA富集和LTQ-FT质谱鉴定的小鼠肝脏内质网N-糖蛋白质组研究

糖基化修饰是生物体内复杂和重要的蛋白质翻译后修饰方式之一.N-糖基化蛋白质在内质网中进行合成的过程中,所有的N-糖链都以甘露糖和葡萄糖结尾,而凝集素ConA对以甘露糖结尾的糖链有较高的亲和性,可以用来富集在内质网中合成的N-糖蛋白质.本文据此提出了一种基于内质网分离和凝集素ConA富集的复杂样品N-糖基化位点研究策略.通过使用高准确度的质谱线性离子阱-傅立叶变换回旋离子共振质谱对N-糖蛋白质进行鉴定,并对N-糖基化位点进行确定.我们采用模式生物C57BL/6J肝脏作为生物样本,在生物水平和质谱水平分别进行了3次重复,共鉴定了212个N-糖蛋白质的323个N-糖基化位点.在这些蛋白中,131个是Swissprot库中已确认的N-糖蛋白质.此方法富集的糖蛋白,糖型统一,有利于样品的分离和PNGaseF酶切作用,提高了鉴定的效率.对鉴定的212个N-糖蛋白质的定位和功能进行了分析,本文鉴定的N-糖蛋白质对现有的鼠肝N-糖蛋白质数据库进行了有效的补充.     

基于固相萃取的微量糖蛋白糖基化修饰表征技术的建立

结合自制亲水固相萃取富集柱和生物质谱鉴定技术,实现了糖基化蛋白质核糖核酸酶B的糖含量测定、糖基化位点确认、聚糖富集及结构表征,以及不同糖型相对丰度分析。结果表明:其糖含量8.47%,糖基化位点为34位的Asn,糖链主要为5种高甘露糖型结构(Man5-9GlcNAc2)。所建立的HILIC富集技术,有利于针对微量生物样本,如生物工程药物糖蛋白及重要功能糖蛋白,开展位点特异性糖链结构解析,为糖蛋白质的药效或功能研究提供线索。     

功能化磁性纳米材料在糖蛋白及糖肽富集中的研究进展

蛋白质糖基化作为最重要的翻译后修饰之一,在生物体诸如细胞信号转导、蛋白质翻译调控、免疫应答等诸多生命过程中发挥重要作用。此外,蛋白质的异常糖基化还与肿瘤等疾病的发生发展密切相关,这为以糖蛋白为目标的疾病生物标志物的发现提供了可能。尽管质谱已经成为糖蛋白质组学的重要分析工具,但糖肽的低丰度和低电离效率使得其直接质谱分析仍面临挑战。在糖蛋白质组学研究中,从复杂的生物样品中富集糖蛋白和糖肽是重要的环节。磁性固相萃取(MSPE)是一种操作简单、成本低和萃取效率高的样品预处理方法。在磁性固相萃取中,磁性吸附剂是影响萃取效果的关键,将功能化磁性纳米材料作为吸附剂进行糖蛋白质组学研究已经得到广泛应用。该文综述了糖分子、离子液体、凝集素、硼酸亲和配体、金属有机框架、共价有机骨架等功能化磁性纳米材料的制备及其在糖蛋白及糖肽富集中的应用。上述功能化磁性纳米材料具有高比表面积、大量作用位点等特点,其富集机理包括亲水相互作用色谱、凝集素亲和作用色谱、硼酸化学法和肼化学法等,主要应用于血清、血浆、细胞、组织、唾液等样品的糖蛋白和糖肽的富集。该文引用了近十年来发表的约90篇源于科学引文索引(SCI)与中文核心期刊的相关论文,并于文末对磁性纳米材料在糖蛋白和糖肽富集领域的发展趋势进行了展望。     

新型核壳型亲水聚合物-硅胶杂化填料的合成及其在蛋白质N-糖链富集中的应用

蛋白质的N-糖基化修饰与多种重要的生理、病理进程密切相关,是多种重大疾病诊断标志物研究的热点。由于糖蛋白本身多是低丰度表达的蛋白质,且糖链结构具有高度微不均一性,这使得蛋白质糖基化修饰的分析具有一定的挑战。本研究利用表面引发-原子转移自由基聚合(SI-ATRP)法,以带有双键的氨基葡萄糖为单体(GMAG),成功制备了新型核壳型亲水聚合物-硅胶杂化填料(pGMAG-SiO₂)。由于在硅胶表面引入致密的亲水聚合物层,该填料不仅保持了硅胶良好的机械强度,而且显著提高了其亲水性,因此非常适合作为亲水填料用于蛋白质的N-糖链富集。以麦芽七糖和鸡卵清蛋白的N-糖链为研究对象,考察了该填料对N-糖链的富集效果,并将该杂化填料成功用于人血浆中糖蛋白N-糖链的富集检测,共鉴定了47种糖型。以上结果表明,pGMAG-SiO₂填料对N-糖链具有较高的亲和性,可以用于N-糖链的高覆盖率鉴定。     

糖组学研究中糖蛋白糖链结构分析技术

遗传信息由DNA传递至蛋白质,再经蛋白质翻译后糖基化修饰形成糖蛋白.与DNA、蛋白质相比,糖蛋白糖链结构更加多样,功能更加复杂,在一些重大的生理、病理事件中发挥着重要调节作用;而糖链如此复杂的功能是由其多样的结构决定的,糖链结构是糖组学研究的重要内容.本文就近年来糖组学研究中糖蛋白样品的提取分离、糖链释放及结构分析的基本方法及相关技术进展作了简要介绍.     

完整糖基化肽段的富集与质谱解析新技术研究进展

蛋白质糖基化是生物体内最重要的翻译后修饰之一,在蛋白质稳定性、细胞内和细胞间信号转导、激素活化或失活和免疫调节等生理过程和病理进程中发挥重要作用。而异常的蛋白质糖基化往往和多种疾病的发生发展密切相关,目前应用于临床检测的多种肿瘤生物标志物大多属于糖蛋白或者糖抗原。因此在组学层次系统分析蛋白质糖基化的变化对阐明生物体内糖基化修饰的调控机理和发现新型疾病标志物都非常重要。基于质谱的蛋白质组学技术为全面分析蛋白质及其修饰提供了有效的分析手段。在自下而上的蛋白质组学研究中,由于完整糖基化肽段同时存在性质各异的肽段骨架和糖链结构、糖肽的相对丰度和离子化效率较低以及糖基化修饰有高度异质性等特点,完整糖肽的分析比其他翻译后修饰更加困难。近年来,为了更全面、系统地分析蛋白质糖基化,研究人员发展了一些新技术,包括完整糖肽的富集技术、质谱的碎裂模式和数据采集模式、质谱数据的解析方法和定量策略等等,大力推进了该领域的研究水平,也为研究蛋白质糖基化相关的生物标志物提供了技术支持。该篇综述主要关注近年来基于质谱的糖蛋白质组学研究中的新进展,重点介绍针对完整N-和O-糖基化肽段的富集新技术和谱图解析新方法,并讨论其在肿瘤早期诊断方面的应用潜力。     

基于质谱的糖蛋白/糖链定量技术研究进展

糖基化修饰是一种重要的蛋白质翻译后修饰。糖基化修饰的蛋白质在生命体内具有重要的生物学功能。研究糖蛋白含量以及蛋白上糖链变化对于阐明糖基化修饰的功能具有重要的意义,也是当今的研究热点。本文就糖蛋白和糖链定量方法的研究进展和应用做了简要概述。     

Affinity monolithic capillary columns for glycomics/proteomics: 1. Polymethacrylate monoliths with immobilized lectins for glycoprotein separation by affinity capillary electrochromatography and affinity nano-liquid chromatography in either a single column or columns coupled in series

In this report, microcolumn separation schemes involving monolithic capillary columns with immobilized lectins, and relevant to nanoglycomics/nanoproteomics were introduced. Positive and neutral monoliths based on poly(glycidyl methacrylate-co-ethylene dimethacrylate) were designed for achieving lectin affinity chromatography (LAC) by nano-LC and CEC. The positive monoliths (i.e., monoliths with cationic sites) afforded relatively high permeability in nano-LC but lack predictable EOF magnitude and direction, while neutral monoliths provided a good compromise between reasonable permeability in nano-LC and predictable EOF in CEC. Lectin affinity nano-LC permitted the enrichment of classes of different glycoproteins having similar N-glycans recognized by the immobilized lectin, whereas lectin affinity CEC provided the simultaneous capturing and separation of different glycoproteins due to differences in charge-to-mass ratio. Also, this investigation demonstrated for the first time the coupling of lectin capillary columns in series (i.e., tandem columns) for enhanced separation of glycoproteins by LAC using the CEC modality. Furthermore, in the coupled columns format, glycoforms of a given glycoprotein were readily separated.     

Synthesis and application of a macroporous boronate affinity monolithic column using a metal-organic gel as a porogenic template for the specific capture of glycoproteins

A macroporous boronate affinity monolithic column was prepared and applied to specifically capture glycoproteins using metal-organic gels (MOGs) as a porogenic template. This newly explored application of MOGs has proven to be a more convenient method for the formation of macropores in contrast to traditional porogenic methods. The poly (3-acrylamidophenylboronic acid-co-ethylene dimethacrylate) monolithic columns were synthesized in stainless columns by in situ polymerization. To fabricate the macroporous formation with a uniformed open-channel network, the preparation conditions, such as reaction temperature, the concentration of the MOGs and the ratio of monomers were systematically investigated. The prepared macroporous monoliths were characterized by scanning electron microscope (SEM) and mercury intrusion porosimetry. Furthermore, horseradish peroxidase (HRP) and transferrin (TF) were chosen as test glycoproteins, and the chromatographic analysis demonstrated that the macroporous boronate affinity monoliths exhibited a higher selectivity and better dynamic binding capacity toward glycoproteins compared with non-glycoproteins. The resulted affinity monolithic column was successfully employed to specifically capture TF from a bovine serum sample.     

One-pot synthesis of an organic-inorganic hybrid affinity monolithic column for specific capture of glycoproteins

An inorganic-organic hybrid affinity monolithic column was synthesized by a novel "one-pot" approach. The resulting hybrid affinity monoliths have potential applications in specific recognition and enrichment of glycoproteins.     

Affinity chromatography with monolithic capillary columns. II. Polymethacrylate monoliths with immobilized lectins for the separation of glycoconjugates by nano-liquid affinity chromatography

Monolithic capillary columns with surface bound lectin affinity ligands were introduced for performing lectin affinity chromatography (LAC) by nano-liquid chromatography (nano-LC). Two kinds of polymethacrylate monoliths were prepared, namely poly(glycidyl methacrylateco-ethylene dimethacrylate) and poly(glycidyl methacrylate-co-ethylene dimethacrylate-co-[2-(methacryloyloxy)ethyl]trimethyl ammonium chloride) to yield neutral and cationic macroporous polymer, respectively. Two lectins including concanavalin (Con A) and wheat germ agglutinin (WGA) were immobilized onto the monolithic capillary columns. The neutral monoliths with immobilized lectins exhibited lower permeability under pressure driven flow than the cationic monoliths indicating that the latter had wider flow-through pores than the former. Both types of monoliths with immobilized lectins exhibited strong affinity toward particular glycoproteins and their oligosaccharide chains (i.e., glycans) having sugar sequences recognizable by the lectin. Due to the strong binding affinity, the monoliths with surface bound lectins allowed the injection of relatively large volume (i.e., several column volumes) of dilute samples of glycoproteins and glycans thus allowing the concentration of the glycoconjugates and their subsequent isolation and detection at low levels (approximately 10(-8) M). To further exploit the lectin monoliths in the isolation of glycoconjugates, two-dimensional separation schemes involving LAC in the first dimension and reversed-phase nano-LC in the second dimension were introduced. The various interrelated methods established in this investigation are expected to play a major role in advancing the sciences of "nano-glycomics".     

Recent advances in monolithic columns for protein and peptide separation by capillary liquid chromatography

Capillary liquid chromatography (cLC) has great potential for protein and peptide separation, with advantages of high efficiency, high resolution, low sample consumption, and high sensitivity when coupled with mass spectrometry. In recent years, monoliths have been widely used as the stationary phases for capillary columns, owing to easy preparation, high permeability, fast mass transfer, and low backpressure. This review summarizes recent advances (2007–2012) in monolithic columns for protein and peptide separation by cLC. After a brief introduction on the preparation of monolithic capillary columns, the emphasis of this review is focused on the recent application of such columns for protein and peptide separation by cLC. Furthermore, the challenges and potential hot points of monolithic capillary columns in the future are discussed.     

Novel method to prepare polystyrene-based monolithic columns for chromatographic and electrophoretic separations by microwave irradiation

Microwave irradiation can provide a viable alternative to the traditional means such as ultraviolet light and thermal initiation for the preparation of monolithic capillary columns. Polystyrene-based monolithic stationary phases were prepared in situ in fused-silica capillaries and simultaneously in vials. The column permeability, electrophoretic and chromatographic behavior were evaluated using pressure-assisted capillary electrochromatography (pCEC), capillary electrochromatography (CEC) and low pressure liquid chromatography (LPLC). With an optimal monolithic material, the largest theoretical plates for preparing the column could be close to 18,000 plates/m for thiourea in the mode of pCEC. Furthermore, the influence of the composition of the porogenic solvents (toluene/isooctane) on the morphology of organic-based monoliths [poly(styrene-divinylbenzene-methacrylic acid)] was systematically studied with mercury intrusion porosimetry and scanning electron microscopy. The monoliths which were prepared with a high content of isooctane had a bigger pore size and better permeability, and hence resulted in a faster separation.     

Novel preparation of organic polymer-based monolithic column by microwave irradation

Microwave irradiation was firstly attempted for the preparation of organic-based monoliths of poly（styrene-divinylbenzene- methacrylic acid）, which single step in situ polymerization was carried out during 15 min. The colunm permeability, electrophoretic and chromatographac behaviors were comparatively evaluated using pressure-assisted CEC, GEC and low pressure-driven separation modes. The largest theoretical plates for the preparing column could be close to 18,0000 plates/m for thiourea in the mode of p-CEC. It provided a viable alternative to traditional initiation means for the perparation of monolithic capillary columns.     

Recent progress in polar stationary phases for CEC

This review summarizes most of the recent developments in the preparation and application of polar stationary phases for CEC covering the literature published since the year 2004. These polar stationary phases have been adopted for separation of analytes by the modes of packing column CEC, open-tubular CEC (o-CEC) and monolithic column CEC. Currently, development of o-CEC using biomolecules, such as protein and DNA, as the immobilized ligands is highlighted partly due to the simplicity of preparation. Furthermore, monolithic columns have been extended quickly, particularly inorganic materials-based monoliths, such as silica, zirconia, hafnium, etc., as an alternative to packed columns have been developed quickly.     

Development of erbium phosphate doped poly(glycidyl methacrylate/ethylene dimethacrylate) spin columns for selective enrichment of phosphopeptides

In this study, a novel method for the highly selective enrichment of phosphopeptides using erbium phosphate doped poly(glycidyl methacrylate/ethylene dimethacrylate) spin columns is presented. Erbium phosphate was synthesized by precipitation from boiling phosphoric acid and incubated overnight in erbium chloride solutions. The resulting powder was embedded in a monolithic poly(glycidyl methacrylate/ethylene dimethacrylate) polymer. The monolith was synthesized in a spin column by radical polymerization. Erbium phosphate demonstrated a high affinity and selectivity for phosphopeptides due to the strong interaction of trivalent erbium ions with the phosphate groups of phosphopeptides. The high selectivity and performance of the designed spin columns were demonstrated by successfully enriching phosphopeptides from tryptically digested protein mixtures containing the model phosphoproteins α‐ and β‐casein, bovine milk, and human saliva. By the implementation of several washing steps, unspecific components were removed and the enriched phosphopeptides were effectively eluted from the spin columns under alkaline conditions. The selective performance of the presented method was further demonstrated by the enrichment of two synthetic phosphopeptides, which were spiked in tryptically digested and dephosphorylated HeLa cell lysates at low ratios. Finally, the presented approach was compared to conventional phosphopeptide enrichment by titanium oxide and revealed higher recoveries for the erbium phosphate doped monoliths.     

Organic–inorganic hybrid fluorous monolithic capillary column for selective solid‐phase microextraction of perfluorinated persistent organic pollutants

A novel construction strategy of monolithic capillary column for selectively enriching perfluorinated persistent organic pollutants was proposed. The organic–inorganic hybrid fluorous monolithic capillary column was synthesized by a “one‐pot” approach via the polycondensation of γ‐methacryloxypropyltrimethoxy‐silane, then in situ copolymerization of 1H,1H,7H‐dodecafluoroheptyl methacrylate and vinyl group on the precondensed siloxanes. The obtained monolithic columns were systematically characterized. The results demonstrated that the optimal column possessed good mechanical stability and high permeability. The adsorption capacities of the optimized monolithic column for perfluorooctanoic acid and perfluorooctane sulfonate were 0.257 and 0.513 μg/mg, respectively. Adsorption capacities of the monoliths were proved to increasing with increasing the amounts of fluorinated monomers in the fluorous monoliths. Sodium 1‐octanesulfonate, as a comparison compound, was hardly adsorbed on the fluorous monolith. In addition, the trace amounts of perfluorooctanoic acid and perfluorooctane sulfonate in water samples can be successfully concentrated about 160 times to their original concentrations by this monolithic column. These results demonstrated that the capacity and selectivity of the affinity fluorous column is high and can be applied to the selective enrichment for the perfluorinated persistent organic pollutants from environmental samples.