Abstract

Non‐coding small regulatory RNAs (sRNAs) have an important role in bacterial stress responses. The binding of sRNAs to their target mRNAs is facilitated by RNA‐binding proteins such as Hfq or ProQ. The Berry Lab has developed a bacterial three‐hybrid (B3H) assay to detect the binding of RNA with both of these RNA chaperones in vivo, by connecting the strength of an RNA‐protein interaction to the expression of a reporter gene. The interaction between a “prey” protein fused to the α‐subunit of RNA polymerase (RNAP) and a “bait” RNA tethered upstream of a test promoter stabilizes the binding of RNAP and increases transcription of the reporter gene lacZ. Despite the promise of the B3H system and its success in detecting many high‐affinity interactions, low signal‐to‐noise for other RNA‐protein interactions currently limits the broader utility of the assay. Computational structure predictions suggested that certain RNAs of interest could misfold when hybridized with other components of the hybrid RNA construct, e.g. an MS2 hairpin (MS2hp) or an exogenous intrinsic terminator. Such misfolding would likely disrupt a bait RNA’s interaction with the prey protein. To avoid this limitation, this study aims to optimize the hybrid RNA construct to improve the breadth of detectable interactions in the B3H assay. To this end, we designed new hybrid RNA constructs with the addition of a GC‐clamp – a short insert of guanines (G) and cytosines (C) flanking a region of interest – to promote proper folding and optimal display of RNA. Several sRNAs and 5’UTRs were cloned into GC‐clamp designs and their in vivo interactions with Hfq were tested in the B3H assay. Preliminary results demonstrate the promise of a short GC‐clamp in improving the B3H signal for many sRNA‐Hfq interactions, and we are currently working to test these GC constructs with additional RNAs. Increasing the sensitivity and generalizability of the B3H assay to study bacterial RNA‐protein interactions will help shed light on the molecular mechanisms of RNA‐chaperone proteins and the important processes in bacteria they regulate, such as adaptation to stress, biofilm formation and virulence.

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