The SINE-encoded B2 retrotransposon is an RNA Polymerase III (POL-III)-derived transcript whose expression is substantially upregulated during various cellular stress responses. Beyond retrotransposition, the B2 non-coding RNA can directly bind and repress the activity of RNA Polymerase II (POL-II), leading to a significant downregulation of transcripts during stress. Notably, our recent findings have shown that B2 is a self-cleaving ribozyme whose activity can be induced by interactions with chromatin-modifying factors through non-canonical epigenetic mechanisms that co-regulate its function across distinct chromatin-binding target loci. Here, by integrating RNA chemical probing, small-angle X-ray scattering, and 3D motif modeling, we determine structural ensemble-to-function relations for the B2 SINE ribozyme RNA. Genetic perturbations of the RNA suggest that the B2 SINE ribozyme has a well-defined secondary and dynamic tertiary structure that depends on the integrity of the critical region, which confers ribozymatic activity and repressive extent by POL-II. Using an RNA engineering approach, we examine the effects of point mutations, deletions of the main cleavage site, and deletions of the cleavage domain on the structural ensemble of the RNA. Combining this approach with in vitro and in vivo functional perturbation methods highlights the relationships between structural ensembles and various biologically relevant functional outcomes. The authors show that the cleavage region of B2 RNA acts as an architectural organizer, essential for maintaining the structural integrity required for ribozyme activity, protein interactions, and transcriptional regulation.
Singhal et al. (Mon,) studied this question.