The antisense RNA, CopA, regulates the replication frequency of plasmid R1 through inhibition of RepA translation by rapid and specific binding to its target RNA (CopT). The stable CopA-CopT complex is characterized by a four-way junction structure and a side-by-side alignment of two long intramolecular helices. The significance of this structure for binding in vitro and control in vivo was tested by mutations in both CopA and CopT. High rates of stable complex formation in vitro and efficient inhibition in vivo required initial loop-loop complexes to be rapidly converted to extended interactions. These interactions involve asymmetric helix progression and melting of the upper stems of both RNAs to promote the formation of two intermolecular helices. Data presented here delineate the boundaries of these helices and emphasize the need for unimpeded helix propagation. This process is directional, i.e. one of the two intermolecular helices (B) must form first to allow formation of the other (B'). A binding pathway, characterized by a hierarchy of intermediates leading to an irreversible and inhibitory RNA-RNA complex, is proposed.
The replication frequency of plasmid R1 is controlled by an antisense RNA, CopA, that inhibits the synthesis of the replication initiator protein, RepA, at the post-transcriptional level. This inhibition is indirect and affects translation of a leader peptide reading frame (tap). Translation of tap is required for repA translation (Blomberg et al., 1992). Here we asked whether an RNA stem-loop sequestering the repA ribosome-binding site blocks tap translation-independent repA expression. Destabilization of this structure resulted in tap-independent RepA synthesis, concomitant with a loss of CopA-mediated inhibition; thus, CopA acts at the level of tap translation. Structure probing of RepA mRNAs confirmed that the introduced mutations induced a local destabilization in the repA ribosome-binding site stem-loop. An increased spacing between the repA Shine-Dalgarno region and the start codon permitted even higher repA expression. In Incl alpha/IncB plasmids, an RNA pseudoknot acts as an activator for rep translation. We suggest that the regulatory pathway in plasmid R1 does not involve an activator RNA pseudoknot.
This communication describes a two unit antisense RNA cassette system for use in gene silencing. Cassettes consist of a recognition unit and an inhibitory unit which are transcribed into a single RNA that carries sequences of non-contiguous complementarity to the chosen target RNA. The recognition unit is designed as a stem-loop for rapid formation of long- lived binding intermediates with target sequences and resembles the major stem-loop of a naturally occurring antisense RNA, CopA. The inhibitory unit consists of either a sequence complementary to a ribosome binding site or of a hairpin ribozyme targeted at a site within the chosen mRNA. The contributions of the individual units to inhibition was assessed using the lacI gene as a target. All possible combinations of recognition and inhibitory units were tested in either orientation. In general, inhibition of lacI expression was relatively low. Fifty per cent inhibition was obtained with the most effective of the constructs, carrying the recognition stem-loop in the antisense orientation and the inhibitory unit with an anti-RBS sequence. Several experiments were performed to assess activities of the RNAs in vitro and in vivo : antisense RNA binding assays, cleavage assays, secondary structure analysis as well as Northern blotting and primer extension analysis of antisense and target RNAs. The problems associated with this antisense RNA approach as well as its potential are discussed with respect to possible optimization strategies.
This communication describes improvement strategies used on a previously described two-unit antisense RNA cassette system. This cassette system encodes RNA with noncontiguous regions of complementarity to a bacterial target RNA, lacI mRNA. One of the units of complementarity was contained within an RNA stem-loop resembling that of the very efficient, naturally occurring antisense RNA CopA. As relatively low inhibitory activity was obtained previously, we tested variants in which several stem-loops were combined within one RNA, each of them directed against a different stretch of target RNA. One to four stem-loop RNAs were tested and found to be relatively ineffective, likely because of low metabolic stability. To increase the intracellular stability of these and other antisense RNAs, a stabilizer element (stem-loop derived from gene 32 mRNA of phage T4) was inserted at their 5'-ends. The results indicate that addition of this element indeed increased antisense RNA efficiency in vivo. As expected, this effect was primarily due to a longer antisense RNA half-life, as shown by RNA abundance (Northern analysis) and decay rates (rifampicin runout experiments). In summary, the results reported indicate that rational design of antisense RNA is feasible, but that the degree of inhibition (approximately 75% maximum inhibition) accomplished here could still be improved.
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