The trpRNA-binding Attenuation Protein (TRAP) from Bacillus subtilis binds a series of GAG and UAG repeats separated by 2–3 nonconserved spacer nucleotides in trp leader mRNA. To identify chemical groups on the RNA required for stability of the TRAP–RNA complex, we introduced several different nucleoside analogs into each pentamer of the RNA sequence 5′-(UAGCC)-3′ repeated 11 times and measured their effect on the TRAP–RNA interaction. Deoxyribonucleoside substitutions revealed that a 2′-hydroxyl group (2′-OH) is required only on the guanosine occupying the third residue of the RNA triplets for high-affinity binding to TRAP. The remaining hydroxyl groups are dispensable. Base analog substitutions identified all of the exocyclic functional groups and N1 nitrogens of adenine and guanine in the second and third nucleotides, respectively, of the triplets as being involved in binding TRAP. In contrast, none of the substitutions made in the first residue caused any detectable changes in affinity, indicating that elements of these bases are not necessary for complex formation and stability. Studies using abasic nucleotides in the first residue of the triplets and in the two spacer residues confirmed that the majority of the specificity and stability of the TRAP–RNA complex is provided by the AG dinucleotide of the triplet repeats. In addition to direct effects on binding, we demonstrate that the N7-nitrogen of adenosine and guanosine in UAG triplet and the 2′-OHs of (UAGCC)11 RNA are involved in the formation of an as yet undetermined structure that interferes with TRAP binding.

Localization of Paracentrotus lividus bep maternal mRNAs at the animal pole occurs by association with the cytoskeleton and involves a 54-kDa protein, called LP54, that is able to bind to the 3′ untranslated regions (UTRs) of bep mRNAs. We describe here the isolation and purification of this protein. Antibodies raised against purified LP54 allowed us to establish its localization in P. lividus eggs and embryos. This localization coincides with the mRNAs with which it is associated, that is, the animal pole in the egg, and, after fertilization, the regions derived from this part of the egg, and finally the oral ectoderm of the pluteus. Association with the cytoskeleton was shown by the copurification of LP54 in a microtubule preparation. Involvement in bep mRNA localization was demonstrated by microinjection of anti-LP54 antibodies in P. lividus eggs, which caused alteration of spatial distribution of bep3 mRNA.

The mRNA surveillance system is known to rapidly degrade aberrant mRNAs that contain premature termination codons in a process referred to as nonsense-mediated decay. A second class of aberrant mRNAs are those wherein the 3′ UTR is abnormally extended due to a mutation in the polyadenylation site. We provide several observations that these abnormally 3′-extended mRNAs are degraded by the same machinery that degrades mRNAs with premature nonsense codons. First, the decay of the 3′-extended mRNAs is dependent on the same decapping enzyme and 5′-to-3′ exonuclease. Second, the decay is also dependent on the proteins encoded by the UPF1, UPF2, and UPF3 genes, which are known to be specifically required for the rapid decay of mRNAs containing nonsense codons. Third, the ability of an extended 3′ UTR to trigger decay is prevented by stabilizing sequences within the PGK1 coding region that are known to protect mRNAs from the rapid decay induced by premature nonsense codons. These results indicate that the mRNA surveillance system plays a role in degrading abnormally extended 3′ UTRs. Based on these results, we propose a model in which the mRNA surveillance machinery degrades aberrant mRNAs due to the absence of the proper spatial arrangement of the translation-termination codon with respect to the 3′ UTR element as defined by the utilization of a polyadenylation site.

The inherent chemical instability of RNA under physiological conditions is primarily due to the spontaneous cleavage of phosphodiester linkages via intramolecular transesterification reactions. Although the protonation state of the nucleophilic 2′-hydroxyl group is a critical determinant of the rate of RNA cleavage, the precise geometry of the chemical groups that comprise each internucleotide linkage also has a significant impact on cleavage activity. Specifically, transesterification is expected to be proportional to the relative in-line character of the linkage. We have examined the rates of spontaneous cleavage of various RNAs for which the secondary and tertiary structures have previously been modeled using either NMR or X-ray crystallographic data. Rate constants determined for the spontaneous cleavage of different RNA linkages vary by almost 10,000-fold, most likely reflecting the contribution that secondary and tertiary structures make towards the overall chemical stability of RNA. Moreover, a correlation is observed between RNA cleavage rate and the relative in-line fitness of each internucleotide linkage. One linkage located within an ATP-binding RNA aptamer is predicted to adopt most closely the ideal conformation for in-line attack. This linkage has a rate constant for transesterification that is ∼12-fold greater than is observed for an unconstrained linkage and was found to be the most labile among a total of 136 different sites examined. The implications of this relationship for the chemical stability of RNA and for the mechanisms of nucleases and ribozymes are discussed.

We report a general method of measuring the complexity of SELEX pools. In analogy to measurements of genome size by C0t analysis, the complexity of a SELEX pool is measured by determining the reannealing rate of its double-stranded PCR product. We applied this technique to study the selection dynamics of a recently reported SELEX to neutrophil elastase. We found that the number of sequences decreased from 107 in round 6 to ∼60 by round 15, the final round. The intermediate rounds are a mixture of a high abundance/low complexity pool with a low abundance/high complexity pool. As the SELEX progresses, the former pool expands at the expense of the latter. This technique should be useful for studying and optimizing SELEX dynamics, as well as for monitoring the progress of SELEX experiments.

The mammalian Alu domain of the signal recognition particle (SRP) consists of a heterodimeric protein SRP9/14 and the Alu portion of 7SL RNA and comprises the elongation arrest function of the particle. To define the domain in Saccharomyces cerevisiae SRP that is homologous to the mammalian Alu domain [Alu domain homolog in yeast (Adhy)], we examined the assembly of a yeast protein homologous to mammalian SRP14 (Srp14p) and scR1 RNA. Srp14p binds as a homodimeric complex to the 5′ sequences of scR1 RNA. Its minimal binding site consists of 99 nt (Adhy RNA), comprising a short hairpin structure followed by an extended stem. As in mammalian SRP9/14, the motif UGUAAU present in most SRP RNAs is part of the Srp14p binding sites as shown by footprint and mutagenesis studies. In addition, certain basic amino acid residues conserved between mammalian SRP14 and Srp14p are essential for RNA binding in both proteins. These findings confirm the common ancestry of the yeast and the mammalian components and indicate that Srp14p together with Adhy RNA represents the Alu domain homolog in yeast SRP that may comprise its elongation arrest function. Despite the similarities, Srp14p selectively recognizes only scR1 RNA, revealing substantial changes in RNA–protein recognition as well as in the overall structure of the complex. The alignment of the three yeast SRP RNAs known to date suggests a common structure for the putative elongation arrest domain of all three organisms.

In established methods for analyzing ribozyme kinetics, radiolabeled RNA substrates are primarily used. Each data point requires the cumbersome sampling, gel electrophoretic separation, and quantitation of reaction products, apart from the continuous loss of substrate by radioactive decay. We have used stable, double fluorescent end-labeled RNA substrates. Fluorescence of one fluorophore is quenched by intramolecular energy transfer (FRET). Upon substrate cleavage, both dyes become separated in two RNA products and fluorescence is restored. This can be followed in real time and ribozyme reactions can be analyzed under multiple (substrate excess) and under single (ribozyme excess) turnover conditions. A detailed comparison of unlabeled, single, and double fluorescent-labeled RNAs revealed moderate kinetic differences. Results with two systems, hammerhead ribozymes in I/II (small ribozyme, large substrate) and in I/III format (large ribozyme, small substrate), are reported.

Ribosome-inactivating proteins (RIPs) are RNA-N-glycosidases widely present in plants that depurinate RNA in ribosomes at a specific universally conserved position, A4324, in the rat 28S rRNA. A small group of RIPs (cofactor-dependent RIPs) require ATP and tRNA to reach maximal activity on isolated ribosomes. Among cofactor-dependent RIPs, gelonin is specifically and uniquely stimulated by tRNATrp. The active species are avian (chicken) and mammalian (beef, rat, and rabbit) tRNATrp, whereas yeast tRNATrp is completely devoid of stimulating activity. In the present article, bovine and yeast tRNATrp with unmodified bases were prepared by assembly of the corresponding genes from synthetic oligonucleotides followed by PCR and T7 RNA polymerase transcription of the amplified products. The two synthetic tRNAs were fully active (bovine) or inactive (yeast) as the wild-type tRNAs. Construction of chimeric tRNATrp transcripts identified the following bovine nucleotides as recognition elements for gelonin-stimulating activity: G26 and bp G12-C23 in the D arm and G57, A59, and bp G51-C63 and U52-A62 in the T arm. Among single-stranded nucleotides, A59 has a prominent role, but full expression of the gelonin-stimulating activity requires an extensive cooperation between nucleotides in both arms.

Posttranscriptional silencing of basic β-1,3-glucanase genes in the tobacco line T17 is manifested by reduced transcript levels of the gn1 transgene and homologous, endogenous basic β-1,3-glucanase genes. An RNA ligation-mediated rapid amplification of cDNA ends (RLM-RACE) technique was used to compare the 3′ termini of gn1 RNAs present in expressing (hemizygous and young homozygous) and silenced (mature homozygous) T17 plants. Full-length, polyadenylated gn1 transcripts primarily accumulated in expressing plants, whereas in silenced T17 plants, mainly 3′-truncated, nonpolyadenylated gn1 RNAs were detected. The relative abundance of these 3′-truncated gn1 RNA species gradually increased during the establishment of silencing in homozygous T17 plants. Similar 3′-truncated, nonpolyadenylated gn1 RNA products were observed in an independent case of β-1,3-glucanase posttranscriptional gene silencing. This suggests that these 3′-truncated gn1 RNAs are a general feature of tobacco plants showing posttranscriptional silencing of the gn1 transgene.

Internal initiation of translation is promoted by internal ribosome entry site (IRES) cis-acting elements. Using transcripts that correspond to the structural domains of the foot-and-mouth disease virus (FMDV) IRES, we have identified RNA–RNA interactions between separated domains (1–2, 3, 4–5, or HH) of the IRES structure. All the assayed domains were able to interact with the full-length IRES as well as with domain 3, although to a different extent, with the most efficient interactions being those occurring between domains 3 and 4–5, and domains 3 and 1–2. RNA–RNA complexes were stable over 1 h of incubation at 37 °C, and depended on Mg2+ and RNA concentration. Neither the antisense domain 1–2 nor tRNA interacted with domain 3, providing experimental evidence of the specificity for the sense strand of the IRES sequence. Additionally, domain 1–2 did not interact with 4–5, leading to the suggestion that domain 3 acts as a scaffold structure where the other domains bind. The thermal disassociation profile of these complexes indicated different strength in these interactions. Whereas 50% of the complexes between domains 3 and 4–5 were destabilized at 45 °C, those formed by domain 1–2 and 3 required temperatures higher than 51 °C. Efficient self-dimerization of domains 3 and 4–5 was found in the absence of other transcripts. Formation of domain 3 homodimer competed with formation of heterocomplexes with other domains, and conversely, domain 3 homodimers were competed out by the presence of the other domains. RNA interactions were also observed at physiological concentrations of Mg2+ and K1+. The identification of the RNA–RNA complexes reported here provide direct experimental evidence of tertiary interactions within IRES elements.

The crystal structure of the RNA duplex [r(CGUGAUCG)dC]2 has been solved at a resolution of 0.97 Å. The model has been refined to R-work and R-free of 14.88% and 19.54% for 23,838 independent reflections. The base-pairing scheme forces the 5′-rC to be excluded from the helix and to be disordered. In the crystals, the sequence promotes the formation of two GoU wobble pairs that cluster around a crystallographic threefold axis in two different ways. In the first contact type, the GoU pairs are exclusively surrounded by water molecules, whereas in the other contact type, the three amino groups of the guanine residues of the symmetry-related GoU pairs trap a sulfate ion. This work provides the first example of the interaction of a GoU pair with a sulfate ion in a helical context. Despite the negative charge on the polynucleotide backbone, the guanine amino N2 is able to attract negatively charged groups that could, in the folding of complex RNA molecules, belong to a negative phosphodiester group from a neighboring strand and, in a RNA–protein complex, to a negative carboxyl group of an aspartate or glutamate side chain.