Loop swapping in an antisense RNA/target RNA pair changes directionality of helix progression

Structural and sequence requirements for the antisense RNA regulating replication of staphylococcal multiresistance plasmid pSK41

pSK41 is a prototypical 46-kb conjugative multiresistance plasmid of Staphylococcus aureus. The pSK41 replication initiation protein (Rep) is rate-limiting for plasmid replication, and its expression is negatively regulated by a small, non-coding antisense transcript, RNAI, that is complementary to the rep mRNA leader region. In this study, enzymatic probing was used to verify the predicted secondary structures of RNAI and its target RNA. We demonstrated that two stem-loop structures of RNAI, SLRNAI-II and SLRNAI-III, were important for inhibition. A putative U-turn motif detected in the loop of SLrep-I (5'-UUGG-3') was analysed for its significance to RNAI-mediated inhibition in vivo and Northern blotting suggested that rep mRNA was processed. Taken together, these observations support our previously proposed model but also raise new questions about the replication control mechanism.

RNA-mediated regulation in bacteria: from natural to artificial systems

Bacteria use various means of RNA-mediated gene regulation. Regulatory RNAs include mRNA leaders that affect expression in cis or in trans, non-coding RNAs that trap regulatory proteins or interact with one or multiple target mRNAs, and RNAs that protect the bacteria against foreign and invasive DNA. The aim of this review is to outline the basic principles of bacterial RNA-mediated regulation, with a special focus on both cis-acting regulatory regions of mRNAs and antisense RNAs (asRNAs), and to give a brief overview of selected examples of RNA-based technology that have paved the way for biotechnological applications.

RNA switches regulate initiation of translation in bacteria

A large variety of RNA-based mechanisms have been uncovered in all living organisms to regulate gene expression in response to internal and external changes, and to rapidly adapt cell growth in response to these signals. In bacteria, structural elements in the 5′ leader regions of mRNAs have direct effects on translation initiation of the downstream coding sequences. The docking and unfolding of these mRNAs on the 30S subunit are critical steps in the initiation process directly modulating and timing translation. Structural elements can also undergo conformational changes in response to environmental cues (i.e., temperature sensors) or upon binding of a variety oftrans-acting factors, such as metabolites, non-coding RNAs or regulatory proteins. These RNA switches can temporally regulate translation, leading either to repression or to activation of protein synthesis.

Control of replication in I-complex plasmids

The closely related plasmids that make up the I-complex group and the more distantly related IncL/M plasmids regulate the frequency of initiation of their replication by controlling the efficiency of translation of the rate limiting replication initiator protein, RepA. Translation initiation of repA is dependent on the formation of a pseudoknot immediately upstream of its Shine-Dalgarno sequence. Formation of this pseudoknot involves base pairing between two complementary sequences in the repA mRNA and requires that the secondary structure sequestering the distal sequence be disrupted by movement of the ribosome translating and terminating a leader peptide, whose coding sequence precedes and overlaps that of repA. Expression of repA is controlled by a small antisense RNA, RNAI, which on binding to its complementary target in the repA mRNA not only pre-empts formation of the pseudoknot, but also inhibits translation of the leader peptide. The requirement that translation of the leader peptide be completed for the pseudoknot to form increases the time available for the inhibitory interaction of RNAI with its target, so that at high copy number the frequency of pseudoknot formation is lowered, reducing the proportion of repA mRNA that are translated. At low copy number, when concentration of RNAI is low, repA is translated with increased frequency, leading to increased frequency of plasmid replication.

Antisense-RNA mediated transcriptional attenuation: importance of a U-turn loop structure in the target RNA of plasmid pIP501 for efficient inhibition by the antisense RNA

Antisense-RNA mediated gene regulation has been found and studied in detail mainly in prokaryotic accessory DNA elements. In spite of different regulatory mechanisms, in all cases a rapid interaction between antisense and target RNA has been shown to be crucial for efficient regulation. Recently, a sequence comparison revealed in 45 antisense RNA control systems a 5' YUNR motif indicative for the formation of a U-turn structure in either an antisense or a target RNA loop and confirmed in the case of the hok/sok system of plasmid R1 its importance for regulation.Here, we demonstrate the importance of the 5' YUNR motif in the target RNA (RNAII) loop L1 of the replication control system of plasmid pIP501. The effect of four individual mutations in L1 was studied in vivo and in vitro. Mutations that maintained the putative U-turn or swapped it from sense to antisense RNA were silent, whereas mutations that eliminated the 5'-YUNR motif showed two- to threefold elevated copy numbers in vivo in correlation with three- to fourfold reduced inhibition rate constants of the complementary RNAIII species in vitro, whereas the half-lives of all RNAIII species were not affected. ENU probing experiments confirmed the U-turn structure for the silent mutation (N-C) and disruption of this structure upon alteration of the invariant U or inversion of the YUNR motif-containing loop. RNA secondary structure probing excluded loop size alterations as a reason for altered inhibition rates. Implications for the pathway and efficiency of RNAII/RNAIII interaction, and hence, pIP501 copy-number control, are discussed.