Single Molecule Tools, Part B: Super-Resolution, Particle Tracking, Multiparameter, and Force Based Methods

<p>1. Watching single DNA replication loops under flow extension</p> <p>Antoine Van Oijen</p> <p>2. Star polymer surface passivation for single molecule detection</p> <p>Jürgen Groll , Martin Möller</p> <p>3. Ultrahigh resolution detection of single active motor proteins in live cells</p> <p>Paul Selvin, Erdal Toprak & Comert Kural</p> <p>4. Molecules and Methods for Superresolution Imaging</p> <p>W.E. Moerner, Michael Thompson, Sam Lord, Julie Biteen, and Nick Conley +…</p> <p>5. Aqueous nanodroplets for studying single molecules</p> <p>Lori Goldner</p> <p>6. High-speed atomic force microscopy techniques for visualizing dynamic behavior of biological macromolecules </p> <p>Toshio Ando</p> <p>7. Single-Biomolecule Spectroscopy Using Microfluidic Platforms</p> <p>Richard Zare, Dr. Olga Dudko, Dr. Jérôme Mathé</p> <p>8. DNA Looping Kinetics Analyzed by Tethered Particle Microscopy</p> <p>Laura Finzi</p> <p>9. Single molecule observation of proteins in vivo</p> <p>Shimon Weiss, Gopal Iyer</p> <p>10. DNA curtains as a high-throughput approach to single molecule imaging</p> <p>Eric Greene</p> <p>11. Single-molecule enzymology of protein synthesis</p> <p>Ruben Gonzalez</p> <p>12. Single molecule fluorescence studies of intrinsically disordered proteins</p> <p>Ashok Deniz</p> <p>13. Nanovesicle trapping for studying transient protein-protein interactions by single molecule FRET</p> <p>Peng Chen</p> <p>14. Tracking single motor proteins in the cytoplasm of mammalian cells</p> <p>Edgar Meyhöfer</p> <p>15. Conformational States of F1-ATPase by Single-Molecule Rotation</p> <p>Hiroyuki Noji</p> <p>16. Single Molecule Sequencing by Fluorescence Imaging</p> <p>Patrice Milos</p> <p>17. Real-Time DNA Sequencing from Single Polymerase Molecules</p> <p>Jonas Korlach</p> <p>18. Micropatterning and single molecule imaging for quantitative analysis of protein-protein interactions in living cells</p> <p>Gerhard Schütz</p> <p>19. Probing virus-receptor interactions by atomic force spectroscopy</p> <p>Peter Hinterdorfer</p> <p>20. Single-Molecule Fluorescence Spectroscopy of Cytochrome P450 in Nanodiscs</p> <p>Elizabeth Rhoades, William M. Atkins</p> <p>21. Analysis of complex single molecule FRET time traces</p> <p>Nils Walter, Mario Blanco</p> <p>22. Application of super-resolution imaging to single particle tracking in nanotechnology</p> <p>Nils Walter, Chamaree de Silva & Anthony Manzo</p> <p>23. Scanning FCS for the characterization of protein dynamics in live cells</p> <p>Petra Schwille</p> <p>24. Single mRNA molecule tracking in live cells</p> <p>Rob Singer</p> <p>25. Single-molecule high-resolution colocalization (SHREC) or Single-molecule optical-trap analyses of protein structure</p> <p>James Spudich</p> <p>26. Nanopore force Spectroscopy tools for analyzing single bio-complexes</p> <p>Amit Meller</p> <p>27. Use of plasmon coupling to reveal DNA dynamics at the single molecule level</p> <p>Jan Liphardt</p> <p>28. "Fluorescence-force spectroscopy" or "Suppression of fluorophore blinking and bleaching" or "Spontaneous intersubunit rotation of the ribosome"</p> <p>Taekjip Ha</p> <p>29. Multiplexed single mRNA imaging in fixed cells</p> <p>Sanjay Tyagi, Arjun Raj</p> <p>30. Size-Minimized Quantum Dots for Single-Molecule and Intracellular Imaging</p> <p>Shuming Nie</p> <p>31. The ABEL trap</p> <p>Adam Cohen, Alex Fields</p> <p>32. An optical torque wrench</p> <p>Steve Block, Arthur La Porta</p> <p>33. Determining the Stoichiometry of Protein Hetero-complexes in Living Cells with Fluorescence Fluctuation Spectroscopy</p> <p>Joachim Mueller</p> <p>34. Fluorescent Visualization of Single Protein-DNA Complexes</p> <p>Steve Kowalzcykowski</p> <p>35. Direct Measurement of Tertiary Contact Cooperativity in RNA Folding by single molecule FRET</p> <p>Daniel Herschlag</p> <p>36. Nanometer-localized multiple single-molecule (NALMS) or Single-molecule nonequilibrium periodic Mg2+-concentration jump experiments</p> <p>Norbert Scherer</p> <p>37. Multiparameter single molecule fluorescence detection with applications to FRET</p> <p>Claus Seidel</p> <p>38. single-particle tracking-photoactivated localization microscopy (sptPALM) within live cells</p> <p>Jennifer Lippincott-Schwartz, Suliana Manley</p> <p>39. Site-specific incoporation of fluorescent probes into RNA polymerase</p> <p>Richard Ebright</p> <p>40. Quantitative single-molecule imaging by confocal laser scanning microscopy</p> <p>Rudolph Rigler</p> <p>41. Studies of DNA-replication at the single molecule level using magnetic tweezers</p> <p>David Bensimon, Vincent Croquette</p> <p>42. RNA labeled for single molecule FRET analysis from ligation with T4 RNA ligases</p> <p>John Abelson</p> <p>43. Combining optical tweezers, single-molecule fluorescence microscopy and microfluidics for studying reversible protein-DNA interactions</p> <p>Gijs Wuite, G. Farge, P. Gross & E.J.G. Peterman</p> <p>44. How dwell time distributions and other such observables in single molecule analysis can be used to extract information from molecular systems</p> <p>Carlos Bustamante, Jeff Moffitt & Yann Robert Chemla</p> <p>45. Atomic force microscopy studies of human rhinovirus: topology and molecular forces</p> <p>Peter Hinterdorfer</p>