The cap structure and the poly(A) tail synergistically activate mRNA translation in vivo. Recent work using Saccharomyces cerevisiae spheroplasts and a yeast cell-free translation system revealed that the poly(A) tail can function as an independent promotor for ribosome recruitment, to internal initiation sites within an mRNA. This raises the question of how regulatory upstream open reading frames and translational repressor proteins binding to the 5′ UTR can function, as well as how regulated polyadenylation can support faithful activation of protein synthesis. We investigated the function of the regulatory upstream open reading frame 4 from the yeast GCN 4 gene and the effect of IRP-1 binding to an iron-responsive element introduced into the 5′ UTR of reporter mRNAs. Both manipulations effectively block cap-dependent translation, whereas ribosome recruitment promoted by the poly(A) tail under noncompetitive conditions can efficiently bypass both blocks. We show that the synergistic use of both, the cap structure and the poly-A tail enforced by mRNA competition reinstates the full extent of translational control by both types of 5′ UTR regulatory elements. With a view towards regulated polyadenylation, we studied the function of poly(A) tails of defined length on the translation of capped mRNAs. We find that poly(A) tail elongation increases translational efficiency, particularly under competitive conditions. Our results integrate recent findings on the function of the poly(A) tail into an understanding of translational control.

We previously showed that the deleterious effects from introducing abasic nucleotides in the hammerhead ribozyme core can, in some instances, be relieved by exogenous addition of the ablated base and that the relative ability of different bases to rescue catalysis can be used to probe functional aspects of the ribozyme structure [Peracchi et al., Proc Nat Acad Sci USA 93:11522]. Here we examine rescue at four additional positions, 3, 9, 12 and 13, to probe transition state interactions and to demonstrate the strengths and weaknesses of base rescue as a tool for structure–function studies. The results confirm functional roles for groups previously probed by mutagenesis, provide evidence that specific interactions observed in the ground-state X-ray structure are maintained in the transition state, and suggest formation in the transition state of other interactions that are absent in the ground state. In addition, the results suggest transition state roles for some groups that did not emerge as important in previous mutagenesis studies, presumably because base rescue has the ability to reveal interactions that are obscured by local structural redundancy in traditional mutagenesis. The base rescue results are complemented by comparing the effects of the abasic and phenyl nucleotide substitutions. The results together suggest that stacking of the bases at positions 9, 13 and 14 observed in the ground state is important for orienting other groups in the transition state. These findings add to our understanding of structure–function relationships in the hammerhead ribozyme and help delineate positions that may undergo rearrangements in the active hammerhead structure relative to the ground-state structure. Finally, the particularly efficient rescue by 2-methyladenine at position 13 relative to adenine and other bases suggests that natural base modifications may, in some instance, provide additional stability by taking advantage of hydrophobic interactions in folded RNAs.

The RNA of satellite tobacco necrosis virus (STNV) is a monocistronic messenger that lacks both a cap and a poly(A) tail. Translation of STNV RNA in vitro is promoted by a 120-nt translational enhancer domain (TED) in the 3′-untranslated region. TED also stimulates translation of heterologous mRNAs. In this study, we show that TED stimulates translation of a cat mRNA by increasing translation efficiency to the level of capped mRNA. This stimulatory activity is not impaired by translation through TED. TED stimulates translation efficiency from different positions within the mRNA, varying from the 5′ end to 940 nt downstream of the coding region. Duplication of TED has an additive effect on translation stimulation only when located at both ends of the mRNA. On dicistronic RNAs, TED stimulates translation of both cistrons to the same extent. These data suggest that TED acts primarily by recruiting the translational machinery to the RNA.

To identify new genes involved in 3′-end formation of mRNAs in Saccharomyces cerevisiae, we carried out a screen for synthetic lethal mutants with the conditional poly(A) polymerase allele, pap1-7. Five independent temperature-sensitive mutations called lcp1 to lcp5 (for lethal with conditional pap1 allele) were isolated. Here, we describe the characterization of the essential gene LCP5 which codes for a protein with a calculated molecular mass of 40.8 kD. Unexpectedly, we found that mutations in LCP5 caused defects in pre-ribosomal RNA (pre-rRNA) processing, whereas mRNA 3′-end formation in vitro was comparable to wild-type. Early cleavage steps (denoted A0 to A2) that lead to the production of mature 18S rRNA were impaired. In vivo depletion of Lcp5p also inhibited pre-rRNA processing. As a consequence, mutant and depleted cells showed decreased levels of polysomes compared to wild-type cells. Indirect immunofluorescence indicated a predominant localization of Lcp5p in the nucleolus. In addition, antibodies directed against Lcp5p specifically immunoprecipitated the yeast U3 snoRNA snR17, suggesting that the protein is directly involved in pre-rRNA processing.

Site-specific photo crosslinking has been used to investigate the RNA neighborhood of 16S rRNA positions U788/U789 in Escherichia coli 30S subunits. For these studies, site-specific psoralen (SSP) which contains a sulfhydryl group on a 17 Å side chain was first added to nucleotides U788/U789 using a complementary guide DNA by annealing and phototransfer. Modified RNA was purified from the DNA and unmodified RNA. For some experiments, the SSP, which normally crosslinks at an 8 Å distance, was derivitized with azidophenacylbromide (APAB) resulting in the photoreactive azido moiety at a maximum of 25 Å from the 4′ position on psoralen (SSP25APA). 16S rRNA containing SSP, SSP25APA or control 16S rRNA were reconstituted and 30S particles were isolated. The reconstituted subunits containing SSP or SSP25APA had normal protein composition, were active in tRNA binding and had the usual pattern of chemical reactivity except for increased kethoxal reactivity at G791 and modest changes in four other regions. Irradiation of the derivatized 30S subunits in activation buffer produced several intramolecular RNA crosslinks that were visualized and separated by gel electrophoresis and characterized by primer extension. Four major crosslink sites made by the SSP reagent were identified at positions U561/U562, U920/U921, C866 and U723; a fifth major crosslink at G693 was identified when the SSP25APA reagent was used. A number of additional crosslinks of lower frequency were seen, particularly with the APA reagent. These data indicate a central location close to the decoding region and central pseudoknot for nucleotides U788/U789 in the activated 30S subunit.

The spliceosomal proteins U1A and U2B′′ each use a homologous RRM domain to bind specifically to their respective snRNA targets, U1hpII and U2hpIV, two stem-loops that are similar yet distinct in sequence. Previous studies have shown that binding of U2B′′ to U2hpIV is facilitated by the ancillary protein U2A′, whereas specific binding of U1A to U1hpII requires no cofactor. Here we report that U2A′ enables U2B′′ to distinguish the loop sequence of U2hpIV from that of U1hpII but plays no role in stem sequence discrimination. Although U2A′ can also promote heterospecific binding of U1A to U2hpIV, a much higher concentration of the ancillary protein is required due to the ∼500-fold greater affinity of U2A′ for U2B′′. Additional experiments have identified a single leucine residue in U1A (Leu-44) that is critical for the intrinsic specificity of this protein for the loop sequence of U1hpII in preference to that of U2hpIV. Our data suggest that most of the difference in RNA-binding specificity between U1A and U2B′′ can be accounted for by this leucine residue and by the contribution of the ancillary protein U2A′ to the specificity of U2B′′.

External guide sequences (EGSs) are small RNA molecules which consist of a sequence complementary to a target mRNA and render the target RNA susceptible to degradation by ribonuclease P (RNase P). EGSs were designed to target the mRNA encoding thymidine kinase (TK) of herpes simplex virus 1 for degradation. These EGSs were shown to be able to direct human RNase P to cleave the TK mRNA sequence efficiently in vitro. A reduction of about 80% in the expression level of both TK mRNA and protein was observed in human cells that steadily expressed an EGS, but not in cells that either did not express the EGS or produced a “disabled” EGS which carried a single nucleotide mutation that precluded RNase P recognition. Thus, EGSs may represent novel gene-targeting agents for inhibition of gene expression and antiviral activity.

Escherichia coli rRNA contains 10 pseudouridines of unknown function. They are made by synthases, each of which is specific for one or more pseudouridines. Here we show that the sfhB (yfiI) ORF of E. coli is a pseudouridine synthase gene by cloning, protein overexpression, and reaction in vitro with rRNA transcripts. Gene disruption by miniTn10(cam) insertion revealed that this synthase gene, here renamed rluD, codes for a synthase which is solely responsible in vivo for synthesis of the three pseudouridines clustered in a stem-loop at positions 1911, 1915, and 1917 of 23S RNA. The absence of RluD results in severe growth inhibition. Both the absence of pseudouridine and the growth defect could be reversed by insertion of a plasmid carrying the rluD gene into the mutant cell, clearly linking both effects to the absence of RluD. This is the first report of a major physiological defect due to the deletion of any pseudouridine synthase. Growth inhibition may be due to the lack of one or more of the 23S RNA pseudouridines made by this synthase since pseudouridines 1915 and 1917 are universally conserved and are located in proximity to the decoding center of the ribosome where they could be involved in modulating codon recognition.

Pestiviruses, such as bovine viral diarrhea virus (BVDV), share many similarities with hepatitis C virus (HCV) yet are more amenable to virologic and genetic analysis. For both BVDV and HCV, translation is initiated via an internal ribosome entry site (IRES). Besides IRES function, the viral 5′ nontranslated regions (NTRs) may also contain cis-acting RNA elements important for viral replication. A series of chimeric RNAs were used to examine the function of the BVDV 5′ NTR. Our results show that: (1) the HCV and the encephalomyocarditis virus (EMCV) IRES element can functionally replace that of BVDV; (2) two 5′ terminal hairpins in BVDV genomic RNA are important for efficient replication; (3) replacement of the entire BVDV 5′ NTR with those of HCV or EMCV leads to severely impaired replication; (4) such replacement chimeras are unstable and efficiently replicating pseudorevertants arise; (5) pseudorevertant mutations involve deletion of 5′ sequences and/or acquisition of novel 5′ sequences such that the 5′ terminal 3–4 bases of BVDV genome RNA are restored. Besides providing new insight into functional elements in the BVDV 5′ NTR, these chimeras may prove useful as pestivirus vaccines and for screening and evaluation of anti-HCV IRES antivirals.

Selenocysteine insertion during selenoprotein biosynthesis begins with the aminoacylation of selenocysteine tRNA[Ser]Sec with serine, the conversion of the serine moiety to selenocysteine, and the recognition of specific UGA codons within the mRNA. Selenocysteine tRNA[Ser]Sec exists as two major forms, differing by methylation of the ribose portion of the nucleotide at the wobble position of the anticodon. The levels and relative distribution of these two forms of the tRNA are influenced by selenium in mammalian cells and tissues. We have generated Chinese hamster ovary cells that exhibit increased levels of tRNA[Ser]Sec following transfection of the mouse tRNA[Ser]Sec gene. The levels of selenocysteine tRNA[Ser]Sec in transfectants increased proportionally to the number of stably integrated copies of the tRNA[Ser]Sec gene. Although we were able to generate transfectants overproducing tRNA[Ser]Sec by as much as tenfold, the additional tRNA was principally retained in the unmethylated form. Selenium supplementation could not significantly affect the relative distributions of the two major selenocysteine tRNA[Ser]Sec isoacceptors. In addition, increased levels of tRNA[Ser]Sec did not result in measurable alterations in the levels of selenoproteins, including glutathione peroxidase.

2′-Deoxynucleoside 5′-α-thiotriphosphates have been incorporated randomly, replacing any of the four nucleotides separately and at a low level in Escherichia coli tRNAAsp transcripts. After some tRNAs were charged with the cognate aminoacyl-tRNA synthetase and biotinylated, charged and uncharged tRNAs were separated by binding to Streptavidin. A comparison of the iodine cleavage pattern of charged and uncharged tRNAs indicated positions of 2′-deoxy-phosphorothioate interference with charging. To separate the 2′-deoxy from the phosphorothioate effect, the same sequence of reactions was performed with the corresponding NTPαS. Several positions were identified with a 2′-deoxy or a phosphorothioate effect. tRNAs with single deoxy substitutions at the identified positions were prepared by enzymatic ligation of chemically synthesized halves. The kinetics of charging these tRNAs were determined. The 2′-deoxy effects identified by the interference assay were confirmed, showing a reduction in charging efficiency of between 2.5–6-fold, except for the terminal A76 with a 25-fold reduction. Inspection of the X-ray structure of the tRNA-synthetase complex showed consistency of most of these findings. Critical 2′-deoxy groups are localized mainly on the proposed contact surface with the synthetase or at the interface of the two tRNA domains. The same overall picture emerged for critical phosphorothioates. With the exception of 2′-deoxy-adenosine-containing tRNAs, multiple 2′-deoxy-substituted tRNAs, prepared by ligation of halves, showed a much larger reduction in charging efficiency than the mono-substituted tRNAs, indicating an additive effect.

The 3′ major domain of Escherichia coli 16S rRNA, which occupies the head of the small ribosomal subunit, is involved in several functions of the ribosome. We have used a site-specific crosslinking procedure to gain further insights into the higher-order structure of this domain. Circularly permuted RNAs were used to introduce an azidophenacyl group at specific positions within the 3′ major domain. Crosslinks were generated in a high-ionic strength buffer that has been used for ribosome reconstitution studies and so enables the RNA to adopt a structure recognized by ribosomal proteins. The crosslinking sites were identified by primer extension and confirmed by assessing the mobility of the crosslinked RNA lariats in denaturing polyacrylamide gels. Eight crosslinks were characterized. Among them, one crosslink demonstrates that helix 28 is proximal to the top of helix 34, and two others show that the 1337 region, located in an internal loop at the junction of helices 29, 30, 41, and 42, is proximal to the center of helix 30 and to a segment connecting helix 28 to helix 29. These relationships of vicinity have previously been observed in native 30S subunits, which suggests that the free domain adopts a conformation similar to that within the 30S subunit. Furthermore, crosslinks were obtained in helix 34, which suggest that the upper and lower portions of this helix are in close proximity.