Bulged-out nucleotides in an antisense RNA are required for rapid target RNA binding in vitro and inhibition in vivo.

Naturally occurring antisense RNAs in prokaryotes are generally short, highly structured and untranslated. Stem-loops are always present, and loop regions serve as primary recognition structures in most cases. Single-stranded tails or internal unstructured regions are required for initiation of stable pairing between antisense and target RNA. Most antisense RNAs contain bulged-out nucleotides or small internal loops in upper stem regions. Here we investigated the role of the bulged-out nucleotides of CopA (the copy number regulator of plasmid R1) in determining the binding properties of this antisense RNA to its target in vitro and the efficiency of a translational inhibition in vivo. The introduction of perfect helicity in the region of the two bulges in CopA decreased pairing rate constants by up to 180-fold, increased equilibrium dissociation constants of the 'kissing intermediate' up to 14-fold, and severely impaired inhibition of repA expression. A previously described loop size mutant of CopA showed decreased pairing rates, but, in contrast to the bulge-less mutant CopAs, shows a decreased dissociation constant of the 'kissing complex'. We conclude that removal of the specific bulges/internal loops within the stem-loop II of CopA impairs the inhibitor, and that creation of an internal loop at a different position does not restore activity, emphasizing the optimal folding of wild-type CopA. The accompanying paper shows that an additional function of bulges can be protection from RNase III cleavage.