Pleiotropic effect of disrupting a conserved sequence involved in a long-range compensatory interaction in the Drosophila Adh gene

Recent advances in experimental analyses of the evolution of RNA secondary structures suggest a more complex scenario than that typically considered by Kimura's classical model of compensatory evolution. In this study, we examine one such case in more detail. Previous experimental analysis of long-range compensatory interactions between the two ends of Drosophila Adh mRNA failed to fit the classical model of compensatory evolution. To further investigate and verify long-range pairing in Drosophila Adh with respect to models of compensatory evolution and its potential functional role, we introduced site-directed mutations in the Drosophila melanogaster Adh gene. We explore two alternative hypotheses for why previous analysis of long-range compensatory interactions failed to fit the classical model. Specifically, we investigate whether the disruption of a conserved short-range pairing within Adh exon 2 has an effect on Adh expression or if there is a dual functional role of a conserved sequence in the 3'-UTR in both long-range pairing and the negative regulation of Adh expression. We find that a classical result was not observed due to the pleiotropic effect of changing a nucleotide involved in both long-range base pairing and the negative regulation of gene expression.     

Programmed cell death in bacteria: translational repression by mRNA end-pairing

The hok / sok and pnd systems of plasmids R1 and R483 mediate plasmid maintenance by killing plasmid-free cells. Translation of the exceptionally stable hok and pnd mRNAs is repressed by unstable antisense RNAs. The different stabilities of the killer mRNAs and their cognate repressors explain the onset of translation in plasmid-free cells. The full-length hok and pnd mRNAs are inert with respect to translation and antisense RNA binding. We have previously shown that the mRNAs contain two negative translational control elements. Thus, the mRNAs contain upstream anti-Shine–Dalgarno elements that repress translation by shielding the Shine–Dalgarno ele-ments. The mRNAs also contain fold-back-inhibition elements ( fbi  ) at their 3' ends that are required to maintain the inert mRNA configuration. Using genetic complementation, we show that the 3' fbi elements pair with the very 5' ends of the mRNAs. This pairing sets the low rate of 3' exonucleolytical processing, which is required for the accumulation of an activatable pool of mRNA. Unexpectedly, the hok and pnd mRNAs were found to contain translational activators at their 5' ends (termed tac  ). Thus, the fbi elements inhibit translation of the full-length mRNAs by sequestration of the tac elements. The fbi elements are removed by 3' exonucleolytical processing. Mutational ana-lyses indicate that the 3' processing triggers refolding of the mRNA 5' ends into translatable configurations in which the 5' tac elements base pair with the anti-Shine–Dalgarno sequences.     

RNA secondary structure and compensatory evolution

The classic concept of epistatic fitness interactions between genes has been extended to study interactions within gene regions, especially between nucleotides that are important in maintaining pre-mRNA/mRNA secondary structures. It is shown that the majority of linkage disequilibria found within the Drosophila Adh gene are likely to be caused by epistatic selection operating on RNA secondary structures. A recently proposed method of RNA secondary structure prediction based on DNA sequence comparisons is reviewed and applied to several types of RNAs, including tRNA, rRNA, and mRNA. The patterns of covariation in these RNAs are analyzed based on Kimura's compensatory evolution model. The results suggest that this model describes the substitution process in the pairing regions (helices) of RNA secondary structures well when the helices are evolutionarily conserved and thermodynamically stable, but fails in some other cases. Epistatic selection maintaining pre-mRNA/mRNA secondary structures is compared to weak selective forces that determine features such as base composition and synonymous codon usage. The relationships among these forces and their relative strengths are addressed. Finally, our mutagenesis experiments using the Drosophila Adh locus are reviewed. These experiments analyze long-range compensatory interactions between the 5' and 3' ends of Adh mRNA, the different constraints on secondary structures in introns and exons, and the possible role of secondary structures in RNA splicing.     

Antisense masking reveals contributions of mRNA-rRNA base pairing to translation of Gtx and FGF2 mRNAs

We previously showed that a 9-nucleotide sequence from the 5' leader of the Gtx homeodomain mRNA facilitates translation initiation by base pairing to 18S rRNA. These earlier studies tested the Gtx element in isolation; we now assess the physiological relevance of this element in the context of two natural mRNAs that contain this sequence in their 5' leaders, Gtx itself and FGF2 (fibroblast growth factor 2). 2'-O-Methyl-modified RNA oligonucleotides were employed to block mRNA-rRNA base pairing by targeting either the Gtx-binding site in 18S rRNA or Gtx elements in recombinant mRNAs containing the Gtx or FGF2 5' leaders linked to a reporter cistron. Studies in cell-free lysates and transfected COS-7 cells showed that translation of mRNAs containing the Gtx or FGF2 5' leaders was decreased by > 50% when oligonucleotides targeting either the rRNA or mRNA were used. Specificity was demonstrated by showing that translation of the recombinant mRNAs was unaffected by control oligonucleotides. In addition, the specific oligonucleotides did not affect the translation of recombinant mRNAs in which the Gtx elements were mutated. Experiments performed using constructs containing Gtx and FGF2 5' leader and coding sequences ruled out possible effects of the reporter cistron. Furthermore, two-dimensional gel electrophoresis revealed that the oligonucleotides used in this study had little overall effect on the proteomes of cells transfected with these oligonucleotides. This study demonstrates that mRNA-rRNA base pairing affects the expression of two cellular mRNAs and describes a new approach for investigating putative mRNA-rRNA base pairing interactions in mammalian cells.     

Complementarity between the mRNA 5' untranslated region and 18S ribosomal RNA can inhibit translation

In eubacteria, base pairing between the 3' end of 16S rRNA and the ribosome-binding site of mRNA is required for efficient initiation of translation. An interaction between the 18S rRNA and the mRNA was also proposed for translation initiation in eukaryotes. Here, we used an antisense RNA approach in vivo to identify the regions of 18S rRNA that might interact with the mRNA 5' untranslated region (5' UTR). Various fragments covering the entire mouse 18S rRNA gene were cloned 5' of a cat reporter gene in a eukaryotic vector, and translation products were analyzed after transient expression in human cells. For the largest part of 18S rRNA, we show that the insertion of complementary fragments in the mRNA 5' UTR do not impair translation of the downstream open reading frame (ORF). When translation inhibition is observed, reduction of the size of the complementary sequence to less than 200 nt alleviates the inhibitory effect. A single fragment complementary to the 18S rRNA 3' domain retains its inhibitory potential when reduced to 100 nt. Deletion analyses show that two distinct sequences of approximately 25 nt separated by a spacer sequence of 50 nt are required for the inhibitory effect. Sucrose gradient fractionation of polysomes reveals that mRNAs containing the inhibitory sequences accumulate in the fractions with 40S ribosomal subunits, suggesting that translation is blocked due to stalling of initiation complexes. Our results support an mRNA-rRNA base pairing to explain the translation inhibition observed and suggest that this region of 18S rRNA is properly located for interacting with mRNA.     

Do eukaryotic mRNA 5' noncoding sequences base-pair with the 18 S ribosomal RNA 3' terminus?

Protein synthesis initiation on prokaryotic mRNAs involves base-pairing of a site preceding the initiation codon with the 3' terminal sequence of 16 S rRNA. It has been suggested that a similar situation may prevail in eukaryotic mRNAs. This suggestion is not based on experiments, but on observation of complementarities between mRNA 5' noncoding sequences and a conserved sequence near the 18 S rRNA 3' terminus. The hypothesis can be evaluated by comparing the number of potential binding sites found in the 5' noncoding sequences with the number of such sites expected to occur by chance. A method for computing this number is presented. The 5' noncoding sequences contain more binding sites than expected for a random RNA chain, but the same is true for 3' noncoding sequences. The effect can be traced to a clustering of purines and pyrimidines, common to noncoding sequences. In conclusion, a close inspection of the available mRNA sequences does not reveal any indication of a specific base-pairing ability between their 5' noncoding segments and the 18 S rRNA 3' terminus.     

Decay of mRNAs targeted by RISC requires XRN1, the Ski complex, and the exosome

RNA interference (RNAi) is a conserved RNA silencing pathway that leads to sequence-specific mRNA decay in response to the presence of double-stranded RNA (dsRNA). Long dsRNA molecules are first processed by Dicer into 21-22-nucleotide small interfering RNAs (siRNAs). The siRNAs are incorporated into a multimeric RNA-induced silencing complex (RISC) that cleaves mRNAs at a site determined by complementarity with the siRNAs. Following this initial endonucleolytic cleavage, the mRNA is degraded by a mechanism that is not completely understood. We investigated the decay pathway of mRNAs targeted by RISC in Drosophila cells. We show that 5' mRNA fragments generated by RISC cleavage are rapidly degraded from their 3' ends by the exosome, whereas the 3' fragments are degraded from their 5' ends by XRN1. Exosome-mediated decay of the 5' fragments requires the Drosophila homologs of yeast Ski2p, Ski3p, and Ski8p, suggesting that their role as regulators of exosome activity is conserved. Our findings indicate that mRNAs targeted by siRNAs are degraded from the ends generated by RISC cleavage, without undergoing decapping or deadenylation.     

Inhibition of c-erbA mRNA splicing by a naturally occurring antisense RNA.

The rat erbA alpha locus encodes two overlapping mRNAs, alpha 1 and alpha 2, which are identical except for their most 3' exons. alpha 1 mRNA encodes a thyroid hormone receptor, while alpha 2 encodes an altered ligand binding domain of unknown function. Previous studies have shown that the ratio of alpha 1 to alpha 2 is highest in cells expressing a high level of a third RNA, Rev-ErbA alpha mRNA, which is transcribed in the opposite direction and is complementary to alpha 2 but not alpha 1 mRNA. It was hypothesized that base pairing with Rev-ErbA alpha blocks splicing of alpha 2 mRNA, thereby favoring formation of the non-overlapping alpha 1. To test this model, a system was developed in which alpha 2 pre-mRNAs were accurately spliced in vitro. Splicing was inhibited by the addition of a 5-fold excess of antisense RNAs containing the 3' end of Rev-ErbA alpha mRNA. Both an antisense RNA extending across the 3' splice site and a shorter RNA complementary only to exon sequences efficiently blocked splicing. However, splicing was only inhibited by complementary RNAs. These observations are consistent with a mechanism in which base pairing with a complementary RNA regulates alternative processing of alpha 1 and alpha 2 mRNAs.     

Long-range RNA-RNA interactions circularize the dengue virus genome

Secondary and tertiary RNA structures present in viral RNA genomes play essential regulatory roles during translation, RNA replication, and assembly of new viral particles. In the case of flaviviruses, RNA-RNA interactions between the 5' and 3' ends of the genome have been proposed to be required for RNA replication. We found that two RNA elements present at the ends of the dengue virus genome interact in vitro with high affinity. Visualization of individual molecules by atomic force microscopy revealed that physical interaction between these RNA elements results in cyclization of the viral RNA. Using RNA binding assays, we found that the putative cyclization sequences, known as 5' and 3' CS, present in all mosquito-borne flaviviruses, were necessary but not sufficient for RNA-RNA interaction. Additional sequences present at the 5' and 3' untranslated regions of the viral RNA were also required for RNA-RNA complex formation. We named these sequences 5' and 3' UAR (upstream AUG region). In order to investigate the functional role of 5'-3' UAR complementarity, these sequences were mutated either separately, to destroy base pairing, or simultaneously, to restore complementarity in the context of full-length dengue virus RNA. Nonviable viruses were recovered after transfection of dengue virus RNA carrying mutations either at the 5' or 3' UAR, while the RNA containing the compensatory mutations was able to replicate. Since sequence complementarity between the ends of the genome is required for dengue virus viability, we propose that cyclization of the RNA is a required conformation for viral replication.     

Chloroplast mRNA 3'' end processing requires a nuclear-encoded RNA-binding protein.

The protein coding regions of plastid mRNAs in higher plants are generally flanked by 3' inverted repeat sequences. In spinach chloroplast mRNAs, these inverted repeat sequences can fold into stem-loop structures and serve as signals for the correct processing of the mature mRNA 3' ends. The inverted repeat sequences are also required to stabilize 5' upstream mRNA segments, and interact with chloroplast protein in vitro. To dissect the molecular components involved in chloroplast mRNA 3' end processing and stability, a spinach chloroplast protein extract containing mRNA 3' end processing activity was fractionated by FPLC and RNA affinity chromatography. The purified fraction consisted of several proteins and was capable of processing the 3' ends of the psbA, rbcL, petD and rps14 mRNAs. This protein fraction was enriched for a 28 kd RNA-binding protein (28RNP) which interacts with both the precursor and mature 3' ends of the four mRNAs. Using specific antibodies to this protein, the poly(A) RNA-derived cDNA for the 28RNP was cloned and sequenced. The predicted amino acid sequence for the 28RNP reveals two conserved RNA-binding domains, including the consensus sequences RNP-CS1 and CS2, and a novel acidic and glycine-rich N-terminal domain. The accumulation of the nuclear-encoded 28RNP mRNA and protein are developmentally regulated in spinach cotyledons, leaves, root and stem, and are enhanced during light-dependent chloroplast development. The general correlation between accumulation of the 28RNP and plastid mRNA during development, together with the result that depletion of the 28RNP from the chloroplast protein extract interferes with the correct 3' end processing of several chloroplast mRNAs, suggests that the 28RNP is required for plastid mRNA 3' end processing and/or stability.