Madhuri Kudaravalli scite author profile

Riboswitches are complex folded RNA domains found in non-coding regions of mRNA that regulate gene expression upon small molecule binding. Recently, Breaker and coworkers reported a tandem aptamer riboswitch (VCI-II) that binds glycine cooperatively. Here, we use hydroxyl radical footprinting and small-angle x-ray scattering (SAXS) to study the conformations of this tandem aptamer as a function of Mg 2+ and glycine concentration. We fit a simple three-state thermodynamic model that describes the energetic coupling between magnesium-induced folding and glycine binding. Furthermore, we characterize the structural conformations of each of the three states: In low salt with no magnesium present, the VCI-II construct has an extended overall conformation, presumably representing unfolded structures. Addition of millimolar concentrations of Mg 2+ in the absence of glycine leads to a significant compaction and partial folding as judged by hydroxyl radical protections. In the presence of millimolar Mg 2+ concentrations, the tandem aptamer binds glycine cooperatively. The glycine binding transition involves a further compaction, additional tertiary packing interactions and further uptake of magnesium ions relative to the state in high Mg 2+ but no glycine. Employing density reconstruction algorithms, we obtain low resolution 3-D structures for all three states from the SAXS measurements. These data provide a first glimpse into the structural conformations of the VCI-II aptamer, establish rigorous constraints for further modeling, and provide a framework for future mechanistic studies.

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Structural inference of native and partially folded RNA by high-throughput contact mapping

Das¹,

Kudaravalli²,

Jonikas

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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The biological behaviors of ribozymes, riboswitches, and numerous other functional RNA molecules are critically dependent on their tertiary folding and their ability to sample multiple functional states. The conformational heterogeneity and partially folded nature of most of these states has rendered their characterization by high-resolution structural approaches difficult or even intractable. Here we introduce a method to rapidly infer the tertiary helical arrangements of large RNA molecules in their native and non-native solution states. Multiplexed hydroxyl radical (⅐OH) cleavage analysis (MOHCA) enables the high-throughput detection of numerous pairs of contacting residues via random incorporation of radical cleavage agents followed by two-dimensional gel electrophoresis. We validated this technology by recapitulating the unfolded and native states of a well studied model RNA, the P4 -P6 domain of the Tetrahymena ribozyme, at subhelical resolution. We then applied MOHCA to a recently discovered third state of the P4 -P6 RNA that is stabilized by high concentrations of monovalent salt and whose partial order precludes conventional techniques for structure determination. The three-dimensional portrait of a compact, non-native RNA state reveals a well ordered subset of native tertiary contacts, in contrast to the dynamic but otherwise similar molten globule states of proteins. With its applicability to nearly any solution state, we expect MOHCA to be a powerful tool for illuminating the many functional structures of large RNA molecules and RNA/protein complexes.hydroxyl radical ͉ molten globule ͉ Tetrahymena ribozyme ͉ two-dimensional gel T he discoveries of catalytic RNAs, silencing RNAs, riboswitches, and a panoply of functional RNA molecules have sweeping implications for our views of evolution from an early ''RNA World'' and for the potential of structured RNAs to act in roles beyond the simple transmission of information laid out in the Central Dogma of Molecular Biology (1). The functions of these RNAs in primitive and modern life are being elucidated at an explosive pace. Nevertheless, a deep understanding of these fundamental biopolymers and their biological roles requires structural portraits of their functional states, and, in this respect, progress has been slow.Our understanding of RNA structure has greatly lagged behind that of protein structure: compared with nearly 40,000 protein structures in the Protein Data Bank, there are currently Ͻ1,000 experimentally determined RNA structures, most of which are small fragments (2). High-resolution approaches using NMR spectroscopy (NMR) and x-ray crystallography have the potential to describe RNA structure at the atomic level, but have been considerably hampered by numerous factors, including limited chemical shift dispersion, the large sizes of structured RNAs, and the poor behavior of RNA at high concentrations.Further enriching and complicating the modeling of RNA behavior is the seemingly pervasive tendency of RNA to form alternative secondary and tert...

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Madhuri Kudaravalli

Structural Transitions and Thermodynamics of a Glycine-Dependent Riboswitch from Vibrio cholerae

Structural inference of native and partially folded RNA by high-throughput contact mapping

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