Gene machines

Single-molecule FRET studies on the cotranscriptional folding of a thiamine pyrophosphate riboswitch.

Proceedings of the National Academy of Sciences of the United States of America 115:2 (2018) 331-336

Authors:

Heesoo Uhm, Wooyoung Kang, Kook Sun Ha, Changwon Kang, Sungchul Hohng

Abstract:

Because RNAs fold as they are being synthesized, their transcription rate can affect their folding. Here, we report the results of single-molecule fluorescence studies that characterize the ligand-dependent cotranscriptional folding of the Escherichia coli thiM riboswitch that regulates translation. We found that the riboswitch aptamer folds into the "off" conformation independent of its ligand, but switches to the "on" conformation during transcriptional pausing near the translational start codon. Ligand binding maintains the riboswitch in the off conformation during transcriptional pauses. We expect our assay will permit the controlled study of the two main physical mechanisms that regulate cotranscriptional folding: transcriptional pausing and transcriptional speed.

Increased PKMζ activity impedes lateral movement of GluA2-containing AMPA receptors.

Molecular brain 10:1 (2017) 56-56

Authors:

Nam-Kyung Yu, Heesoo Uhm, Jaehoon Shim, Jun-Hyeok Choi, Sangsu Bae, Todd Charlton Sacktor, Sungchul Hohng, Bong-Kiun Kaang

Abstract:

Protein kinase M zeta (PKMζ), a constitutively active, atypical protein kinase C isoform, maintains a high level of expression in the brain after the induction of learning and long-term potentiation (LTP). Further, its overexpression enhances long-term memory and LTP. Thus, multiple lines of evidence suggest a significant role for persistently elevated PKMζ levels in long-term memory. The molecular mechanisms of how synaptic properties are regulated by the increase in PKMζ, however, are still largely unknown. The α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor (AMPAR) mediates most of the fast glutamatergic synaptic transmission in the brain and is known to be critical for the expression of synaptic plasticity and memory. Importance of AMPAR trafficking has been implicated in PKMζ-mediated cellular processes, but the detailed mechanisms, particularly in terms of regulation of AMPAR lateral movement, are not well understood. In the current study, using a single-molecule live imaging technique, we report that the overexpression of PKMζ in hippocampal neurons immobilized GluA2-containing AMPARs, highlighting a potential novel mechanism by which PKMζ may regulate memory and synaptic plasticity.

Ligand Recognition Mechanism of Thiamine Pyrophosphate Riboswitch Aptamer

BULLETIN OF THE KOREAN CHEMICAL SOCIETY 38:12 (2017) 1465-1473

Authors:

Heesoo Uhm, Sungchul Hohng

Precision and accuracy of single-molecule FRET measurements - a worldwide benchmark study

(2017)

Authors:

Björn Hellenkamp, Sonja Schmid, Olga Doroshenko, Oleg Opanasyuk, Ralf Kühnemuth, Soheila Rezaei Adariani, Anders Barth, Victoria Birkedal, Mark E Bowen, Hongtao Chen, Thorben Cordes, Tobias Eilert, Carel Fijen, Markus Götz, Giorgos Gouridis, Enrico Gratton, Taekjip Ha, Christian A Hanke, Andreas Hartmann, Jelle Hendrix, Lasse L Hildebrandt, Johannes Hohlbein, Christian G Hübner, Eleni Kallis, Achillefs N Kapanidis, Jae-Yeol Kim, Georg Krainer, Don C Lamb, Nam Ki Lee, Edward A Lemke, Brié Levesque, Marcia Levitus, James J McCann, Nikolaus Naredi-Rainer, Daniel Nettels, Thuy Ngo, Ruoyi Qiu, Carlheinz Röcker, Hugo Sanabria, Michael Schlierf, Benjamin Schuler, Henning Seidel, Lisa Streit, Philip Tinnefeld, Swati Tyagi, Niels Vandenberk, Keith R Weninger, Bettina Wünsch, Inna S Yanez-Orozco, Jens Michaelis, Claus AM Seidel, Timothy D Craggs, Thorsten Hugel

Bacterial Translocation Ratchets: Shared Physical Principles with Different Molecular Implementations: How bacterial secretion systems bias Brownian motion for efficient translocation of macromolecules.

BioEssays : news and reviews in molecular, cellular and developmental biology 39:10 (2017)

Authors:

Christof Hepp, Berenike Maier

Abstract:

Secretion systems enable bacteria to import and secrete large macromolecules including DNA and proteins. While most components of these systems have been identified, the molecular mechanisms of macromolecular transport remain poorly understood. Recent findings suggest that various bacterial secretion systems make use of the translocation ratchet mechanism for transporting polymers across the cell envelope. Translocation ratchets are powered by chemical potential differences generated by concentration gradients of ions or molecules that are specific to the respective secretion systems. Bacteria employ these potential differences for biasing Brownian motion of the macromolecules within the conduits of the secretion systems. Candidates for this mechanism include DNA import by the type II secretion/type IV pilus system, DNA export by the type IV secretion system, and protein export by the type I secretion system. Here, we propose that these three secretion systems employ different molecular implementations of the translocation ratchet mechanism.