光学椭偏成像技术在生物分子研究中的应用

光学椭偏显微成像是一种新型超薄膜及表面显示技术,是研究生物分子与固体表面吸附以及生物分子之间相互作用的一种简单、快速和可靠的手段。它不仅能够大面积精确显示超薄膜的厚度分布,而且能够用于表面实时吸附的动力学研究。在抗原抗体检测分析方面,它不需要像酶联免疫法、荧光免疫法和放射免疫法那样对待测物作标记,也不会对待测生物分子活性造成任何扰动和损伤,操作简单,费用低廉。另外,它还弥补了传统的椭偏法的不足之处,能够有效地区分非特异性吸附、脱吸附或表面污染带来的干扰。     

酿酒酵母细胞表面工程应用研究新进展

酿酒酵母表面展示工程是一个新兴的蛋白表达系统,由于它能进行蛋白翻译后修饰,能方便地对表达的蛋白产物进行检测和筛选,近年来应用研究发展迅猛。它在构建全细胞催化剂、抗原/抗体库、生物吸附剂、生物传感器、组合蛋白文库、免疫检测及亲和纯化中取得了很多新的应用,在蛋白质分子的功能研究与应用中发挥了更加重要的作用。     

分子识别诱导的蛋白质和核酸多层膜的有序组装

通过生物大分子之间的特异性结合,采用表面等离激元共振技术监测,报导了支撑于固体表面脂单层膜上进行的亲和素、生物素标记的质粒ＤＮＡ、以及从系统性红斑狼疮患者血清中获得的抗ＤＮＡ抗体多层膜的有序组装。这种生物大分子的组装技术可以用于生物传感器以检测特定的抗原抗体。     

分子识别诱导的蛋白质和核酸多层膜的有序组装

通过生物大分子之间的特异性结合,采用表面等离激元共振技术监测,报导了支撑于固体表面脂单层膜上进行的亲和素、生物素标记的质粒ＤＮＡ,以及从系统性红斑狼疮患者血清中获得的抗ＤＮＡ抗体多层膜的有序组装。这种生物大分子的组装技术可以用于生物传感器以检测特定的抗原抗体。     

蛋白质微阵列检测抗原-抗体相互作用

为了制备蛋白质微阵列和研究芯片表面抗原-抗体的相互作用,研究了如何在玻片表面固化蛋白质和用荧光染料（Cy3,Cy5）对蛋白质进行标记.结果表明,在醛基修饰的玻璃表面,通过共价偶联的方法将抗原或抗体固定到芯片表面,能使二者保持其特异性结合能力.同时,荧光标记后的抗原或抗体仍然具有特异性结合能力.蛋白质微阵列是通过机械手在玻片表面排阵制作的.芯片上的荧光信号获取采用了激光共焦荧光扫描系统.用不同浓度的抗原探针阵列,对其相应的抗体靶分子的特异性结合进行了分析和研究.此外,还通过在玻片表面固定兔IgG和固定鼠IgG,对羊抗兔和羊抗鼠抗体与其相应抗原的特异性相互作用进行了检测.     

藻胆蛋白荧光探针及其标记

藻胆蛋白是一系列新型的荧光标记探针,具有优良的荧光特性,以藻胆蛋白荧光探针标记抗体还可用于血清可溶性抗原（或抗体）的荧光免疫检测,其标记方法可分为直接法和间接法。结合藻胆蛋白的特点,研究藻胆蛋白的标记方法有助于提高荧光免疫检测的灵敏度。     

光学蛋白芯片技术在噬菌体M13KO7检测中的应用

将亲和素共价固定在表面改性后的硅片上,通过亲和素与生物素相互作用将生物素标记的噬菌体抗体GP3固定在亲和素膜层表面,当含有M13KO7噬菌体的样品经过抗体表面时,通过噬菌体与抗体之间的相互作用噬菌体就会被抗体捕获,生物学信号可以通过芯片上的膜层厚度变化表现出来,这种膜层厚度变化可以被椭偏生物传感器技术识别。结果表明,GP3抗体在芯片表面形成了饱和的抗体膜层,厚度为6.9nm;M13KO7噬菌体与芯片上固定的抗体会发生特异性相互作用,噬菌体被抗体捕获后形成的复合物膜层厚度为17.5nm,并且随着噬菌体浓度升高膜层厚度增加,检测含有M13KO7噬菌体的样品灵敏度为109pfu/mL。与其它研究病毒与抗体相互作用方法相比光学蛋白芯片技术具有简便快捷、无需标记待检样品和结果直观等优点,为研究病毒与其抗体相互作用以及疾病早期临床诊断提供了一个新的方法。     

基于生物膜干涉技术检测PDL1抗体与PDL1抗原的亲和力

生物膜干涉（biolayer interferometry,BLI）技术可对抗体与抗原的相互作用进行亲和力、动力学的全面分析。在抗体克隆筛选、动力学常数测定中对链霉亲和素（streptavidin,SA）生物传感器的需求量较大,但目前鲜有关于SA传感器重复利用的报道。基于BLI技术、再生SA生物传感器建立一种使用再生后的传感器检测PDL1抗体与PDL1抗原亲和力的方法。通过将生物素化的PDL1抗原偶联至SA生物传感器上,再与单链抗体、双价单链抗体、完整抗体和双特异性抗体这4类PDL1抗体结合,计算抗原抗体的亲和力常数,利用甘氨酸（10 mmol·L^-1,pH 1.7）再生SA传感器,再次进行分子间相互作用力分析。结果显示,重复性相对标准偏差（relative standard deviation,RSD）均值为6.87%,批间重复性RSD为0.82%,稳定性RSD均值为6.13%,说明运用甘氨酸再生后的SA生物传感器测分子间的亲和力数据可靠、重现性好、稳定性高,再生后的传感器可继续用于本样品的实时、无标记的抗原抗体相互作用力分析。BLI技术可节省检测成本,为SA传感器的重复利用提供理论依据。     

酿酒酵母表面展示表达系统及应用

酵母细胞表面展示表达系统是一种固定化表达异源蛋白质的真核展示系统,即把异源靶蛋白基因序列与特定的载体基因序列融合后导入酵母细胞,利用酿酒酵母细胞内蛋白转运到膜表面的机制（GPI锚定）使靶蛋白定位于酵母细胞表面并进行表达。它利用细胞表面展示技术使外源蛋白固定化于细胞表面,从而生产微生物细胞表面蛋白,可应用于生物催化剂、细胞吸附剂、活疫苗、环境治理、蛋白质文库筛选、高亲和抗体、生物传感器、抗原／抗体库构建、免疫检测及亲和纯化、癌症诊断等领域。国内对这一方面研究较少,本文主要介绍了该技术的基本原理、研究现状、应用及其发展前景。     

纳米多孔硅阻抗生物传感器的研究

构建了1种基于多孔硅材料,无需标记的纳米生物传感器,用于对牛血清白蛋白分子进行检测。通过对多孔硅进行表面处理,形成氧化膜,将抗体固定到多孔硅氧化层表面。在磷酸盐缓冲液中,通过电化学检测系统检测加入抗原后,传感器的阻抗值的变化。磷酸缓冲液（PBS）/抗体-氧化层/硅,构成电解液/绝缘层/半导体（electro-lyte-insulator-semiconductor,EIS）结构。传感器的线性检测范围为0.01～0.27mg/mL,检测限为0.01mg/mL。     

Feasibility of protein A for the oriented immobilization of immunoglobulin on silicon surface for a biosensor with imaging ellipsometry

The feasibility of using protein A to immobilize antibody on silicon surface for a biosensor with imaging ellipsometry was presented in this study. The amount of human IgG bound with anti-IgG immobilized by the protein A on silicon surface was much more than that bound with anti-IgG immobilized by physical adsorption. The result indicated that the protein A could be used to immobilize antibody molecules in a highly oriented manner and maintain antibody molecular functional configuration on the silicon surface. High reproducibility of the amount of antibody immobilization and homogenous antibody adsorption layer on surfaces could be obtained by this immobilization method. Imaging ellipsometry has been proven to be a fast and reliable detection method and sensitive enough to detect small changes in a molecular monolayer level. The combination of imaging ellipsometry and surface modification with protein A has the potential to be further developed into an efficient immunoassay protein chip.     

Detection of Cytomegalovirus Antibodies Using a Biosensor Based on Imaging Ellipsometry

Background

Cytomegalovirus (CMV) is the most common infectious cause of mental disability in newborns in developed countries. There is an urgent need to establish an early detection and high-throughput screening method for CMV infection using portable detection devices.

Methods

An antibody analysis method is reported for the detection and identification of CMV antibodies in serum using a biosensor based on high spatial resolution imaging ellipsometry (BIE). CMV antigen (CMV-3A) was immobilized on silicon wafers and used to capture CMV antibodies in serum. An antibody against human immunoglobulin G (anti-IgG) was used to confirm the IgG antibody against CMV captured by the CMV-3A.

Results

Our results show that this assay is rapid and specific for the identification of IgG antibody against CMV. Further, patient serum was quantitatively assessed using the standard curve method, and the quantitative results were in agreement with the enzyme-linked immunosorbent assay. The CMV antibody detection sensitivity of BIE reached 0.01 IU/mL.

Conclusions

This novel biosensor may be a valuable diagnostic tool for analysis of IgG antibody against CMV during CMV infection screening.     

A surface modification strategy on silicon nitride for developing biosensors

A surface modification strategy for the use of giant magnetoresistive materials in the detection of protein-protein interactions is developed. This modification strategy is based on silanization of semiconductive materials. A native silicon nitride surface was treated with concentrated hydrofluoric acid to improve surface homogeneity. Nano-strip was used to oxidize silicon nitride to form a hydrophilic layer. Aminopropyltriethoxysilane was subsequently used to functionalize the treated surfaces to form amine groups, which were further activated with glutaraldehyde to introduce a layer of aldehyde groups. The effectiveness of this modification strategy was validated by chemiluminescence immunoassays of purified 6x His-HrpW of Pseudomonas syringae pv. tomato DC3000 and human transferrin. Signals with intensities related to concentrations of these two immobilized model proteins were observed. The modified surface was also validated by a more complex system: intercellular proteins secreted by DC3000. HrpW in these protein mixtures was successfully recognized by anti-HrpW antibodies when mixed proteins were immobilized onto activated surfaces. This surface modification strategy provides a platform onto which proteins can be directly immobilized for biosensor and protein array applications.     

Photografted poly(ethylene glycol) matrix for affinity interaction studies

A poly(ethylene glycol) (PEG)-based matrix for studies of affinity interactions is developed and demonstrated. The PEG matrix, less than 0.1 microm thick, is graft copolymerized onto a cycloolefin polymer from a mixture of PEG methacrylates using a free radical reaction initiated by UV light at 254 nm. The grafting process is monitored in real time, and characteristics such as thickness, homogeneity, relative composition, photostability, and performance in terms of protein resistance in complex biofluids and sensor qualities are investigated with null ellipsometry, infrared spectroscopy, and surface plasmon resonance. The matrix is subsequently modified to contain carboxyl groups, thereby making it possible to immobilize ligands in a controlled and functional manner. Human serum albumin and fibrinogen are immobilized and successfully detected by antibody recognition using surface plasmon resonance. The results are encouraging and suggest that the PEG matrix is suitable for biochip and biosensor applications in demanding biofluids.     

Controlled antibody immobilization onto immunoanalytical platforms by synthetic peptide

Antibody immobilization on a solid surface is inevitable in the preparation of immunochips/sensors. Antibody-binding proteins such as proteins A and G have been extensively employed to capture antibodies on sensor surfaces with right orientations, maintaining their full functionality. Because of their synthetic versatility and stability, in general, small molecules have more advantages than proteins. Nevertheless, no small molecule has been used for oriented and specific antibody immobilization. Here is described a novel strategy to immobilize an antibody on various sensor surfaces by using a small antibody-binding peptide. The peptide binds specifically to the Fc domain of immunoglobulin G (IgG) and, therefore, affords a properly oriented antibody surface. Surface plasmon resonance analysis indicated that a peptide linked to a gold chip surface through a hydrophilic linker efficiently captured human and rabbit IgGs. Moreover, antibodies captured by the peptide exhibited higher antigen binding capacity compared with randomly immobilized antibodies. Peptide-mediated antibody immobilization was successfully applied on the surfaces of biosensor substrates such as magnetic particles and glass slides. The antibody-binding peptide conjugate introduced in this work is the first small molecule linker that offers a highly stable and specific surface platform for antibody immobilization in immunoassays.     

Enhanced sensitivity detection of protein immobilization by fluorescent interference on oxidized silicon

We present a silicon chip-based approach for the enhanced sensitivity detection of surface-immobilized fluorescent molecules. Green fluorescent protein (GFP) is bound to the silicon substrate by a disuccinimidyl terephtalate-aminosilane immobilization procedure. The immobilized organic layers are characterized by surface analysis techniques, like ellipsometry, atomic force microscopy (AFM) and X-ray induced photoelectron spectroscopy. We obtain a 20-fold enhancement of the fluorescent signal, using constructive interference effects in a fused silica dielectric layer, deposited before immobilization onto the silicon. Our method opens perspectives to increase by an order of magnitude the fluorescent response of surface immobilized DNA- or protein-based layers for a variety of biosensor applications.     

Three-dimensional immobilization of beta-galactosidase on a silicon surface

Many alternative strategies to immobilize and stabilize enzymes have been investigated in recent years for applications in biosensors. The entrapment of enzymes within silica-based nanospheres formed through silicification reactions provides high loading capacities for enzyme immobilization, resulting in high volumetric activity and enhanced mechanical stability. Here we report a strategy for chemically associating silica nanospheres containing entrapped enzyme to a silicon support. beta-galactosidase from E. coli was used as a model enzyme due to its versatility as a biosensor for lactose. The immobilization strategy resulted in a three-dimensional network of silica attached directly at the silicon surface, providing a significant increase in surface area and a corresponding 3.5-fold increase in enzyme loading compared to enzyme attached directly at the surface. The maximum activity recovered for a silicon square sample of 0.5 x 0.5 cm was 0.045 IU using the direct attachment of the enzyme through glutaraldehyde and 0.16 IU when using silica nanospheres. The immobilized beta-galactosidase prepared by silica deposition was stable and retained more than 80% of its initial activity after 10 days at 24 degrees C. The ability to generate three-dimensional structures with enhanced loading capacity for biosensing molecules offers the potential to substantially amplify biosensor sensitivity.     

Immobilization of antibodies through the surface regions having the highest density in lysine groups on finally inert support surfaces

Immobilization of anti-horseradish peroxidase on glyoxyl-agarose proceeds rapidly, and after the immobilization, it was found that the antibody captured almost the same amount of peroxidase than the free antibody. After boiling the antibodies in the presence of SDS and mercaptoethanol, more than 95% of the immobilized antibodies presented the four subunits attached to the support.The reduction of the preparation converts the glyoxyl groups into very hydrophilic and inert hydroxyl-groups. That way, the final support was fully unable to adsorb any protein under any condition, and the only adsorbed proteins on the immobilized antibody are these recognized by the antibody. The immobilized antibody maintained intact their capacity to capture peroxidase after 20 weeks of storage at 4 °C.The high functionality of the immobilized antibody and the fully inert surface suggest that this technique may be a very suitable one to immobilize antibodies for biosensor design or immuno-chromatographic matrices.     

In situ protein microarrays capable of real-time kinetics analysis based on surface plasmon resonance imaging

In recent years, in situ protein synthesis microarray technologies have enabled protein microarrays to be created on demand just before they are needed. In this paper, we utilized the TUS-TER immobilization technology to allow label-free detection with real-time kinetics of protein–protein interactions using surface plasmon resonance imaging (SPRi). We constructed an expression-ready plasmid DNA with a C-terminal TUS fusion tag to directionally immobilize the in situ synthesized recombinant proteins onto the surface of the biosensor. The expression plasmid was immobilized on the polyethylene imine-modified gold surface, which was then coupled with a cell-free expression system on the flow cell of the SPRi instrument. The expressed TUS fusion proteins bind on the surface via the immobilized TER DNA sequence with high affinity (∼3–7 × 10⁻¹³ M). The expression and immobilization of the recombinant in situ expressed proteins were confirmed by probing with specific antibodies. The present study shows a new low cost method for in situ protein expression microarrays that has the potential to study the kinetics of protein–protein interactions. These protein microarrays can be created on demand without the problems of stability associated with protein arrays used in the drug discovery and biomarker discovery fields.     

Improvement of antibody immobilization using hyperbranched polymer and protein A

For the construction of a well-defined antibody surface, protein A was used as a binding material to immobilize antibodies onto gold-derivatized transducers. The traditional method tends to assemble protein A directly onto the gold-derivatized transducers. In this paper, we tried to indirectly bind protein A onto sensors through hyperbranched polymer (HBP) which was synthesized from p-phenylenediamine and trimesic acid. The three-dimensional structure of HBP and the characteristics including orientation control and biocompatibility of protein A led to highly efficient immunoreactions and enhanced detection system performance. With this strategy, cysteamine monolayer was first assembled onto Au electrodes associated with the piezoelectric quartz crystal; secondly, the cysteamine-modified gold electrode was further modified by the activated HBP; thirdly, protein A was immobilized onto the HBP film; and finally, antibodies were immobilized onto the surface of protein A film for detecting the corresponding antigen. The quartz crystal microbalance immunosensor thus fabricated was applied to detect hepatitis B surface antigen in solutions that ranged from 0.71 to 300 μg mL⁻¹. The detection limit was estimated to be 0.53 μg mL⁻¹. The immunosensor holds good selectivity, sensitivity, and repeatability.