Chemical basis of glycine riboswitch cooperativity
- 27 November 2007
- journal article
- Published by Cold Spring Harbor Laboratory in RNA
- Vol. 14 (1) , 25-34
- https://doi.org/10.1261/rna.771608
Abstract
The glycine binding riboswitch forms a unique tandem aptamer structure that binds glycine cooperatively. We employed nucleotide analog interference mapping (NAIM) and mutagenesis to explore the chemical basis of glycine riboswitch cooperativity. Based on the interference pattern, at least two sites appear to facilitate cooperative tertiary interactions, namely, the minor groove of the P1 helix from aptamer 1 and the major groove of the P3a helix from both aptamers. Mutation of these residues altered both the cooperativity and binding affinity of the riboswitch. The data support a model in which the P1 helix of the first aptamer participates in a tertiary interaction important for cooperativity, while nucleotides in the P1 helix of the second aptamer interface with the expression platform. These data have direct analogy to well-characterized mutations in hemoglobin, which provides a framework for considering cooperativity in this RNA-based system.Keywords
This publication has 37 references indexed in Scilit:
- Structural Transitions and Thermodynamics of a Glycine-Dependent Riboswitch from Vibrio choleraeJournal of Molecular Biology, 2007
- An RNA Sensor for Intracellular Mg2+Cell, 2006
- Characterization of hemoglobin bassett (α94Asp→Ala), a variant with very low oxygen affinityAmerican Journal of Hematology, 2004
- Potential contact sites between the protein and RNA subunit in the Bacillus subtilis RNase P holoenzyme 1 1Edited by J. KarnJournal of Molecular Biology, 2002
- Application of Imprinted Synthetic Polymers in Binding Assay DevelopmentMethods, 2000
- A chemical phylogeny of group I introns based upon interference mapping of a bacterial ribozyme 1 1Edited by D. DraperJournal of Molecular Biology, 2000
- Nucleotide Analog Interference MappingMethods, 1999
- Novel Water-Mediated Hydrogen Bonds as the Structural Basis for the Low Oxygen Affinity of the Blood Substitute Candidate rHb(α96Val→Trp),Biochemistry, 1998
- Hemoglobin roanne [α94(G1) asp å glu]: a variant of the α1β2 interface with an unexpected high oxygen affinityBiochimica et Biophysica Acta (BBA) - Protein Structure and Molecular Enzymology, 1995
- On the nature of allosteric transitions: A plausible modelJournal of Molecular Biology, 1965