Application of atomic force microscopy to the study of micromechanical properties of biological materials

Atomic force microscopy (AFM) has been used to study the micromechanical properties of biological systems. Its unique ability to function both as an imaging device and force sensor with nanometer resolution in both gaseous and liquid environments has meant that AFM has provided unique insights into the mechanical behaviour of tissues, cells and single molecules. As a surface scanning device, AFM can map properties such as adhesion and the Young's modulus of surfaces. As a force sensor and nanoindentor AFM can directly measure properties such as the Young's modulus of surfaces or the binding forces of cells. As a stress-strain gauge AFM can study the stretching of single molecules or fibres and as a nanomanipulator it can dissect biological particles such as viruses or DNA strands. The present paper reviews key research that has demonstrated the versatility of AFM and how it can be exploited to study the micromechanical behaviour of biological materials.     

原子力显微镜对纳米生物结构的观察和操纵

原子力显微镜不仅能对纳米生物结构进行观察,而且也能对其进行操纵。对纳米生物结构的观察已深入到生物大分子结构水平。原子力显微镜对生物大分子的操纵包括从染色质中提取DNA用于基因分析、对膜蛋白的结构进行观察、对蛋白构象进行可控操纵等。这些纳米技术的应用将揭示生物系统更多的结构和功能信息。     

Surface topography of membrane domains

Elucidating origin, composition, size, and lifetime of microdomains in biological membranes remains a major issue for the understanding of cell biology. For lipid domains, the lack of a direct access to the behaviour of samples at the mesoscopic scale has constituted for long a major obstacle to their characterization, even in simple model systems made of immiscible binary mixtures. By its capacity to image soft surfaces with a resolution that extends from the molecular to the microscopic level, in air as well as under liquid, atomic force microscopy (AFM) has filled this gap and has become an inescapable tool in the study of the surface topography of model membrane domains, the first essential step for the understanding of biomembranes organization. In this review we mainly focus on the type of information on lipid microdomains in model systems that only AFM can provide. We will also examine how AFM can contribute to understand data acquired by a variety of other techniques and present recent developments which might open new avenues in model and biomembrane AFM applications.     

Extraction of membrane proteins from a living cell surface using the atomic force microscope and covalent crosslinkers

The force curve mode of the atomic force microscope (AFM) was applied to extract intrinsic membrane proteins from the surface of live cells using AFM tips modified by amino reactive bifunctional covalent crosslinkers. The modified AFM tips were individually brought into brief contact with the living cell surface to form covalent bonds with cell surface molecules. The force curves recorded during the detachment process from the cell surface were often characterized by an extension of a few hundred nanometers followed mostly by a single step jump to the zero force level. Collection and analysis of the final rupture force revealed that the most frequent force values (of the force) were in the range of 0.4–0.6 nN. The observed rupture force most likely represented extraction events of intrinsic membrane proteins from the cell membrane because the rupture force of a covalent crosslinking system was expected to be significantly larger than 1.0 nN, and the separation force of noncovalent ligand-receptor pairs to be less than 0.2 nN, under similar experimental conditions. The transfer of cell surface proteins to the AFM tip was verified by recording characteristic force curves of protein stretching between the AFM tips used on the cell surface and a silicon surface modified with amino reactive bifunctional crosslinkers. This method will be a useful addition to bionanotechnological research for the application of AFM.     

Single-molecule recognition force spectroscopy of transmembrane transporters on living cells

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.     

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。     

Heterogeneous cell mechanical properties: an atomic force microscopy study.

Atomic force microscopy (AFM) is a non-invasive microscopy to explore living biological systems like cells in liquid environment. Thus AFM is an appropriate tool to investigate surface chemical modification and its influence on biological systems. In particular, control over biomaterial surface chemistry can result in a regulated cell response. This report investigates the influence of adhesive and non-adhesive surfaces on the cell morphology and the influence of the cytoskeleton structure on the local mechanical properties. In this study, the main work concerns a thorough investigation of the height images obtained with an AFM as therecorded images provide the evolution of the mechanical properties of the cell as function of its local structure. Information on the cell elasticity due to the cytoskeleton organization is deduced when comparing the AFM tip indentation depth versus the distance between the cytoskeleton bundles for the different samples.     

Magnetic force microscopy of iron oxide nanoparticles and their cellular uptake

Magnetic force microscopy has the capability to detect magnetic domains from a close distance, which can provide the magnetic force gradient image of the scanned samples and also simultaneously obtain atomic force microscope (AFM) topography image as well as AFM phase image. In this work, we demonstrate the use of magnetic force microscopy together with AFM topography and phase imaging for the characterization of magnetic iron oxide nanoparticles and their cellular uptake behavior with the MCF7 carcinoma breast epithelial cells. This method can provide useful information such as the magnetic responses of nanoparticles, nanoparticle spatial localization, cell morphology, and cell surface domains at the same time for better understanding magnetic nanoparticle‐cell interaction. It would help to design magnetic‐related new imaging, diagnostic and therapeutic methods. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Cellular secretion studied by force microscopy

Using the optical microscope, real adventures in cellular research began in earnest in the latter half of the nineteenth century. With the development of the electron microscope, ultramicroscopy, and improved cell staining techniques, significant advances were made in defining intracellular structures at the nanometer level. The invention of force microscopy, the atomic force microscope (AFM) in the mid 1980s, and the photonic force microscope (PFM) in the mid 1990s, finally provided the opportunity to study live cellular structure-function at the nanometer level. Working with the AFM, dynamic cellular and subcellular events at the molecular level were captured in the mid 1990s, and a new cellular structure 'the porosome' in the plasma membrane of all secretory cells has been defined, where specific docking and fusion of secretory vesicles occur. The molecular mechanism of fusion of the secretory vesicle membrane at the base of the porosome membrane in cells, and the regulated release of intravesicular contents through the porosome opening to the extracellular space, has been determined. These seminal discoveries provide for the first time a molecular mechanism of cell secretion, and the possibility to ameliorate secretory defects in disease states.     

The application of atomic force microscopy to the study of living vertebrate cells in culture

Atomic force microscopy (AFM), a relatively new variant of scanning probe microscopy developed for the material sciences, is becoming an increasingly important tool in other disciplines. In this review I describe in nontechnical terms some of the basic aspects of using AFM to study living vertebrate cells. Although AFM has some unusual attributes such as an ability to be used with living cells, AFM also has attributes that make its use in cell biology a real challenge. This review was written to encourage researchers in the biological and biomedical sciences to consider AFM as a potential (and potent) tool for their cell biological research.     

ANALYSIS OF LIGAND–RECEPTOR INTERACTIONS IN CELLS BY ATOMIC FORCE MICROSCOPY

ABSTRACT

Atomic force microscopy (AFM) increasingly has been used to analyse “receptor” function, either by using purified proteins (“molecular recognition microscopy”) or, more recently, in situ in living cells. The latter approach has been enabled by the use of a modified commercial AFM, linked to a confocal microscope, which has allowed adhesion forces between ligands and receptors in cells to be measured and mapped, and downstream cellular responses analysed. We review the application of AFM to cell biology and, in particular, to the study of ligand–receptor interactions and draw examples from our own work and that of others to show the utility of AFM, including for the exploration of cell surface functionalities. We also identify shortcomings of AFM in comparison to “standard” methods, such as receptor auto-radiography or immuno-detection, that are widely applied in cell biology and pharmacological analysis.     

Probing elasticity and adhesion of live cells by atomic force microscopy indentation

Atomic force microscopy (AFM) indentation has become an important technique for quantifying the mechanical properties of live cells at nanoscale. However, determination of cell elasticity modulus from the force–displacement curves measured in the AFM indentations is not a trivial task. The present work shows that these force–displacement curves are affected by indenter-cell adhesion force, while the use of an appropriate indentation model may provide information on the cell elasticity and the work of adhesion of the cell membrane to the surface of the AFM probes. A recently proposed indentation model (Sirghi, Rossi in Appl Phys Lett 89:243118, 2006), which accounts for the effect of the adhesion force in nanoscale indentation, is applied to the AFM indentation experiments performed on live cells with pyramidal indenters. The model considers that the indentation force equilibrates the elastic force of the cell cytoskeleton and the adhesion force of the cell membrane. It is assumed that the indenter-cell contact area and the adhesion force decrease continuously during the unloading part of the indentation (peeling model). Force–displacement curves measured in indentation experiments performed with silicon nitride AFM probes with pyramidal tips on live cells (mouse fibroblast Balb/c3T3 clone A31-1-1) in physiological medium at 37°C agree well with the theoretical prediction and are used to determine the cell elasticity modulus and indenter-cell work of adhesion. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

利用原子力显微镜对A型流感病毒的形态学研究

利用透射电子显微镜(TEM)和原子力显微镜(AFM)观察流感病毒(H1N1),探讨AFM在病毒形态研究中的应用,为病毒形态学研究提供一种新型、简便、快捷的工具.TEM采用磷钨酸负染方法,AFM采用轻敲模式在大气常温下扫描成像,并对主要指标长度(直径)、Ra、Rq等进行测量.两种方法最终得到相似的形态学结果,流感病毒呈球状、丝状,并有一些形状介于两者之间.TEM提供了流感病毒二维图像,可见钉状突起,AFM则呈现了流感病毒三维图像,且可见病毒表面有凹凸不平的特征和边缘有齿轮状的突起,同时获得表面粗糙度等可以量化指标.与TEM观察相比,原子力显微镜是一种制样简单、观察直观的新型病毒形态学研究工具,其表征参数可以作为病毒形态学研究的量化指标.     

原子力显微镜研究多西他赛对人肺腺癌A549细胞的作用机制

利用原子力显微镜(AFM)研究了化疗药物多西他赛对肺腺癌细胞A549的作用机制。选取了不同浓度多西他赛作用下的A549细胞,观察和分析了多西他赛对A549细胞形貌信息和生物力学特性的影响。结果表明细胞的峰谷差和超微结构的平均粗糙度随着药物浓度增加而减小,表面粘附力随着药物浓度增加而增大。该结果对AFM可作为一种利用纳米量级分辨率进行药物药效评估的工具进行了佐证。     

原子力显微镜研究不同刺激条件下T细胞的形态和生物力学特性

T细胞的抗原识别和活化可以直接影响整个免疫应答的性质、效能和结果,在人体免疫反应中具有核心作用.细胞的形态结构和力学特性决定着细胞的功能的发挥.利用原子力显微镜（AFM）从纳米水平和皮牛顿量级探测分析静息的T细胞和不同刺激剂（超抗原SEA和植物凝集素PHA）活化的T细胞的形态结构和生物力学特性.研究发现静息的T细胞呈较为规则的圆形,细胞表面相对光滑均一,活化后细胞高度和体积明显增大,体积增大为静息T细胞的2~3倍,高度增加了约50%,这是T细胞经过刺激剂活化后增殖、分化而增大的表现.同时发现活化后的T细胞表面粗糙度增大,细胞表面形成100 nm~1 μm颗粒状团簇结构.这种微纳结构域的形成与T细胞经过活化后细胞表面分子表达和细胞因子的分泌有关,并且与免疫突触的形成和功能发挥密切关联.经过PHA和SEA活化后的T细胞表面粘附力增大,是静息的T细胞的3-6倍,而细胞硬度明显减小,这种力学特性的变化有利于T细胞与病原体的相关作用从而清除病原体.通过AFM的研究,可以进一步的了解T淋巴细胞形态变化与细胞行为之间的关系,为更好地理解T细胞的结构与功能提供了更多可视化的依据.     

Identification of TrkA on living PC12 cells by atomic force microscopy

In neural cells, nerve growth factor (NGF) initiates its survival signal through the binding to its cell surface receptor tyrosine kinase A (TrkA). Understanding the pattern of TrkA distribution and association in living cells can provide a fingerprint for the diagnostic comparison with alterations underlying ligand-receptor dysfunction seen in various neurological diseases. In this study, we use the NGF-TrkA-specific interaction as a probe to identify TrkA on living PC12 cell by atomic force microscopy (AFM). An NGF-modified AFM tip was used to perform force volume (FV) imaging, generating a 2D force map to illustrate the distribution and association of TrkA on PC12 cell membrane. It is found that TrkA is highly aggregated at local regions of the cell. This unique protein association may be required to promote its function as a receptor of NGF. The methodology that we developed in this study can be adapted by other systems, thus providing a general tool for investigating protein association in its natural environment.     

Cell classification by moments and continuous wavelet transform methods

Image processing techniques are bringing new insights to biomedical research. The automatic recognition and classification of biomedical objects can enhance work efficiency while identifying new inter-relationships among biological features. In this work, a simple rule-based decision tree classifier is developed to classify typical features of mixed cell types investigated by atomic force microscopy (AFM). A combination of continuous wavelet transform (CWT) and moment-based features are extracted from the AFM data to represent that shape information of different cellular objects at multiple resolution levels. The features are shown to be invariant under operations of translation, rotation, and scaling. The features are then used in a simple rule-based classifier to discriminate between anucleate versus nucleate cell types or to distinguish cells from a fibrous environment such as a tissue scaffold or stint. Since each feature has clear physical meaning, the decision rule of this tree classifier is simple, which makes it very suitable for online processing. Experimental results on AFM data confirm that the performance of this classifier is robust and reliable.     

Single cell analytics for nanobiology

Single cell analytics allows quantitative investigation of single biological cells from a structural, functional and proteomics point of view and opens possibilities to a novel unamplified cell analysis inherently insensitive to ensemble-averaging, cell-cycle or cell-population effects. We report on three different experimental methods and their application to cellular systems with single molecule sensitivity at the single cell level. Firstly, atomic force microscopy (AFM) can be used to elucidate the surface structure of living bacteria down to the nanometer scale where identification of irregular surface areas and 2D-arrays of regular protein s-layers is possible. Secondly, single cell manipulation and probing experiments with optical tweezers (OT) force spectroscopy allows quantitative identification of individual recognition events of membrane bound receptors. And thirdly, a novel, single cell analysis for protein fingerprinting in structured microfluidic device format will allow a future (label-free) on-chip electrophoretical protein separation of single cells without preamplification.     

Atomic force microscopy measurements. Measurements of binding strength between a single pair of molecules in physiological solutions

Atomic force microscopy (AFM) measurements of intermolecular binding strength between a single pair of complementary cell adhesion molecules in physiological solutions provided the first quantitative evidence for their cohesive function. This novel AFM based nanobiotechnology opens a molecular mechanic approach for studying structure to function related properties of any type of individual biological macromolecules. The presented example of Porifera cell adhesion glyconectin proteoglycans showed that homotypic carbohydrate to carbohydrate interactions between two primordial proteogylycans can hold the weight of 1600 cells. Thus, glyconectin type carbohydrates, as the most peripheral cell surface molecules of sponges (today’s simplest living Metazoa), are proposed to the primary cell adhesive molecules essential for the evolution of the multicellularity.