Because RNA carries a high negative charge, its folding into secondary and tertiary structures can be exquisitely sensitive to salt concentration. Folding of RNA tertiary structures is particularly affected by the concentration of divalent ions and the types of mono- and divalent ions presents. Investigation ion association with an RNA is a difficult problem, as binding in the sample molecule may vary from entirely delocalized interactions with the RNA electrostatic field to chelation of partially dehydrated ions at specific sites. How one views the role of ions in directing RNA folding depends on the relative importance assigned to such non-specific and specific binding modes. The purpose of the proposed work is to systematically examine ion-RNA interactions in a series of RNAs of known and increasingly complex non- canonical and tertiary structures. Approaches that will be used are calorimetric and UV melting experiments (which report the differences in the extent of ion association between folded and unfolded states, and provide a direct measure of ion-induced stabilization), and methods that detect the extent of monovalent or divalent ion association with the folded RNA structure (equilibrium dialysis or titrations using fluorescent indicators of free ion concentrations).
Specific aims of the work include (i) Investigation of divalent ion interactions at specific RNA sites, including the affinity, monovalent ion salt dependence of binding, and selectivity for different alkaline earth ions; (ii) Determination of what RNA structures develop selectivity for monovalent ions (alkali metal and ammonium), and whether selectivity can be attributed to one or a few specific coordination sites; (iii) Initial attempts to compare calculated and experimentally measured electrostatic potentials in an RNA. These experiments should provide a picture of how ions are distributed around each RNA and the degree to which different classes of associated ions contribute to thermodynamic stability of RNA structures. This information will fill in a crucial aspect of non-canonical and tertiary RNA folding energetics.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
1R01GM058545-01
Application #
2729089
Study Section
Molecular and Cellular Biophysics Study Section (BBCA)
Project Start
1999-02-01
Project End
2003-01-31
Budget Start
1999-02-01
Budget End
2000-01-31
Support Year
1
Fiscal Year
1999
Total Cost
Indirect Cost
Name
Johns Hopkins University
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
045911138
City
Baltimore
State
MD
Country
United States
Zip Code
21218
Draper, David E (2013) Folding of RNA tertiary structure: Linkages between backbone phosphates, ions, and water. Biopolymers 99:1105-13
Li, Biao; Kimmel, Marek (2013) Factors influencing ascertainment bias of microsatellite allele sizes: impact on estimates of mutation rates. Genetics 195:563-72
Trachman 3rd, Robert J; Draper, David E (2013) Comparison of interactions of diamine and Mg²? with RNA tertiary structures: similar versus differential effects on the stabilities of diverse RNA folds. Biochemistry 52:5911-9
Lambert, Dominic; Draper, David E (2012) Denaturation of RNA secondary and tertiary structure by urea: simple unfolded state models and free energy parameters account for measured m-values. Biochemistry 51:9014-26
Leipply, Desirae; Draper, David E (2011) Evidence for a thermodynamically distinct Mg2+ ion associated with formation of an RNA tertiary structure. J Am Chem Soc 133:13397-405
Leipply, Desirae; Draper, David E (2011) Effects of Mg2+ on the free energy landscape for folding a purine riboswitch RNA. Biochemistry 50:2790-9
Lambert, Dominic; Leipply, Desirae; Draper, David E (2010) The osmolyte TMAO stabilizes native RNA tertiary structures in the absence of Mg2+: evidence for a large barrier to folding from phosphate dehydration. J Mol Biol 404:138-57
Leipply, Desirae; Draper, David E (2010) Dependence of RNA tertiary structural stability on Mg2+ concentration: interpretation of the Hill equation and coefficient. Biochemistry 49:1843-53
Chen, Alan A; Draper, David E; Pappu, Rohit V (2009) Molecular simulation studies of monovalent counterion-mediated interactions in a model RNA kissing loop. J Mol Biol 390:805-19
Lambert, Dominic; Leipply, Desirae; Shiman, Ross et al. (2009) The influence of monovalent cation size on the stability of RNA tertiary structures. J Mol Biol 390:791-804

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