适配体传感器在微生物检测中的应用

适配体是一类特异的核酸序列,具有靶分子广、特异性强、稳定等优点.该类核酸分子在体外通过SELEX(systematic evolution of ligands by exponential enrichment)技术(系统进化的指数富集技术)鉴定和筛选得到.相对于抗体,适配体为诊断和检测分析系统中的识别配基提供了另一个选择.适配体生物传感器是将生物识别元件和信号转换元件紧密结合,从而检测目标化合物的分析装置.适配体生物传感器在微生物检测方面具有分析速度快、灵敏度高、专一性强等特点,在微生物检测中显示出良好的应用前景.介绍了适配体、SELEX流程以及适配体传感器,综述了适配体传感器在微生物检测中的应用.     

检测环境污染物的适配体生物传感器研究进展

适配体生物传感器可利用适配体作为识别元件,将适配体的优良特性和目前先进的检测技术进行结合,例如光学、电化学纳米集成技术或生物膜干涉测量法,为其在有毒有害物质检测和环境实时监测领域构筑了良好应用前景。然而,适配体传感器的进一步应用仍有许多问题亟待解决,比如:环境的复杂性会对其应用产生限制;适配体固化到传感器表面的方式会影响适配体的结构和功能,从而影响检测效果。本文将主要研究适配体筛选策略的最新进展并对适配体传感器检测环境中小分子污染物的应用展开综述。     

综述与专论: 基于核酸适配体传感器的即时检测（POCT）技术

即时检测（point-of-care testing，POCT）是一种检测成本低、检测速度快、准确度高、能自我采样获得临床诊断结果的新型诊断技术。该技术在临床诊断、病情监控与疫情防控等领域发挥了重要作用。核酸适配体是一种能够特异性识别多种靶标的分子探针，具有易合成、批间差异小、易实现信号放大等突出优势，是生物医学传感器中重要的分子识别元件。本文概述了核酸适配体探针的现有筛选方法和进展，总结了核酸适配体POCT传感器信号放大策略，着重介绍了各类核酸适配体传感器在POCT领域的应用现状，并对核酸适配体POCT传感器的发展前景进行了展望。     

适配体结合蛋白质靶标的亲和力表征方法及其在疾病诊断中的应用

核酸适配体是通过体外指数富集配体系统进化（SELEX）技术筛选获得,并能够和蛋白质靶标高特异性、高亲和力结合的单链寡核苷酸。核酸适配体不但具有抗体的识别特性,而且具有自己独特的优良性能,目前已应用于分析检验、食品安全和生物医药等各个领域。蛋白质具有多种多样的生物功能以及临床诊断价值。因此,核酸适配体针对蛋白质靶标并在蛋白质相关的基础研究领域受到广泛的关注。核酸适配体应用性能的优劣取决于与其靶标蛋白质的亲和力与特异性。本文主要综述核酸适配体对蛋白质靶标的亲和力表征方法,以及在药物研发、肿瘤检测、生物成像以及生物传感器方面的应用。     

适配体传感器检测抗生素的研究进展

抗生素作为一种微生物的次级代谢产物,具有杀死或抑制微生物生长的作用。抗生素的滥用导致了它在食物中的残留量逐年增加。因此,需要建立一种快速灵敏检测方法用于食品中抗生素残留量的检测。核酸适配体传感器因其高选择性、高特异性和高灵敏性等优点而备受关注。同时,借助纳米材料独特的光、电特性,能够进一步提高适配体传感器的性能。本文综述了目前用于抗生素检测的核酸适配体传感器如荧光适配体传感器、比色适配体传感器和电化学适配体传感器等的研究进展。此外,还对该研究领域面临的挑战和未来前景进行了展望。     

基于表面等离子共振的适配体传感器应用研究进展

基于表面等离子共振的适配体传感器是利用适配体进行高特异性、高灵敏度、高通量检测的新型生物传感器。我们在简要阐述适配体的筛选方法、偶联技术及适配体传感器工作原理的基础上,结合最新的研究结果,对基于表面等离子共振的适配体传感器在生物活性小分子检测、传染病检测、肿瘤标志物检测、食品安全监测等方面的应用研究进展进行了综述。     

适配体在受体和分子传感器中的应用研究进展

适配体是从随机寡核苷酸文库中筛选得到的一类可以结合特异靶分子的寡核苷酸序列,在生物医学中具有极其诱人的应用前景.与传统抗体相比,由于具有制备简便、易于修饰、稳定性好,以及结合目标物范围广等特点,适配体已广泛应用于生物传感器的开发,一方面可以用作敏感元件,用于实现对靶分子的识别和检测;另一方面,可以作为敏感元件与传感器件耦合的桥梁,提高耦合的效率.此外,近年来在基于适配体的生物传感器中引入各种纳米材料例如金属纳米颗粒、碳材料和功能性纳米球等也促进了基于适配体的生物传感器在分析性能和商业应用等方面的提升和改进.本文首先简要介绍了基于SELEX技术筛选适配体的方法,总结了适配体的基本特性;其次,详细概括和总结了适配体生物传感器的基本原理及其分类;随后,结合近年来基于适配体的生物传感器领域的最新研究成果,重点介绍了适配体在生物传感器开发中的应用,主要包括在仿生嗅觉与味觉受体传感器方面的应用以及在检测小分子物质和蛋白质的应用;最后,对适配体在生物传感器中的应用面临的问题及其发展趋势进行了分析和展望.     

食源性致病细菌适配体生物传感器研究进展

食品安全是如今大众关注的焦点,而食源性致病细菌是导致食品安全问题事件频发的主要原因之一,因此需要开发一种快速灵敏便宜的检测方法,对食源性致病细菌进行监督检测。适配体是在体外基于SELEX技术,从单链寡核苷酸随机文库中筛选出的对靶标具有高亲和性、特异性的寡核苷酸(DNA或RNA)片段。由于食源性致病细菌的表面结构物质复杂,基于SELEX技术的适配体筛选方式被不断改良。本文介绍了几种SELEX改良技术,同时对适配体结合力的十种表征方法进行了比较,并对几种常见食源性致病细菌重要的(DNA、RNA、劈裂)适配体进行总结。由于适配体具有众多优于抗体的特性,用于食源性致病细菌检测的适配体生物传感器得到快速发展,其中电化学传感器及光学传感器应用最为广泛。对食源性致病细菌的光学适配体传感器与电化学适配体传感器的最新研究进展进行重点综述,并提出了未来适配体传感器的发展趋势,旨在为微生物检测技术开拓新领域,指引新方向。     

研究报告：鳗弧菌（Vibrio anguillarum）核酸适配体的筛选及其结合蛋白的分离鉴定

目的鳗弧菌（Vibrio anguillarum）是水产养殖中的重要条件致病菌,每年给水产养殖业造成巨大的经济损失,研究其致病机制、对其进行快速的检测鉴定是其病害防治的前提和基础。核酸适配体因其高亲和力、高特异性等多种优点,在微生物的靶标分析、检测鉴定以及致病机制等多个领域都呈现出较好的应用潜力。因此,筛选鳗弧菌的核酸适配体,利用核酸适配体对鳗弧菌相关位点进行分析鉴定,不仅能为鳗弧菌的检测鉴定提供一个新的手段,对于探索鳗弧菌相关位点在其病害防治中的作用也具有重要意义。方法以鳗弧菌为靶目标,采用每轮测序的SELEX筛选方法,从高频序列中筛选鳗弧菌的核酸适配体;采用单链DNA浓度法测定核酸适配体的亲和力,研究核酸适配体对鳗弧菌的亲和特异性;采用Origin软件、选择反比例函数（Hyperbola函数）进行非线性拟合,获得核酸适配体的亲和常数（K_d）和最大亲和力（A_m）;采用磁分离技术和聚丙烯酰胺凝胶电泳分离纯化出核酸适配体H5的结合蛋白,通过质谱对该蛋白质进行分析鉴定,并利用Prabi、Phyre2、Psortb 3.0等在线网站分析该结合蛋白的...     

基于核酸适配体的DNA纳米结构在肿瘤研究中的应用进展

DNA纳米结构具有强大的分子载带量、良好的稳定性、可编辑性和生物相容性等特点,是纳米材料领域的研究热点。核酸适配体是一段短的寡核苷酸序列(RNA或ss DNA),能够折叠成特定的三维结构与靶标高特异性、高亲和力的结合。将核酸适配体的分子识别特性和DNA纳米结构相结合,可将靶向识别、生物成像及药物递送等特点集于一体,在生命科学研究领域,尤其是肿瘤领域,有着良好的应用前景。本文介绍了DNA纳米结构和核酸适配体的特点与优势,对近年来核酸适配体-DNA纳米结构在肿瘤标志物检测、靶向成像以及药物靶向递送的研究进展进行了综述,并对其发展前景进行了展望,期待核酸适配体-DNA纳米结构能为肿瘤的靶向诊疗提供新的策略。     

Research progress in the detection of common foodborne hazardous substances based on functional nucleic acids biosensors

With the further improvement of food safety requirements, the development of fast, highly sensitive, and portable methods for the determination of foodborne hazardous substances has become a new trend in the food industry. In recent years, biosensors and platforms based on functional nucleic acids, along with a range of signal amplification devices and methods, have been established to enable rapid and sensitive determination of specific substances in samples, opening up a new avenue of analysis and detection. In this paper, functional nucleic acid types including aptamers, deoxyribozymes, and G-quadruplexes which are commonly used in the detection of food source pollutants are introduced. Signal amplification elements include quantum dots, noble metal nanoparticles, magnetic nanoparticles, DNA walkers, and DNA logic gates. Signal amplification technologies including nucleic acid isothermal amplification, hybridization chain reaction, catalytic hairpin assembly, biological barcodes, and microfluidic system are combined with functional nucleic acids sensors and applied to the detection of many foodborne hazardous substances, such as foodborne pathogens, mycotoxins, residual antibiotics, residual pesticides, industrial pollutants, heavy metals, and allergens. Finally, the potential opportunities and broad prospects of functional nucleic acids biosensors in the field of food analysis are discussed.     

Biosensors for the detection of bacteria

This review will consider the role of biosensors towards the detection of infectious bacteria, although non-infectious ones will be considered where necessary. Recently, there has been a heightened interest in developing rapid and reliable methods of detection. This is especially true for detection of organisms involved in bioterrorism, food poisoning, and clinical problems such as antibiotic resistance. Biosensors can assist in achieving these goals, and sensors using several of the different types of transduction modes are discussed: electrochemical, high frequency (surface acoustic wave), and optical. The paper concludes with a discussion of three areas that may make a great impact in the next few years: integrated (lab-on-a-chip) systems, molecular beacons, and aptamers.     

Analytical potential of gold nanoparticles in functional aptamer-based biosensors

Gold nanoparticles (AuNPs) exhibit many predominant capabilities such as high biocompatibility, chemical stability, strong localized surface plasmon resonance absorption, and high extinction coefficient in the visible region. These properties have enabled the extensive use of AuNPs in optical and electrochemical biosensors. As a kind of functional nucleic acids, aptamers can be considered as a valid alternative to antibodies or other bio-receptors and have been widely employed to develop novel biosensors. We are summarizing here the state of the art of AuNP-based biosensors that use functional aptamers as molecular recognition elements. In many cases, AuNPs themselves can be used as a probe for detection, such as various colorimetric aptasensors and fluorescent aptasensors. They also can be used as probe vectors to enlarge detection signals and to increase the number of conceivable substrates in electrochemical aptasensors.     

Analytical applications of aptamers

So far, several bio-analytical methods have used nucleic acid probes to detect specific sequences in RNA or DNA targets through hybridisation. More recently, specific nucleic acids, aptamers, selected from random sequence pools, have been shown to bind non-nucleic acid targets, such as small molecules or proteins. The development of in vitro selection and amplification techniques has allowed the identification of specific aptamers, which bind to the target molecules with high affinity. Many small organic molecules with molecular weights from 100 to 10,000 Da have been shown to be good targets for selection. Moreover, aptamers can be selected against difficult target haptens, such as toxins or prions. The selected aptamers can bind to their targets with high affinity and even discriminate between closely related targets.

Aptamers can thus be considered as a valid alternative to antibodies or other bio-mimetic receptors, for the development of biosensors and other analytical methods. The production of aptamers is commonly performed by the SELEX (systematic evolution of ligands by exponential enrichment) process, which, starting from large libraries of oligonucleotides, allows the isolation of large amounts of functional nucleic acids by an iterative process of in vitro selection and subsequent amplification through polymerase chain reaction.

Aptamers are suitable for applications based on molecular recognition as analytical, diagnostic and therapeutic tools. In this review, the main analytical methods, which have been developed using aptamers, will be discussed together with an overview on the aptamer selection process.     

In vitro selection and characterization of DNA aptamers recognizing chloramphenicol

Chloramphenicol (Cam), although an effective antibiotic, has lost favour due to some fatal side effects. Thus there is an urgent need for rapid and sensitive methods to detect residues in food, feed and environment. We engineered DNA aptamers that recognize Cam as their target, by conducting in vitro selections. Aptamers are nucleic acid recognition elements that are highly specific and sensitive towards their targets and can be synthetically produced in an animal-friendly manner, making them ethical innovative alternatives to antibodies. None of the isolated aptamers in this study shared sequence homology or structural similarities with each other, indicating that specific Cam recognition could be achieved by various DNA sequences under the selection conditions used. Analyzing the binding affinities of the sequences, demonstrated that dissociation constants (K_d) in the extremely low micromolar range, which were lower than those previously reported for Cam-specific RNA aptamers, were achieved. The two best aptamers had G rich (>35%) nucleotide regions, an attribute distinguishing them from the rest and apparently responsible for their high selectivity and affinity (K_d ∼ 0.8 and 1 μM respectively). These aptamers open up possibilities to allow easy detection of Cam via aptamer-based biosensors.     

DNA biosensors based on water-soluble conjugated polymers

Conjugated polymers (CPs) with large, delocalised molecular structures exhibit unique optical and electrochemical characteristics that can be used as excellent sensing elements. Recently, research on chemical and biological sensors that use water-soluble CPs as transducers has generated intense interest. Two main sensing mechanisms are used for the detection of DNA-related events, such as hybridisation, mismatch, single nucleotide polymorphism (SNP), SNP genotyping, conformational changes, and cleavage of the nucleic acids. One mechanism takes advantage of the fluorescence resonance energy transfer (FRET) between CPs and a chromophore label on the nucleic acid probes in which a series of cationic polyfluorene, polythiophene and polyarylene derivatives are frequently used. The other mechanism relies on the conformational effects of CPs, which is induced by combination of the specific targets in which cationic polythiophene derivatives are often used. The electron transfer property of CPs are always used to design high sensitive electrochemical DNA biosensors. Here we review recent progress in the development of optical and electrochemical DNA biosensors based on water-soluble CPs.     

DNA based biosensors

Compared to advances in enzyme sensors, immunosensors, and microbial biosensors, relatively little work exists on DNA based biosensors. Here we review the DNA based biosensors that rely on nucleic acid hybridization. Major types DNA biosensors--electrochemical, optical, acoustic, and piezoelectric--are introduced and compared. The specificity and response characteristics of DNA biosensors are discussed. Overall, a promising future is foreseen for the DNA based sensor technology.     

Nucleic acid aptamers as aptasensors for plant biology

Our knowledge of cell- and tissue-specific quantification of phytohormones is heavily reliant on laborious mass spectrometry techniques. Genetically encoded biosensors have allowed spatial and some temporal quantification of phytohormones intracellularly, but there is still limited information on their intercellular distributions. Here, we review nucleic acid aptamers as an emerging biosensing platform for the detection and quantification of analytes with high affinity and specificity. Options for DNA aptamer technology are explained through selection, sequencing analysis and techniques for evaluating affinity and specificity, and we focus on previously developed DNA aptamers against various plant analytes. We suggest how these tools might be applied in planta for quantification of molecules of interest both intracellularly and intercellularly.     

Ultrasensitive nucleic acid biosensors for early cancer diagnostics

We have developed ultrasensitive nucleic acid detection systems involving an amplification step where the analytical signal correlates directly to the amount of nucleic acid in the solution So far, we have performed nucleic acid quantification on several breast cancer susceptibility genes and were able to detect nucleic acid amounts that ranged from 0.1–1.0 fg of nucleic acid, which is at least 1000 times more sensitive than conventional fluorescent detection methods. The biosensors are so sensitive that they can be used for direct detection of breast cancer susceptibility genes in mRNA without involving a PCR step.