Translational control of maturation-protein synthesis in phage MS2: a role for the kinetics of RNA folding?

The gene for the maturation (A) protein of the single-stranded RNA coliphage MS2 is preceded by an untranslated leader of 130 nt. Secondary structure of the leader was deduced by phylogenetic comparison and by probing with enzymes and chemicals. The RNA folds into a cloverleaf, i.e., three stem-loop structures enclosed by a long-distance interaction (LDI). This LDI is essential for translational control. Its 3'moiety contains the Shine-Dalgarno region of the A-protein gene, whereas its complement is located 80 nt upstream, i.e., about 30 nt from the 5'-terminus of the RNA chain. Mutational analysis shows that this base pairing represses expression of the A-protein gene. We present a model in which translational starts can only take place on nonequilibrated RNA, in which base pairing between the complementary regions has not yet taken place. We suggest that this pairing is kinetically delayed by the intervening sequence, which contains the three hairpins of the cloverleaf. The model is mainly based on the observation that reducing the length of the intervening sequence reduces expression, whereas increasing the length has the opposite effect. In addition, further stabilization of the LDI by a stronger base pair does not lead to a decrease in A-protein synthesis. Such a decrease is predicted to occur if translation would be controlled by the equilibrium structure of the leader RNA. These and other observations fit a kinetic model of translational control by RNA folding.     

Structural and combinatorial constraints on base pairing in large nucleotide sequences

In this paper we discuss the constraints and combinatorial problems of folding long RNA and single stranded DNA molecules into base paired structures. A computer code FOLD-A was designed to perform base pairing foldings of very long sequence chains and search for low energy configurations. The logic of the FOLD-A algorithm is described in some detail. The applications of FOLD-A to the A-protein gene of MS2 and the whole genome of the phi X 174 phage with over 5300 bases are discussed in the accompanying paper.     

The dimer initiation site hairpin mediates dimerization of the human immunodeficiency virus, type 2 RNA genome

The untranslated leader of retroviral RNA genomes encodes multiple structural signals that are critical for virus replication. In the human immunodeficiency virus, type 1 (HIV-1) leader, a hairpin structure with a palindrome-containing loop is termed the dimer initiation site (DIS), because it triggers in vitro RNA dimerization through base pairing of the loop-exposed palindromes (kissing loops). Controversy remains regarding the region responsible for HIV-2 RNA dimerization. Different studies have suggested the involvement of the transactivation region, the primer binding site, and a hairpin structure that is the equivalent of the HIV-1 DIS hairpin. We have performed a detailed mutational analysis of the HIV-2 leader RNA, and we also used antisense oligonucleotides to probe the regions involved in dimerization. Our results unequivocally demonstrate that the DIS hairpin is the main determinant for HIV-2 RNA dimerization. The 6-mer palindrome sequence in the DIS loop is essential for dimer formation. Although the sequence can be replaced by other 6-mer palindromes, motifs that form more than two A/U base pairs do not dimerize efficiently. The inability to form stable kissing-loop complexes precludes formation of dimers with more extended base pairing. Structure probing of the DIS hairpin in the context of the complete HIV-2 leader RNA suggests a 5-base pair elongation of the DIS stem as it is proposed in current RNA secondary structure models. This structure is supported by phylogenetic analysis of leader RNA sequences from different viral isolates, indicating that RNA genome dimerization occurs by a similar mechanism for all members of the human and simian immunodeficiency viruses.     

Random removal of inserts from an RNA genome: selection against single-stranded RNA.

We have monitored the evolution of insertions in two MS2 RNA regions of known secondary structure where coding pressure is negligible or absent. Base changes and shortening of the inserts proceed until the excessive nucleotides can be accommodated in the original structure. The stems of hairpins can be dramatically extended but the loops cannot, revealing natural selection against single-stranded RNA. The 3' end of the MS2 A-protein gene forms a small hairpin with an XbaI sequence in the loop. This site was used to insert XbaI fragments of various sizes. Phages produced by these MS2 cDNA clones were not wild type, nor had they retained the full insert. Instead, every revertant phage had trimmed the insert in a different way to leave a four- to seven-membered loop to the now extended stem. Similar results were obtained with inserts in the 5' untranslated region. The great number of different revertants obtained from a single starting mutant as well as sequence inspection of the crossover points suggest that the removal of redundant RNA occurs randomly. The only common feature among all revertants appears the potential to form a hairpin with a short loop, suggesting that single-stranded RNA negatively affects the viability of the phage. To test this hypothesis, we introduced XbaI fragments of 34 nucleotides that could form either a long stem with a small loop or a short stem with a large loop (26 nucleotides). The base-paired inserts were perfectly maintained for many generations, whereas the unpaired versions were quickly trimmed back to reduce the size of the loop. These data confirm that single-stranded RNA adversely affects phage fitness and is strongly selected against. The repair of the RNA genome that we describe here appears as the result of random recombination. Of the plethora of recombinants, only those able to adopt a base-paired structure survive. The frequency with which our inserts are removed seems higher than measured by others for small inserts in a reading frame in Q beta RNA. To account for this higher frequency, we suggest models in which the single-stranded nature of our inserts induces random recombination at the site of the insertion.     

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.     

A Short Sequence Motif in the 5′ Leader of the HIV-1 Genome Modulates Extended RNA Dimer Formation and Virus Replication

The 5′ leader of the HIV-1 RNA genome encodes signals that control various steps in the replication cycle, including the dimerization initiation signal (DIS) that triggers RNA dimerization. The DIS folds a hairpin structure with a palindromic sequence in the loop that allows RNA dimerization via intermolecular kissing loop (KL) base pairing. The KL dimer can be stabilized by including the DIS stem nucleotides in the intermolecular base pairing, forming an extended dimer (ED). The role of the ED RNA dimer in HIV-1 replication has hardly been addressed because of technical challenges. We analyzed a set of leader mutants with a stabilized DIS hairpin for in vitro RNA dimerization and virus replication in T cells. In agreement with previous observations, DIS hairpin stability modulated KL and ED dimerization. An unexpected previous finding was that mutation of three nucleotides immediately upstream of the DIS hairpin significantly reduced in vitro ED formation. In this study, we tested such mutants in vivo for the importance of the ED in HIV-1 biology. Mutants with a stabilized DIS hairpin replicated less efficiently than WT HIV-1. This defect was most severe when the upstream sequence motif was altered. Virus evolution experiments with the defective mutants yielded fast replicating HIV-1 variants with second site mutations that (partially) restored the WT hairpin stability. Characterization of the mutant and revertant RNA molecules and the corresponding viruses confirmed the correlation between in vitro ED RNA dimer formation and efficient virus replication, thus indicating that the ED structure is important for HIV-1 replication.     

The HIV-1 leader RNA conformational switch regulates RNA dimerization but does not regulate mRNA translation

The untranslated leader RNA is the most conserved part of the human immunodeficiency virus type I (HIV-1) genome. It contains many regulatory motifs that mediate a variety of steps in the viral life cycle. Previous work showed that the full-length leader RNA can adopt two alternative structures: a long distance interaction (LDI) and a branched multiple-hairpin (BMH) structure. The BMH structure exposes the dimer initiation site (DIS) hairpin, whereas this motif is occluded in the LDI structure. Consequently, these structures differ in their capacity to form RNA dimers in vitro. The BMH structure is dimerization-competent, due to DIS hairpin formation, but also presents the splice donor (SD) and RNA packaging (Psi) hairpins. In the LDI structure, an extended RNA packaging (Psi(E)) hairpin is folded, which includes the splice donor site and gag coding sequences. The gag initiation codon is engaged in a long distance base pairing interaction with sequences in the upstream U5 region in the BMH structure, thus forming the evolutionarily conserved U5-AUG duplex. Therefore, the LDI-BMH equilibrium may affect not only the process of RNA dimer formation but also translation initiation. In this study, we designed mutations in the 3'-terminal region of the leader RNA that alter the equilibrium of the LDI-BMH structures. The mutant leader RNAs are affected in RNA dimer formation, but not in their translation efficiency. These results indicate that the LDI-BMH status does not regulate HIV-1 RNA translation, despite the differential presentation of the gag initiation codon in both leader RNA structures.     

Substrate shape specificity of E coli RNase P ribozyme is dependent on the concentration of magnesium ion

The bacterial RNase P ribozyme can accept a hairpin RNA with CCA-3' tag sequence as well as a cloverleaf pre-tRNA as substrate in vitro, but the details are not known. By switching tRNA structure using an antisense guide DNA technique, we examined the Escherichia coli RNase P ribozyme specificity for substrate RNA of a given shape. Analysis of the RNase P reaction with various concentrations of magnesium ion revealed that the ribozyme cleaved only the cloverleaf RNA at below 10 mM magnesium ion. At 10 mM magnesium ion or more, the ribozyme also cleaved a hairpin RNA with a CCA-3' tag sequence. At above 20 mM magnesium ion, cleavage site wobbling by the enzyme in tRNA-derived hairpin occurred, and the substrate specificity of the enzyme became broader. Additional studies using another hairpin substrate demonstrated the same tendency. Our data strongly suggest that raising the concentration of metal ion induces a conformational change in the RNA enzyme.     

The complete nucleotide sequence of the group II RNA coliphage GA

The complete nucleotide sequence of the RNA coliphage GA, a group II phage, is presented. The entire genome comprises 3466 bases. Three large open reading frames were identified, which correspond to the maturation protein gene (390 amino acids), the coat protein gene (129 amino acids) and the replicase beta-subunit protein gene (531 amino acids). In addition, untranslated regions occur at the 5' (135 bases) and 3' (122 bases) ends of the molecule. Two intercistronic untranslated regions occur between the cistrons for the maturation and coat proteins, and between the coat and beta-subunit proteins. We have compared the nucleotide sequence of GA RNA with the published sequence of MS2 RNA, and show that they are related. The comparative structures of two important regulatory regions are presented; the coat protein binding site which is involved in translational repression of the replicase beta-subunit protein gene, and a hairpin in a region proximal to the lysis protein gene.     

Structure of an RNA hairpin from HRV-14.

The 5' noncoding region of the picornaviral genome begins with a cloverleaf which is required for viral replication, due at least in part to an interaction with the viral RNA polymerase as part of a fusion with the predominant viral protease. The necessary region of the cloverleaf has previously been narrowed to a highly conserved stem-loop. The solution structure of a 14-nucleotide RNA hairpin, which is part of the conserved stem-loop from human rhinovirus isotype 14, is presented here. The secondary structure of the hairpin is identical to predictions: a five base pair stem is bounded by a triloop with sequence UAU. However, the fold of the triloop is novel, with stacking of the second loop base onto the closing base pair of the stem, and deviations from A form geometry are introduced into the stem regions bordering the triloop, particularly on the 3' side. These deviations and the associated triloop structure could help to explain the distinct sequence conservation and mutational analysis data observed for the stem region of the hairpin, as compared to a second sequentially similar stem in the intact stem-loop.     

A correlation between N2-dimethylguanosine presence and alternate tRNA conformers.

Even though the evolutionary conservation of the cloverleaf model is strongly suggestive of powerful constraints on the secondary structure of functional tRNAs, some mitochondrial tRNAs cannot be folded into this form. From the optimal base pairing pattern of these recalcitrant tRNAs, structural correlations between the length of the anticodon stem and the lengths of connector regions between the two helical domains, formed by the coaxial stacking of the anticodon and D-stems and the acceptor and T-stems, have been derived and used to scan the tRNA and tRNA gene database. We show here that some cytosolic tRNA gene sequences that are compatible with the cloverleaf model can also be folded into patterns proposed for the unusual mitochondrial tRNAs. Furthermore, the ability to be folded into these atypical structures correlates in the mature RNA sequences with the presence of dimethylguanosine, whose role may be to prevent the unusual mitochondrial tRNA pattern folding.