共查询到19条相似文献,搜索用时 78 毫秒
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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。 相似文献
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原子力显微镜(atomic force microscope,AFM)是扫描探针显微镜(SPM)的一种,其分辨率达到纳米级,能对从原子到分子尺度的结构进行三维成像和测量,能观察任何活的生命样品及动态过程。本文概述了AFM的基本工作原理及在生物医学上对DNA、蛋白质、细胞及生物过程等方面进行的研究。 相似文献
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原子力显微镜(AFM)不仅能对纳米生物结构进行实时动态的形态和结构观察,而且还能以10^-12N(pN)的精度对溶液中生物分子表面的相互作用力进行直接测量,逐渐成为一种研究受体-配体间相互作用的良好工具。本简要综述用AFM研究受体-配体间作用力、受体-配体间相互作用的影响因素及对这些因素的处理方法。 相似文献
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人工操纵病毒的原子力显微镜研究 总被引:5,自引:0,他引:5
人工操纵生物大分子是目前科学研究的一个前沿领域, 我们利用改进的“分子梳”方法,首次实现了复杂的体系——一种线性噬菌体病毒的人工拉直与定向. 这种操纵是在大面积平整的固体表面实现的, 并利用原子力显微镜对拉直前后的病毒进行了观察与测量. 相似文献
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肌动蛋白的原子力显微镜研究 总被引:6,自引:1,他引:5
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。 相似文献
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目的 采用原子力显微镜对应用抗菌剂纳米Ag-Ti02作用后的口腔两种常见致病菌的分子形貌进行观测,为研究其抑菌机制提供有力的直观影像科学依据和可靠、直观的实验方法.方法 选择两种菌种:白色假丝酵母菌、变形链球菌,采用液体稀释法将纳米Ag-TiO2与两种菌相互作用,分别使用光学显微镜、原子力显微镜观察两种菌的细胞微观形态变化.结果 抗菌剂与两种菌作用后,细菌形态均有不同程度的改变,甚至是死亡.结论 原子力显微镜能直观地显示白色假丝酵母菌,变形链球菌的分子结构,通过本实验在研究纳米Ag-TiO2抗菌剂对白色假丝酵母菌,变形链球菌的抑菌机理形态学改变方面做了进一步的完善. 相似文献
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原子力显微术不仅能够提供样品表面纳米级别分辨率的三维图像数据,而且能够对pN级微小力进行测量,同时将两者结合发展出的TREC(topography and recognition)显微术还能够在进行高分辨成像的同时实现对特定分子的定位。原子力显微术的这些特点使之成为生物化学、细胞生物学等生物研究的有利工具。本文主要介绍了原子力显微镜高分辨成像和检测生物分子识别的原理,以及TREC显微术在生物学上的应用。 相似文献
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Observing single biomolecules at work with the atomic force microscope 总被引:28,自引:0,他引:28
Progress in the application of the atomic force microscope (AFM) to imaging and manipulating biomolecules is the result of improved instrumentation, sample preparation methods and image acquisition conditions. Biological membranes can be imaged in their native state at a lateral resolution of 0.5-1 nm and a vertical resolution of 0. 1-0.2 nm. Conformational changes that are related to functions can be resolved to a similar resolution, complementing atomic structure data acquired by other methods. The unique capability of the AFM to directly observe single proteins in their native environments provides insights into the interactions of proteins that form functional assemblies. In addition, single molecule force spectroscopy combined with single molecule imaging provides unprecedented possibilities for analyzing intramolecular and intermolecular forces. This review discusses recent examples that illustrate the power of AFM. 相似文献
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An overview of the biophysical applications of atomic force microscopy 总被引:10,自引:0,他引:10
The potentialities of the atomic force microscopy (AFM) make it a tool of undeniable value for the study of biologically relevant samples. AFM is progressively becoming a usual benchtop technique. In average, more than one paper is published every day on AFM biological applications. This figure overcomes materials science applications, showing that 17 years after its invention, AFM has completely crossed the limits of its traditional areas of application. Its potential to image the structure of biomolecules or bio-surfaces with molecular or even sub-molecular resolution, study samples under physiological conditions (which allows to follow in situ the real time dynamics of some biological events), measure local chemical, physical and mechanical properties of a sample and manipulate single molecules should be emphasized. 相似文献
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原子力显微技术在酶学研究中的应用 总被引:1,自引:0,他引:1
酶在生物体的生命活动中占有及其重要的地位,机体功能的和谐统一有赖于酶的作用。原子力显微技术(AFM)作为一门新发展起来的技术,为人们认识酶的结构与功能提供了又一新的窗口。AFM能够在生理条件下对生物样品进行三维成像,在分子水平上实时监测生理生化反应。AFM还能够在皮牛顿精度上测定分子间作用力。目前,AFM已用于单分子酶的化学性质及其作用原理的研究。本简述AFM在酶学中的应用情况。 相似文献
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Quantitative characterization of biomolecular assemblies and interactions using atomic force microscopy 总被引:4,自引:0,他引:4
Atomic force microscopy (AFM) has been applied in many biological investigations in the past 15 years. This review focuses on the application of AFM for quantitatively characterizing the structural and thermodynamic properties of protein-protein and protein-nucleic acid complexes. AFM can be used to determine the stoichiometries and association constants of multiprotein assemblies and to quantify changes in conformations of proteins and protein-nucleic acid complexes. In addition, AFM in solution permits the observation of the dynamic properties of biomolecular complexes and the measurement of intermolecular forces between biomolecules. Recent advances in cryogenic AFM, AFM on two-dimensional crystals, carbon nanotube probes, solution imaging, high-speed AFM, and manipulation capabilities enhance these applications by improving AFM resolution and the dynamic and operative capabilities of the AFM. These developments make AFM a powerful tool for investigating the biomolecular assemblies and interactions that govern gene regulation. 相似文献
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Milhiet PE Dosset P Giocondi MC Le Grimellec C 《Journal de la Société de Biologie》2004,198(2):169-174
The atomic force microscope (AFM) allows to explore the surface of biological samples bathed in physiological solutions, with vertical and horizontal resolutions ranging from nanometers to angstr?ms. Complex biological structures as well as single molecules can be observed and recent examples of the possibilities offered by the AFM in the imaging of intact cells, isolated membranes, membrane model systems and single molecules are discussed in this review. Applications where the AFM tip is used as a nanotool to manipulate biomolecules and to determine intra and intermolecular forces from single molecules are also presented. 相似文献
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To gain insights into how biological molecules function, advanced technologies enabling imaging, sensing, and actuating single molecules are required. The atomic force microscope (AFM) would be one of novel potential tools for these tasks. In this study, techniques and efforts using AFM to probe biomolecules are introduced and reviewed. The state-of-art techniques for characterizing specific single receptor using the functionalized AFM tip are discussed. An example of studying the angiotensin II type 1 (AT1) receptors expressed in sensory neuronal cells by AFM with a functionalized tip is given. Perspectives for identifying and characterizing specific individual membrane proteins using AFM in living cells are provided. Given that many diseases have their roots at the molecular scale and are best understood as a malfunctioning biological nanomachines, the prospects of these unique techniques in basic biomedical research or in clinical practice are beyond our imagination. 相似文献
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Using a sharp tip attached at the end of a soft cantilever as a probe, the atomic force microscope (AFM) explores the surface topography of biological samples bathed in physiological solutions. In the last few years, the AFM has gained popularity among biologists. This has been obtained through the improvement of the equipment and imaging techniques as well as through the development of new non-imaging applications. Biological imaging has to face a main difficulty that is the softness and the dynamics of most biological materials. Progress in understanding the AFM tip-biological samples interactions provided spectacular results in different biological fields. Recent examples of the possibilities offered by the AFM in the imaging of intact cells, isolated membranes, membrane model systems and single molecules at work are discussed in this review. Applications where the AFM tip is used as a nanotool to manipulate biomolecules and to determine intra- and intermolecular forces from single molecules are also presented. 相似文献
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Atomic force microscopy (AFM) has proven to be a powerful tool in biological sciences. Its particular advantage over other high-resolution methods commonly used is that biomolecules can be investigated not only under physiological conditions but also while they perform their biological functions. Single-molecule force spectroscopy with AFM tip-modification techniques can provide insight into intermolecular forces between individual ligand-receptor pairs of biological systems. Here we present protocols for force spectroscopy of living cells, including cell sample preparation, tip chemistry, step-by-step AFM imaging, force spectroscopy and data analysis. We also delineate critical steps and describe limitations that we have experienced. The entire protocol can be completed in 12 h. The model studies discussed here demonstrate the power of AFM for studying transmembrane transporters at the single-molecule level. 相似文献
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We describe here a method for constructing ordered molecular arrays and for detecting binding of biomolecules to these arrays using atomic force microscopy (AFM). These arrays simplify the discrimination of surface-bound biomolecules through the spatial control of ligand presentation. First, photolithography is used to spatially direct the synthesis of a matrix of biological ligands. A high-affinity binding partner is then applied to the matrix, which binds at locations defined by the ligand array. AFM is then used to detect the presence and organization of the high-affinity binding partner. Streptavidin-biotin arrays of 100 x 100 microns and 8 x 8 microns elements were fabricated by this method. Contact and noncontact AFM images reveal a dense lawn of streptavidin specific to the regions of biotin derivatization. These protein regions are characterized by a height profile of approximately 40 A over the base substrate with a 350-nm edge corresponding to the diffraction zone of the photolithography. High resolution scans reveal a granular topography dominated by 300 A diameter features. The ligand-bound protein can then be etched from the substrate using the AFM tip, leaving an 8 A shelf that probably corresponds to the underlying biotin layer. 相似文献