1st Edition

Atomic Force Microscopy in Nanobiology

Edited By Kunio Takeyasu Copyright 2014
    458 Pages 24 Color & 172 B/W Illustrations
    by Jenny Stanford Publishing

    Recent developments in atomic force microscopy (AFM) have been accomplished through various technical and instrumental innovations, including high-resolution and recognition imaging technology under physiological conditions, fast-scanning AFM, and general methods for cantilever modification and force measurement. All these techniques are now highly powerful not only in material sciences but also in basic biological sciences. There are many nanotechnology books that focus on materials, instruments, and applications in engineering and medicine, but only a few of them are directed toward basic biological sciences. This book tries to bridge this gap.

    Edited by a prominent researcher, this volume provides an overview of modern AFM technologies: the basic AFM protocols in Part I, newly developed technologies in Part II, and the most recent applications of AFM technologies in biological sciences in Parts III and IV. The chapters are contributed by some of the leading scientists in the field of nanobiology.

    Basics for AFM. A Short Story of AFM in Biology. Protocols for Specimen and Substrate Preparation, and Data Correction Methods. Chemical Modification of AFM Probe and Coupling with Biomolecules. Single Molecule Dissection and Isolation Based on AFM Nano-Manipulations. Development of AFM Technology: Imaging Dynamics and Complexities. Structural Biology with Cryo AFM and Computational Modeling. Development of Non-Contact High-Resolution AFM and its Biological Applications. Development of Recognition Imaging – From Molecule to Cells. Development of High-Speed AFM and Its Biological Applications. Real-Time AFM Combined with an Inverted Optical Microscope for Wetcell/Tissue Imaging. Imaging Membranes, Proteins and DNA. AFM imaging of Cells (Fixed and Living) and of Particularcellular Organelles and Compartments. Determination of the Architecture of Multi-Subunit Proteins Using AFM Imaging. Capturing Membrane Proteins at Work. Enzymes and DNA: Molecular Motors in Action. Genome Folding Mechanisms in the Three Domains of Life Revealed by AFM Imaging. Imaging, Force Spectroscopy and Physiology. Membrane Dynamics: Lipid-Protein Interaction Studied by AFM. Nano Surgery and Cytoskeletal Mechanics of Single Cell. Functional Investigations on Nuclear Pores with Atomic Force Microscopy. Mechanotransduction: Probing its Mechanisms at the Nanoscale using the Atomic Force Microscope.

    Biography

    Kunio Takeyasu was trained as a zoologist and neuro-pharmacologist in his early career when he was a graduate student at Hiroshima University and Osaka University. After his postdoctoral research on the molecular and cell biological aspects of membrane proteins such as acetylcholine receptors and ion-motive ATPases at Cornell University and the Johns Hopkins University, he joined the University of Virginia as an assistant professor in 1988 and started to utilize atomic force microscopy (AFM) in biological studies. After four years of research and teaching at The Ohio State University, he moved to Kyoto University as a full professor in 1995. Since then, he has been developing technologies for biological application of AFM. His most recent research has been focused on single-molecule imaging of membrane proteins and chromatin at sub-second time region with nanometer space resolution. Prof. Takeyasu has been a member of the Biophysical Society and the American Society for Cell Biology.

    "An outstanding review of the current AFM technology and a must-read for light microscopists interested in super-resolution approaches."

    Prof. Michael Tamkun, Colorado State University, USA

    "In the last decade, atomic force microscope (AFM) has developed as a tool for imaging the surface of biological samples and for measuring forces at the nanoscale level. Edited by Dr. Takeyasu, this book covers many topics from basic AFM protocols to specific ones that are essential to investigate ligand–receptor binding strength, motion, and dissociation dynamics. It also discusses newly developed technologies and provides new approaches to understand the molecular mechanisms in biological sciences."

    Prof. Juan C. Alonso, Centro Nacional de Biotecnologia (CSIC), Spain