Your search keyword '"Stefanie Mortimer"' showing total 2 results

1. Time-Resolved RNA SHAPE Chemistry

Author

Stefanie Mortimer and Kevin M. Weeks

Subjects

chemistry.chemical_classification, Time Factors, Molecular Structure, Stereochemistry, RNase P, Hydrolysis, Molecular Sequence Data, RNA, General Chemistry, Biochemistry, Ribonuclease P, Catalysis, Protein tertiary structure, Primer extension, Substrate Specificity, Folding (chemistry), chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Ribose, Molecule, Nucleotide

Abstract

Selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) chemistry yields quantitative RNA secondary and tertiary structure information at single nucleotide resolution. SHAPE takes advantage of the discovery that the nucleophilic reactivity of the ribose 2'-hydroxyl group is modulated by local nucleotide flexibility in the RNA backbone. Flexible nucleotides are reactive toward hydroxyl-selective electrophiles, whereas constrained nucleotides are unreactive. Initial versions of SHAPE chemistry, which employ isatoic anhydride derivatives that react on the minute time scale, are emerging as the ideal technology for monitoring equilibrium structures of RNA in a wide variety of biological environments. Here, we extend SHAPE chemistry to a benzoyl cyanide scaffold to make possible facile time-resolved kinetic studies of RNA in approximately 1 s snapshots. We then use SHAPE chemistry to follow the time-dependent folding of an RNase P specificity domain RNA. Tertiary interactions form in two distinct steps with local tertiary contacts forming an order of magnitude faster than long-range interactions. Rate-determining tertiary folding requires minutes despite that no non-native interactions must be disrupted to form the native structure. Instead, overall folding is limited by simultaneous formation of interactions approximately 55 A distant in the RNA. Time-resolved SHAPE holds broad potential for understanding structural biogenesis and the conformational interconversions essential to the functions of complex RNA molecules at single nucleotide resolution.

Published

2008

2. Slow Conformational Dynamics at C2′-endo Nucleotides in RNA

Author

Kevin M. Weeks, Joseph M. Krahn, Nancy L. Thompson, Costin M. Gherghe, and Stefanie Mortimer

Subjects

Stereochemistry, Acylation, Molecular Sequence Data, Kinetics, Biochemistry, Article, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Ribose, Molecule, Nucleotide, Ribonucleoprotein, chemistry.chemical_classification, Base Sequence, Nucleotides, Hydrolysis, RNA, General Chemistry, chemistry, Electrophile, Nucleic Acid Conformation, Thermodynamics

Abstract

RNA molecules undergo local conformational dynamics on timescales spanning picoseconds to minutes. Slower local motions have the greater potential to govern RNA folding, ligand recognition, and ribonucleoprotein assembly reactions but are difficult to detect in large RNAs with complex structures. RNA SHAPE chemistry employs acylation of the ribose 2'-hydroxyl position to measure local nucleotide flexibility in RNA and is well-characterized by a mechanism in which each nucleotide samples unreactive (closed) and reactive (open) states. We monitor RNA conformational dynamics over distinct time domains by varying the electrophilicity of the acylating reagent. Select C2'-endo nucleotides are nonreactive toward fast reagents but reactive toward slower SHAPE reagents in both model RNAs and in a large RNA with a tertiary fold. We conclude, first, that the C2'-endo conformation by itself does not govern SHAPE reactivity. However, some C2'-endo nucleotides undergo extraordinarily slow conformational changes, on the order of 10(-4) s(-1). Due to their distinctive local dynamics, C2'-endo nucleotides have the potential to function as rate-determining molecular switches and are likely to play central, currently unexplored, roles in RNA folding and function.

Published

2008