原子力显微镜及其在肿瘤研究中的应用

原子力显微术是一种利用原子、分子间的相互作用力来观察物体表面超微结构的新型实验技术.介绍了原子力显微镜作为一种显微探测和操纵工具的主要特点及其在肿瘤研究中的优势,评述了国内外有关原子力显微镜在肿瘤的诊断、治疗、抗肿瘤药物开发等研究中的应用情况,展望了原子力显微镜应用于肿瘤单细胞研究的前景.     

原子力显微镜在生物领域中的应用

原子力显微镜(AFM)作为生物样品表面表征的有力工具,具有独特的优势.本文在介绍原子力显微镜基本原理的基础上,综述了原子力显微镜样品制备以及原子力显微镜形貌分析、力曲线以及动力学分析在生物领域中的应用.     

胶体金修饰纳米免疫传感器的制备与性能测定

基于原子力显微术,利用电化学、胶体金修饰等,进行与生物分子的结构与功能相关的免疫识别研究。利用分子自组装技术,设计出胶体金修饰CD29免疫传感器,并将原子力显微镜(AFM)针尖修饰CD29后,利用力曲线模式,对免疫传感器进行分子识别及活性点分析。CD29免疫传感器的活性点分析表明,只有62.5%的表面区域有明显力的黏附性,即活性部位,其余部分无活性。通过AFM扫描表面,发现抗体在表面聚集成团状,失去蛋白分子的原有结构,且将活性部位隐藏于内部。推断出这可能是导致蛋白失活的主要原因。     

双链DNA 膜效应在序列点突变电化学检测中的应用

报道一种基于金表面的双链DNA膜效应检测DNA点突变的新方法。致密的双链DNA分子层可以将电化学信号分子禁闭在金表面和双链DNA之间,或者将信号分子与金表面隔离开,使其无法接触裸金面．在实验系统中采用Fe(CN）6^3-为信号分子,在升高温度时,双链DNA膜被破坏,信号分子离开或接触金表面,解链曲线会出现一个陡峭的电化学信号变化。在特定的温度下,完全互补的序列和单碱基点突变的序列的信号比达到了100：1。这种方法简单而且灵敏,同时避免了复杂的共价修饰信号分子的过程。     

抗癌药物奥沙利铂与DNA分子相互作用的研究

奥沙利铂被称为第三代铂类药物,特别对胃肠道肿瘤具有较好的疗效.目前大多数的研究表明奥沙利铂的主要作用靶点是DNA分子,但它与DNA分子形成的关键结构和作用机制仍处在探索阶段.本研究运用紫外可见吸收光谱和原子力显微镜观察探索奥沙利铂与DNA在活体外的相互作用过程,从而揭示奥沙利铂产生抗癌作用的主要分子结构基础.首先使用紫外光谱研究了较高浓度奥沙利铂与DNA的作用过程.在此基础上,进一步采用原子力显微镜在高定向热解石墨表面观察了不同浓度奥沙利铂与质粒DNA在37℃条件下作用不同时间后的结构形貌变化,分析了奥沙利铂与DNA相互作用的过程.高分辨原子力显微观察结果表明奥沙利铂与DNA作用后可导致质粒DNA的结构发生显著的变化.随着作用时间的增加,DNA分子逐渐由伸展的链状变化为相互缠绕并带有许多结点的紧密结构,最终变化为更紧密的球状结构.本研究结果表明奥沙利铂可通过化学键合作用和静电作用使质粒DNA逐渐凝集为紧密的球状结构,这种结构可能对奥沙利铂的抗癌活性和毒性产生重要影响.     

原子力显微镜在生物领域中的应用

原子力显微镜(AFM)作为生物样品表面表征的有力工具, 具有独特的优势。本文在介绍原子力显微镜基本原理的基础上, 综述了原子力显微镜样品制备以及原子力显微镜形貌分析、力曲线以及动力学分析在生物领域中的应用。     

红细胞膜弹性特性的AFM力曲线测量

人血红细胞生存环境的微小变化都会直接影响到膜骨架蛋白网络形变和细胞膜弹性力学性能的改变。利用原子力显微镜力曲线测量红细胞膜表面弹性,根据相关力。距离曲线图谱信息,分析活性红细胞在不同生理溶液环境中细胞膜弹性、黏附性与渗透脆性等变化特征。实验结果表明,经不同生理溶液制备的红细胞在维持其渗透压平衡条件下,细胞形态特征基本正常,直径约7-8μm。当力曲线图谱表征的膜弹性等力学特性,波动较大且差异明显时,形变恢复作用力变化范围为30-150pN,黏附力变化范围为3.9-35nN。尤其是在探针接近和撤离膜表面过程中,不同程度的多峰锯齿波、压痕深度、黏滞拖拽线程和链状伸展形式的相关力曲线图谱,表征细胞膜表面存在着复杂作用力。在无Ca^2＋／Mg^2＋的D-PBS缓冲液中,通过调节Na^＋,K^＋浓度,改变生理溶液渗透压,红细胞形变显著,出现棘轮状、球形和血影空囊等形态,对应的细胞膜弹性等力曲线图谱信息也相对更为复杂。研究表明红细胞膜弹性特性和膜骨架形变都与生理环境中的溶质（糖类与晶体电解质等）、浓度和渗透压等因素有直接关系。这为深入了解生物膜的结构和动力学提供了证据,也为原子力显微镜应用于红细胞膜病的临床诊断提供了依据。     

单分子装置：传感器、连接器、致动器

生物大分子之所以可以实现生物学功能是与其独特的力学性质息息相关的。作为纳米科技领域一个重要工具,原子力显微镜（AFM）可以对纳米尺度的生物大分子进行操纵并检测其力学性质。本文介绍了利用原子力显微镜对几类特殊蛋白以及DNA的力学性质的研究结果,发现这些生物分子具有很好的力学传感、连接和致动能力,将来有望作为单分子装置在纳米世界发挥更多功用。     

高碱性pH诱导紫膜片层表面结构变化的原子力显微镜直接观测

报道了在高碱性pH下,紫膜中细菌视紫红质(BR)表面结构变化的直观信息.紫外可见光谱实验发现,当pH上升到12.6,BR分子上的生色团视黄醛脱落,分子完全变性;原子力显微镜实验观测到在此pH下,紫膜片层的晶格结构瓦解,BR分子在紫膜上无规则聚集,同时出现非特征“岛屿”结构和特征“岛屿”结构.     

肌动蛋白的原子力显微镜研究

原子力显微镜 (AFM )是一种能够在生理条件下对生物大分子、活细胞表面以及细胞膜下结构进行在体或离体研究的强有力的新型工具 ,具有原子级的成像分辨率和纳牛顿级的力测定功能。目前原子力显微镜已被广泛地应用于生物大分子、超分子体系的结构解析、动力学过程观察 ,分子力学研究及细胞功能鉴定。原子力显微镜能够通过尖锐探针扫描待测样品表面 ,收集被测样品表面地貌坐标数据从而对单分子或细胞进行成像或操作 ,并能通过移动探针、记录探针与样品之间的作用力 ,对生物大分子 (蛋白质、核酸和多糖等 )的结构力学特性进行分析以获取分子构象、功能及其相互关系的有用信息。肌动蛋白是一种细胞内普遍存在 ,具有广泛、复杂生理功能的重要蛋白质 ,原子力显微镜的各项功能已广泛地用于肌动蛋白结构、功能及动力学研究。通过综述原子力显微镜在肌动蛋白研究中的应用 ,阐明了原子力显微镜在现代生命科学研究中的重要意义及巨大应用前景。     

Surface Plasmon Resonance Studies of the Hybridization Behavior of DNA-Modified Gold Nanoparticles with Surface-Attached DNA Probes

Colloidal gold nanoparticles (AuNPs) have been extensively investigated as amplification tags to improve the sensitivity of surface plasmon resonance (SPR) biosensors. When using the so-called AuNP-enhanced SPR technique for DNA detection, the density of single-stranded DNA (ssDNA) on both the AuNPs and planar gold substrates is of crucial importance. Thus, in this work, we carried out a systematical study about the influence of surface ssDNA density onto the hybridization behavior of various DNA-modified AuNPs (DNA-AuNPs) with surface-attached DNA probes by using surface plasmon resonance spectroscopy. The lateral densities of the ssDNA on both the AuNPs and planar gold substrates were controlled by using different lengths of oligo-adenine sequence (OAS) as anchoring group. Besides SPR measurements, the amount of the captured DNA-AuNPs after the hybridization was further identified via atomic force microscope (AFM). SPR and AFM results clearly indicated that a higher ssDNA density on either the AuNPs or the gold substrates would give rise to better hybridization efficiency. Moreover, SPR data showed that the captured DNA-AuNPs could not be removed from SPR sensor surfaces using various dehybridization solutions regardless of surface ssDNA density. Consequently, it is apparent that the hybridization behavior of DNA-AuNPs was different from that of solution-phase ssDNA. Based on these data, we hypothesized that both multiple recognitions and limited accessibility might account for the hybridization of DNA-AuNPs with surface-attached ssDNA probes.

     

Ultrastable atomic force microscopy: Improved force and positional stability

Atomic force microscopy (AFM) is an exciting technique for biophysical studies of single molecules, but its usefulness is limited by instrumental drift. We dramatically reduced positional drift by adding two lasers to track and thereby actively stabilize the tip and the surface. These lasers also enabled label-free optical images that were spatially aligned to the tip position. Finally, sub-pN force stability over 100 s was achieved by removing the gold coating from soft cantilevers. These enhancements to AFM instrumentation can immediately benefit research in biophysics and nanoscience.     

Genetic recombination in Bacillus subtilis: a division of labor between two single-strand DNA-binding proteins

We have investigated the structural, biochemical and cellular roles of the two single-stranded (ss) DNA-binding proteins from Bacillus subtilis, SsbA and SsbB. During transformation, SsbB localizes at the DNA entry pole where it binds and protects internalized ssDNA. The 2.8-Å resolution structure of SsbB bound to ssDNA reveals a similar overall protein architecture and ssDNA-binding surface to that of Escherichia coli SSB. SsbA, which binds ssDNA with higher affinity than SsbB, co-assembles onto SsbB-coated ssDNA and the two proteins inhibit ssDNA binding by the recombinase RecA. During chromosomal transformation, the RecA mediators RecO and DprA provide RecA access to ssDNA. Interestingly, RecO interaction with ssDNA-bound SsbA helps to dislodge both SsbA and SsbB from the DNA more efficiently than if the DNA is coated only with SsbA. Once RecA is nucleated onto the ssDNA, RecA filament elongation displaces SsbA and SsbB and enables RecA-mediated DNA strand exchange. During plasmid transformation, RecO localizes to the entry pole and catalyzes annealing of SsbA- or SsbA/SsbB-coated complementary ssDNAs to form duplex DNA with ssDNA tails. Our results provide a mechanistic framework for rationalizing the coordinated events modulated by SsbA, SsbB and RecO that are crucial for RecA-dependent chromosomal transformation and RecA-independent plasmid transformation.     

DNA microdevice for electrochemical detection of Escherichia coli 0157:H7 molecular markers

An electrochemical DNA sensor based on the hybridization recognition of a single-stranded DNA (ssDNA) probe immobilized onto a gold electrode to its complementary ssDNA is presented. The DNA probe is bound on gold surface electrode by using self-assembled monolayer (SAM) technology. An optimized mixed SAM with a blocking molecule preventing the nonspecific adsorption on the electrode surface has been prepared. In this paper, a DNA biosensor is designed by means of the immobilization of a single stranded DNA probe on an electrochemical transducer surface to recognize specifically Escherichia coli (E. coli) 0157:H7 complementary target DNA sequence via cyclic voltammetry experiments. The 21 mer DNA probe including a C6 alkanethiol group at the 5' phosphate end has been synthesized to form the SAM onto the gold surface through the gold sulfur bond. The goal of this paper has been to design, characterise and optimise an electrochemical DNA sensor. In order to investigate the oligonucleotide probe immobilization and the hybridization detection, experiments with different concentration of DNA and mismatch sequences have been performed. This microdevice has demonstrated the suitability of oligonucleotide Self-assembled monolayers (SAMs) on gold as immobilization method. The DNA probes deposited on gold surface have been functional and able to detect changes in bases sequence in a 21-mer oligonucleotide.     

DNA nanofilm thickness measurement on microarray in air and in liquid using an atomic force microscope

The measurement of the thickness of DNA films on microarray as a function of the medium (liquid, air) is gaining importance for understanding the signal response of biosensors. Thiol group has been used to attach DNA strands to gold micropads deposited on silicon surface. Atomic force microscopy (AFM) was employed in its height mode to measure the change in the pad thickness and in its force mode to measure the indentation depth of the nanofilm. A good coherence between the height and force modes is observed for the film thickness in air. The adhesion force was found to be an alternative way to measure the surface coverage of the biolayer at nanoscopic scale. However the force analysis (compression, steric and electrostatic) provides baseline information necessary to interpret the AFM height image in liquid. Analysis of the film thickness distribution shows that the height of the DNA strands depends on both the DNA strand length (15-35 base pairs) and the environment (air, liquid). In air, longer strands lay down onto gold surface whereas the charge reversal of gold in liquid causes a repulsion of longer strands, which stand up.     

A simple and efficient enzymatic method for covalent attachment of DNA to cellulose. Application for hybridization-restriction analysis and for in vitro synthesis of DNA probes.

Single-stranded DNAs (ssDNAs) were covalently bound by a simple and efficient enzymatic method to a solid support matrix and used to develop several new procedures for gene analysis. The novel procedure to prepare a ssDNA stably coupled to a solid support employed T4 DNA ligase to link covalently oligo (dT)-cellulose and (dA)-tailed DNA. Beginning with essentially any double stranded DNA the procedure generates a ssDNA linked by its 5' end to a cellulose matrix in a concentration of over 500 ng per mg. DNA from the plasmid pBR322 (4300 bp) and a fragment of the beta-globin gene (1800 bp) were coupled to the solid support and used for several experiments. The ssDNAs on the cellulose efficiently hybridized with as little as 5 pg of complementary double-stranded DNAs. The DNA hybrids formed on the solid support were specifically and efficiently cleaved by restriction endonucleases. These specific restriction cuts were utilized for the diagnosis of correct sequences. In addition, the ssDNA on the solid support served as an efficient template for the synthesis of complementary ssDNAs. The complementary synthesized ssDNAs were uniformly labeled, more than two kilobases in size, and largely full length. About 85% of the ssDNA linked to cellulose was available for the synthesis of complementary DNA, and after strand-separation, the preparation was reusable for the synthesis of additional complementary DNA.     

Bacillus subtilis DprA Recruits RecA onto Single-stranded DNA and Mediates Annealing of Complementary Strands Coated by SsbB and SsbA

Naturally transformable bacteria recombine internalized ssDNA with a homologous resident duplex (chromosomal transformation) or complementary internalized ssDNAs (plasmid or viral transformation). Bacillus subtilis competence-induced DprA, RecA, SsbB, and SsbA proteins are involved in the early processing of the internalized ssDNA, with DprA physically interacting with RecA. SsbB and SsbA bind and melt secondary structures in ssDNA but limit RecA loading onto ssDNA. DprA binds to ssDNA and facilitates partial dislodging of both single-stranded binding (SSB) proteins from ssDNA. In the absence of homologous duplex DNA, DprA does not significantly increase RecA nucleation onto protein-free ssDNA. DprA facilitates RecA nucleation and filament extension onto SsbB-coated or SsbB plus SsbA-coated ssDNA. DprA facilitates RecA-mediated DNA strand exchange in the presence of both SSB proteins. DprA, which plays a crucial role in plasmid transformation, anneals complementary strands preferentially coated by SsbB to form duplex circular plasmid molecules. Our results provide a mechanistic framework for conceptualizing the coordinated events modulated by SsbB in concert with SsbA and DprA that are crucial for RecA-dependent chromosomal transformation and RecA-independent plasmid transformation.     

Direct Force Measurement of the Interaction Between Liposome and the C2A Domain of Synaptotagmin I using Atomic Force Microscopy

The binding force between a liposome and the C2A domain of synaptotagmin I was determined by an atomic force microscopy (AFM). Liposomes were immobilized on the surface of the L1 sensor chip and the C2A domains, which recognize phosphatidylserine, were chemically conjugated onto a gold-coated cantilever tip. The average interaction force between the C2A domain and the liposome was 306 (±57) pN while the force between untreated cantilever and the liposome was 58 (±16) pN. This work helps understand the physicochemical interactions between proteins and lipid vesicles for the design of high affinity protein probes against the apoptotic cell surface. Revisions requested 13 December 2005; Revisions received 9 January 2006     

Electrochemical properties of DNA-intercalating doxorubicin and methylene blue on n-hexadecyl mercaptan-doped 5'-thiol-labeled DNA-modified gold electrodes

Interactions between DNA-intercalating molecules, methylene blue (MB) and doxorubicin (DOX), and gold surface modified by various DNA species and n-hexadecyl mercaptan (HDM) were investigated by cyclic voltammetry (CV). Hydrophilic DOX was completely blocked by the HDM film from contacting the gold electrode whereas hydrophobic MB could readily partition into the film. Unlabeled single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) underwent non-specific adsorption on gold surface but the adsorbed DNA can be partially displaced by HDM. Thiol-labeled ssDNA and dsDNA adsorbed on gold surface via both thiol-gold linkage and non-specific interactions between DNA strands and gold. The non-specific interactions could be interrupted by the addition of HDM, forming a mixed monolayer containing both HDM and DNA attached to the gold surface at 5'-thiol termini. The presence of ssDNA and dsDNA in the monolayer facilitated the redox reaction of MB and DOX on the modified electrode. Both MB and DOX diffuse along the ssDNA in the ssDNA-containing monolayers, and they additionally intercalate into the dsDNA in the dsDNA-containing monolayers. No sufficient evidence is shown to indicate that an organized monolayer is formed by the thiol-labeled dsDNA on gold surface, and that the redox reactions of MB and DOX were carried out by electron transfer through DNA helix.     

Atomic force microscopy of oriented linear DNA molecules labeled with 5nm gold spheres.

The atomic force microscope (AFM;1) can image DNA and RNA in air and under solutions at resolution comparable to that obtained by electron microscopy (EM) (2-7). We have developed a method for depositing and imaging linear DNA molecules to which 5nm gold spheres have been attached. The gold spheres facilitate orientation of the DNA molecules on the mica surface to which they are absorbed and are potentially useful as internal height standards and as high resolution gene or sequence specific tags. We show that by modulating their adhesion to the mica surface, the gold spheres can be moved with some degree of control with the scanning tip.