Abstract
Riboswitches are RNAs that modulate gene expression by ligand-induced conformational changes. However, the way in which sequence dictates alternative folding pathways of gene regulation remains unclear. In this study, we compute energy landscapes, which describe the accessible secondary structures for a range of sequence lengths, to analyze the transcriptional process as a given sequence elongates to full length. In line with experimental evidence, we find that most riboswitch landscapes can be characterized by three broad classes as a function of sequence length in terms of the distribution and barrier type of the conformational clusters: low-barrier landscape with an ensemble of different conformations in equilibrium before encountering a substrate; barrier-free landscape in which a direct, dominant “downhill” pathway to the minimum free energy structure is apparent; and a barrier-dominated landscape with two isolated conformational states, each associated with a different biological function. Sharing concepts with the “new view” of protein folding energy landscapes, we term the three sequence ranges above as the sensing, downhill folding, and functional windows, respectively. We find that these energy landscape patterns are conserved in various riboswitch classes, though the order of the windows may vary. In fact, the order of the three windows suggests either kinetic or thermodynamic control of ligand binding. These findings help understand riboswitch structure/function relationships and open new avenues to riboswitch design.
Highlights
Riboswitches are RNAs in the untranslated (UTR) regions of messenger RNAs that can undergo a structural transition in response to a highly specific intracellular ligand [1,2,3,4]
Consistent with experimental evidence, we find that most riboswitch landscapes can be characterized by three broad classes as a function of sequence length in terms of the distribution and barrier type of the conformational clusters: Low-barrier landscape with an ensemble of conformations in equilibrium before encountering a substrate; barrier-free landscape with a dominant ‘‘downhill’’ pathway to the minimum free energy structure; and barrier-dominated landscape with two isolated conformational states with different functions
Sharing concepts with the ‘‘new view’’ of protein folding energy landscapes, we term the three sequence ranges above as the sensing, downhill folding, and functional windows, respectively. We find that these energy landscape patterns are conserved between riboswitch classes, though the order of the windows may vary
Summary
Riboswitches are RNAs in the untranslated (UTR) regions of messenger RNAs (mRNAs) that can undergo a structural transition in response to a highly specific intracellular ligand [1,2,3,4]. More than twenty classes of riboswitches are known and classified according to their cognate intracellular metabolite [4]. This list of ligands that bind riboswitches has expanded from small molecule metabolites to include second messengers such as cyclic di-guanosine monophosphate (cdGMP) [14,15,16], other RNAs [17], and possibly hormones [18]
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