Eda Koculi scite author profile

RNA molecules are exquisitely sensitive to the properties of counterions. The folding equilibrium of the Tetrahymena ribozyme is measured by non-denaturing gel electrophoresis in the presence of divalent group IIA metal cations. The stability of the folded ribozyme increases with the charge density (ζ) of the cation. Similar scaling is found when the free energy of the RNA folded in small and large metal cations is measured by urea denaturation. Brownian dynamics simulations of a polyelectrolyte show that the experimental observations can be explained by non-specific ion-RNA interactions in the absence of site-specific metal chelation. The experimental and simulation results establish that RNA stability is largely determined by a combination of counterion charge and the packing efficiency of condensed cations that depends on the excluded volume of the cations.

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Folding of the Tetrahymena Ribozyme by Polyamines: Importance of Counterion Valence and Size

Koculi¹,

Lee²,

Thirumalai³

et al. 2004

Journal of Molecular Biology

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Counterion Charge Density Determines the Position and Plasticity of RNA Folding Transition States

Koculi

Thirumalai

Woodson

2006

Journal of Molecular Biology

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Folding path of P5abc RNA involves direct coupling of secondary and tertiary structures

Koculi

Cho

Desai

et al. 2012

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Folding mechanisms in which secondary structures are stabilized through the formation of tertiary interactions are well documented in protein folding but challenge the folding hierarchy normally assumed for RNA. However, it is increasingly clear that RNA could fold by a similar mechanism. P5abc, a small independently folding tertiary domain of the Tetrahymena thermophila group I ribozyme, is known to fold by a secondary structure rearrangement involving helix P5c. However, the extent of this rearrangement and the precise stage of folding that triggers it are unknown. We use experiments and simulations to show that the P5c helix switches to the native secondary structure late in the folding pathway and is directly coupled to the formation of tertiary interactions in the A-rich bulge. P5c mutations show that the switch in P5c is not rate-determining and suggest that non-native interactions in P5c aid folding rather than impede it. Our study illustrates that despite significant differences in the building blocks of proteins and RNA, there may be common ways in which they self-assemble.

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Eda Koculi

Charge Density of Divalent Metal Cations Determines RNA Stability

Folding of the Tetrahymena Ribozyme by Polyamines: Importance of Counterion Valence and Size

Counterion Charge Density Determines the Position and Plasticity of RNA Folding Transition States

Folding path of P5abc RNA involves direct coupling of secondary and tertiary structures

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