BEGIN:VCALENDAR VERSION:2.0 PRODID:OpenCms 20.0.18 BEGIN:VTIMEZONE TZID:Europe/Berlin X-LIC-LOCATION:Europe/Berlin BEGIN:DAYLIGHT TZOFFSETFROM:+0100 TZOFFSETTO:+0200 TZNAME:CEST DTSTART:19700329T020000 RRULE:FREQ=YEARLY;BYDAY=-1SU;BYMONTH=3 END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:+0200 TZOFFSETTO:+0100 TZNAME:CET DTSTART:19701025T030000 RRULE:FREQ=YEARLY;BYDAY=-1SU;BYMONTH=10 END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTAMP:20210309T164256 UID:1e1e83bd-80ee-11eb-907c-000e0c3db68b SUMMARY:ICP Kolloquium: Prof. Dr. Ulrich F. Keyser, 04. Februar 2021, „Polymer and ion dynamics in nanopores revealed by designed DNA nanostructures“ DESCRIPTION:Prof. Dr. Ulrich F. KeyserCavendish Laboratory, University of Cambridge, UKDonnerstag, 04. Februar 2021, 16:00 Uhrvia zoom\n \nPolymer and ion dynamics in nanopores revealed by designed DNA nanostructures\nAbstract:DNA nanotechnology is transformative for experiments that require molecular control over the shape of nanometer-sized objects. In combination with nanopores DNA self-assembly allows for novel experiments that reveal the physics of ions, and polymers on the single molecule level [1].Nanopore sensing, best known for DNA sequencing, translates the three-dimensional structure of molecules into ionic current signals. Designed DNA molecules enable multiplexed protein sensing with an all-electrical approach [2] and may pave the way to data storage applications [3]. Here, I will discuss our recent developments to detect and localise structures as accurately as possible along DNA molecules approaching super-resolution microscopy [3,4]. The localisation is enabled by the signal-to-noise ratio and asymmetry of our glass nanopores [5]. In the second part of the talk, I will discuss how we can study ion dynamics using DNA origami structures [6,7] including the creation of an all-optical voltage sensor based on Foerster resonant energy transfer [8]. The talk will end with our efforts to actuate DNA origami by incorporation of PNIPAM for temperature activated motion [9] and an outlook on future development and questions.\n[1] U. F. Keyser. Enhancing nanopore sensing with DNA nanotechnology. Nature Nanotechnology, 11:106-108, 2016.[2] N. A. W. Bell and U. F. Keyser. Digitally encoded DNA nanostructures for multiplexed, single-molecule protein sensing with nanopores. Nature Nanotechnology, 11:645-651, 2016.[3] K. Chen, J. Kong, J. Zhu, N. Ermann, P. Predki, and U. F. Keyser. Digital Data Storage Using DNA Nanostructures and Solid-State Nanopores. Nano Letters, 19(2):1210-1215, 2019[4] K. Chen, F. Gularek, B. Liu, E. Weinhold, and U. F. Keyser. Electrical DNA Sequence Mapping Using Oligodeoxynuc leotide Labels and Nanopores. ACS nano (published online) 2021. https://dx.doi.org/10.1021/acsnano.0c07947?ref=pdf[5] N. A. W. Bell, K. Chen, S. Ghosal, M. Ricci, and U. F. Keyser. Asymmetric dynamics of DNA entering and exiting a strongly confining nanopore. Nature Communications, 8:380, 2017.[6] V. V. Wang, N. Ermann, and U. F. Keyser. Current enhancement in solid-state nanopores depends on three-dimensional DNA structure. Nano Letters, 19(8):5661-5666, 2019.[7] C.-Y. Li, E. A. Hemmig, J. Kong, J. Yoo, S. Hernández-Ainsa, U. F. Keyser, and A. Aksimentiev. Ionic Conductivity, Structural Deformation and Programmable Anisotropy of DNA Origami in Electric Field. ACS nano, 9(2):1420-1433, 2015.[8] E. A. Hemmig, C. Fitzgerald, C. Maffeo, L. Hecker, S. E. Ochmann, A. Aksimentiev, P. Tinnefeld, and U. F. Keyser. Optical voltage sensing using DNA origami. Nano Letters, 18(3):1962-1971, 2018.[9] V. Turek, R. Chikkaraddy, S. Cormier, B. Stockham, T. Ding, U. F. Keyser, and J. J. Baumberg. Thermo-responsive Actuation of a DNA Origami Flexor. Adv. Funct. Mater., 28(25):1706410, 2018 DTSTART;TZID=Europe/Berlin;VALUE=DATE:20210204 URL;VALUE=URI:https://www.icp.uni-stuttgart.de/news/events/ICP-Kolloquium-Prof.-Dr.-Ulrich-F.-Keyser-04-00001.-Februar-2021-Polymer-and-ion-dynamics-in-nanopores-revealed-by-designed-DNA-nanostructures/ END:VEVENT END:VCALENDAR