“Single molecule biophysics and nanotechnology” 6h lecture + 6h labs by Prof. Robert Szoszkiewicz, Dept. of Physics, Kansas State University, USA. Picture adopted from S. Block group, Stanford, USA Yasuda et al. Nature 2001. Picture adopted from T. Ha group, UIUC, USA Abbondanzieri et al. Nature 2005. How it is possible to visualize a single protein or a DNA molecule? Would you like to learn how not only to see them, but also how to stretch them, squeeze them and knot them? Are you interested to learn how to ”see” enzymatic catalysis at a single molecule level? Do you want to learn how to “name” each single atom within a basic organic molecule like benzene using a very sharp stick and a few extra tools? How would you track a progress of a chemical reaction occurring between two simple molecules moving fast and freely in a gas phase? If you became just a little bit curious about those questions, then join us and feel welcomed into the fascinating world of the single molecules and their studies for the need of molecular biophysics and nanotechnology! The six hour lecture course will be supplemented by four hours of hands-on wet labs and two hours computer labs. Wet labs will feature usage of atomic force microscopy to adsorb, visualize and manipulate single biomolecules. Computer labs will introduce commonly used computer program used to visualize and simulate manipulations of single biomolecules. CLASS LOCATION AND HOURS: Tuesday, Feb 24, 2015: 8:15 – 9:45: 2h Lecture: Conference Room S3 (3rd floor) IPPT, PAN, ul. Pawińskiego 5B, Warszawa 10:00 – 11:30: 2h Wet Lab: Room 226A, IPPT, PAN Thursday, Feb 26, 2015: 8:15 – 9:45: 2h Lecture: Conference Room S3 (3rd floor) IPPT, PAN 10:00 – 11:30: 2h Wet Lab: Room 226A, IPPT, PAN Friday, Feb 27, 2015: 8:15 – 9:45: 2h Lecture: Conference Room S3 (3rd floor) IPPT, PAN 11:00 – 12:30: 2h Computer Lab: Room 105A, Wydzial Inżynierii Materiałowej, ul. Wołoska 141 INSTRUCTOR INFORMATION: Prof. R. Szoszkiewicz, IPPT, PAN, room 226B, robertszosz@gmail.com. TEACHING OUTCOMES: Get the grasp of single molecule methods and their applications in contemporary bio/nano-technology. GRADING SCHEME: final paper describing some research applications based on works distributed during the lecture. PRELIMINARY LECTURE OUTLINE (6h): 1. Our toolbox for single molecule biophysics and nanotechnology: • Why single molecules? • Main techniques and their strengths for measuring molecular properties of single molecules (inorganic, organic and biomolecules). • Time-resolved methods, distance resolved methods, force-sensitive methods. 2. Structural, chemical and nanomechanical properties of single molecules: why they are important and which of them can be measured. 3. Introduction to single molecule biophysics (I): fluorescence methods (FRET, TIRF, confocal microscopy, immobilization schemes, nanopores, some microfluidic schemes). 4. Introduction to single molecule biophysics (II): optical manipulation methods (optical tweezers) and magnetic manipulation methods (magnetic tweezers). 5. Introduction to single molecule biophysics (III): mechanical manipulation methods using AFM. 6. Introduction to single molecule nanotechnology: how to name and manipulate a single atom or a molecule adsorbed on an arbitrary surface or moving freely within in a gas phase (molecular beams and their applications); templates for manipulation of many single molecules. PRELIMINARY OUTLINE OF LABS/PRACTICAL TRAINING (6h): 1. Two hours hands-on wet labs featuring learning of how to prepare an arbitrary surface for adsorptions of single molecules onto registered nano-sized spots. Methods will include usage of Atomic Force Microscopy (AFM) techniques. 2. Two hours hands-on wet labs featuring learning of how to use AFM to visualize and/or manipulate single biological molecules adsorbed on arbitrary surfaces. 3. Two hours hands-on computer lab activities. Computer lab activities will involve basic visualization and manipulations of simple protein using Visual Molecular Dynamics (VMD) program. CREDITS INFO: Successful completion of the Course will be awarded with 2 ECTS Credit Points.
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