Summary
Many regulatory RNAs undergo changes in their structure from the dominant ground-state (GS) toward short-lived low-abundance ‘excited-states’ (ES) that reorganize local elements of secondary structure. ESs are increasingly observed in vitro and implicated in the folding and biological activities of regulatory RNAs and as targets for developing therapeutics. However, whether these ESs also form with comparable abundance within the complex cellular environment remains unknown. Here, we developed an approach for assessing the relative stability and abundance of RNA ESs within the functional cellular context. The approach uses point substitution mutations to increase the population of an inactive ES relative to the active GS. The cellular activity of such ES-stabilizing mutants then provides an indirect measure of any residual population of the active GS within the functional cellular context. Compensatory rescue mutations that restore the GS are used to control for changes in cellular activity arising due to changes in sequence. The approach is applied to probe ESs in two highly conserved and functionally important regulatory RNAs from HIV-1: the transactivation response element (TAR) and the Rev response element (RRE). For both RNAs, ES-stabilizing mutations inhibited cellular activity to a degree that correlates with the extent to which they stabilize the ES relative to the GS in vitro. These results indicate that the non-native ESs of TAR and RRE likely form in cells with abundances comparable to those measured in vitro and their targeted stabilization provides a new avenue for developing anti-HIV therapeutics.