A macromolecular crowding study of RNA folding and activity: polymer pore size matters!
(Conference Presentation)

Richard Börner; Erica Fiorini; Bishnu Paudel; David Rueda; Roland K. O. Sigel

doi:10.1117/12.2209290

27 April 2016 A macromolecular crowding study of RNA folding and activity: polymer pore size matters! (Conference Presentation)

Richard Börner, Erica Fiorini, Bishnu Paudel, David Rueda, Roland K. O. Sigel

Author Affiliations +

Proceedings Volume 9719, Biophysics, Biology, and Biophotonics: the Crossroads; 971909 (2016) https://doi.org/10.1117/12.2209290
Event: SPIE BiOS, 2016, San Francisco, California, United States

Abstract

Catalytic RNAs, like the group IIB intron ribozyme of S. cerevesiae, require a high magnesium(II) concentration to show folding and function in vitro [1]. In contrast, in vivo conditions are characterized by a highly crowded cellular environment and much lower ion concentration. Molecular crowding agents are a widespread tool to mimic cellular crowding [2]. However, particular physical/chemical properties explaining the crowders influence are mostly not understood. In this study, we gain new insights on how polymer properties like viscosity, pore size etc. influence the activity and folding of a large RNA. We combined bulk activity assays and single-molecule Förster Resonance Energy Transfer experiments, screening the PEG volume fraction (%) and molecular weight (MW). Our results revealed that upon the influence of crowding agents, a compaction of the underlying structure depends on the PEG % and the presence of different PEG MW and % unveiled an optimal pore size in terms of catalytic activity. In summary, an increasing density of the crowding environment shifts the RNA towards the most compact state, but the ribozyme is only active if the crowders network matches its size [4]. We interpret the most compact state as necessary, but not sufficient, to keep the ribozyme active. Financial support from the European Research Council (MIRNA N° 259092, to RKOS), the Swiss National Fund (SNF), and the Forschungskredit Grant of the University of Zürich (FK-14-096 and 15-092 to RB) are gratefully acknowledged. [1] Swisher J.F., Su L.J., Brenowitz M., Anderson V.E., Pyle A.M., J. Mol. Bio., 315, 297-310 (2002). [2] Kilburn D., Roh J.H., Guo L., Briber R.M., Woodson S.A., JACS, 132, 8690-6 (2010). [3] Steiner M., Karunatilaka K.S., Sigel R.K.O., Rueda D., Proc. Natl. Acad. Sci. U.S.A.,105, 13853-8 (2008). [4] aBörner R, Fiorini E, Sigel R.K.O., Chimia, 69, 207-212 (2015).; bFiorini E., Paudel B., Börner R., Rueda D., Sigel R.K.O., submitted. [5] König S.L.B., Hadzic M., Fiorini E., Börner R., Kowerko D., Blanckenhorn W.U., Sigel R.K.O., PLoS ONE, 8, e84157 (2013).

Conference Presentation

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Richard Börner, Erica Fiorini, Bishnu Paudel, David Rueda, and Roland K. O. Sigel "A macromolecular crowding study of RNA folding and activity: polymer pore size matters! (Conference Presentation)", Proc. SPIE 9719, Biophysics, Biology, and Biophotonics: the Crossroads, 971909 (27 April 2016); https://doi.org/10.1117/12.2209290

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KEYWORDS

Polymers

In vitro testing

In vivo imaging

Ions

Molecular energy transfer

Resonance energy transfer

Biology

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