The unusual stability of the IS10 anti-sense RNA is critical for its function and is determined by the structure of its stem-domain.

IS10 transposition is regulated by an approximately 70 nt anti-sense RNA, RNA-OUT. RNA-OUT folds into a duplex 'stem-domain' topped by a loosely paired 'loop-domain'. The loop-domain is critical for RNA-RNA pairing per se; pairing initiates by interaction of the RNA-OUT loop with the 5' end of the target mRNA. We show here that RNA-OUT is unusually stable in vivo (half-life 60 min) and that this stability is conferred by specific features of the RNA-OUT stem-domain. One critical feature is stable base-pairing: mutations that disrupt stem pairing destabilize RNA-OUT in vivo and abolish anti-sense control; combinations of mutations that restore pairing also restore both stability and control. We propose that the stem renders RNA-OUT resistant to 3' exoribonucleases. Other features of the stem-domain prevent this essential duplex from being an effective substrate for double-strand nucleases: two single base mutations disrupt antisense control by making RNA-OUT susceptible to RNase III. Mutations in the loop region have little effect on RNA-OUT stability. Implications for IS10 biology and the design of efficient anti-sense RNAs are discussed.     

Insertion sequence IS10 anti-sense pairing initiates by an interaction between the 5' end of the target RNA and a loop in the anti-sense RNA

Transposition of insertion sequence IS10 is regulated by an anti-sense RNA which inhibits transposase expression when IS10 is present in multiple copies per cell. The anti-sense RNA (RNA-OUT) consists of a stem domain topped by a flexibly paired loop; the 5' end of the target molecule, RNA-IN, is complementary to the top of the loop, and complementarity extends for 35 base-pairs down one side of RNA-OUT. We present here genetic evidence that anti-sense pairing, both in vitro and in vivo, initiates by interaction of the 5' end of RNA-IN and the loop domain of RNA-OUT; other features of the reaction are discussed. In the context of this model, we discuss features of this anti-sense system which are important for its biological effectiveness, and suggest that IS10 provides a convenient model for design of efficient artificial anti-sense RNA molecules.     

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.     

Anti-sense RNAs of cucumber mosaic virus in transgenic plants assessed for control of the virus

Three synthetic genes for the production of anti-sense RNA to different regions of the cucumber mosaic virus (CMV) genome were constructed using virus-derived double-stranded cDNA coupled to a promoter sequence from cauliflower mosaic virus. The genes were used to transform tobacco plants by a Ti plasmid vector. Transgenic plants obtained with the three constructs produced anti-sense RNA at different levels. Plants expressing each of the three anti-sense RNAs were inoculated with CMV and their sensitivity to the virus infection was compared with the non-transformed plants. Only one plant line which expressed relatively low levels of one of the anti-sense RNAs showed resistance to CMV but other plants expressing the same or the other two antisense RNAs had similar sensitivity to CMV infection as the non-transformed plants.     

Bulged-out nucleotides protect an antisense RNA from RNase III cleavage.

Bulged-out nucleotides or internal loops are present in the stem-loop structures of several antisense RNAs. We have used the antisense/target RNA system (CopA/CopT) that controls the copy number of plasmid R1 to examine the possible biological function of bulged-out nucleotides. Two regions within the major stem-loop of the antisense RNA, CopA, carry bulged-out nucleotides. Base pairing in either one or both of these regions of the stem was restored by site-specific mutagenesis and in one case a new internal loop was introduced. The set of mutant and wild-type CopA variants was characterized structurally in vitro. The results reported here indicate a possible function of the bulges: their presence protects CopA RNA from being a substrate for the double-strand-specific enzyme RNase III. In vitro cleavage rates were drastically increased when either the lower or both bulges were absent. This is paralleled by a similar, but not identical, effect of the bulges on metabolic stability of the CopA RNAs in vivo. The degradation pathways of wild-type and mutant CopA in various strain backgrounds are discussed. In the accompanying paper, we address the significance of bulges in CopA for binding to the target RNA in vitro and for its inhibitory efficiency in vivo.     

Structural analysis of late intermediate complex formed between plasmid ColIb-P9 Inc RNA and its target RNA. How does a single antisense RNA repress translation of two genes at different rates?

The antisense Inc RNA encoded by the IncIalpha ColIb-P9 plasmid replicon controls the translation of repZ encoding the replication initiator and its leader peptide repY at different rates with different mechanisms. The initial loop-loop base pairing between Inc RNA and the target in the repZ mRNA leader inhibits formation of a pseudoknot required for repZ translation. A subsequent base pairing at the 5' leader of Inc RNA blocks repY translation. To delineate the molecular basis for the differential control, we analyzed the intermediate complexes formed between RepZ mRNA and Inc RNA(54), a 5'-truncated Inc RNA derivative. We found that the initial base pairing at the loops transforms into a more stable intermediate complex by its propagation in both directions. The resulting extensive base pairing indicates that the inhibition of the pseudoknot formation is established at this stage. Furthermore, the region of extensive base pairing includes bases different in related plasmids showing different incompatibility. Thus, the observed extensive base pairing is important for determining the incompatibility of the low-copy-number plasmids. We discuss the evolution of replication control systems found in IncIalpha, IncB, and IncFII group plasmids.     

The effect of loop size in antisense and target RNAs on the efficiency of antisense RNA control.

Most natural antisense RNAs display a high degree of secondary structure with stem-loops as their most prominent feature. Mutations affecting the inhibitory activity of these RNAs most often map in or close to loop regions in both the antisense and target RNAs. The primary recognition loops often contain 5-7 unpaired nucleotides. Nucleotide changes in the loops affect the binding rate and, hence, the inhibitory effect on the activity of the target RNA. Here we address the question whether loop sizes affect binding rates between antisense and target RNAs, using the replication control system of plasmid R1 as a model system. By creating a series of loop size mutants we show that loop size alterations have strong effects on the binding rates between the two reactant RNAs in vitro, and that most of the mutations analyzed display corresponding effects on antisense RNA control in vivo. Our data suggest that the three-dimensional structures of antisense and target RNA stem-loops are crucial for determining binding rates. The implications of these results for the design of efficient artificial antisense RNA control systems are discussed.     

Self containment, a property of modular RNA structures, distinguishes microRNAs

RNA molecules will tend to adopt a folded conformation through the pairing of bases on a single strand; the resulting so-called secondary structure is critical to the function of many types of RNA. The secondary structure of a particular substring of functional RNA may depend on its surrounding sequence. Yet, some RNAs such as microRNAs retain their specific structures during biogenesis, which involves extraction of the substructure from a larger structural context, while other functional RNAs may be composed of a fusion of independent substructures. Such observations raise the question of whether particular functional RNA substructures may be selected for invariance of secondary structure to their surrounding nucleotide context. We define the property of self containment to be the tendency for an RNA sequence to robustly adopt the same optimal secondary structure regardless of whether it exists in isolation or is a substring of a longer sequence of arbitrary nucleotide content. We measured degree of self containment using a scoring method we call the self-containment index and found that miRNA stem loops exhibit high self containment, consistent with the requirement for structural invariance imposed by the miRNA biogenesis pathway, while most other structured RNAs do not. Further analysis revealed a trend toward higher self containment among clustered and conserved miRNAs, suggesting that high self containment may be a characteristic of novel miRNAs acquiring new genomic contexts. We found that miRNAs display significantly enhanced self containment compared to other functional RNAs, but we also found a trend toward natural selection for self containment in most functional RNA classes. We suggest that self containment arises out of selection for robustness against perturbations, invariance during biogenesis, and modular composition of structural function. Analysis of self containment will be important for both annotation and design of functional RNAs. A Python implementation and Web interface to calculate the self-containment index are available at http://kim.bio.upenn.edu/software/.     

A small RNA activates CFA synthase by isoform‐specific mRNA stabilization

Small RNAs use a diversity of well‐characterized mechanisms to repress mRNAs, but how they activate gene expression at the mRNA level remains not well understood. The predominant activation mechanism of Hfq‐associated small RNAs has been translational control whereby base pairing with the target prevents the formation of an intrinsic inhibitory structure in the mRNA and promotes translation initiation. Here, we report a translation‐independent mechanism whereby the small RNA RydC selectively activates the longer of two isoforms of cfa mRNA (encoding cyclopropane fatty acid synthase) in Salmonella enterica. Target activation is achieved through seed pairing of the pseudoknot‐exposed, conserved 5′ end of RydC to an upstream region of the cfa mRNA. The seed pairing stabilizes the messenger, likely by interfering directly with RNase E‐mediated decay in the 5′ untranslated region. Intriguingly, this mechanism is generic such that the activation is equally achieved by seed pairing of unrelated small RNAs, suggesting that this mechanism may be utilized in the design of RNA‐controlled synthetic circuits. Physiologically, RydC is the first small RNA known to regulate membrane stability.     

NAR Breakthrough Article: FDF-PAGE: a powerful technique revealing previously undetected small RNAs sequestered by complementary transcripts

Small RNAs, between 18nt and 30nt in length, are a diverse class of non-coding RNAs that mediate a range of cellular processes, from gene regulation to pathogen defense. They guide ribonucleoprotein complexes to their target nucleic acids by Watson–Crick base pairing. We report here that current techniques for small RNA detection and library generation are biased by formation of RNA duplexes. To address this problem, we established FDF-PAGE (fully-denaturing formaldehyde polyacrylamide gel electrophoresis) to prevent annealing of sRNAs to their complement. By applying FDF-PAGE, we provide evidence that both strands of viral small RNA are present in near equimolar ratios, indicating that the predominant precursor is a long double-stranded RNA. Comparing non-denaturing conditions to FDF-PAGE uncovered extensive sequestration of miRNAs in model organisms and allowed us to identify candidate small RNAs under the control of competing endogenous RNAs (ceRNAs). By revealing the full repertoire of small RNAs, we can begin to create a better understanding of small RNA mediated interactions.     

Functional Analysis of the Core Human Immunodeficiency Virus Type 1 Packaging Signal in a Permissive Cell Line

Packaging of type C retrovirus genomic RNAs into budding virions requires a highly specific interaction between the viral Gag precursor and unique cis-acting packaging signals on the full-length RNA genome, allowing the selection of this RNA species from among a pool of spliced viral RNAs and similar cellular RNAs. This process is thought to involve RNA secondary and tertiary structural motifs since there is little conservation of the primary sequence of this region between retroviruses. To confirm RNA secondary structures, which we and others have predicted for this region, disruptive, compensatory, and deletion mutations were introduced into proviral constructs, which were then assayed in a permissive cell line. Disruption of either of two predicted stem-loops was found to greatly reduce RNA encapsidation and replication, whereas compensatory mutations restoring base pairing to these stem-loops had a wild-type phenotype. A GGNGR motif was identified in the loops of three hairpins in this region. Results were consistent with the hypothesis that the process of efficient RNA encapsidation is linked to dimerization. Replication and encapsidation were shown to occur at a reduced rate in the absence of the previously described kissing hairpin motif.     

Antisense RNA regulation in prokaryotes: rapid RNA/RNA interaction facilitated by a general U-turn loop structure

Efficient gene control by antisense RNA requires rapid bi-molecular interaction with a cognate target RNA. A comparative analysis revealed that a YUNR motif (Y=pyrimidine, R=purine) is ubiquitous in RNA recognition loops in antisense RNA-regulated gene systems. The (Y)UNR sequence motif specifies two intraloop hydrogen bonds forming U-turn structures in many anticodon-loops and all T-loops of tRNAs, the hammerhead ribozyme and in other conserved RNA loops. This structure creates a sharp bend in the RNA phosphate-backbone and presents the following three to four bases in a solvent-exposed, stacked configuration providing a scaffold for rapid interaction with complementary RNA. Sok antisense RNA from plasmid R1 inhibits translation of the hok mRNA by preventing ribosome entry at the mok Shine & Dalgarno element. The 5' single-stranded region of Sok-RNA recognizes a loop in the hok mRNA. We show here, that the initial pairing between Sok antisense RNA and its target in hok mRNA occurs with an observed second-order rate-constant of 2 x 10(6) M(-1) s(-1). Mutations that eliminate the YUNR motif in the target loop of hok mRNA resulted in reduced antisense RNA pairing kinetics, whereas mutations maintaining the YUNR motif were silent. In addition, RNA phosphate-backbone accessibility probing by ethylnitrosourea was consistent with a U-turn structure formation promoted by the YUNR motif. Since the YUNR U-turn motif is present in the recognition units of many antisense/target pairs, the motif is likely to be a generally employed enhancer of RNA pairing rates. This suggestion is consistent with the re-interpretation of the mutational analyses of several antisense control systems including RNAI/RNAII of ColE1, CopA/CopT of R1 and RNA-IN/RNA-OUT of IS10.     

Antisense RNA control of gene expression in bacteriophage P22. II. Kinetic mechanism and cation specificity of the pairing reaction.

The bacteriophage P22 sar RNA-ant mRNA pairing reaction was characterized kinetically. The pairing reaction proceeds by a three-step pathway. First, reversible base pairs form between complementary hairpin loops in sar RNA and ant RNA (Kd = 270 nM). Next, stable duplex formation initiates between single-stranded nucleotides in sar RNA and ant RNA; the ant RNA nucleotides are at the bottom of a hairpin stem that is partially accessible. Concomitant unwinding of one sar RNA hairpin and the complementary ant RNA hairpin then occurs, to form a partially paired intermediate (k2 = 12 min(-1). Finally, a complete duplex forms after unwinding of the other sar RNA hairpin and the complementary ant RNA hairpin (k3 = 7 min(-1). Experiments with sar RNA sequence and length variants demonstrate that the precise structures of both sar RNA hairpins affect the kinetic parameters. The pairing reaction is Mg2+-dependent, and shows high specificity for the required cation. Maximal pairing rates are achieved when more than one Mg2+ ion is bound. The cation-dependence and specificity indicate a requirement for Mg2+-dependent tertiary structure.     

Dimer initiation signal of human immunodeficiency virus type 1: its role in partner selection during RNA copackaging and its effects on recombination

Frequent human immunodeficiency virus type 1 (HIV-1) recombination occurs during DNA synthesis when portions of the two copackaged RNAs are used as templates to generate a hybrid DNA copy. Therefore, the frequency of copackaging of genomic RNAs from two different viruses (heterozygous virion formation) affects the generation of genotypically different recombinants. We hypothesized that the selection of copackaged RNA partners is largely determined by Watson-Crick pairing at the dimer initiation signal (DIS), a 6-nucleotide palindromic sequence at the terminal loop of stem-loop 1 (SL1). To test our hypothesis, we examined whether heterozygous virion formation could be encouraged by manipulation of the DIS. Three pairs of viruses were generated with compensatory DIS mutations, designed so that perfect DIS base pairing could only occur between RNAs derived from different viruses, not between RNAs from the same virus. We observed that vector pairs with compensatory DIS mutations had an almost twofold increase in recombination rates compared with wild-type viruses. These data suggest that heterozygous virion formation was enhanced in viruses with compensatory DIS mutations (from 50% to more than 90% in some viral pairings). The role of the SL1 stem in heterozygous virion formation was also tested; our results indicated that the intermolecular base pairing of the stem sequences does not affect RNA partner selection. In summary, our results demonstrate that the Watson-Crick pairing of the DIS is a major determinant in the selection of the copackaged RNA partner, and altering the base pairing of the DIS can change the proportion of heterozygous viruses in a viral population. These results also strongly support the hypothesis that HIV-1 RNA dimers are formed prior to encapsidation.     

Resistance of human hepatitis delta virus RNAs to dicer activity

The endonuclease dicer cleaves RNAs that are 100% double stranded and certain RNAs with extensive but <100% pairing to release approximately 21-nucleotide (nt) fragments. Circular 1,679-nt genomic and antigenomic RNAs of human hepatitis delta virus (HDV) can fold into a rod-like structure with 74% pairing. However, during HDV replication in hepatocytes of human, woodchuck, and mouse origin, no approximately 21-nt RNAs were detected. Likewise, in vitro, purified recombinant dicer gave <0.2% cleavage of unit-length HDV RNAs. Similarly, rod-like RNAs of potato spindle tuber viroid (PSTVd) and avocado sunblotch viroid (ASBVd) were only 0.5% cleaved. Furthermore, when a 66-nt hairpin RNA with 79% pairing, the putative precursor to miR-122, which is an abundant liver micro-RNA, replaced one end of HDV genomic RNA, it was poorly cleaved, both in vivo and in vitro. In contrast, this 66-nt hairpin, in the absence of appended HDV sequences, was >80% cleaved in vitro. Other 66-nt hairpins derived from one end of genomic HDV, PSTVd, or ASBVd RNAs were also cleaved. Apparently, for unit-length RNAs of HDV, PSTVd, and ASBVd, it is the extended structure with <100% base pairing that confers significant resistance to dicer action.     

Aberrant c-myc RNAs of Burkitt's lymphoma cells have longer half-lives.

BL67 and BL18 are Burkitt's lymphoma cell lines with t(8;14) translocations (the breakpoint is in the first exon and first intron, respectively) in which the mu-heavy chain switch region is fused to the c-myc gene in head to head orientation. In both cell lines only aberrant c-myc RNAs are found. BL67 cells contain two c-myc RNA species of 2.4 and 3.5 kb. The 2.4-kb RNA is initiated at several cryptic promoters in the first intron. The 3.5-kb RNA is transcribed from the immunoglobulin heavy chain anti-sense strand across the breakpoint of the translocation into the first exon of the c-myc gene and is then normally spliced using the physiological splice donor and acceptor sites of the c-myc gene. BL18 contains c-myc RNA of 2.4 kb initiated at cryptic promoters in the first intron and additional RNAs of 0.90 kb and 0.74 kb transcribed from the dual c-myc promoters on the reciprocal fragment of the translocation. The cytoplasmic turnover of these RNAs differs significantly from that of the normal c-myc message. The 3.5-kb RNA of BL67 cells and the 0.90-kb and 0.74-kb RNAs of BL18 cells, which are both hybrid molecules consisting of c-myc and immunoglobulin sequences, have a half-life of several hours in contrast to the normal c-myc message with a half-life of 15 min. The aberrant 2.4-kb c-myc RNAs of BL67 and BL18 cells are also more stable than the normal c-myc message and disappear with a half-life of 50 min.(ABSTRACT TRUNCATED AT 250 WORDS)